,image_name,pub_number,title,figs_norm,short_description,long_description,short_description_token_count,long_description_token_count,draft_class,cpc_class,relevant_terms,associated_claims,compound,references 0,EP_3500211_B1 (1).png,EP3500211B1,CASE FOR DENTAL TREATMENT DEVICE,['FIG2'],"['FIG2 depicts a perspective view of an outer surface of a first (e g , bottom) panel of the case when the case is in a closed position, according to an embodiment']","['FIG2 depicts a perspective view of the outer surface of the bottom panel 210A of the case 200 when the case is 200 in the closed position, according to an embodiment. The bottom concave portion 230A formed in the inner surface of the bottom panel 210A may form or be referred to as a bottom convex portion 240A relative to the outer surface of the bottom panel 210A. More particularly, as the depth of the bottom concave portion 230A formed in the inner surface of the bottom panel 210A increases, the height/elevation of the bottom convex portion 240A of the outer surface of the bottom panel 210A also increases. As a result, the bottom convex portion 240A may have a shape that resembles the shape of the bottom of the dental treatment device 100. More particularly, the wall(s) defining the bottom convex portion 240A may include a tray-accommodating portion 242A and a handle accommodating portion 244A. The tray-accommodating portion 242A may be substantially crescent-shaped. A remainder of the outer surface of the bottom panel 210A may be a substantially planar portion 245A.', 'One or more first openings (one is shown: 250A) may be formed through the bottom panel 210A. The first opening 250A may extend through the substantially planar portion 246A (e.g., between the outline formed by the protrusions 248A). The first opening 250A may provide a path of fluid communication between the internal volume of the case 200 and an exterior of the case 200. The path may allow liquid (e.g., water, whitening composition, saliva, etc.) in the bottom convex portion 240A to drain therethrough and air to circulate therethrough. Also shown in FIG2, when the case 200 is in the closed position, the tapered sides 224A, 223B of the first and second tabs 220A, 220B may be aligned.']",35,340,perspective view,A,"[{'element_identifier': '200', 'terms': ['case', 'cases']}]","['1. A case (200, 500, 900) for a dental treatment device (100), comprising: a bottom panel (210A, 510A, 910A) having an inner surface and an outer surface, wherein the inner surface of the bottom panel defines a first concave portion (230A), wherein a wall defining the first concave portion (230A) is sloped or curved such that the depth of the first concave portion (230A) increases gradually, and wherein the first concave portion (230A) forms a corresponding first convex portion (240A) of the outer surface of the bottom panel (210A, 510A, 910A); a top panel (210B, 910B) having an inner surface and an outer surface, wherein the inner surface of the top panel defines a second concave portion (230B), wherein the second concave portion (230B) forms a corresponding second convex portion (240B) of the outer surface of the top panel (210B, 910B), wherein the second convex portion (540B) includes a curvature (546B), and wherein the second convex portion (540B) does not have any substantially planar portion; and a hinge (215) that joins the bottom panel (210A, 510A, 910A) and the top panel (210B, 910B) and allows the bottom panel (210A, 510A, 910A) and the top panel (210B, 910B) to pivot between an open position and a closed position; wherein the first concave portion (230A) and the second concave portion (230B) define an internal volume for storing the dental treatment device (100) when the bottom panel (210A, 510A, 910A) and the top panel (210B, 910B) are in the closed position, and wherein a wall defining the first convex portion (240A) includes a crescent-shaped tray accommodating portion (242A) and a handle accommodating portion (244A).']",False,"['200', '10']" 1,EP_3500211_B1 (2).png,EP3500211B1,CASE FOR DENTAL TREATMENT DEVICE,['FIG3'],"['FIG3 depicts a perspective view of an outer surface of a second (e g , top) panel of the case when the case is in the closed position, according to an embodiment']","['FIG3 depicts a perspective view of the outer surface of the top panel 210B of the case 200 when the case 200 is in the closed position, according to an embodiment. The top concave portion 230B formed in the inner surface of the top panel 210B may form a top convex portion 240B relative to the outer surface of the top panel 210B. More particularly, as the depth of the top concave portion 230B formed in the inner surface of the top panel 210B increases, the height/elevation of the top convex portion 240B of the outer surface of the top panel 210B also increases. As a result, the top convex portion 240B may have a shape that resembles the shape of the top of the dental treatment device 100. More particularly, the wall(s) defining the top convex portion 240B may include a tray-accommodating portion 242B and a handle accommodating portion 244B. The tray-accommodating portion 242B may be substantially crescent-shaped. A remainder of the outer surface of the top panel 210B may be a substantially planar portion 245B.']",35,195,perspective view,A,"[{'element_identifier': '200', 'terms': ['case', 'cases']}]","['1. A case (200, 500, 900) for a dental treatment device (100), comprising: a bottom panel (210A, 510A, 910A) having an inner surface and an outer surface, wherein the inner surface of the bottom panel defines a first concave portion (230A), wherein a wall defining the first concave portion (230A) is sloped or curved such that the depth of the first concave portion (230A) increases gradually, and wherein the first concave portion (230A) forms a corresponding first convex portion (240A) of the outer surface of the bottom panel (210A, 510A, 910A); a top panel (210B, 910B) having an inner surface and an outer surface, wherein the inner surface of the top panel defines a second concave portion (230B), wherein the second concave portion (230B) forms a corresponding second convex portion (240B) of the outer surface of the top panel (210B, 910B), wherein the second convex portion (540B) includes a curvature (546B), and wherein the second convex portion (540B) does not have any substantially planar portion; and a hinge (215) that joins the bottom panel (210A, 510A, 910A) and the top panel (210B, 910B) and allows the bottom panel (210A, 510A, 910A) and the top panel (210B, 910B) to pivot between an open position and a closed position; wherein the first concave portion (230A) and the second concave portion (230B) define an internal volume for storing the dental treatment device (100) when the bottom panel (210A, 510A, 910A) and the top panel (210B, 910B) are in the closed position, and wherein a wall defining the first convex portion (240A) includes a crescent-shaped tray accommodating portion (242A) and a handle accommodating portion (244A).']",False,"['200', '11']" 2,EP_3500211_B1 (6).png,EP3500211B1,CASE FOR DENTAL TREATMENT DEVICE,['FIG9'],"['FIG9 depicts a perspective view of another case in a closed position, according to an embodiment']","['FIG9 depicts a perspective view of another case 900 in a closed position, according to an embodiment. In the case 900, the first tab 920A may be positioned substantially equidistant between the third and fourth sides 913A, 914A of the bottom panel 910A. The second tab 920B may include two portions defining a slot therebetween. The first tab 920A may extend upward from the bottom panel 910A to be received within the slot. Thus, the first tab 920A may be positioned between the two portions of the second tab 920B.']",17,97,perspective view,A,"[{'element_identifier': '900', 'terms': ['case']}]","['1. A case (200, 500, 900) for a dental treatment device (100), comprising: a bottom panel (210A, 510A, 910A) having an inner surface and an outer surface, wherein the inner surface of the bottom panel defines a first concave portion (230A), wherein a wall defining the first concave portion (230A) is sloped or curved such that the depth of the first concave portion (230A) increases gradually, and wherein the first concave portion (230A) forms a corresponding first convex portion (240A) of the outer surface of the bottom panel (210A, 510A, 910A); a top panel (210B, 910B) having an inner surface and an outer surface, wherein the inner surface of the top panel defines a second concave portion (230B), wherein the second concave portion (230B) forms a corresponding second convex portion (240B) of the outer surface of the top panel (210B, 910B), wherein the second convex portion (540B) includes a curvature (546B), and wherein the second convex portion (540B) does not have any substantially planar portion; and a hinge (215) that joins the bottom panel (210A, 510A, 910A) and the top panel (210B, 910B) and allows the bottom panel (210A, 510A, 910A) and the top panel (210B, 910B) to pivot between an open position and a closed position; wherein the first concave portion (230A) and the second concave portion (230B) define an internal volume for storing the dental treatment device (100) when the bottom panel (210A, 510A, 910A) and the top panel (210B, 910B) are in the closed position, and wherein a wall defining the first convex portion (240A) includes a crescent-shaped tray accommodating portion (242A) and a handle accommodating portion (244A).']",False,"['900', '17']" 3,EP_3500342_B1 (2).png,EP3500342B1,TRANS-SEPTAL IMPLANTABLE MEDICAL DEVICE,['FIG3'],['FIG3 is a schematic block diagram of an implantable medical device (IMD) in accordance with the disclosure'],"[""FIG3 is a highly schematic illustration of an IMD 50 that may be configured for deployment within a heart chamber of a patient's heart, near a septum of the heart. The septum may be considered as having a first chamber facing side that faces the heart chamber and a second opposing chamber facing side. In some cases, the heart chamber may be the RV, and thus the septum in question is the ventricular septum 10, having an RV facing side 12 and an LV facing side 14. This is merely illustrative, as for example the IMD 50 may be implantable within the RA, meaning that the septum in question is the atrial septum 11, having an RA facing side 13 and an LA facing side 15. The IMD 50 includes a housing 52 having a proximal end 51 and a distal end 53."", 'Returning to FIG3, the adjustment mechanism 60 may include a coupling 72 that may, for example, be rigidly coupled to the inner shaft 68 such that rotation of the coupling 72 produces rotation of the inner shaft 68. The coupling 72 may be configured such that a separate adjustment tool may be mated with the coupling 72. In some cases, the adjustment tool may be used to rotate the coupling 72 to rotate the inner shaft 68. In some cases, the coupling 72 may, for example, represent a tether loop. Rotating the tether loop may cause the inner shaft 68 to rotate in the same direction as the tether loop, and the rotation of the inner shaft 68 relative to the outer shaft 66 while the outer shaft 66 is constrained from rotating causes translation of the outer shaft 66 relative to the housing 52. It is contemplated that the coupling may be a mechanical coupling, an electrical coupling, a hydraulic coupling and/or any other suitable coupling as desired, depending on the type of LV electrode position adjustment assembly 40 used.']",19,355,schematic block diagram,A,"[{'element_identifier': '24', 'terms': ['power source']}, {'element_identifier': '72', 'terms': ['coupling']}, {'element_identifier': '20', 'terms': ['IMD']}, {'element_identifier': '52', 'terms': ['housing']}, {'element_identifier': '66', 'terms': ['outer shaft']}, {'element_identifier': '53', 'terms': ['distal end']}, {'element_identifier': '26', 'terms': ['circuitry']}, {'element_identifier': '58', 'terms': ['lumen']}, {'element_identifier': '60', 'terms': ['adjustment mechanism']}, {'element_identifier': '68', 'terms': ['inner shaft']}]","[""1. An implantable medical device (IMD) configured for deployment at a ventricular septum of a patient's heart, the ventricular septum of the patient's heart having a right ventricle (RV) facing side and a left ventricle (LV) facing side, the IMD comprising: a housing having a proximal end and a distal end, the housing configured to be positioned at least in part in the right ventricle (RV) of the patient's heart with the distal end of the housing proximate the RV facing side of the ventricular septum once the IMD is implanted in the patient's heart; a power source (24) disposed within the housing; circuitry (26) disposed within the housing and operatively coupled to the power source; a first RV electrode (28) adjacent the distal end of the housing and positioned to be facing the RV facing side of the ventricular septum once the IMD is implanted, the first RV electrode operatively coupled with the circuitry in the housing; a second RV electrode (32) spaced proximally of the first RV electrode, the second RV electrode operatively coupled with the circuitry in the housing; an LV electrode (36) positioned distally of the first RV electrode and at least partially in the ventricular septum once the IMD is implanted, the LV electrode operatively coupled with the circuitry in the housing; and an LV electrode position adjustment assembly for adjusting a distance that the LV electrode is positioned distally of the first RV electrode, wherein the LV electrode position adjustment assembly comprises a coupling secured relative to the housing, wherein the coupling is configured to mate with a separate adjustment tool that can move the coupling relative to the housing to adjust the distance that the LV electrode is positioned distally of the first RV electrode, characterized in that the IMD is a dual chamber leadless cardiac pacemaker (LCP)."", '2. The IMD of claim 1, wherein the LV electrode position adjustment assembly comprises a fixation helix extending distally from the housing, with the LV electrode positioned on the fixation helix, the fixation helix including a proximal shaft portion extending through a lumen of the housing and terminating in the coupling such that rotating the coupling rotates the fixation helix relative to the housing and causes the fixation helix to thread itself into the ventricular septum.', '3. The IMD of claim 1, wherein the LV electrode position adjustment assembly comprises: an inner shaft operatively coupled to the coupling; and an outer shaft threadedly engaged with the inner shaft and configured to not rotate relative to the housing, wherein rotation of the inner shaft via the coupling results in translation of the outer shaft relative to the housing, wherein the LV electrode is secured relative to the outer shaft and translates with the outer shaft.']",False,"['26', '24', '72', '58', '68', '66', '52', '60', '53', '3', '20']" 4,EP_3500342_B1 (5).png,EP3500342B1,TRANS-SEPTAL IMPLANTABLE MEDICAL DEVICE,['FIG9'],['FIG9 is a schematic view of an IMD in combination with a delivery device in accordance with the disclosure'],"['FIG9 provides an example of implanting the IMD 90 proximate the ventricular septum 10. As illustrated, the first RV electrode 100 and the second RV electrode 102 are both ring electrodes, but this is not required. The IMD 90 is secured within a delivery device 120, which includes an implantation tool 122 that extends within the delivery device 120 and that may be used for several purposes. For example, the implantation tool 122 may engage the tether loop 94 to hold the IMD 90 relative to the delivery device 120 while delivering the IMD 90 to the implantation site. In some cases, the implantation tool 122 may subsequently be used to rotate the tether loop 94 relative to the housing of the IMD 90 and thus extend or retract the outer shaft 96 bearing the LV electrode 98. As shown, the LV electrode 98 is proximate the LV facing side 14 of the ventricular septum 10. In some cases, the LV electrode 98 may instead be disposed within the ventricular septum 10, at an intermediate depth between the RV facing side 12 of the ventricular septum 10 and the LV facing side 14 of the ventricular septum 10. In some cases, a plurality of LV electrodes may be provided, each at a different position along the outer shaft 96 so that each is at a different depth in the ventricular septum 10. The circuitry 26 may include a selector (not explicitly shown) to select which one (or more) of the plurality of LV electrodes to use.']",19,279,schematic view,A,"[{'element_identifier': '14', 'terms': ['LV facing side']}, {'element_identifier': '12', 'terms': ['RV facing side']}, {'element_identifier': '98', 'terms': ['LV electrode']}, {'element_identifier': '94', 'terms': ['tether loop']}, {'element_identifier': '96', 'terms': ['outer shaft']}, {'element_identifier': '93', 'terms': ['distal end']}, {'element_identifier': '104', 'terms': ['fixation tines']}, {'element_identifier': '102', 'terms': ['second RV electrode']}, {'element_identifier': '10', 'terms': ['ventricular septum']}, {'element_identifier': '26', 'terms': ['circuitry']}, {'element_identifier': '120', 'terms': ['delivery device']}]","[""1. An implantable medical device (IMD) configured for deployment at a ventricular septum of a patient's heart, the ventricular septum of the patient's heart having a right ventricle (RV) facing side and a left ventricle (LV) facing side, the IMD comprising: a housing having a proximal end and a distal end, the housing configured to be positioned at least in part in the right ventricle (RV) of the patient's heart with the distal end of the housing proximate the RV facing side of the ventricular septum once the IMD is implanted in the patient's heart; a power source (24) disposed within the housing; circuitry (26) disposed within the housing and operatively coupled to the power source; a first RV electrode (28) adjacent the distal end of the housing and positioned to be facing the RV facing side of the ventricular septum once the IMD is implanted, the first RV electrode operatively coupled with the circuitry in the housing; a second RV electrode (32) spaced proximally of the first RV electrode, the second RV electrode operatively coupled with the circuitry in the housing; an LV electrode (36) positioned distally of the first RV electrode and at least partially in the ventricular septum once the IMD is implanted, the LV electrode operatively coupled with the circuitry in the housing; and an LV electrode position adjustment assembly for adjusting a distance that the LV electrode is positioned distally of the first RV electrode, wherein the LV electrode position adjustment assembly comprises a coupling secured relative to the housing, wherein the coupling is configured to mate with a separate adjustment tool that can move the coupling relative to the housing to adjust the distance that the LV electrode is positioned distally of the first RV electrode, characterized in that the IMD is a dual chamber leadless cardiac pacemaker (LCP)."", '3. The IMD of claim 1, wherein the LV electrode position adjustment assembly comprises: an inner shaft operatively coupled to the coupling; and an outer shaft threadedly engaged with the inner shaft and configured to not rotate relative to the housing, wherein rotation of the inner shaft via the coupling results in translation of the outer shaft relative to the housing, wherein the LV electrode is secured relative to the outer shaft and translates with the outer shaft.', '5. The IMD of any one of claims 1 to 4, wherein the coupling comprises a rotatable tether loop coupled to a proximal end of the inner shaft, such that rotating the rotatable tether loop rotates the inner shaft relative to the outer shaft, thereby causing the outer shaft to translate in response.', '7. The IMD of any one of claims 2 to 6, further comprising one or more fixation tines that are configured to extend into the ventricular septum and curve over to anchor the IMD in place relative to the ventricular septum.']",False,"['120', '102', '93', '104', '96', '98', '94', '00', '10', '104', '10', '14', '12', '9', '26']" 5,EP_3500773_B1 (3).png,EP3500773B1,TENSIONING DEVICE,['FIG12'],['FIG12 is a cross-sectional view of the handle assembly and pulley wheel of FIG11 along the line B - B'],"['The insert 90 includes opposite first and second faces 95, 96, as shown most clearly in FIG12. The insert 90 is located in the aperture 88 in the boss 86 such that the first face 95 is flush with a surface 98 of the boss 86. An annular sleeve 100 may extend from the second face 96 of the insert 90. This sleeve 100 may be sized to be received within the first hole 76 of the coupling member 66, such that the sleeve 100 is in contact with and lines a side wall of the hole 76.']",22,105,cross-sectional view,A,"[{'element_identifier': '28', 'terms': ['spindle']}, {'element_identifier': '30', 'terms': ['aperture', 'apertures']}, {'element_identifier': '12', 'terms': ['main body']}, {'element_identifier': '80', 'terms': ['raised guide area']}, {'element_identifier': '98', 'terms': ['surface']}, {'element_identifier': '142', 'terms': ['keeper']}, {'element_identifier': '18', 'terms': ['handle assembly']}, {'element_identifier': '86', 'terms': ['boss']}, {'element_identifier': '100', 'terms': ['sleeve']}, {'element_identifier': '90', 'terms': ['insert']}, {'element_identifier': '89', 'terms': ['side wall']}, {'element_identifier': '134', 'terms': ['first end']}, {'element_identifier': '36', 'terms': ['groove']}, {'element_identifier': '144', 'terms': ['spring']}, {'element_identifier': '32', 'terms': ['axis']}]","['1. A tensioning device (10) for a horizontal lifeline comprising: a pulley (14) including a drive spindle (28) and a pulley wheel (14) connected to the drive spindle (28), said lifeline passing, in use, around the pulley wheel (14); a locking member (38) configured to engage, in use, with a part of said lifeline to prevent relative movement of the lifeline with respect to the locking member (38) in a first direction; and a handle assembly (18) connected to the drive spindle (28), the handle assembly (18) being moveable between a first, disengaged position in which rotation of the handle assembly (18) does not cause rotation of the drive spindle (28) and a second, engaged position in which rotation of the handle assembly (18) rotates the drive spindle (28), characterised in that : movement of the handle assembly (18) between the first and second positions is along an axis of the drive spindle (28), wherein the drive spindle (28) includes a drive shaft section (136) and in the first position the handle assembly (18) is engaged with the drive shaft section (136) and in the second position the handle assembly (18) is not engaged with the drive shaft section (136), and wherein rotation of the drive spindle (28) rotates the pulley (14) to move the lifeline in a second direction relative to the locking member (38), thereby tensioning the lifeline.', '5. A tensioning device as claimed in Claim 3 or Claim 4, wherein the arm (68) comprises an elongate member having a first end (104) and a second end (106), the arm (68) being pivotally connected to the coupling member (66) proximate the first end (104), and the second end (106) being further from the connection between the coupling member (66) and the drive spindle (28) when the arm (68) is in the second position than the first position and wherein the pulley (14) is mounted in a main body (12) of the device (10) and, when the arm (68) is in the second position, the second end (106) of the arm (68) extends beyond a perimeter of the main body (12).', '7. A tensioning device as claimed in any one of Claims 3 to 6, wherein one of the coupling member (66) and the arm (68) includes a detent (82) and the other one of the coupling member (66) and the arm (68) includes a stop surface (120,122), the detent (82) contacting the stop surface (120,122) to limit relative movement between the arm (68) and the coupling member (66) and wherein the detent (82) contacts the stop surface (120,122) when the arm (68) is in the second position.']",True,"['11', '89', '28', '86', '142', '100', '32', '36', '80', '86', '90', '144', '36', '3', '28', '98', '30', '12', '134', '18']" 6,EP_3500773_B1 (5).png,EP3500773B1,TENSIONING DEVICE,['FIG20'],['FIG20 is a perspective view of the pulley wheel of FIG11 '],"['The drive spindle 28 connected to the pulley 14 includes a first shaft section 130 having a circular cross-sectional shape of a first diameter and a second shaft section 132 having a circular cross-sectional shape of a second diameter. The first diameter is larger than the second diameter. As shown in FIG20, the pulley wheel flanges 34 extend radially from the first shaft section 130. Furthermore, apertures 30 in the housing plates 20, 22 are sized to receive the first shaft section 130. In particular, a first end 134 of the drive spindle 28, at the end of the first shaft section 130, protrudes through an aperture 30 in the second, rear housing plate 22.']",11,131,perspective view,A,"[{'element_identifier': '20', 'terms': ['plates', 'plate']}, {'element_identifier': '76', 'terms': ['hole', 'holes']}, {'element_identifier': '90', 'terms': ['insert']}, {'element_identifier': '36', 'terms': ['groove']}, {'element_identifier': '68', 'terms': ['arm']}, {'element_identifier': '92', 'terms': ['perimeter edge']}, {'element_identifier': '136', 'terms': ['drive shaft section']}, {'element_identifier': '18', 'terms': ['handle assembly']}, {'element_identifier': '94', 'terms': ['hole']}, {'element_identifier': '78', 'terms': ['second hole']}, {'element_identifier': '70', 'terms': ['base plate']}, {'element_identifier': '72', 'terms': ['second face']}, {'element_identifier': '98', 'terms': ['surface']}, {'element_identifier': '88', 'terms': ['aperture']}, {'element_identifier': '82', 'terms': ['post']}, {'element_identifier': '28', 'terms': ['spindle']}, {'element_identifier': '130', 'terms': ['first shaft section']}, {'element_identifier': '86', 'terms': ['boss']}, {'element_identifier': '34', 'terms': ['flanges']}, {'element_identifier': '138', 'terms': ['between opposite drive surfaces']}, {'element_identifier': '132', 'terms': ['second shaft section']}]","['1. A tensioning device (10) for a horizontal lifeline comprising: a pulley (14) including a drive spindle (28) and a pulley wheel (14) connected to the drive spindle (28), said lifeline passing, in use, around the pulley wheel (14); a locking member (38) configured to engage, in use, with a part of said lifeline to prevent relative movement of the lifeline with respect to the locking member (38) in a first direction; and a handle assembly (18) connected to the drive spindle (28), the handle assembly (18) being moveable between a first, disengaged position in which rotation of the handle assembly (18) does not cause rotation of the drive spindle (28) and a second, engaged position in which rotation of the handle assembly (18) rotates the drive spindle (28), characterised in that : movement of the handle assembly (18) between the first and second positions is along an axis of the drive spindle (28), wherein the drive spindle (28) includes a drive shaft section (136) and in the first position the handle assembly (18) is engaged with the drive shaft section (136) and in the second position the handle assembly (18) is not engaged with the drive shaft section (136), and wherein rotation of the drive spindle (28) rotates the pulley (14) to move the lifeline in a second direction relative to the locking member (38), thereby tensioning the lifeline.', '7. A tensioning device as claimed in any one of Claims 3 to 6, wherein one of the coupling member (66) and the arm (68) includes a detent (82) and the other one of the coupling member (66) and the arm (68) includes a stop surface (120,122), the detent (82) contacting the stop surface (120,122) to limit relative movement between the arm (68) and the coupling member (66) and wherein the detent (82) contacts the stop surface (120,122) when the arm (68) is in the second position.', '11. A horizontal lifeline system as claimed in Claim 9 or Claim 10, wherein the pulley (14) is located between two housing plates (20,22) and the lifeline enters a space between the housing plates (20,22) at a first location and exits the space between the housing plates (20,22) at a second location, such that the lifeline is in contact with the pulley wheel (14) around at least half the circumferential length of the pulley wheel (14).']",True,"['78', '82', '70', '70', '72', '98', '86', '94', '68', '88', '90', '92', '76', '18', '08', '68', '98', '19', '34', '130', '138', '132', '136', '28', '20', '36', '20']" 7,EP_3500773_B1.png,EP3500773B1,TENSIONING DEVICE,['FIG2'],['FIG2 is a schematic diagram showing how the tensioning device of FIG1 is mounted and the path of a lifeline through the device'],"['In use the tensioning device 10 is located and connected between an anchor point, which may comprise a building, frame or suitable stanchion, and a lifeline in the form of an elongate flexible cord or cable. In particular, and as illustrated in FIG2, a part of the brake mechanism 16 is connected to the anchor point by means of a suitable connector such as a shackle. The lifeline cable enters the tensioning device 10 at a first location, passes around the pulley 14 and a first, free end of the lifeline extends from the device 10 at a second location. This is illustrated by the dashed arrow in FIG2. The other, second end of the lifeline is connected to a second anchor point at a distance from the first anchor point. Workers working at height connect themselves to the lifeline between the tensioning device 10 and the second anchor point by suitable personal fall arrest equipment.']",23,170,schematic diagram,A,"[{'element_identifier': '64', 'terms': ['release arm']}, {'element_identifier': '38', 'terms': ['locking member']}, {'element_identifier': '81', 'terms': ['edge']}, {'element_identifier': '68', 'terms': ['arm']}]","['1. A tensioning device (10) for a horizontal lifeline comprising: a pulley (14) including a drive spindle (28) and a pulley wheel (14) connected to the drive spindle (28), said lifeline passing, in use, around the pulley wheel (14); a locking member (38) configured to engage, in use, with a part of said lifeline to prevent relative movement of the lifeline with respect to the locking member (38) in a first direction; and a handle assembly (18) connected to the drive spindle (28), the handle assembly (18) being moveable between a first, disengaged position in which rotation of the handle assembly (18) does not cause rotation of the drive spindle (28) and a second, engaged position in which rotation of the handle assembly (18) rotates the drive spindle (28), characterised in that : movement of the handle assembly (18) between the first and second positions is along an axis of the drive spindle (28), wherein the drive spindle (28) includes a drive shaft section (136) and in the first position the handle assembly (18) is engaged with the drive shaft section (136) and in the second position the handle assembly (18) is not engaged with the drive shaft section (136), and wherein rotation of the drive spindle (28) rotates the pulley (14) to move the lifeline in a second direction relative to the locking member (38), thereby tensioning the lifeline.', '3. A tensioning device as claimed in Claim 1 or Claim 2, the handle assembly (18) comprising a coupling member (66) and an arm (68), the coupling member (66) being connected to the drive spindle (28) and the arm (68) being pivotally connected to the coupling member (66).', '12. A horizontal lifeline system as claimed in any one of Claims 9 to 11, further comprising a release arm (64) rotatable to selectively disengage the locking member (38) from the lifeline.']",True,"['64', '68', '112', '29', '81', '1', '38', '2', '13']" 8,EP_3501091_B1.png,EP3501091B1,MODULATION OF AC/AC MMC,['FIG1'],['FIG1 is a schematic circuit diagram of an embodiment of a three-phase-to-single-phase AC/AC MMC in accordance with the present invention'],"['Embodiments will now be described more fully hereinafter with reference to the accompanying drawings, in which certain embodiments are shown. However, other embodiments in many different forms are possible within the scope of the present disclosure. Rather, the following embodiments are provided by way of example so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art. Like numbers refer to like elements throughout the description. FIG1 is a schematic illustration of an MMC 1 in direct double-star configuration between a first AC network L, which is a three-phase network having currents iLi, iL2 and iL3, and the, and a second AC network R, which is a single-phase network having the current iR and the voltage uR. The first AC network may e.g. be a national power distribution network which may have a utility frequency (power line/mains frequency) of for instance 50 or 60 Hz. The second AC network R may e.g. be for a railway electrification system, and may have a utility frequency of for instance 25 Hz, 50/3 Hz (synchronous) or 16.70 Hz (asynchronous).', 'The MMC 1 also comprises a controller 14 which is schematically shown in FIG1. The controller may be a control system comprising a central unit and/or distributed units associated with respective legs 11 or branches 12. The controller 14 may be configured, e.g. by means of computer programming, to perform embodiments of the method of the present disclosure.']",30,284,schematic circuit diagram,H,"[{'element_identifier': '13', 'terms': ['cells', 'cell']}, {'element_identifier': '14', 'terms': ['controller']}, {'element_identifier': '1', 'terms': ['MMC']}]","['9. A direct AC/AC MMC (1) configured to be connected between a first AC network (L) being a three-phase AC network and having a first waveform and a first frequency and a second AC network (R) being a single-phase AC network and having a second waveform and a second frequency, the MMC having a double-star topology with a plurality of phase legs (11), each phase leg having a first branch (12a) and a second branch (12b), each of the first and second branches (12) comprising a plurality of series connected bipolar cells (13), the MMC further comprising a controller (14) comprising: processing circuitry; and storage storing instructions executable by said processor circuitry characterised in that the said controller is operative to: perform a first modulation (31) based on a reference signal (Ref_3ph) of the first AC network (L), independently of a reference signal of the second AC network (R), to generate, for each phase leg (11), a first integer command signal (N Lk ) corresponding to a first combination of cell states in the first (12a) and second (12b) branches of the phase leg needed for generating the first waveform; perform a second modulation (31) based on a reference signal (Ref_1ph) of the second AC network (R), independently of the reference signal of the first AC network (L), to generate, for each phase leg (11), a second integer command signal (N Rk ) corresponding to a second combination of cell states in the first (12a) and second (12b) branches of the phase leg needed for generating the second waveform; based on the first and second integer command signals (N LK , N RK ), map (32) to each branch (12) a number of cell states to be used for concurrently generating both the first and second waveforms, generating branch-level command signals (N ka , N kb ) to a capacitor voltage balancing algorithm; and based on the mapping (32) and a capacitor voltage balancing algorithm, send firing signals to the plurality of cells (13) of each branch (12).']",False,"['13', '13', '13', '13', '14', '13', '13', '1', '14']" 9,EP_3501828_B1.png,EP3501828B1,"PRINTED CIRCUIT BOARD INSPECTING APPARATUS, METHOD FOR DETECTING ANOMALY IN SOLDER PASTE AND COMPUTER READABLE RECORDING MEDIUM",['FIG2'],"['FIG2 is a flowchart of a method of detecting whether an anomaly in solder pastes printed on a printed circuit board occurred, according to various embodiments of the present disclosure']","['FIG2 is a flowchart of a method of detecting whether an anomaly in solder pastes printed on a printed circuit board occurred, according to various embodiments of the present disclosure.', 'Process steps, method steps, and algorithms are sequentially illustrated in the flowcharts of FIG2, 6, 7, 8 and 9 but the processes, methods, and algorithms may be performed in a predetermined sequence as appropriate. In other words, the steps of processes, methods, and algorithms described in various embodiments of the present disclosure are not necessarily performed in the sequence described herein. Further, although some steps are described as being non-simultaneously performed, they may be simultaneously performed in another embodiment. Further, examples of processes shown in the drawings do not mean that the exemplary processes exclude other changes and modifications, do not mean that some of the exemplary processes or the steps of the processes are necessary in one of various embodiments of the present disclosure, and do not mean that the exemplary processes are preferable.']",31,189,flowchart,B,"[{'element_identifier': '210', 'terms': []}, {'element_identifier': '230', 'terms': ['described below. In step', 'may perform steps']}, {'element_identifier': '130', 'terms': ['processor']}, {'element_identifier': '100', 'terms': []}, {'element_identifier': '220', 'terms': ['In step', 'may perform steps']}, {'element_identifier': '2', 'terms': ['following Equation']}, {'element_identifier': '101', 'terms': ['screen printer']}, {'element_identifier': '110', 'terms': ['image sensor']}, {'element_identifier': '120', 'terms': ['memory']}]","['1. A printed circuit board inspection apparatus (100), characterized by a memory (120) configured to store a machine-learning based model (320, 420) configured to derive a probability value that each of two solder pastes has measurement shape information when the two solder pastes are printed on a printed circuit board through two apertures having a predetermined aperture shape, which are formed in a stencil, using aperture shape information of the two apertures and the measurement shape information about each of the two solder pastes; an image sensor (110) configured to obtain an image (340) of a first printed circuit board; and a processor (130) electrically connected with the memory (120), wherein the processor (130) is configured to: obtain, from the image (340) of the first printed circuit board obtained by the image sensor (110), measurement shape information about each of a plurality of solder pastes printed on the first printed circuit board through a plurality of apertures formed in the stencil, obtain aperture shape information about each of the plurality of apertures, obtain probability values that a first solder paste printed through a first aperture of the plurality of apertures and each of a plurality of second solder pastes printed through second apertures other than the first aperture of the plurality of apertures have the measurement shape information when the first solder paste and the plurality of second solder pastes are printed on the first printed circuit board, by applying the obtained measurement shape information and the obtained aperture shape information to the machine-learning based model (320, 420), and detect whether an anomaly in the first solder paste occurred based on the obtained probability values.']",False,"['100', '101', '110', '120', '130', '2', '210', '220', '230', '18']" 10,EP_3501902_B1 (2).png,EP3501902B1,LOAD CARRIER FOOT,['FIG5'],['FIG5 shows a cross-sectional view of the load carrier assembly of FIG1 '],"['On the upper end or upper portion 203 of the supporting member 202, further elements of a locking mechanism 200 for releasably locking the load bar 300 to the load carrier foot 2 can be fixed as shown in FIG5. The upper end can also be referred to as load bar side end of the supporting member 202 as it is close to the load bar when the same is mounted on the load carrier foot 2. The lower end or lower portion 254 of the supporting member 202 can also be referred to as foot pad side end of the supporting member 202 as it is arranged closer to the foot pad 3. A pivot pin 256 is provided in the lower portion 254. In the assembly, the pivot pin 256 is arranged parallel with the pivot pin 610 of the holder 6 and fixed on the supporting member 202 non-movably with respect to the same. The pivot pin 256 defines another force application section 252 for receiving a force from the force distribution member 510.', 'Since forces are transferred via the contact surfaces 519, 521 and the contact surfaces 519, 521 are allowed to translatory and slidingly move with respect to the pivot pins 610, 256, it is ensured that the normal forces acting on the contact surfaces 519, 521 maintain an equilibrium. Imaginary lines reflecting the direction the normal forces act on the contact surfaces intersect at a point S as is shown in FIG5. The equilibrium is reached when the point S intersects with an imaginary elongated middle axis of the tightening member 8. In other words, the force equilibrium is reached when both contact normals on the contact surfaces 519, 521 and a virtual extension or axis of the tightening member 8 coincide in the same point S. Due to the described construction, the force distribution member 510 automatically seeks an orientation in which the above equilibrium condition is fulfilled.', 'As illustrated in FIG5, the supporting member 202 can be an operating member of a locking mechanism 200 for releasably locking the load bar 300 on the load carrier foot 2. The operating member can comprise two operating portions 280 each having a push surface 282 being configured for thumb operation by a user. The locking mechanism comprises an engaging section 206 adapted to engage with the load bar 300 and coupled to the supporting member 202 by means of a bolt 216 which acts as a force transfer member for transferring a force from the supporting member 202 on the engaging section 206. Accordingly, the load carrier foot 2 can be configured such that the tightening mechanism 500 additionally operates the locking mechanism 200.']",14,480,cross-sectional view,B,"[{'element_identifier': '5', 'terms': ['front cover']}, {'element_identifier': '208', 'terms': ['supporting section']}, {'element_identifier': '61', 'terms': ['coupling portion']}, {'element_identifier': '519', 'terms': ['contact surfaces', 'contact surface']}, {'element_identifier': '404', 'terms': ['pivot portion']}, {'element_identifier': '216', 'terms': ['bolt']}, {'element_identifier': '204', 'terms': ['locking member']}, {'element_identifier': '402', 'terms': ['supporting portion']}, {'element_identifier': '200', 'terms': ['locking mechanism']}, {'element_identifier': '521', 'terms': ['second contact surface', 'second contact surfaces']}, {'element_identifier': '300', 'terms': ['load bar']}, {'element_identifier': '500', 'terms': ['tightening mechanism']}, {'element_identifier': '256', 'terms': ['pivot pin', 'pivot pins']}, {'element_identifier': '41', 'terms': ['coupling portion']}, {'element_identifier': '610', 'terms': ['pivot pin', 'pivot pins']}, {'element_identifier': '62', 'terms': ['force application section']}, {'element_identifier': '206', 'terms': ['engaging section']}, {'element_identifier': '2', 'terms': ['load carrier foot']}, {'element_identifier': '4', 'terms': ['rear cover']}, {'element_identifier': '81', 'terms': ['portion']}, {'element_identifier': '406', 'terms': ['supporting surface']}, {'element_identifier': '510', 'terms': ['force distribution member']}, {'element_identifier': '3', 'terms': ['foot pad']}, {'element_identifier': '700', 'terms': ['load carrier bracket']}]","['1. Load carrier foot (2) for supporting a load bar (300) on a vehicle (1) said load carrier foot (2) comprising a supporting member (202) mountable to said load bar (300), a coupling member (6) for coupling said load carrier foot (2) to said vehicle (1), and a tightening mechanism (500) for tightening said coupling member (6), wherein said tightening mechanism (500) force transmittingly couples said coupling member (6) with said supporting member (202) characterized in that said tightening mechanism (500) force transmittingly couples said coupling member (6) with said supporting member (202) by means of a force distribution member (510) which is configured to transfer a received input force on at least two force application sections (62, 252) while being translatory movably held with respect to each force application section (62, 252).', '3. Load carrier foot (2) according to claim 1 or 2, wherein said force distribution member (510) comprises a force input section (512) for receiving said input force, said force input section (512) being coupled to a first coupling portion (61) of said coupling member (6), and wherein at least one force application section (62) of said at least two force application sections (62, 252) is provided at a second coupling portion (64) of said coupling member (6).', '4. Load carrier foot (2) according to claim 3, wherein said force input section (512) is configured for a torque-free force transfer and preferably comprises a force receiving member (514) pivotably held on said force distribution member (510) and adapted to receive a tightening member (8), preferably a threaded bolt.']",True,"['200', '62', '206', '300', '216', '4', '610', '510', '256', '3', '81', '2', '61', '41', '700', '5', '404', '204', '200', '519', '208', '406', '402', '300', '62', '2', '4', '521', '500', '41', '700', '12']" 11,EP_3501990_B1 (1).png,EP3501990B1,QUANTITATIVE BLOCKAGE ANALYSIS OF A GRID IN ICING CONDITIONS,['FIG4'],['FIG4 shows a cross sectional view of an aircraft engine with an exemplary embodiment of an analysis system'],['FIG4 shows a cross sectional view of an aircraft engine 401 with an air-intake protection grid 403. The aircraft engine 401 comprises an analysis system 405 with an optical sensor 407 that communicates with a processor unit 409. The processor unit 409 communicates with a display unit 411.'],18,53,cross-sectional view,B,"[{'element_identifier': '307', 'terms': ['In displaying step']}, {'element_identifier': '303', 'terms': ['In determination step']}, {'element_identifier': '403', 'terms': ['grid']}, {'element_identifier': '301', 'terms': ['capturing step']}, {'element_identifier': '411', 'terms': ['display unit']}, {'element_identifier': '300', 'terms': ['method']}, {'element_identifier': '405', 'terms': ['analysis system']}, {'element_identifier': '409', 'terms': ['processor unit']}, {'element_identifier': '401', 'terms': ['aircraft engine']}, {'element_identifier': '407', 'terms': ['optical sensor']}, {'element_identifier': '305', 'terms': ['In counting step']}]","['1. An analysis system (100) for quantitative blockage analysis of a grid in icing conditions, comprising - at least one optical sensor (101, 407), - a processor unit (105, 409), and - a display unit (107, 411), wherein the at least one optical sensor is configured to continuously capture a series of pictures of a grid (103, 403, 601) and to submit each picture of the series of pictures to the processor unit, wherein the processor unit is configured to determine a color scale value for each of a number of areas in at least a field of each picture, and wherein the processor unit is configured to count a number of areas in a particular field (501) of a particular picture (500) that show a color scale value greater than an absolute reference value, wherein the processor unit is configured to calculate a time remaining until a critical icing condition is reached based on a model of an icing behavior of the grid and the number of areas that show a color scale value greater than the absolute reference value, and wherein the processor unit is further configured to calculate a warning signal based on the time remaining until the critical icing condition of the grid is reached, and to display the warning signal on the display unit.', '12. A method for quantitative blockage analysis of a grid in icing conditions, comprising the following steps: - capturing (301) a series of pictures of a grid (103, 403) by using an optical sensor (101, 407) and submitting each picture of the series of pictures to a processor unit (105 ,409); - determining (303) a color scale value for each of a number of areas in at least a field of each picture; - counting (305) a number of areas in a particular field of a particular picture that show a color scale value greater than an absolute reference value, and - extrapolating (203) a time remaining until a critical icing condition is reached by using a model of an icing behavior of the grid and the number of areas that show a color scale value greater than the absolute reference value; and - displaying (207) a warning signal on a display unit based on the remaining time calculated by using the model.']",True,"['300', '301', '303', '305', '307', '411', '401', '409', '407', '405', '403', '16']" 12,EP_3502589_B1 (4).png,EP3502589B1,"HORIZONTAL GAS-LIQUID SEPARATOR FOR AIR CONDITIONER, AND AIR CONDITIONER",['FIG9'],['FIG9 is a sectional view of a horizontal gas-liquid separator for an air conditioner according to an embodiment of the present invention '],"['According to some embodiments of the present invention, as illustrated in FIG9, the end of the refrigerant inlet pipe 120 has an elbow section, and the elbow section is gradually bent downwards in a direction from a fixed end of the elbow section to a free end of the elbow section. Thus, the gaseous refrigerant entrained with liquid refrigerant component can be further prevented from directly flowing out through the gas outlet 111 after the gas-liquid mixed refrigerant enters the cavity 110, which results in a phenomenon of poor gas-liquid separation effect. In some embodiments of the present invention, as illustrated in FIG9, the out end of the refrigerant inlet pipe 120 has a bent section, and the bent section is connected to a straight pipe section in a smooth transition. Thus, after entering the cavity 110, the gas-liquid refrigerant can flow to the right sidewall of the cavity 110 in a lower-right direction (left and right directions as shown in FIG9) and turns back, so as to increase the gas-liquid separation stroke, and improve gas-liquid separation effect.']",24,208,sectional view,B,"[{'element_identifier': '130', 'terms': ['plate', 'plates']}, {'element_identifier': '9', 'terms': ['andFig.']}, {'element_identifier': '100', 'terms': ['gas-liquid separator']}, {'element_identifier': '132', 'terms': ['notch', 'notches']}, {'element_identifier': '120', 'terms': ['inlet pipe']}]","['1. A horizontal gas-liquid separator for an air conditioner, comprising: a housing (10) defining a cavity (110), the cavity (110) has a gas outlet (111) formed in a top of the cavity (110) and a liquid outlet (112) formed in a bottom of the cavity (110), a minimum distance between the gas outlet (111) and a left sidewall of the cavity (110) being denoted by L1, and a minimum distance between the liquid outlet (112) and the left sidewall of the cavity (110) being denoted by L2; and a refrigerant inlet pipe (120) located on a left sidewall of the housing (10) and having an end extending into the cavity (110) and facing a right sidewall of the cavity (110), a distance between an end face of the end of the refrigerant inlet pipe (120) and the left sidewall being denoted by L3, and the L3 being greater than or equal to the L1, the L3 being greater than or equal to the L2, the horizontal gas-liquid separator further comprising a partition plate (130) disposed in the cavity (110), the partition plate (130) being located on a right side of the gas outlet (111) to divide the cavity (110) into a plurality of sub-cavities arranged in a left-right direction, and the partition plate (130) defining a penetrating hole communicating two adjacent sub-cavities.', '11. The horizontal gas-liquid separator according to claim 8, wherein the partition plate defines a notch at an outer peripheral edge of the partition plate, a maximum depth of the notch is denoted by H, a diameter of the central through hole is denoted by D1, an outer diameter of the partition plate is denoted by D2 and the H, the D1 and the D2 satisfy: 0.01 D 2 − D 1 ≤ H ≤ 0.25 D 2 − D 1 .']",False,"['100', '132', '130', '120', '32', '12', '9', '18']" 13,EP_3503603_B1 (2).png,EP3503603B1,TECHNIQUES FOR ROUTING REGISTRATION REQUEST OF ROAMING USER EQUIPMENT BY ROUTING ENTITY,['FIG3'],['FIG3 shows a block diagram of an exemplary bridge entity 260 according to the disclosure'],['FIG3 shows a block diagram of an exemplary bridge entity 260 according to the disclosure. The bridge entity 260 can be connected between a plurality of visited network slices 240 and a plurality of home network slices 210. The bridge entity 260 comprises a routing table 301 and a processor 302.'],15,54,block diagram,H,"[{'element_identifier': '210', 'terms': ['network slice', 'network slices']}, {'element_identifier': '203', 'terms': ['registration request message']}, {'element_identifier': '301', 'terms': ['routing table']}, {'element_identifier': '302', 'terms': ['processor']}, {'element_identifier': '240', 'terms': ['network slice', 'network slices']}, {'element_identifier': '260', 'terms': ['entity']}]","['1. A 5G communication system (200), comprising: at least one visited network slice (240) comprising a visited network access entity (251, 252); a home network slice (210) comprising a home Access and Mobility Management Function, AMF, entity (221); and a router entity (260) coupled between the visited network access entity (251) and the home AMF entity (221), wherein the router entity (260) is configured to route a registration request message (203) of a roaming user equipment, UE, (202) received from the visited network access entity (251) to the home AMF entity (221), wherein the router entity (260) is a central entity located at a central location of the 5G communication system (200) outside the at least one visited network slice (240) and the home network slice (210), wherein the visited network access entity (251, 252) comprises a routing table which comprises at least one internal route (253) for routing messages from non-roaming UEs (202) that are configured for the at least one visited network slice (240) and an external route (254) for routing messages (203) from roaming UEs (202) that are not configured for the at least one visited network slice (240).', '10. A visited network access entity of a visited network slice (240), the visited network access entity (300) comprising: a routing table comprising at least one internal route (253) which routes messages from non-roaming UEs (202), that are configured for the visited network slice, to a network entity (251) of the visited network slice (240) and an external route (254) for routing messages (203) from roaming UEs (202), that are not configured for the visited network slice, to a router entity (260) ; and a processor configured to forward an incoming registration request message (203) from the roaming and ef non-roaming UE (202) based on looking up the routing table with respect to an identity, UE ID, of the roaming and non-roaming UE (202) comprised in the registration request message (203) and/or a public land mobile network identity, PLMN ID, derived from the UE ID.']",False,"['260', '301', '240', '302', '210', '203', '203', '3', '17']" 14,EP_3504510_B1 (2).png,EP3504510B1,"DISTANCE SENSOR, ALIGNMENT SYSTEM AND METHOD",['FIG3A'],['FIG3A shows a part of an embodiment of a distance sensor in more detail'],"['FIG3A shows a first embodiment of the processing device 40. In this embodiment the processing device 40 includes a lookup table 44 that includes for each of a plurality of values hi a respective value pvi that was observed for the property indicative for the distance. The value pairs hi, pvi were obtained in an initialization mode wherein the distances hi were varied and measured with a reference distance meter. The embodiment further includes a subtraction element 41 to determine the difference pv-pvi, an absolute value determining element 42 to determine the absolute value of this difference, and an optimizer 43 to select the index i that minimizes this absolute value. Hence, in this embodiment the estimated value h for the average height h is determined as: ĥ = hj, wherein j=miniAbspv−pvi']",14,146,embodiment,B,"[{'element_identifier': '48', 'terms': ['calculated in processing module']}, {'element_identifier': '45', 'terms': ['optimizer']}, {'element_identifier': '40', 'terms': ['processing device']}, {'element_identifier': '42', 'terms': ['absolute value determining element', '3A in that elements']}, {'element_identifier': '43', 'terms': ['optimizer', '3A in that elements']}, {'element_identifier': '41', 'terms': ['subtraction element']}, {'element_identifier': '49', 'terms': ['processing module']}, {'element_identifier': '44', 'terms': ['lookup table']}, {'element_identifier': '46', 'terms': ['interpolator']}]","['1. A distance sensor (1) for estimating a distance to a surface (Os) of an object (O), the distance sensor including a micro electric mechanical system , MEMS, (5) comprising a MEMS device (10) having a surface (12), denoted as MEMS sensor surface, to be arranged opposite the surface (Os) of said object (O) and a MEMS driver (20) for generating an ac driving signal to cause the MEMS sensor surface to vibrate, characterized in that it comprises a detection means (30) to determine a value of a property of a dynamic behavior of the MEMS (5) and a processing device (40) to estimate an average distance (h) from a measurement of the dampening of the MEMS sensor surface, as a measured distance (D 2 ) between the MEMS sensor surface (12) and the surface (O s ) of the object (O) based on the determined value for said property.']",True,"['41', '42', '43', '44', '40', '41', '45', '44', '46', '40', '40', '48', '49', '40', '16']" 15,EP_3504510_B1 (4).png,EP3504510B1,"DISTANCE SENSOR, ALIGNMENT SYSTEM AND METHOD",['FIG5B'],['FIG5B schematically illustrates a fourth embodiment of an alignment system including an approach stage'],"['FIG5B schematically illustrates a fourth embodiment of an alignment system 100 comprising an approach stage 160 configured to position the first object 101 with respect to the second object 102. In one embodiment, a plurality of object stage actuators 121a,121b are disposed between the object stage 111a, 111b and the approach stage 160.']",14,57,embodiment,B,"[{'element_identifier': '160', 'terms': ['approach stage']}, {'element_identifier': '100', 'terms': ['alignment system']}, {'element_identifier': '180', 'terms': ['controller']}, {'element_identifier': '102', 'terms': ['second object']}, {'element_identifier': '101', 'terms': ['object', 'objects']}]","['1. A distance sensor (1) for estimating a distance to a surface (Os) of an object (O), the distance sensor including a micro electric mechanical system , MEMS, (5) comprising a MEMS device (10) having a surface (12), denoted as MEMS sensor surface, to be arranged opposite the surface (Os) of said object (O) and a MEMS driver (20) for generating an ac driving signal to cause the MEMS sensor surface to vibrate, characterized in that it comprises a detection means (30) to determine a value of a property of a dynamic behavior of the MEMS (5) and a processing device (40) to estimate an average distance (h) from a measurement of the dampening of the MEMS sensor surface, as a measured distance (D 2 ) between the MEMS sensor surface (12) and the surface (O s ) of the object (O) based on the determined value for said property.', '7. An alignment system (100) for positioning and/or keeping a first object (101) at a controlled distance (D1) with respect to a second object (102), the alignment system (100) comprising a distance sensor (1) according to one of the previous claims and further comprising an object stage (111) configured to hold the first object (101) or the second (102) object, wherein a surface (101a) of the first object (101) is at a distance (D1) over a surface (102a) of the second object (102); an object stage actuator (121) configured to actuate the object stage (111) to vary the distance (D1) between the surfaces (101a, 102a) of the first and second objects (101,102); a controller (180) configured to control the object stage actuator (121) as a function of the estimated average distance (h) indicated by said distance sensor to position and/or keep the first object (101) at the controlled distance (D1) with respect to a second object (102).', '12. The alignment system according to any of the claims 7-11, comprising an approach stage (160) configured to position the first object (101) with respect to the second object (102), wherein a plurality of object stage actuators (121a,121b) are disposed between the object stage (111) and the approach stage (160).']",True,"['100', '180', '101', '102', '160', '101', '102', '100', '18']" 16,EP_3504510_B1.png,EP3504510B1,"DISTANCE SENSOR, ALIGNMENT SYSTEM AND METHOD",['FIG1A'],['FIG1A shows a part of an embodiment of a distance sensor in more detail'],"['FIG1A schematically shows the MEMS device as a membrane having a membrane surface 12 that vibrates with an amplitude A. The membrane may have lateral dimensions in the order of a few micrometers to few hundred of micrometers. The membrane may for example have a circular membrane surface with a diameter in said range as the lateral dimension or a square membrane having an edge in said range as the lateral dimension. Also membranes having a form other than circular or square may be employed, e.g. rectangular or oval. More specifically, the membrane may have a lateral dimension in the range of 1-1000 micrometer, for example in the range of 20-500 micrometer, for example in the range of 50-200 micrometer.']",14,134,embodiment,B,"[{'element_identifier': '30', 'terms': ['detection means']}, {'element_identifier': '1', 'terms': ['distance sensor']}, {'element_identifier': '20', 'terms': ['MEMS driver']}, {'element_identifier': '40', 'terms': ['processing device']}, {'element_identifier': '10', 'terms': ['MEMS device']}]","['1. A distance sensor (1) for estimating a distance to a surface (Os) of an object (O), the distance sensor including a micro electric mechanical system , MEMS, (5) comprising a MEMS device (10) having a surface (12), denoted as MEMS sensor surface, to be arranged opposite the surface (Os) of said object (O) and a MEMS driver (20) for generating an ac driving signal to cause the MEMS sensor surface to vibrate, characterized in that it comprises a detection means (30) to determine a value of a property of a dynamic behavior of the MEMS (5) and a processing device (40) to estimate an average distance (h) from a measurement of the dampening of the MEMS sensor surface, as a measured distance (D 2 ) between the MEMS sensor surface (12) and the surface (O s ) of the object (O) based on the determined value for said property.']",True,"['30', '20', '40', '1', '10', '14']" 17,EP_3504950_B1 (1).png,EP3504950B1,LATERAL TRANSPORT SYSTEM FOR HARVESTER AND METHOD OF USING THE SAME,['FIG2'],['FIG2 is a left side view of an exemplary lateral transport system of FIG1 in a stowed configuration'],"['The system 100 comprises a tongue 112 pivotally coupled to the chassis 102. The tongue 112 comprises a distal end 114 pivotally coupled to the chassis 102 and a proximal end 116 at the opposing end. The proximal end 116 is configured to be coupled to a cab for pulling the system 100 during transport or during a mowing operation (see, e.g., cab or harvester 109 and frame 111 of FIG2). Between the distal and proximal ends 114, 116, the tongue 112 comprises a lateral flange 118 fixedly coupled to the tongue 112. The system 100 comprises a secondary double-sided flange 118 with a gap therebetween for pivotally receiving the flange 120.']",18,125,left side view,A,"[{'element_identifier': '128', 'terms': ['wheels']}, {'element_identifier': '100', 'terms': ['system']}, {'element_identifier': '148', 'terms': ['lateral member']}, {'element_identifier': '126', 'terms': ['field suspension system']}, {'element_identifier': '104', 'terms': ['cutting elements']}, {'element_identifier': '146', 'terms': ['lateral member', 'lateral members']}, {'element_identifier': '112', 'terms': ['tongue']}, {'element_identifier': '118', 'terms': ['flange']}, {'element_identifier': '138', 'terms': ['wheels', 'wheel']}, {'element_identifier': '102', 'terms': ['chassis']}, {'element_identifier': '152', 'terms': ['side member']}, {'element_identifier': '108', 'terms': ['frame']}, {'element_identifier': '109', 'terms': ['harvester']}, {'element_identifier': '114', 'terms': ['distal end', 'proximal ends']}, {'element_identifier': '120', 'terms': ['flange']}]","['1. A lateral transport system (100) for a harvester (109), comprising: a chassis (102); first and second ground wheels (128, 130) rotatably coupled to the chassis (102); and a lateral transport assembly (132) operably coupled to the chassis (102) and operable between a transport operation mode and a stowed operation mode, the lateral transport assembly (132) comprising: a tongue (112) pivotally coupled to the chassis (102); a first suspension element (134) rotatable about a first axis (142) and a second axis (144), the first axis (142) being perpendicular to the second axis (144) ; a second suspension element (136) rotatably about the second axis (144); and a hydraulic actuation system (160, 230) operably coupled to the tongue (112), the first suspension element (134), and the second suspension element (136); wherein in the transport operation mode, hydraulic fluid is allowed to flow into the hydraulic actuation system (160, 230) to rotate the first suspension element (134) about the first axis (142), and subsequently rotate the first and second suspension elements (134, 136) about the second axis (144); characterized in that in the transport operation mode, a first tongue hydraulic cylinder (122) is actuated to extend to partially rotate the tongue (112) relative to the chassis (102) prior to rotation of the first suspension element (134) about the first axis (142); and after rotation of the first suspension element (134) about the first axis (142), a second tongue hydraulic cylinder (101) is actuated to extend to rotate the tongue (112) relative to the chassis (102) to a laterally extending position.', '4. The lateral transport system (100) of any of claims 1-3, wherein: the first tongue hydraulic cylinder (122) is pivotally coupled between a first flange (118) of the tongue (112) and a first flange (110) of the chassis (102); and the second tongue hydraulic cylinder (101) is pivotally coupled between the first flange (118) of the tongue (112) and a second flange (103) of the tongue (112).', '7. A harvester (109), comprising: a frame (111); the lateral transport system (100) according to any of the claims 1-6; first and second lift cylinders (210, 212) operably coupled to the frame (111) and configured to selectively lift and lower the lateral transport system (100) relative to the frame (111).']",False,"['109', '100', '146', '114', '120', '118', '102', '112', '50', '138', '152', '36', '148', '128', '16', '104', '108', '126']" 18,EP_3505148_B1 (4).png,EP3505148B1,ABSORBENT ARTICLE,['FIG7'],['FIG7 shows schematic partial enlarged views of hip hold portions for illustrating other arrangements of a rigid portion and a rigid area according to embodiments of the present invention'],"['Note that the rigid area 70 and the rigid portion 60 may be assumed to have elongated shapes if at least two line segments with differing lengths can be obtained upon drawing at least two line segments connecting two points on the outline defining the shape of the rigid portion 60 or the rigid area 70. For example, when the rigid portion 60 and the rigid area 70 have shapes as shown in FIG7 (c), the direction of the longest line segment ST among the line segments obtained by connecting two points on the outline defining the shape of the rigid area 70 is preferably arranged to be substantially parallel to the second imaginary line X2, and in this way, the area with enhanced rigidity may be extended more widely in the direction of the second imaginary line X2. In this way, the formation of wrinkles in the vicinity of a recess where stress is likely to concentrate may be more effectively prevented. Also, even when wrinkles are formed, the effect of dispersing wrinkles may be further enhanced.']",29,191,schematic views,A,"[{'element_identifier': '51', 'terms': ['recess']}, {'element_identifier': '5', 'terms': ['wrapping sheet']}, {'element_identifier': '42', 'terms': ['second protrusion']}, {'element_identifier': '41', 'terms': ['first protrusion']}, {'element_identifier': '70', 'terms': ['rigid area', 'rigid areas']}, {'element_identifier': '60', 'terms': ['rigid portion', 'rigid portions']}]","['1. An absorbent article (1) comprising: a main body (8) including a liquid-pervious topsheet (3), a liquid-impervious backsheet (2), and an adsorbent member (4) arranged between the topsheet (3) and the backsheet (2); and a hip hold portion (H); wherein the main body (8) has a shape with a prescribed length in a front-back direction and a prescribed width in a direction orthogonal to the front-back direction; wherein the hip hold portion (H) includes a side region (10) protruding from a backward side portion of the main body (8), the side region (10) including a first protrusion (41) including a portion with a greatest width from a front-back direction centerline (CL), a first recess (51) that is in front of and adjacent to the first protrusion (41), and a second protrusion (42) that is in front of and adjacent to the first recess (51); and wherein an outline of the first recess (51) includes a curved line, and a plurality of rigid portions (60) with enhanced rigidity is provided on a first imaginary line (X1) passing through a bottom point of the first recess (51) and a center of a circle of curvature of a curve at the bottom point of the first recess (51), the rigid portion (60) being an embossed portion, and wherein an area of a rigid portion (60) closer to the centerline (CL) is arranged to be smaller than an area of a rigid portion (60) farther away from the centerline (CL).']",False,"['51', '60', '70', '42', '60', '41', '51', '70', '60', '42', '41', '70', '60', '5', '42', '16']" 19,EP_3505233_B1 (2).png,EP3505233B1,DEVICE FOR STIRRING LIQUIDS AND LIQUID MIXTURES,['FIG3'],"['FIG3 shows, in a schematic way, a stirring container provided with four stirring devices, according to an embodiment of the present invention']","['FIG3 shows in a schematic way a stirring container provided with four stirring devices 21, according to an embodiment of the present invention. Each of the stirring devices 21 comprises a wall flange 3 for attachment along the inner side of the stirring container wall 1. This stirring container wall 1 thereby provides the corresponding attachment flange 2. Depending on the embodiment, the wall flange 3 itself is attached along the inner side or along the outer side to the attachment flange 2; in the present embodiment, that is along the outer side. Each of the stirring devices 21 now further comprises a rotor 11 that ends in a stirring shaft 12. This stirring shaft 12 is now provided with one or more stirring elements 13, under de form of rudder propellers. The length of the stirring shaft 12 can vary. Of course, other stirring elements 13 can be chosen and/or parts thereof, such as propellers blades, can also be provided directly along the outer side of the holder 11a. The stirring devices 21 are mounted out of centre in the stirring container.']",25,200,schematic,B,"[{'element_identifier': '12', 'terms': ['stirring shaft']}, {'element_identifier': '11', 'terms': ['rotor']}, {'element_identifier': '18', 'terms': ['space']}, {'element_identifier': '21', 'terms': ['device', 'devices']}, {'element_identifier': '3', 'terms': ['wall flange']}, {'element_identifier': '13', 'terms': ['stirring element', 'stirring elements']}]","['1. A device (21) for stirring liquids and liquid mixtures, - said device (21) comprising a housing (7a, 7b) extending in an axial direction, in which the housing (7a, 7b) comprises a proximal end and a distal end, and defines an internal volume that is closed at its distal end by a distal cover (7b), and that is radially enclosed by a cylindrical side wall (7a) of the housing (7a, 7b), - said device (21) further comprising a rotor (11) that is adapted for being enclosed by liquids and liquid mixtures, and that is connected to at least one stirring element (13), in which the rotor (11) defines a holder (11a) that receives said housing (7a, 7b) along its distal end, in such a way that the rotor (11) sits onto the housing (7a, 7b), mutually rotatable about the axial direction, wherein said holder (11a) further comprises a plurality of permanent magnets (14), and wherein said device (21) further comprises a plurality of electromagnetic windings (9), which windings (9) are comprised by said internal volume, and which windings (9) are configured for interacting electromagnetically with the permanent magnets (14), through said side wall (7a) of the housing (7a, 7b), thereby exercising a force-couple onto the rotor (11), around the axial direction, characterized in that said rotor holder (11a) is mounted onto the side wall (7a) of the housing (7a, 7b) by means of a proximal slide bearing (23), said bearing (23) providing a direct slide bearing of radial rotary type.', '8. The device (21) of the previous claim 7, characterized in that said holder (11a) encloses a semi-open space (18), that is positioned between the distal end of the holder (11a) and the distal end of the housing (7a, 7b), and in which said opening (19) realizes a fluid connection of the semi-open space (18) to the environment of the stirring device (21).']",False,"['3', '21', '11', '12', '13', '13', '12', '13', '13', '12', '11', '13', '12', '11', '11', '21', '21', '21', '18']" 20,EP_3505370_B1 (4).png,EP3505370B1,TYRE AND TYRE SET,['FIG5'],['FIG5 is a cross-sectional view taken along line B-B of FIG4 '],"['FIG5 illustrates a cross-sectional view taken along the line B-B in FIG4. As illustrated in FIG5, in the tyres 1A and 1B according to the embodiment, since the first walls 14 of the shoulder blocks 13 are parallel with the respective tyre meridian sections, the contact area of adjacent first and second tyres 1A and 1B on the shoulder blocks 13 becomes large when two tyres 1A and 1B are stacked. Thus, the tyre set 20 in which a plurality of tyre 1 according to the embodiment is stacked can suppress the collapse of tyres 1A and 1B even when vibration and an external force, e.g., inertial force, acts on the tyre set 20.']",15,128,cross-sectional view,B,"[{'element_identifier': '14', 'terms': ['first walls', 'first wall']}, {'element_identifier': '12', 'terms': ['middle blocks', 'middle block']}, {'element_identifier': '20', 'terms': ['tyre set']}, {'element_identifier': '16', 'terms': ['lateral edges']}, {'element_identifier': '13', 'terms': ['shoulder blocks', 'shoulder block']}]","['1. A tyre (1) comprising: a tread portion (2) being provided with blocks (10) each protruding toward a ground contact surface (10a) thereof from a tread bottom surface (9a), and axially spaced side portions (3) extending from the tread portion (2) to bead portions (4); the blocks (10) comprising a pair of rows of shoulder blocks (13) spaced in a tyre circumferential direction, each row being arranged on a respective one of tread edges (Te); in each row, the shoulder blocks (13) each comprising an overhanging portion (13a) located axially outside the corresponding side portion (3); the overhanging portion (13a) comprising a pair of first walls (14) extending in substantially parallel with a tyre meridian cross-section, wherein each first wall (14) has an angle within 5 degrees with respect to the tyre meridian cross-section; and the shoulder blocks (13) having shoulder block lengths (L1) which are lengths in the tyre circumferential direction measured between the pair of first walls (14) along the ground contact surface (10a), wherein the shoulder block lengths (L1) are shorter than gap lengths (L2) which are lengths in the tyre circumferential direction measured on the tread bottom surface (9a) between adjacent shoulder blocks (13), characterized in that the shoulder block lengths (L1) are in a range of from 90% to 98% of the gap lengths (L2).', '5. The tyre (1) according to any one of claims 1 to 4, the blocks (10) further comprising a pair of rows of middle blocks (12) spaced in a tyre circumferential direction and arranged axially inside the pair of rows of the shoulder blocks (13), wherein in axially adjacent rows of the shoulder blocks (13) and the middle blocks (12), the shoulder blocks (13) and the middle blocks (12) are arranged alternately in the tyre circumferential direction, the middle blocks (12) have middle-end positions (12e) located axially outermost on the tread bottom surface (9a), and axial middle-end distances (L4) from the middle-end positions (12e) to the tread edge (Te) located axially outwardly of the middle-end positions (12e) are longer than shoulder block heights (H1) at the middle-end positions (12e).', '8. A tyre set (20) comprising: a first tyre (1A) and a second tyre (1B) each according to any one of claims 1 to 7, when the first tyre (1A) is stacked on the second tyre (1B) such that one of the side portions of the first tyre (1A) lies on one of the side portions of the second tyre (1B), the respective shoulder blocks (13) of the first tyre (1A) are positioned into the respective gaps between adjacent shoulder blocks (13) of the second tyre (1B).']",False,"['20', '12', '14', '14', '13', '13', '12', '16']" 21,EP_3506145_B1 (5).png,EP3506145B1,DATA INTEGRITY PROTECTION METHOD AND DEVICE,"['FIG10', ' FIG9']","['FIG9 shows a flow diagram of verifying an integrity protection summary according to an embodiment ', 'FIG10 shows a schematic diagram of a data integrity protection device according to an embodiment ']","['In another embodiment, the central node may also be used for determining whether the data in the industrial control system changes or not by verifying the second integrity protection summary of the industrial control system. As shown in FIG9, step S901, the central node extracts data features and identity features including data to be protected in all control components of the industrial control system. Step S902, the central node recalculates the second integrity protection summary of the system, e.g., the root hash value 300. Step S903, the central node judges whether the recalculated second integrity protection summary coincides with the stored second integrity protection summary or not; if coinciding, it indicates that each control component in the system and the firmware or configuration file thereof are normal and are not damaged or modified, then a signal about that the system is normal is output to the user in step S906; and if not coinciding, it indicates that the data of one or more control components in the industrial control system changes, the central node may further determine the data in which control component changes. Thus, the central node further recalculates the first integrity protection summary of each control component in step S904, and then executes matching in step S905, i.e., matching the recalculated first integrity protection summary with the stored first integrity protection summary of the corresponding control component, if matching, it indicates that the control component is normal; if not matching, it indicates that the data in the control component changes, and the central node can determine the control component having the data change according to the extracted identity feature information, and then notifies the user of the control component having data abnormality. ', 'The preferred embodiments of the present invention are described above in combination with examples. Understandably, the method or the central node disclosed herein may be implemented by software, hardware or a combination of hardware and software. FIG10 shows a data integrity protection device implemented by program modules or hardware modules according to an embodiment of the present invention. As shown in FIG10, the data integrity protection device includes a correlation establishment module 101 and a summary generation module 102. The correlation establishment module 101 is configured to establish a correlation among a plurality of control components in an industrial control system, e.g., to rank the n control components, so that the data integrity summary generated for each control component is only correlated to one or all of the control components previous to the control component. The summary generation module 102 is configured to determine a summary indicating the integrity of data to be protected in the kth control component based on identity features and data features of other control components correlated to any control component (e.g., the kth control component among the n control components) among the n control components.']",30,517,"flow diagram, schematic diagram",G,"[{'element_identifier': '101', 'terms': ['correlation establishment module']}, {'element_identifier': '102', 'terms': ['summary generation module']}, {'element_identifier': '10', 'terms': ['andFIG.']}]","['10. A data integrity protection device, comprising: a correlation establishment module (101), configured to establish a correlation among a plurality of control components in an industrial control system; and a summary generation module (102), configured to determine a summary indicating the integrity of data to be protected in a first control component based on identity features and data features of other control components correlated to the first control component among the plurality of control components, wherein the data features are used for identifying the data to be protected in the control components, and the first control component is any one of the plurality of control components, wherein the summary generation module is further configured to: determine a first integrity protection summary specific to the first control component, the first integrity protection summary being only used for indicating the integrity of the data to be protected in the first control component, and determine a second integrity protection summary shared by the plurality of control components including the first control component, the second integrity protection summary being used for indicating the integrity of the data to be protected in the plurality of control components, wherein the summary generation module is further configured to determine the second integrity protection summary based on the identity feature and the data feature of each of the plurality of control components, and to distribute the second integrity protection summary to each of the plurality of control components.']",True,"['9', '101', '102', '10', '24']" 22,EP_3506695_B1 (5).png,EP3506695B1,METHOD AND DEVICE FOR RELEASING SEMI-PERSISTENT SCHEDULING RESOURCE,"['FIG7', ' FIG9']","['FIG9 is a schematic structural diagram of hardware of a base station according to an embodiment of the present invention ', 'FIG7 is a schematic structural diagram of hardware of a base station according to an embodiment of the present invention']","['When the processing unit 33 is a processor, the receiving unit 32 is a receiver, and the sending unit 31 is a transmitter, the user equipment in this embodiment of the present invention may be shown in FIG9. FIG9 is a schematic structural diagram of hardware of a base station according to an embodiment of the present invention. As shown in FIG9, the user equipment may include a receiver 41, a transmitter 42, a processor 43, and a memory 44. The memory 44 may include a high-speed RAM memory, or may include a nonvolatile memory NVM, for example, at least one magnetic disk memory. The memory 44 may store computer executable program code, the program code includes an instruction, and when the processor 43 executes the instruction, the instruction enables the processor 43 to complete various processing functions and implement the method steps of the embodiments. ', 'When the processing unit 12 is a processor, the receiving unit 11 is a receiver, and the sending unit 13 is a transmitter, the base station in this embodiment of the present invention may be shown in FIG7. FIG7 is a schematic structural diagram of hardware of a base station according to an embodiment of the present invention. As shown in FIG7, the base station may include a receiver 21, a transmitter 22, a processor 23, and a memory 24. The memory 24 may include a high-speed RAM memory, or may include a nonvolatile memory NVM, for example, at least one magnetic disk memory. The memory 24 may store computer executable program code, the program code includes an instruction, and when the processor 23 executes the instruction, the instruction enables the processor 23 to complete various processing functions and implement the method steps of the embodiments.']",40,332,schematic structural diagram,H,"[{'element_identifier': '24', 'terms': ['memory']}, {'element_identifier': '12', 'terms': ['processing unit']}, {'element_identifier': '11', 'terms': ['receiving unit']}, {'element_identifier': '9', 'terms': ['andFIG.']}, {'element_identifier': '100', 'terms': ['cycle is']}, {'element_identifier': '21', 'terms': ['receiver']}, {'element_identifier': '23', 'terms': ['processor']}, {'element_identifier': '13', 'terms': ['sending unit']}]","['4. The method according to claim 1, wherein if the service change information comprises the cycle change information, or the service change information comprises the cycle change information and the update information, and the first service data comprises service data whose transmission cycle is a first cycle and service data whose transmission cycle is a second cycle, the second service data is the service data whose transmission cycle is the first cycle, wherein the first cycle is a cycle before a change, and the second cycle is a cycle after the change; the first service information further comprises an identifier of an original first SPS corresponding to the service data whose transmission cycle is the first cycle; the SPS information further comprises an identifier of a new first SPS corresponding to the new SPS resource, wherein the new SPS resource is a resource corresponding to the service data whose transmission cycle is the second cycle; the target SPS resource comprises a resource corresponding to the identifier of the original first SPS; and after the sending, by the base station, DCI to the UE, the method further comprises: releasing, by the base station, the target SPS resource based on the identifier of the original first SPS.', '9. Abase station (100), comprising: a) a receiving unit (11), configured to receive service information sent by user equipment UE, wherein the service information comprises first service information of first service data, the first service information comprises service change information or initial configuration information, and the service change information comprises at least one of cycle change information and update information; b) a processing unit (12), configured to determine, based on the first service information, semi-persistent scheduling, SPS, information corresponding to the first service data, wherein the SPS information comprises indication information of a new SPS resource; and c) a sending unit (13), configured to send downlink control information, DCI, to the UE, wherein the DCI comprises the SPS information, and the DCI is used to instruct the UE to activate the new SPS resource and release a target SPS resource, wherein the target SPS resource is an SPS resource corresponding to second service data that has been transmitted; and d) wherein the service information further comprises second service information corresponding to the second service data, and the second service information comprises data sending completion information and an identifier of a second SPS corresponding to the second service data; e) the SPS information further comprises an identifier of a first SPS corresponding to the new SPS resource; f) the target SPS resource comprises a resource corresponding to the identifier of the second SPS; and g) the processing unit is further configured to: after the DCI is sent to the UE, release the target SPS resource based on the identifier of the second SPS.']",True,"['100', '11', '12', '13', '9', '24', '21', '23', '7', '29']" 23,EP_3506695_B1 (6).png,EP3506695B1,METHOD AND DEVICE FOR RELEASING SEMI-PERSISTENT SCHEDULING RESOURCE,"['FIG8', ' FIG9']","['FIG8 is a schematic structural diagram of user equipment according to an embodiment of the present invention ', 'FIG9 is a schematic structural diagram of hardware of a base station according to an embodiment of the present invention ']","['When an integrated unit is used, FIG8 is a schematic structural diagram of user equipment according to an embodiment of the present invention. The user equipment 300 includes a sending unit 31, a receiving unit 32, and a processing unit 33. The sending unit 31 and the receiving unit 32 are configured to support communications between the UE and the base station. The processing unit 33 is configured to perform control management on an action of the UE. ', 'When the processing unit 33 is a processor, the receiving unit 32 is a receiver, and the sending unit 31 is a transmitter, the user equipment in this embodiment of the present invention may be shown in FIG9. FIG9 is a schematic structural diagram of hardware of a base station according to an embodiment of the present invention. As shown in FIG9, the user equipment may include a receiver 41, a transmitter 42, a processor 43, and a memory 44. The memory 44 may include a high-speed RAM memory, or may include a nonvolatile memory NVM, for example, at least one magnetic disk memory. The memory 44 may store computer executable program code, the program code includes an instruction, and when the processor 43 executes the instruction, the instruction enables the processor 43 to complete various processing functions and implement the method steps of the embodiments.']",37,251,schematic structural diagram,H,"[{'element_identifier': '9', 'terms': ['andFIG.']}, {'element_identifier': '300', 'terms': ['one large data segment', 'user equipment']}, {'element_identifier': '43', 'terms': ['processor']}, {'element_identifier': '33', 'terms': ['processing unit']}, {'element_identifier': '44', 'terms': ['memory']}, {'element_identifier': '31', 'terms': ['sending unit']}, {'element_identifier': '32', 'terms': ['receiving unit']}]","['1. A method for releasing a semi-persistent scheduling resource, comprising: a) receiving (S201, S301, S401, S501), by a base station (100), service information sent by user equipment (300), UE, wherein the service information comprises first service information of first service data, the first service information comprises service change information or initial configuration information, and the service change information comprises at least one of cycle change information and update information; b) determining (S202, S302, S403), by the base station based on the first service information, semi-persistent scheduling, SPS, information corresponding to the first service data, wherein the SPS information comprises indication information of a new SPS resource; and c) sending (S203, S303, S403, S502), by the base station, downlink control information, DCI, to the UE, wherein the DCI comprises the SPS information, and the DCI is used to instruct the UE to activate the new SPS resource and release a target SPS resource, wherein the target SPS resource is an SPS resource corresponding to second service data that has been transmitted; and d) wherein the service information further comprises second service information corresponding to the second service data, and the second service information comprises data sending completion information and an identifier of a second SPS corresponding to the second service data; e) the SPS information further comprises an identifier of a first SPS corresponding to the new SPS resource; f) the target SPS resource comprises a resource corresponding to the identifier of the second SPS; and g) after the sending, by the base station, DCI to the UE, the method further comprises: releasing, by the base station, the target SPS resource based on the identifier of the second SPS.', '9. Abase station (100), comprising: a) a receiving unit (11), configured to receive service information sent by user equipment UE, wherein the service information comprises first service information of first service data, the first service information comprises service change information or initial configuration information, and the service change information comprises at least one of cycle change information and update information; b) a processing unit (12), configured to determine, based on the first service information, semi-persistent scheduling, SPS, information corresponding to the first service data, wherein the SPS information comprises indication information of a new SPS resource; and c) a sending unit (13), configured to send downlink control information, DCI, to the UE, wherein the DCI comprises the SPS information, and the DCI is used to instruct the UE to activate the new SPS resource and release a target SPS resource, wherein the target SPS resource is an SPS resource corresponding to second service data that has been transmitted; and d) wherein the service information further comprises second service information corresponding to the second service data, and the second service information comprises data sending completion information and an identifier of a second SPS corresponding to the second service data; e) the SPS information further comprises an identifier of a first SPS corresponding to the new SPS resource; f) the target SPS resource comprises a resource corresponding to the identifier of the second SPS; and g) the processing unit is further configured to: after the DCI is sent to the UE, release the target SPS resource based on the identifier of the second SPS.']",True,"['300', '31', '32', '33', '8', '44', '43', '9', '30']" 24,EP_3507964_B1 (3).png,EP3507964B1,MALWARE DETECTION FOR PROXY SERVER NETWORKS,['FIG4'],['FIG4 is a diagram of computing devices that may be used to implement the systems and methods described herein Like reference numbers and designations in the various drawings indicate like elements '],"['FIG4 is a block diagram of computing devices 400, 450 that may be used to implement the systems and methods described in this document, as either a client or as a server or plurality of servers. Computing device 400 is intended to represent various forms of digital computers, such as laptops, desktops, workstations, personal digital assistants, servers, blade servers, mainframes, and other appropriate computers. Computing device 450 is intended to represent various forms of mobile devices, such as personal digital assistants, cellular telephones, smartphones, and other similar computing devices. Additionally, computing device 400 or 450 can include Universal Serial Bus (USB) flash drives. The USB flash drives may store operating systems and other applications. The USB flash drives can include input/output components, such as a wireless transmitter or USB connector that may be inserted into a USB port of another computing device. The components shown here, their connections and relationships, and their functions, are meant to be exemplary only, and are not meant to limit implementations of the inventions described and/or claimed in this document.']",31,206,diagram,G,"[{'element_identifier': '464', 'terms': ['memory']}, {'element_identifier': '416', 'terms': ['display']}, {'element_identifier': '404', 'terms': ['memory']}, {'element_identifier': '412', 'terms': ['controller']}, {'element_identifier': '470', 'terms': ['receiver module']}, {'element_identifier': '400', 'terms': ['computing device', 'computing devices']}, {'element_identifier': '414', 'terms': ['low speed bus', 'low-speed expansion port']}, {'element_identifier': '402', 'terms': ['processor']}, {'element_identifier': '468', 'terms': ['transceiver']}, {'element_identifier': '456', 'terms': ['display interface']}, {'element_identifier': '424', 'terms': ['rack server system']}, {'element_identifier': '480', 'terms': ['cellular telephone']}, {'element_identifier': '458', 'terms': ['control interface']}, {'element_identifier': '454', 'terms': ['display']}, {'element_identifier': '462', 'terms': ['external interface']}, {'element_identifier': '420', 'terms': ['standard server']}, {'element_identifier': '452', 'terms': ['processor']}, {'element_identifier': '472', 'terms': ['through expansion interface']}, {'element_identifier': '406', 'terms': ['storage device']}, {'element_identifier': '408', 'terms': ['interface', 'controller']}]","['8. A non-transitory, computer-readable medium storing instructions operable when executed to cause at least one processor to perform operations comprising the method of any one of claims 1 to', '9. 9. A system comprising: memory for storing instructions; and one or more processors operable to execute the stored instructions to cause the system to perform operations comprising the method of any one of claims 1 to']",False,"['416', '400', '408', '404', '412', '406', '420', '402', '414', '424', '17', '480', '470', '472', '166', '468', '464', '4', '452', '458', '094', '462', '456', '454']" 25,EP_3509062_B1.png,EP3509062B1,"AUDIO RECOGNITION DEVICE, AUDIO RECOGNITION METHOD, AND PROGRAM",['FIG1'],['FIG1 is a block diagram showing a configuration example of an audio recognition system according to an embodiment to which the present technology is applied'],"['FIG1 is a block diagram showing a configuration example of an audio recognition system according to an embodiment to which the present technology is applied.', 'As shown in FIG1, a plurality of (N in the example of FIG1) client terminals 13-1 to 13-N and an audio recognition server 14 are connected to an audio recognition system 11 via a network 12 such as the Internet. Note that the client terminals 13-1 to 13-N are configured similarly to each other, and hereinafter, are referred to as a client terminal 13 as appropriate in a case where there is no need to distinguish each other.', 'The communication unit 21 performs various types of communication with the client terminal 13 via the network 12 in FIG1. For example, the communication unit 21 receives the audio information transmitted from the client terminal 13 and supplies the audio information to the input sound processing unit 22. Furthermore, the communication unit 21 transmits the audio recognition result information supplied from the audio recognition result output processing unit 27 to the client terminal 13.']",25,200,block diagram,G,"[{'element_identifier': '14', 'terms': ['audio recognition server', 'audio recognition servers']}, {'element_identifier': '12', 'terms': ['network']}, {'element_identifier': '1', 'terms': ['Patent Document']}]","['12. The audio recognition apparatus according to claim 1, further comprising: a communication unit that communicates with another apparatus via a network; and an input sound processing unit that performs processing of detecting a speech section in which the audio information includes audio, wherein the communication unit acquires the audio information transmitted from the another apparatus via the network, supplies the audio information to the input sound processing unit, and transmits the audio recognition result information output from the output processing unit to the another device via the network.']",False,"['1', '14', '12', '19']" 26,EP_3509278_B1 (3).png,EP3509278B1,ELECTRONIC COMPONENT AND ELECTRONIC DEVICE COMPRISING SAME,['FIG5'],['FIG5 is a cross-sectional view illustrating an electronic component according to various embodiments of the present disclosure'],"['Further referring to FIG5, the electronic component 404 may include at least one recess 441a formed in the substrate 441. The recess 441a is formed on the other face of the substrate 441 (e.g., the face opposite the face on which the sensor element 443 is disposed or the face facing the flexible printed circuit board 449) at or adjacent to an edge of the other face. In one embodiment, when the flexible printed circuit board 449 extends to one side of the substrate 441 in a first direction D1, the recess 441a may extend in a second direction D2 intersecting or orthogonal to the first direction D1. The flexible printed circuit board 449 may be disposed to be at least partially correspond to a region where the solder bumps 449a are arranged on the other face of the substrate 441, and may extend to pass through the section where the recess 441a is formed. For example, the recess 441a may extend across the region facing the flexible printed circuit board 449 on the other face of the substrate 441. In some embodiments, the extending length of the recess 441a may be greater than or equal to the width W1 or W2 of the flexible printed circuit board.']",19,223,cross-sectional view,A,"[{'element_identifier': '451', 'terms': ['molding portion']}, {'element_identifier': '601', 'terms': ['package manufacturing operation']}, {'element_identifier': '605', 'terms': ['post-processing operation']}, {'element_identifier': '449', 'terms': ['flexible printed circuit board']}, {'element_identifier': '600', 'terms': ['electronic component manufacturing method']}, {'element_identifier': '604', 'terms': ['cutting operation']}, {'element_identifier': '602', 'terms': ['mounting operation']}, {'element_identifier': '404', 'terms': ['electronic component']}, {'element_identifier': '603', 'terms': ['molding operation']}]","['1. An electronic component (304, 404, 704) comprising: a substrate (341, 441, 741) having a sensor element (343, 443, 743) mounted on one face thereof; a flexible printed circuit board (349, 449, 749) coupled to face a remaining face of the substrate and extending to one side of the substrate in a first direction (D1); characterised by at least one recess (441a, 741c) formed at an edge of the remaining face of the substrate, wherein the recess is located at least in a region facing the flexible printed circuit board on the remaining face of the substrate and extends in a second direction (D2) intersecting the first direction.', '4. The electronic component of claim 1, further comprising: a molding portion (351, 451, 751) provided to enclose at least a periphery of the substrate.']",True,"['404', '44', '451', '449', '600', '601', '602', '603', '605', '604', '16']" 27,EP_3509396_B1 (1).png,EP3509396B1,INDUCTION HEATING DEVICE AND LOAD DETECTION METHOD IN INDUCTION HEATING DEVICE,['FIG3'],"['FIG3 is a view illustrating sections A and B included in left heating zone Lh, right heating zone Rh, and central heating zone Ch, respectively']","['FIG3 is a view illustrating two sections (sections A and B) included in left heating zone Lh, right heating zone Rh, and central heating zone Ch, respectively.', 'As illustrated in FIG3, in left heating zone Lh and right heating zone Rh, section A has two heating coils 3 which are heating coil A1 and heating coil A2 arranged behind heating coil A1. Section B has two heating coils 3 which are heating coil B1 and heating coil B2 arranged behind heating coil B1.']",28,94,view,H,"[{'element_identifier': '8', 'terms': ['switching unit', 'switching units']}, {'element_identifier': '23', 'terms': ['output current detector']}, {'element_identifier': '4', 'terms': ['driver', 'drivers']}, {'element_identifier': '50', 'terms': ['controller']}, {'element_identifier': '10', 'terms': ['detector']}, {'element_identifier': '3', 'terms': ['heating coils', 'heating coil']}]","['1. An induction heating device comprising: a top panel (2) on which a load is placeble; a plurality of heating coils (3, 31, 32, 33, 34, A1, A2, B1, B2) provided below the top panel (2); a driver (4) configured to supply a high frequency power to the plurality of heating coils (3, 31, 32, 33, 34, A1, A2, B1, B2); an electric signal detector (10) configured to detect an electric signal relating to an element included in the driver (4); and a controller (50) configured to receive the electric signal and control the driver (4), characterized in that the controller (50) is configured to cause the driver (4) to supply a first detection current which is a high frequency power to the plurality of heating coils (3, 31, 32, 33, 34, A1, A2, B1, B2), and determine whether the load is placed above the plurality of heating coils (3, 31, 32, 33, 34, A1, A2, B1, B2) based on an electric signal in response to the first detection current, and when determining that the load is not placed above the plurality of heating coils (3, 31, 32, 33, 34, A1, A2, B1, B2) based on the first detection current, the controller (50) is configured to cause the driver (4) to supply a second detection current which is a high frequency power and has a larger current value than the current value of the first detection current to the plurality of heating coils (3, 31, 32, 33, 34, A1, A2, B1, B2), and determine whether the load is placed above the plurality of heating coils (3, 31, 32, 33, 34, A1, A2, B1, B2) based on an electric signal in response to the second detection current.', '2. The induction heating device according to claim 1, further comprising a switching unit (8) configured to connect or disconnect each of the plurality of heating coils (3, 31, 32, 33, 34, A1, A2, B1, B2) to or from the driver (4) under control of the controller (50), wherein, when the first detection current or the second detection current is supplied, the controller (50) causes the switching unit (8) to connect all of the plurality of heating coils (3, 31, 32, 33, 34, A1, A2, B1, B2) to the driver (4), when determining that the load is placed above the plurality of heating coils (3, 31, 32, 33, 34, A1, A2, B1, B2) based on the electric signal in response to the first detection current or the second detection current, the controller (50) controls the driver (4) and the switching unit (8) such that a third detection current which is a high frequency power is sequentially and independently supplied to each of the plurality of heating coils (3, 31, 32, 33, 34, A1, A2, B1, B2), and the controller (50) determines whether the load is placed above each of the plurality of heating coils (3, 31, 32, 33, 34, A1, A2, B1, B2) based on an electric signal in response to the third detection current.']",True,"['3', '3', '3', '3', '3', '3', '4', '3', '8', '3', '8', '10', '50', '23']" 28,EP_3510908_B1 (1).png,EP3510908B1,ACCESSORY FOR A VACUUM CLEANER SUCTION HEAD FOR COLLECTING LARGE DEBRIS,['FIG2'],['FIG2 is another axonometric view of the suction head separate from the accessory according to the first embodiment of the invention'],"['The base plate 11 of the suction head 1 is shown in FIG2. This figure also shows the base plate channel 12, the surface around said channel (which often is decisive for the vacuuming performance), and the two seats for strips of velvet.']",21,49,axonometric view,A,"[{'element_identifier': '24', 'terms': ['ribs', 'rib']}, {'element_identifier': '201', 'terms': ['accessory']}, {'element_identifier': '12', 'terms': ['channel']}, {'element_identifier': '11', 'terms': ['base plate']}, {'element_identifier': '25', 'terms': ['wheels']}, {'element_identifier': '21', 'terms': ['main body']}, {'element_identifier': '23', 'terms': ['edges']}]","['1. An accessory (201, 202, 203, 204, 205) for a suction head (1) for a vacuum cleaner, said accessory (201-205) comprising engaging means (29) configured for removably connecting said accessory to said suction head (1) at its base plate (11), wherein said accessory (201-205) comprises a main body (21) having a lower face (21A) which, during use, is directed towards the surface to be vacuumed, and a top face (21B) comprising said engaging means (29) wherein said main body (21) comprises a transverse slot (22) configured to be situated in correspondence to the mouth of a channel (12) of the base plate (11) of the suction head (1) when said accessory (201-205) is connected to said suction head (1); wherein said main body (21) comprises spacer members (23, 24, 25) for spacing, during use, the lower face (21A) of said main body (21) with respect to the surface to be vacuumed; and wherein said spacer members (23, 24, 25) comprise a longitudinal rib system (23, 24) comprising a plurality of front longitudinal ribs (24) upstream of said transverse slot (22) and a plurality of rear longitudinal ribs (24) downstream of said transverse slot (22) forming tunnels.', '2. The accessory (201-205) according to claim 1, wherein said longitudinal rib system (23, 24) comprises lateral edges (23) along the lateral sides of the accessory (201-205).', '4. The accessory (201-205) according to claim 3, wherein said wheel system (25) comprises four wheels (25) arranged within the general contour of the accessory (201-205).']",False,"['12', '201', '25', '23', '10', '11', '24', '21', '24', '24', '25', '23']" 29,EP_3511789_B1 (2).png,EP3511789B1,CUTTING SYSTEM,['FIG3'],['FIG3 is a plan view of a workpiece to which an adapter is attached according to the embodiment'],"['The first cutting machines 20A and 20B are each a device that accommodates a plurality of workpieces 5 (see FIG3), selects one of the workpieces 5 accommodated therein, and cuts the selected workpiece 5. The second cutting machines 20C and 20D are each a device that cuts one workpiece 5 accommodated therein. For example, the cutting machines 20A to 20D each machine a workpiece 5 to produce a dental prosthesis. The shape of the workpiece 5 is a circular plate shape, for example. The workpiece 5 is formed from any of various materials such as zirconia, wax, polymethylmethacrylate resin (PMMA), hybrid resin, PEEK (polyetheretherketone resin) and gypsum. When zirconia is used as the material of a workpiece 5, a semi-sintered zirconia is used, for example. Note however that there is no particular limitation on the shape and the material of the workpiece 5.', 'As shown in FIG3, in the present embodiment, an adapter 8 (referred to also as a holder) is attached to the workpiece 5. The workpiece 5, with the adapter 8 attached thereto, is accommodated in and machined by the cutting machines 20A to 20D. Herein, an insertion hole 8a is formed in the central portion of the adapter 8. The workpiece 5 is attached to the adapter 8 as the workpiece 5 is inserted into the insertion hole 8a. In the following description, a workpiece 5 refers to a workpiece 5 that is attached to the adapter 8. A workpiece 5 includes, beside the workpiece 5, the adapter 8 attached to the workpiece 5.']",18,298,plan view,G,"[{'element_identifier': '5', 'terms': ['workpiece', 'workpieces']}]","['1. A cutting system (10) comprising: a first cutting machine (20A,20B) that machines a workpiece (5) to produce a dental prosthesis; a second cutting machine (20C,20D) that machines a workpiece (5) to produce a dental prosthesis; a display device (70) that displays first model information of the first cutting machine (20A,20B) and second model information of the second cutting machine (20C,20D); and a controller (54) that is connected to the first cutting machine (20A,20B) and the second cutting machine (20C,20D) and transmits job data for the dental prosthesis to the first cutting machine (20A,20B) and the second cutting machine (20C,20D), wherein the controller (54) includes: a first display controller (56) that displays a basic screen (72X) on the display device (70), the basic screen (72X) including a common area (74) where a first screen (75) showing some of common items that are common between the first model information and the second model information is displayed, and a specific area (90) where a second screen (91) showing some other ones of the common items that are common between the first model information and the second model information or a second screen (91) showing the other ones of the common items and specific items included in one of the first model information and the second model information is displayed; a second display controller (58) that displays the first screen (75) in the common area; a switcher (62) that switches between displaying the first model information and displaying the second model information on the basic screen (72X); and a third display controller (60) that displays the second screen (91) associated with the first cutting machine (20A,20B) in the specific area (90) when display is switched to the first model information, and that displays the second screen (91) associated with the second cutting machine (20C,20D) in the specific area (90) when display is switched to the second model information.']",False,"['5', '20']" 30,EP_3511789_B1.png,EP3511789B1,CUTTING SYSTEM,['FIG1'],['FIG1 is a schematic view showing an exemplary configuration of a cutting system according to one embodiment'],"['As shown in FIG1, a cutting system 10 (which may be referred to as the ""system 10"" as appropriate) includes first cutting machines 20A and 20B, second cutting machines 20C and 20D, and a control terminal 50. Hereinafter, the first cutting machines 20A and 20B and the second cutting machines 20C and 20D may be referred to as the cutting machines 20A to 20D as appropriate. The cutting machines 20A to 20D are connected to the control terminal 50 via lines L so as to enable wired communication. Note that the cutting machines 20A to 20D and the control terminal 50 may communicate with each other wirelessly. While four cutting machines 20A to 20D are connected to one control terminal 50 in the present embodiment, two, three or five or more cutting machines may be connected to one control terminal 50.']",17,156,schematic view,G,"[{'element_identifier': '30', 'terms': ['machining device']}, {'element_identifier': '40', 'terms': ['carrier device']}, {'element_identifier': '50', 'terms': ['control terminal']}, {'element_identifier': '10', 'terms': ['system']}, {'element_identifier': '71', 'terms': ['input device']}]","['1. A cutting system (10) comprising: a first cutting machine (20A,20B) that machines a workpiece (5) to produce a dental prosthesis; a second cutting machine (20C,20D) that machines a workpiece (5) to produce a dental prosthesis; a display device (70) that displays first model information of the first cutting machine (20A,20B) and second model information of the second cutting machine (20C,20D); and a controller (54) that is connected to the first cutting machine (20A,20B) and the second cutting machine (20C,20D) and transmits job data for the dental prosthesis to the first cutting machine (20A,20B) and the second cutting machine (20C,20D), wherein the controller (54) includes: a first display controller (56) that displays a basic screen (72X) on the display device (70), the basic screen (72X) including a common area (74) where a first screen (75) showing some of common items that are common between the first model information and the second model information is displayed, and a specific area (90) where a second screen (91) showing some other ones of the common items that are common between the first model information and the second model information or a second screen (91) showing the other ones of the common items and specific items included in one of the first model information and the second model information is displayed; a second display controller (58) that displays the first screen (75) in the common area; a switcher (62) that switches between displaying the first model information and displaying the second model information on the basic screen (72X); and a third display controller (60) that displays the second screen (91) associated with the first cutting machine (20A,20B) in the specific area (90) when display is switched to the first model information, and that displays the second screen (91) associated with the second cutting machine (20C,20D) in the specific area (90) when display is switched to the second model information.']",False,"['10', '40', '30', '30', '50', '18', '40', '30', '71', '30']" 31,EP_3513064_B1 (3).png,EP3513064B1,BLADE TIP EXTENSION,['FIG4'],['FIG4 shows components of a lightning protection system already present inside the blade'],"[""FIG4 schematically shows the tip end 24 of the wind turbine blade 18 to which the tip extension 20 (not shown in FIG4) is to be fitted. The blade 18 includes a lightning protection system 60. The lightning protection system 60 comprises a lightning receptor block 62 inside the tip 64 of the blade 18. In this example, the lightning receptor block 62 is a brass block. A lightning receptor (not shown), referred to as a 'blade tip receptor' and typically in the form of a brass bolt, is screwed through the outer shell 66 of the blade 18 and into the brass block 62. The lightning receptor block 62 is hereafter referred to as the 'blade tip receptor block' 62.""]",13,138,schematic,F,"[{'element_identifier': '24', 'terms': ['tip end']}, {'element_identifier': '72', 'terms': ['dashed line']}, {'element_identifier': '18', 'terms': ['blade', 'blades']}, {'element_identifier': '64', 'terms': ['tip']}, {'element_identifier': '74', 'terms': ['end surface']}, {'element_identifier': '76', 'terms': ['connector']}, {'element_identifier': '16', 'terms': ['rotor']}, {'element_identifier': '66', 'terms': ['outer shell']}, {'element_identifier': '62', 'terms': ['block']}, {'element_identifier': '60', 'terms': ['system']}, {'element_identifier': '70', 'terms': ['down conductor cable']}, {'element_identifier': '68', 'terms': ['polyurethane implant']}]","['1. A wind turbine blade assembly (22) comprising: a wind turbine blade (18) having a tip end (24) defining an end surface (74) of the blade; a blade lightning protection system (60) provided inside the blade and having a blade tip receptor block (62) inside the tip end of the blade; a blade tip connector (76) mounted at a predetermined position to the end surface of the blade and electrically connected to the blade tip receptor block; a tip extension (20) in the form of a sock fitted over the tip end of the blade to extend the length of the blade, the tip extension including one or more lightning receptors (50); a tip extension connector (54) fixed at a predetermined position inside the tip extension and electrically connected to the one or more lightning receptors of the tip extension; wherein the predetermined positions of the blade tip connector (76) and the tip extension connector (54) are selected such that when the tip extension is fitted to the blade, the connecters are mutually aligned and form a push-fit connection inside the tip extension.', '10. A tip extension (20) for the wind turbine blade assembly (22) of any preceding claim, wherein the tip extension is in the form of a sock and comprises an outer shell (28) defining a substantially hollow interior for receiving a tip end (24) of a wind turbine blade (18), and wherein the tip extension includes one or more lightning receptors (50) and a tip extension connector (54) fixed at a predetermined position within the interior of the tip extension and electrically connected to the lightning receptor(s), characterised in that the tip-extension connector being arranged to form a push-fit connection with a blade tip connector (76) provided at the tip end of the blade when the tip extension is fitted to the blade in order to connect the lightning receptor(s) of the tip extension to a lightning protection system (60) of the blade.']",True,"['18', '70', '60', '62', '24', '66', '68', '4', '64', '72', '18', '66', '68', '76', '74', '5', '16']" 32,EP_3513139_B1 (3).png,EP3513139B1,ROBOT ARM LAUNCHING SYSTEM,"['FIG5', ' FIG6']","['FIG6 is a schematic drawing showing a payload guide of the launching assembly ', 'FIG5 is a schematic drawing showing the launching assembly during operation using a second type of effector']","['Referring in addition to FIG6, the payload guide 44 may include an electro-mechanical interface, such as an electro-mechanical case 90. The adaptor 88 and the electro-mechanical case 90 of the payload guide 44 may be in communication with the control system 20b. The payload guide 44 may be configured to send and receive data from the control system 20b. The electro-mechanical case 90 may include at least one sensor 92 for sensing a number of effectors 48, 52, 54 in the payload guide 44. The control system 20b may include a converting module 94 that is in communication with the electro-mechanical case 90 for converting electronic messages and power from the control system 20b to a signal that is readable by the effectors 48, 52, 54 for executing a launching sequence. The electro-mechanical case 90 may also include at least one electrical connector 93 or a plurality of electrical connectors that mate with the effectors 48, 52, 54 to charge batteries of the effectors 48, 52, 54 when the effectors are being stored. The electrical connector 93 may be electrically connected to a power source for transferring power to the effectors. The electrical connector 93 may be connected to the power source via additional electrical connections in the payload guide magazine. ', 'As shown in FIG5, the end portion 84 may be engageable with an adaptor 88 arranged on an electro-mechanical case 90 of the canister or payload guide 44. The end portion 84 may be rotatable about a horizontal axis of the distal portion 80 to engage the adaptor 88. The end portion 84 may be rotated to extend vertically downward and lowered via the distal portion 80 pivoting in a vertically downward direction. The end portion 84 may engage the payload guide 44 within the payload guide magazine 34 when the payload guide 44 is in a stored position. After engagement with the adaptor 88 of the payload guide 44, the adaptor 88 and the end portion 84 may be locked together for movement such that the distal portion 80 may be pivoted in a vertically upward direction to raise the payload guide 44 out of the payload guide magazine 34. The payload guide 44 may then be in an engaged position where the payload guide 44 is engaged with the end portion 84. The end portion 84 may then be rotated to extend vertically upward for firing the effector 48 from the payload guide 44.', 'As shown in FIG5, the payload guide 44 may be configured to hold two second effectors 48 and the corresponding payload guide magazine 28 may be configured to hold five payload guides, such that the payload guide magazine 28 associated with the second effectors may contain ten second effectors. All of the numbers are just examples, and any number of effectors may be used. The robot arm 72 may be configured to move up to around 453 kilograms (around 1000 pounds). As also shown in FIG5, the robot arm 72 may also be configured to engage the first effectors. The payload guide magazine 32 may be configured to hold 3 first effector containers that each contain a single first effector. The payload guide magazines 28, 32, 34 may be configured to hold more or fewer containers or payload guides such that more or fewer effectors may be contained and used during various launching sequences.']",30,617,schematic,B,"[{'element_identifier': '28', 'terms': ['guide magazine', 'guide magazines']}, {'element_identifier': '30', 'terms': ['canisters', 'canister']}, {'element_identifier': '80', 'terms': ['distal portion']}, {'element_identifier': '48', 'terms': ['effectors', 'effector']}, {'element_identifier': '94', 'terms': ['converting module']}, {'element_identifier': '93', 'terms': ['electrical connector']}, {'element_identifier': '34', 'terms': ['payload guide magazine']}, {'element_identifier': '40', 'terms': ['housing']}, {'element_identifier': '76', 'terms': ['proximate portion']}, {'element_identifier': '78', 'terms': ['proximate end']}, {'element_identifier': '90', 'terms': ['electro-mechanical case']}, {'element_identifier': '16', 'terms': ['launching sequence may require']}, {'element_identifier': '88', 'terms': ['adaptor']}, {'element_identifier': '26', 'terms': ['robot']}, {'element_identifier': '82', 'terms': ['distal end']}, {'element_identifier': '70', 'terms': ['main body']}, {'element_identifier': '74', 'terms': ['one joint']}, {'element_identifier': '32', 'terms': ['payload guide magazine']}]","['1. An effector launching system (20) that is located on a moving platform (24), the launching system comprising: a plurality of effectors (48, 52, 54, 86); a robot (26) that includes: a main body (70) that is fixed to the moving platform, and a moveable robot arm (72) having an end portion (84) that is engageable with the plurality of effectors for firing the plurality of effectors; a sensor (98) for detecting movement of the moving platform; a processor (100) that is in communication with the sensor; and a motion stabilization controller (102) that is in communication with the processor and the robot arm for controlling movement of the robot arm, wherein the motion stabilization controller adjusts the robot arm in response to the detected movement of the moving platform to maintain the end portion in a static position when the end portion is engaged with at least one of the plurality of effectors; and further comprising a payload guide (44, 50) that houses the plurality of effectors, wherein the payload guide has an engaged position and a storage position, the payload guide being engaged with the end portion of the robot arm when in the engaged position for firing the effector from the payload guide, the payload guide being disengaged from the end portion when in the storage position.', '3. The effector launching system of claim 1 or 2 further comprising a payload guide magazine (28, 32, 34) that houses a plurality of payload guides, the payload guide magazine being configured to automatically dispense one of the plurality of payload guides when another one of the plurality of payload guides is expended.']",True,"['80', '90', '82', '4', '48', '38', '34', '28', '32', '78', '76', '30', '26', '74', '70', '40', '6', '94', '88', '93', '90', '48', '52', '6', '16']" 33,EP_3513536_B1.png,EP3513536B1,SYSTEM AND METHOD FOR SIGNAL DENSITY REDUCTION IN FREQUENCY DOMAIN,['FIG4'],['FIG4 illustrates an example table of frequency domain density reduction information according to example embodiments described herein'],"['According to an example embodiment, a frequency domain density reduction rate indicator is provided to reduce the overhead associated with indicating the frequency domain density reduction rate. The frequency domain density reduction rate indicator may be in the form of an index into a table (or some other similar data arrangement). FIG4 illustrates an example table 400 of frequency domain density reduction rate information. Table 400 includes a frequency domain density reduction rate indication 405 and associated CSI-RS transmission frequency 410. As an illustrative example, an indicator of 1 indicates that every other PRB conveys the CSI-RS, while an indicator of 0 indicates that every PRB conveys the CSI-RS.']",17,125,table,H,"[{'element_identifier': '1', 'terms': ['Step']}, {'element_identifier': '100', 'terms': ['communications system']}, {'element_identifier': '400', 'terms': ['table']}, {'element_identifier': '2', 'terms': ['Step']}, {'element_identifier': '105', 'terms': ['access node']}, {'element_identifier': '405', 'terms': ['density reduction rate indication']}, {'element_identifier': '110', 'terms': ['including UEs']}, {'element_identifier': '410', 'terms': ['associated CSI-RS transmission frequency']}]","['1. A method for operating an access node, the method comprising: sending (509), by the access node to a user equipment, UE, a frequency domain density reduction rate indicator and a frequency shift index indicator for one or more channel state indicator reference signal, CSI-RS, resources, wherein the frequency domain density reduction rate indicator indicates a number of physical resource blocks, PRBs, skipped between successive CSI-RS transmissions and the frequency shift index indicator indicates a shift of a CSI-RS starting PRB; wherein the frequency domain density reduction rate indicator and/or the frequency shift index indicator corresponding to each CSI-RS resource in an active set of K CSI-RS resources are sent during a radio resource control, RRC, configuration stage of a CSI-RS resource configuration process; wherein at least one frequency domain density reduction rate indicator and/ or at least one frequency shift index indicator configured during the RRC configuration stage is reconfigured for at least one CSI-RS resource in an activated set of N CSI-RS resources during an activation/release stage of the CSI-RS resource configuration process by sending, to the UE, uplink grants and/or medium access control, MAC, control elements, CE; and wherein at least one frequency domain density reduction rate indicator and/or at least one frequency shift index indicator configured during the RRC configuration stage and/ or at least one CSI-RS resource in the activated set of N CSI-RS resources configured during the activation/ release stage of the CSI-RS resource configuration process is reconfigured by sending, to the UE, downlink control information, DCI.']",True,"['116', '100', '112', '105', '110', '1', '400', '405', '410', '2', '3', '4', '17']" 34,EP_3513669_B1 (2).png,EP3513669B1,"CONDUCTIVE CONTACT STRUCTURE, BATTERY ASSEMBLY AND ELECTRONIC CIGARETTE HAVING SAME",['FIG5'],['FIG5 is a schematic perspective diagram illustrating a connecting structure of a sealing member according to the present disclosure'],"['Specifically, as shown in FIG5, in the embodiment of the present disclosure, the sealing member 14 comprises a large-diameter section 141 and at least one small-diameter section 142 located at an outer periphery of the large-diameter section 141. The large-diameter section 141 blocks the through-hole 1111 and is provided with a retaining hole 1411 through which the positive electrode assembly 12 passes, and the small-diameter section 142 is provided with a positioning groove 1421/positioning block 1311. Here, in the embodiment, two small-diameter sections 142 are provided at both sides of the large-diameter section 141. The large-diameter section 141 blocks the through-hole 1111, thereby effectively preventing oil from penetrating from the through-hole 1111. The two small-diameter sections 142 are integrally formed with the large diameter section 141, and two positioning grooves 1421 are sleeved on the two positioning blocks 1311 provided by the insulating assembly 13, preventing the one-piece sealing member 14 with a large diameter from sealing, effectively saving the material cost, and reducing the installation space 70 at the same time.']",19,216,schematic perspective diagram,A,"[{'element_identifier': '1411', 'terms': ['retaining hole']}, {'element_identifier': '14', 'terms': ['sealing member']}, {'element_identifier': '1421', 'terms': ['positioning grooves', 'positioning groove']}]","['1. A conductive contact structure suitable to be used in a battery assembly (100), wherein the battery assembly (100) comprises a cover body (50) and a main body (30) in which a main control board (90) is built, wherein an installation space (70) is formed between the cover body (50) and the main body (30), wherein the conductive contact structure (10) comprises a negative electrode assembly (11), a sealing member (14), an insulating assembly (13) and a positive electrode assembly (12), which are provided in the installation space (70) sequentially, the negative electrode assembly (11) passes through the cover body (50) to abut against the sealing member (14), the negative electrode assembly (11) is provided with a through-hole (1111) in which an external load is installed, one end of the insulating assembly (13) covers the positive electrode assembly (12) in the main body (30), and the other end abuts against the sealing member (14), the positive electrode assembly (12) partially passes through the insulating assembly (13) and the sealing member (14) sequentially, the positive electrode assembly (12) is received in the through-hole (1111), and the main control board (90) is electrically connected to the positive electrode assembly (12) and the negative electrode assembly (11); characterized in that one of the insulating assembly (13) and the sealing member (14) is provided with at least one positioning block (1311), while the other thereof is provided with a positioning groove (1421), one of the positioning blocks (1311) is inserted into one of the positioning grooves (1421), and the sealing member (14) is fixed to the insulating assembly (13).', '2. The conductive contact structure according to claim 1, wherein the sealing member (14) comprises a large-diameter section (141) and at least one small-diameter section (142) located at an outer periphery of the large-diameter section (141), the large-diameter section (141) blocks the through-hole (1111) and is provided with a retaining hole (1411) through which the positive electrode assembly (12) passes, and the small-diameter section (142) is provided with a positioning groove (1421)/a positioning block (1311).']",True,"['4', '1421', '1411', '5', '14']" 35,EP_3513821_B1.png,EP3513821B1,MATERIAL FOR BLOOD PURIFICATION,"['FIG1', ' FIG2']","['FIG1 is a view showing the opening portions and the non-opening portions in the material for blood purification in the form of a knitted fabric ', 'FIG2 is a schematic view of a circuit and a device used in a pressure loss measurement test ']","['The opening ratio means a ratio of the opening portions to the sum of the opening portions (3 in FIG1) and the non-opening portions (2 in FIG1) in the material for blood purification in the form of a knitted fabric, and is a value obtained by image processing. Specifically, the opening ratio is calculated using the following procedures. ', 'A pressure loss of the material for blood purification in the form of a knitted fabric can be measured by laminating layers of the material for blood purification in the form of a knitted fabric and allowing simulated blood to pass through the laminate perpendicularly. In this regard, the simulated blood refers to a solution set so as to have the same rate of shear as that of human blood, and examples of the simulated blood include a 50 wt% glycerin aqueous solution. A specific measurement method will be described below. First, layers of the material for blood purification in the form of a knitted fabric are laminated in a container having an inlet and outlet at the top and bottom. The material for blood purification in the form of a knitted fabric is set to have a loading density of 0.30 g/cm3 in the container. Next, simulated blood is allowed to pass through the container at a given flow rate, and the inlet pressure and outlet pressure are each measured. Then, a pressure loss can be determined by subtracting the outlet pressure value from the inlet pressure value. The flow rate (mL/min) of simulated blood in measurement is set on the basis of 100mL/min per 145 cm3 of container volume, taking clinical practice of blood purification into consideration. With a container having a volume of, for example, 5 cm3, a measurement is carried out with the flow rate set at 100 mL/min/ 145 cm3 × 5 cm3 = 3.4 mL/min. A schematic view of a circuit and a device used in a pressure loss measurement test is shown in FIG2. In FIG2, simulated blood or human blood 5 which is ready for passing through a column 4 is sucked up using a pump 10 and is allowed to pass through the column 4. At this time, an inlet pressure measurement device 8 and an outlet pressure measurement device 9 are used to measure the respective pressures to thereby determine a pressure loss. Simulated blood or human blood 5 which is ready for passing through the column is kept in a constant temperature water bath 11 at a constant temperature of 37°C. In addition, a constant temperature water bath 11 is kept at constant temperature using a heater 12. For a circuit 7, a commercially available blood circuit can be used.']",45,502,"schematic view, view",A,"[{'element_identifier': '7', 'terms': ['Material']}, {'element_identifier': '12', 'terms': ['Material']}, {'element_identifier': '11', 'terms': ['Material']}, {'element_identifier': '2', 'terms': ['Material']}, {'element_identifier': '64', 'terms': ['mixed with']}, {'element_identifier': '6', 'terms': ['in Table']}, {'element_identifier': '10', 'terms': ['in Table']}, {'element_identifier': '3', 'terms': ['Material']}]","['1. A material for blood purification, the material comprising a water-insoluble material in which a ligand having an amide group(s) and an amino group(s) is bound to a substrate, wherein the content of the amide group(s) is 3.0 to 7.0 mmol per 1 g dry weight of the water-insoluble material; and wherein the content of the amino group(s) is 1.0 to 7.0 mmol per 1 g dry weight of the water-insoluble material.']",True,"['2', '3', '7', '6', '10', '12', '11', '64']" 36,EP_3514490_B1 (2).png,EP3514490B1,MICROELECTROMECHANICAL SYSTEM (MEMS) DEVICE READOUT WITH OPTICAL DIRECTIONAL COUPLER,['FIG2'],['FIG2 is a cross-section view of the MEMS device of FIG1 according to the embodiments of the present disclosure'],"['As shown in FIG2, in one embodiment, the waveguides 122 and 124 are fabricated on substrate 140. In example embodiments, substrate 140 is fabricated from at least one of glass, silicon or silicon oxide. In one such embodiment, waveguides 122 and 124 may be fabricated photolytically on the substrate 140 from at least one of epoxy and silicon. In some example embodiments, waveguides 122 and 124 are fabricated from epoxy on a glass substrate 140. In some example embodiments, waveguides 122 and 124 are fabricated from silicon on a silicon oxide substrate 140.']",21,105,cross-sectional view,G,"[{'element_identifier': '7', 'terms': ['fourth optical power.Example']}, {'element_identifier': '100', 'terms': ['MEMS device']}, {'element_identifier': '20', 'terms': ['second optical power.Example']}, {'element_identifier': '105', 'terms': ['electrode']}, {'element_identifier': '147', 'terms': ['silicon oxide layer']}, {'element_identifier': '115', 'terms': ['vibrating proof mass']}, {'element_identifier': '140', 'terms': ['substrate']}, {'element_identifier': '110', 'terms': ['substrate']}, {'element_identifier': '150', 'terms': ['reference']}]","['1. A microelectromechanical systems (MEMS) device comprising: an optical directional coupler comprising: at least one light source configured to provide a light beam; at least one substrate; a first waveguide formed on the at least one substrate, the first waveguide having a first end and the second end, wherein the first end of the first waveguide is coupled to the at least one light source, wherein the light beam is introduced into the first end of the first waveguide; a second waveguide formed on the substrate, the second waveguide having a third end and a fourth end, wherein the first waveguide and the second waveguide are positioned adjacent to each other at a central region of the optical directional coupler at a distance such that the light beam is at least partially evanescently coupled between the first waveguide and the second waveguide in the central region when the light beam is introduced into the first end of the first waveguide; a first photodetector coupled to a second end of the first waveguide, wherein the first photodetector is configured to detect a first optical power in the light beam propagating through the first waveguide at the second end; and a second photodetector coupled to a fourth end of the second waveguide, wherein the second photodetector is configured to detect a second optical power in the light beam propagating through the second waveguide at the fourth end; at least one vibrating proof mass positioned adjacent to the optical directional coupler in a first direction from the optical directional coupler, wherein the at least one vibrating proof mass is equidistant from the first waveguide and the second waveguide, wherein when one or more inertial forces are applied to the MEMS device in at least one of the first and a second direction, the at least one vibrating proof mass is configured to move in the first direction; at least one processor coupled to the first photodetector and the second photodetector, wherein the processor is configured to determine the displacement of the at least one proof mass from the optical directional coupler as a function of the first optical power and the second optical power.']",False,"['100', '140', '115', '20', '147', '105', '7', '150', '147', '110']" 37,EP_3514490_B1 (5).png,EP3514490B1,MICROELECTROMECHANICAL SYSTEM (MEMS) DEVICE READOUT WITH OPTICAL DIRECTIONAL COUPLER,['FIG4'],['FIG4 is a top view of one exemplary embodiment of a MEMS device including two optical directional couplers and two vibrating proof masses according to the embodiments of the present disclosure'],"['FIG4 illustrates another example embodiment of a MEMS device comprising at least one optical directional coupler. MEMS device 400 shown in FIG4, comprises two directional couplers 492 and 494, both of which are used in the process of determining the angular rate of rotation in the MEMS device, by determining positions of vibrating proof masses 415 and 475. For example, FIG4 is one example of MEMS device 400 that uses two directional couplers, each directional coupler having two waveguides. As seen in FIG4, MEMS device 400 includes waveguides 422 and 424 comprised in a first directional coupler 492, and waveguides 462 and 464 comprised in a second directional coupler 496.']",31,121,view,G,"[{'element_identifier': '464', 'terms': ['waveguides', 'waveguide']}, {'element_identifier': '407', 'terms': ['electrode']}, {'element_identifier': '412', 'terms': ['photodetectors', 'photodetector']}, {'element_identifier': '415', 'terms': ['vibrating proof mass', 'vibrating proof masses']}, {'element_identifier': '452', 'terms': ['further includes two photodetectors']}, {'element_identifier': '422', 'terms': ['waveguides', 'waveguide']}, {'element_identifier': '400', 'terms': ['MEMS device']}, {'element_identifier': '414', 'terms': ['further includes two photodetectors']}, {'element_identifier': '476', 'terms': ['electrode']}, {'element_identifier': '494', 'terms': ['second directional coupler']}, {'element_identifier': '465', 'terms': ['second light source', 'Light sources']}, {'element_identifier': '424', 'terms': ['waveguides', 'waveguide']}, {'element_identifier': '454', 'terms': ['further includes two photodetectors']}, {'element_identifier': '425', 'terms': ['light source']}, {'element_identifier': '406', 'terms': ['electrode']}, {'element_identifier': '475', 'terms': ['vibrating proof mass', 'vibrating proof masses']}, {'element_identifier': '150', 'terms': ['reference']}, {'element_identifier': '485', 'terms': ['such as central region']}]","['1. A microelectromechanical systems (MEMS) device comprising: an optical directional coupler comprising: at least one light source configured to provide a light beam; at least one substrate; a first waveguide formed on the at least one substrate, the first waveguide having a first end and the second end, wherein the first end of the first waveguide is coupled to the at least one light source, wherein the light beam is introduced into the first end of the first waveguide; a second waveguide formed on the substrate, the second waveguide having a third end and a fourth end, wherein the first waveguide and the second waveguide are positioned adjacent to each other at a central region of the optical directional coupler at a distance such that the light beam is at least partially evanescently coupled between the first waveguide and the second waveguide in the central region when the light beam is introduced into the first end of the first waveguide; a first photodetector coupled to a second end of the first waveguide, wherein the first photodetector is configured to detect a first optical power in the light beam propagating through the first waveguide at the second end; and a second photodetector coupled to a fourth end of the second waveguide, wherein the second photodetector is configured to detect a second optical power in the light beam propagating through the second waveguide at the fourth end; at least one vibrating proof mass positioned adjacent to the optical directional coupler in a first direction from the optical directional coupler, wherein the at least one vibrating proof mass is equidistant from the first waveguide and the second waveguide, wherein when one or more inertial forces are applied to the MEMS device in at least one of the first and a second direction, the at least one vibrating proof mass is configured to move in the first direction; at least one processor coupled to the first photodetector and the second photodetector, wherein the processor is configured to determine the displacement of the at least one proof mass from the optical directional coupler as a function of the first optical power and the second optical power.', '6. The MEMS device of claim 2, wherein the at least one light source comprises: a first light source configured to provide the light beam; and a second light source configured to provide the second light beam.']",False,"['412', '422', '415', '407', '414', '424', '452', '454', '464', '475', '400', '23', '455', '485', '494', '406', '476', '150', '425', '465']" 38,EP_3514634_B1 (4).png,EP3514634B1,TIMEPIECE MOVEMENT AND TIMEPIECE,['FIG16'],['FIG16 is an enlarged view illustrating a meshing portion between an indicating hand gear and a second intermediate pinion in a train wheel according to a second embodiment'],"['FIG16 is an enlarged view illustrating a meshing portion between an indicating hand gear and a second intermediate pinion in a train wheel according to a second embodiment.', 'The second embodiment illustrated in FIG16 is different from the first embodiment in that a pair of teeth 50 adjacent to each other in a plurality of teeth 50 belonging to an indicating hand gear 133a is an elastic tooth 152.', 'As illustrated in FIG16, the elastic tooth 152 increases the load received by the rotor 202 when the indicating hand 40 is located at the reference position, which is the above-described reference load unit. The elastic tooth 152 is provided with an elastic portion 156 which is elastically deformable and a rigid body 157 which is not elastically deformable. Each of the pair of elastic teeth 152 includes first tooth surfaces 153 (facing tooth surfaces) facing each other in the circumferential direction of the indicating hand gear 133a and second tooth surfaces 154 facing sides opposite to the first tooth surfaces 153. The first tooth surface 153 is formed from the elastic portion 156. The second tooth surface 154 is formed from the rigid body 157. A slit 159 extending inward in the radial direction from the vicinity of the tooth tip of the elastic tooth 152 is formed between the elastic portion 156 and the rigid body 157.']",28,244,enlarged view,G,"[{'element_identifier': '157', 'terms': ['rigid body']}, {'element_identifier': '30', 'terms': ['train wheel']}, {'element_identifier': '154', 'terms': []}, {'element_identifier': '156', 'terms': ['elastic portion', 'elastic portions']}, {'element_identifier': '153', 'terms': ['first tooth surface', 'first tooth surfaces']}, {'element_identifier': '159', 'terms': ['slit']}, {'element_identifier': '152', 'terms': ['elastic teeth', 'elastic tooth']}, {'element_identifier': '162', 'terms': ['tooth groove']}, {'element_identifier': '161', 'terms': ['tooth groove']}]","['1. A timepiece movement (1) comprising: a stepping motor (20) that has a rotor (202) for rotating an indicating hand (40); a control unit (10) to rotate the rotor by using a main drive pulse (P1) and an auxiliary drive pulse (P2), and to determine a reference position of the indicating hand by detecting a rotation state of the rotor when the indicating hand is rotated by using a detection drive pulse based on the main drive pulse; a train wheel (30) to transmit a drive force of the stepping motor to the indicating hand, and that has a first gear (33) and a second gear (32) which mesh with each other; and an elastic portion (56) that is disposed in the first gear, and that is elastically deformed by coming into contact with the second gear when the indicating hand is located at the reference position, wherein the first gear includes an elastic tooth (52) which is a tooth belonging to the first gear, and which has a first tooth surface (53) facing an upstream side in a first rotation direction of the first gear and a second tooth surface (54) facing a downstream side in the first rotation direction, wherein one of the first tooth surface and the second tooth surface is formed from the elastic portion, and characterized in that the other one of the first tooth surface and the second tooth surface is formed from a rigid body.', '3. The timepiece movement according to claim 1, wherein the first gear includes a pair of elastic teeth (152) belonging to the first gear and adjacent to each other, wherein a width of a tooth groove (161) between the pair of elastic teeth is smaller than a tooth thickness of the tooth (32c) belonging to the second gear, wherein the respective pair of elastic teeth have facing tooth surfaces (153) which face each other in a circumferential direction, and wherein the facing tooth surfaces are formed from the elastic portion.']",False,"['16', '30', '152', '156', '157', '156', '154', '162', '157', '153', '153', '162', '154', '159', '161', '159', '39']" 39,EP_3514634_B1.png,EP3514634B1,TIMEPIECE MOVEMENT AND TIMEPIECE,['FIG1'],['FIG1 is a block diagram illustrating a configuration example of a timepiece according to a first embodiment'],"['FIG1 is a block diagram illustrating a configuration example of a timepiece 1 according to a first embodiment.', 'As illustrated in FIG1, the timepiece 1 includes a battery 2, an oscillator circuit 3, a frequency divider circuit 4, a storage unit 5, a control unit 10, a first motor 20a, a second motor 20b, a third motor 20c, a train wheel 30a, a train wheel 30b, a train wheel 30c, a first indicating hand 40a, a second indicating hand 40b, and a third indicating hand 40c.', 'The timepiece 1 illustrated in FIG1 is an analog timepiece which displays a measured time by using the indicating hand 40. In the example illustrated in FIG1, the timepiece 1 includes three indicating hands 40. However, the number of the indicating hands 40 may be one, two, four, or more. In this case, for each of the indicating hands 40, the timepiece 1 includes the indicating hand drive unit 121, the motor load detection unit 122, the motor 20, and the train wheel 30.']",17,202,block diagram,G,"[{'element_identifier': '12', 'terms': ['indicating hand drive unit']}, {'element_identifier': '10', 'terms': ['control unit']}, {'element_identifier': '1', 'terms': ['timepiece']}]","['1. A timepiece movement (1) comprising: a stepping motor (20) that has a rotor (202) for rotating an indicating hand (40); a control unit (10) to rotate the rotor by using a main drive pulse (P1) and an auxiliary drive pulse (P2), and to determine a reference position of the indicating hand by detecting a rotation state of the rotor when the indicating hand is rotated by using a detection drive pulse based on the main drive pulse; a train wheel (30) to transmit a drive force of the stepping motor to the indicating hand, and that has a first gear (33) and a second gear (32) which mesh with each other; and an elastic portion (56) that is disposed in the first gear, and that is elastically deformed by coming into contact with the second gear when the indicating hand is located at the reference position, wherein the first gear includes an elastic tooth (52) which is a tooth belonging to the first gear, and which has a first tooth surface (53) facing an upstream side in a first rotation direction of the first gear and a second tooth surface (54) facing a downstream side in the first rotation direction, wherein one of the first tooth surface and the second tooth surface is formed from the elastic portion, and characterized in that the other one of the first tooth surface and the second tooth surface is formed from a rigid body.']",False,"['1', '10', '12', '22', '27']" 40,EP_3514666_B1 (1).png,EP3514666B1,TOUCH PRESSURE DETECTION MODULE AND DEVICE,['FIG3'],['FIG3 is a schematic diagram of a key touch of a pressure sensing component based touch pressure detection module according to an embodiment of the present invention'],"['FIG3 is a schematic diagram of key touch of the pressure sensing component based touch pressure detection module according to an embodiment of the present invention. As shown in FIG3, the pressure sensing component 2 is not directly touched by a finger 5, a cover 3 (for example, a cover plate of a mobile phone) is arranged on the pressure sensing component 2; the cover 3 is attached to the pressure sensing component 2 via an adhesive 4, and the finger 5 applies a pressure on the pressure sensing component 2 by touching the cover 3. When the finger 5 touches the cover 3, a pressure is applied on the cover 3, and the pressure is transferred to the pressure sensing component 2 via the cover 3 and the adhesive 4. In some embodiments, the finger may alternatively directly touch the pressure sensing component 2, which is not limited in the embodiments of the present invention.']",27,171,schematic diagram,G,"[{'element_identifier': '3', 'terms': ['cover']}, {'element_identifier': '20', 'terms': ['first substrate', 'first substrates']}]","['1. A touch pressure detection apparatus, comprising: a cover (3), a fingerprint identification module (6), a touch response component (1) and a pressure sensing component (2); wherein the pressure sensing component (2) and the fingerprint identification module (6) are arranged below the cover (3), and the pressure sensing component (2) is arranged below the fingerprint identification module (6); the pressure sensing component (2) comprises a first substrate (20) and a second substrate (21) that are oppositely arranged; a variable gap exists between the first substrate (20) and the second substrate (21); and when the fingerprint identification module (6) is subject to an external pressure, the pressure is transferred to the pressure sensing component (2) such that the variable gap between the first substrate (20) and the second substrate (21) changes due to the pressure; wherein a recess is formed at a bottom surface of the cover (3), the fingerprint identification module (6) is received in the recess, and the cover (3) provides a fingerprint collection interface for the fingerprint identification module (6); the touch pressure detection apparatus is applied to a touch terminal, the touch terminal comprises a middle frame (8), the cover (3) is a cover glass of a touch screen; the first substrate (20) and the second substrate (21) are arranged between the cover (3) and the middle frame (8); the fingerprint identification module (6) comprises a fingerprint identification chip (60) and a reinforcing steel sheet; the fingerprint identification chip (60) is arranged between the cover (3) and the reinforcing steel sheet; the reinforcing steel sheet is grounded and reused as the second substrate (21) of the pressure sensing component (2), and the first substrate (20) of the pressure sensing component (2) is arranged on the middle frame (8), wherein the second substrate (21) comprises a ground electrode of the pressure sensing component (2); or the reinforcing steel sheet is connected to the touch response component (1) and reused as the first substrate (20) of the pressure sensing component (2), and the second substrate (21) of the pressure sensing component (2) is arranged on the middle frame (8), wherein the first substrate (20) comprises a transceiver electrode of the pressure sensing component (2).']",True,"['3', '20']" 41,EP_3514923_B1 (3).png,EP3514923B1,"MOTOR, CRADLE HEAD AND PHOTOGRAPHING DEVICE",['FIG4'],['FIG4 is a view of a partial structure of an electric motor shown in FIG3 from another angle'],"['Referring to FIG4 at the same time, a first positioning structure 1115 is formed on the first body 111. The first positioning structure 1115 is used to determine a relative mounting position between the magnetic ring 113 and the first body 111. In some embodiments, the first positioning structure 1115 is a slot. Specifically, a step portion 1116 is formed in the first body 111. The step portion 1116 is annular-shaped. The inner diameter of the step portion 1116 is smaller than the inner diameter of the first side wall 1112, such that the step portion 1116 protrudes from the inner surface of the first side wall 1112. The first positioning structure 1115 is the slot formed on the step portion 1116. The first positioning structure 1115 is formed into a surface of the step portion 1116 facing away from the first bottom wall 1111.']",18,159,view,F,"[{'element_identifier': '11', 'terms': ['electric motor', 'electric motors']}, {'element_identifier': '1114', 'terms': ['first shaft']}, {'element_identifier': '1116', 'terms': ['step portion']}, {'element_identifier': '1115', 'terms': ['first positioning structure']}, {'element_identifier': '1113', 'terms': ['first limiter']}, {'element_identifier': '113', 'terms': ['magnetic ring']}, {'element_identifier': '1131', 'terms': ['second positioning structure']}]","['1. A gimbal (10), comprising: an electric motor (11); and a rotation bracket (12) connected to the electric motor (11) and driven by the electric motor (11) to rotate, wherein the electric motor (11) includes: a first body (111); a second body (112); a magnetic ring (113) disposed in the first body (111); a position sensing assembly (115) disposed in the second body (112); and a mechanical limit mechanism disposed between the first body (111) and the second body (112) to define a limiting position of the first body (111) when rotating relative to the second body (112), wherein: a positioning structure (1131) is formed on the magnetic ring (113) in a position where a pre-determined magnetic field of the magnetic ring (113) is located; and when the first body (111) rotates relative to the second body (112) to the limiting position, the position sensing assembly (115) is capable of sensing a pre-determined magnetic field signal.', '4. The gimbal (10) of claim 1, wherein: the magnetic ring (113) includes a multipole magnetic ring (113); and the second positioning structure (1131) is formed at a position having a peak-to-peak value of one pair of magnetic poles of the magnetic ring (113).', '6. The gimbal (10) of claim 5, wherein: a first limiter (1113) is formed protruding from the first bottom wall (1111); a second limiter (1124) is formed on the second body (112) and capable of cooperating with the first limiter (1113); and the first limiter (1113) and the second limiter (1124) together form the mechanical limit mechanism.', '8. The gimbal (10) of claim 1, wherein: the first body (111) includes a first shaft (1114); and the first shaft (1114) and the second body (112) are capable of rotatably cooperating with each other, such that the first body (111) and the second body (112) are capable of rotatably connecting one to another.']",False,"['11', '1113', '1116', '1131', '1115', '113', '1114', '4', '16']" 42,EP_3514923_B1 (4).png,EP3514923B1,"MOTOR, CRADLE HEAD AND PHOTOGRAPHING DEVICE",['FIG5'],['FIG5 is a main view of an assembled structure shown in FIG4'],"['When being assembled, the magnetic ring 113 is mounted inside the first housing space 111a of the first body 111. The first positioning structure 1115 and the second positioning structure 1131 are mutually engaged to confine the magnetic ring 113 inside the first body 111. The second positioning structure 1131 is separated from an end of the first positioning structure 1113 adjacent to the second positioning structure 1131 by a pre-determined angle a1 (referring to FIG5). In some embodiments, the angle a1 is about 5°. Of course, the angle a1 may increase or decrease according to actual requirements. For example, the angle a1 can be as small as about 0°, or as great as over 10° or multiple of 10°, and will not be described in detail.']",12,147,view,F,"[{'element_identifier': '1113', 'terms': ['first limiter']}, {'element_identifier': '113', 'terms': ['magnetic ring']}, {'element_identifier': '1131', 'terms': ['second positioning structure']}, {'element_identifier': '11', 'terms': ['electric motor', 'electric motors']}]","['1. A gimbal (10), comprising: an electric motor (11); and a rotation bracket (12) connected to the electric motor (11) and driven by the electric motor (11) to rotate, wherein the electric motor (11) includes: a first body (111); a second body (112); a magnetic ring (113) disposed in the first body (111); a position sensing assembly (115) disposed in the second body (112); and a mechanical limit mechanism disposed between the first body (111) and the second body (112) to define a limiting position of the first body (111) when rotating relative to the second body (112), wherein: a positioning structure (1131) is formed on the magnetic ring (113) in a position where a pre-determined magnetic field of the magnetic ring (113) is located; and when the first body (111) rotates relative to the second body (112) to the limiting position, the position sensing assembly (115) is capable of sensing a pre-determined magnetic field signal.', '4. The gimbal (10) of claim 1, wherein: the magnetic ring (113) includes a multipole magnetic ring (113); and the second positioning structure (1131) is formed at a position having a peak-to-peak value of one pair of magnetic poles of the magnetic ring (113).', '6. The gimbal (10) of claim 5, wherein: a first limiter (1113) is formed protruding from the first bottom wall (1111); a second limiter (1124) is formed on the second body (112) and capable of cooperating with the first limiter (1113); and the first limiter (1113) and the second limiter (1124) together form the mechanical limit mechanism.']",False,"['1113', '1131', '11', '113', '5', '17']" 43,EP_3514923_B1 (5).png,EP3514923B1,"MOTOR, CRADLE HEAD AND PHOTOGRAPHING DEVICE",['FIG6'],['FIG6 is a view of another partial structure of an electric motor shown in FIG3 from another angle'],"['Referring to FIG6 at the same time, the second body 112 also includes a second limiter 1124. The second limiter 1124 is capable of cooperating with the first limiter 1113 to limit a rotation angle when the first body 111 rotates relative to the second body 112. In some embodiments, the second limiter 1124 is formed on an end surface of the second shaft 1123. The second limiter 1124 is substantially an arc-shaped protrusion.']",18,82,view,F,"[{'element_identifier': '1123', 'terms': ['second shaft']}, {'element_identifier': '116', 'terms': ['pressing plate']}, {'element_identifier': '1124', 'terms': ['second limiter']}, {'element_identifier': '112', 'terms': ['second body']}, {'element_identifier': '115', 'terms': ['sensing assembly']}]","['1. A gimbal (10), comprising: an electric motor (11); and a rotation bracket (12) connected to the electric motor (11) and driven by the electric motor (11) to rotate, wherein the electric motor (11) includes: a first body (111); a second body (112); a magnetic ring (113) disposed in the first body (111); a position sensing assembly (115) disposed in the second body (112); and a mechanical limit mechanism disposed between the first body (111) and the second body (112) to define a limiting position of the first body (111) when rotating relative to the second body (112), wherein: a positioning structure (1131) is formed on the magnetic ring (113) in a position where a pre-determined magnetic field of the magnetic ring (113) is located; and when the first body (111) rotates relative to the second body (112) to the limiting position, the position sensing assembly (115) is capable of sensing a pre-determined magnetic field signal.', '6. The gimbal (10) of claim 5, wherein: a first limiter (1113) is formed protruding from the first bottom wall (1111); a second limiter (1124) is formed on the second body (112) and capable of cooperating with the first limiter (1113); and the first limiter (1113) and the second limiter (1124) together form the mechanical limit mechanism.', '9. The gimbal (10) of claim 8, wherein: the second body (112) includes a second shaft (1123); and the first shaft (1114) is capable of rotatably inserting into the second shaft (1123).']",False,"['116', '1124', '115', '1123', '112', '6', '18']" 44,EP_3514923_B1 (6).png,EP3514923B1,"MOTOR, CRADLE HEAD AND PHOTOGRAPHING DEVICE",['FIG7'],['FIG7 is a main view of an assembled structure shown in FIG6 '],"['The positioning sensing assembly 115 is attached to the second shaft 1123 and is enclosed in the second housing space 112a of the second body 112. The pressing plate 116 is pressed on top of the position sensing assembly 115. The plurality of mounting posts 1162 penetrate through the corresponding plurality of through-holes 1151c to couple to the corresponding plurality of mounting holes 1125, such that the position sensing assembly 115 is fixed to the second shaft 112. The first position sensor 1152a is separated from an end of the second limiter 1124 adjacent to the first position sensor 1152a by a pre-determined angle a2 (referring to FIG7). In some embodiments, the angle a2 is about 40°. Of course, the angle a2 may increase or decrease according to actual requirements, and will not be described in detail. The coil winding 114 is securely mounted in the second housing space 112a of the second body 112.']",12,173,view,F,"[{'element_identifier': '112', 'terms': ['second body']}, {'element_identifier': '116', 'terms': ['pressing plate']}, {'element_identifier': '115', 'terms': ['sensing assembly']}, {'element_identifier': '1124', 'terms': ['second limiter']}]","['1. A gimbal (10), comprising: an electric motor (11); and a rotation bracket (12) connected to the electric motor (11) and driven by the electric motor (11) to rotate, wherein the electric motor (11) includes: a first body (111); a second body (112); a magnetic ring (113) disposed in the first body (111); a position sensing assembly (115) disposed in the second body (112); and a mechanical limit mechanism disposed between the first body (111) and the second body (112) to define a limiting position of the first body (111) when rotating relative to the second body (112), wherein: a positioning structure (1131) is formed on the magnetic ring (113) in a position where a pre-determined magnetic field of the magnetic ring (113) is located; and when the first body (111) rotates relative to the second body (112) to the limiting position, the position sensing assembly (115) is capable of sensing a pre-determined magnetic field signal.', '6. The gimbal (10) of claim 5, wherein: a first limiter (1113) is formed protruding from the first bottom wall (1111); a second limiter (1124) is formed on the second body (112) and capable of cooperating with the first limiter (1113); and the first limiter (1113) and the second limiter (1124) together form the mechanical limit mechanism.']",False,"['115', '112', '116', '1124', '7', '19']" 45,EP_3515006_B1 (3).png,EP3515006B1,"INTEGRATED CIRCUIT, TRANSMITTER AND TRANSMISSION METHOD",['FIG12'],['FIG12 is a diagram illustrating a code resource setting rule table according to Embodiment 3 of the present invention'],"['FIG12 is a diagram illustrating a code resource setting rule table according to Embodiment 3 of the present invention.', 'In Embodiment 3 as in the case of other embodiments, different offset patterns are applied to cyclic shift amount candidate X and cyclic shift amount candidate X+4 of the antenna port with identification number 0. Furthermore, in Embodiment 3, different offset patterns are applied to cyclic shift amount candidate 2M (M=0, 1, ...) and cyclic shift amount candidate 2M+1. While a basic offset pattern is applied to one of cyclic shift amount candidate 2M and cyclic shift amount candidate 2M+1, offset pattern ""0, 1, 2, 3"" or ""0, -1, -2, -3"" is applied to the other (refer to FIG12).', 'In contrast, as shown in FIG12, while the basic offset pattern is applied to one of cyclic shift amount candidate 2M and cyclic shift amount candidate 2M+1, offset pattern ""0, 1, 2, 3"" or ""0, -1, -2, -3"" is applied to the other, and it is thereby possible to reduce the bias in the cyclic shift amount applied to the antenna port with identification number 1. To be more specific, in FIG12, when attention is focused on the cyclic shift amount group to which an offset pattern other than the basic offset pattern is applied, the cyclic shift amount pairs corresponding to identification numbers 0 and 1 used for 2-antenna transmission are ""4, 5"", ""1, 0,"" ""6, 7"" and ""3, 2"" and the cyclic shift amount is more distributed, with less bias.']",19,315,diagram,H,"[{'element_identifier': '7', 'terms': ['Embodiment']}, {'element_identifier': '5', 'terms': ['Embodiment']}, {'element_identifier': '4', 'terms': ['cyclic shift amount candidates', 'cyclic shift amount candidate']}, {'element_identifier': '2', 'terms': ['than']}, {'element_identifier': '6', 'terms': ['Embodiment']}, {'element_identifier': '21', 'terms': ['antenna ports', 'andFIG.']}, {'element_identifier': '3', 'terms': ['Embodiment']}]","['1. An integrated circuit located in an apparatus, said integrated circuit comprising circuitry, which, in operation, is configured to perform a process, said process comprising the steps of: generating, for each of a plurality of antenna ports, respective reference signals using information relating to a first cyclic shift index, the first cyclic shift index being associated with a first antenna port of the plurality of antenna ports; and mapping, for each of the plurality of antenna ports, the respective reference signals to frequency resources, wherein, when the first cyclic shift index is less than half of a total number of cyclic shift indexes, the respective reference signals of each of the plurality of antenna ports are mapped to a first frequency resource; and when the first cyclic shift index is greater than or equal to half of the total number of cyclic shift indexes, the respective reference signals of a half of the plurality of antenna ports are mapped to the first frequency resource and the respective reference signals of the remaining half of the plurality of antenna ports are mapped to a second frequency resource that is different from the first frequency resource; and transmitting the mapped respective reference signals.']",False,"['5', '2', '41', '21', '4', '6', '3', '5', '7', '2', '42', '2', '4', '6', '43', '3', '5', '6', '32', '6', '12']" 46,EP_3515006_B1 (4).png,EP3515006B1,"INTEGRATED CIRCUIT, TRANSMITTER AND TRANSMISSION METHOD",['FIG13'],['FIG13 is a diagram illustrating another code resource setting rule table according to Embodiment 3 of the present invention'],"['Furthermore, when different offset patterns are applied to cyclic shift amount candidate 2M (M=0,1, ...) and cyclic shift amount candidate 2M+1, if there are two continuous cyclic offset amount candidates among cyclic shift amount candidates of the reference antenna port which are associated with offset patterns other than the basic offset pattern, offset pattern ""0, 1, 2, 3"" may be associated with one (for example, one with a smaller value), and offset pattern ""0, -1, -2, -3"" may be associated with the other (for example, one with a greater value). In FIG13, while offset pattern ""0, 1, 2, 3"" is associated with cyclic shift amount 3 of the antenna port with identification number 0, offset pattern ""0, -1, -2, -3"" is associated with cyclic shift amount 4 of the antenna port with identification number 0.']",19,173,diagram,H,"[{'element_identifier': '7', 'terms': ['Embodiment']}, {'element_identifier': '5', 'terms': ['Embodiment']}, {'element_identifier': '4', 'terms': ['cyclic shift amount candidates', 'cyclic shift amount candidate']}, {'element_identifier': '2', 'terms': ['than']}, {'element_identifier': '6', 'terms': ['Embodiment']}, {'element_identifier': '21', 'terms': ['antenna ports', 'andFIG.']}, {'element_identifier': '3', 'terms': ['Embodiment']}]","['1. An integrated circuit located in an apparatus, said integrated circuit comprising circuitry, which, in operation, is configured to perform a process, said process comprising the steps of: generating, for each of a plurality of antenna ports, respective reference signals using information relating to a first cyclic shift index, the first cyclic shift index being associated with a first antenna port of the plurality of antenna ports; and mapping, for each of the plurality of antenna ports, the respective reference signals to frequency resources, wherein, when the first cyclic shift index is less than half of a total number of cyclic shift indexes, the respective reference signals of each of the plurality of antenna ports are mapped to a first frequency resource; and when the first cyclic shift index is greater than or equal to half of the total number of cyclic shift indexes, the respective reference signals of a half of the plurality of antenna ports are mapped to the first frequency resource and the respective reference signals of the remaining half of the plurality of antenna ports are mapped to a second frequency resource that is different from the first frequency resource; and transmitting the mapped respective reference signals.']",False,"['5', '2', '41', '21', '4', '42', '2', '7', '4', '5', '6', '43', '6', '3', '3', '5', '33', '6', '6', '13']" 47,EP_3515006_B1 (5).png,EP3515006B1,"INTEGRATED CIRCUIT, TRANSMITTER AND TRANSMISSION METHOD",['FIG14'],['FIG14 is a diagram illustrating a code resource setting rule table according to Embodiment 4 of the present invention'],"['FIG14 is a diagram illustrating a code resource setting rule table according to Embodiment 4 of the present invention.', 'In FIG14, while basic offset pattern ""0, 4, 2, 6"" is applied to cyclic shift amount candidates 0 to 3 of an antenna port with identification number 0, an offset pattern different from the basic offset pattern is applied to cyclic shift amount candidates 4 to 7 of the antenna port with identification number 0. That is, in generalized expression, different offset patterns are applied to cyclic shift amount candidate X and cyclic shift amount candidate X+4 of the antenna port with identification number 0. In particular, while the basic offset pattern is applied to cyclic shift amount candidate X, offset pattern ""0, 4, 1, 5"" or offset pattern ""0, 4, 3, 7"" is applied to cyclic shift amount candidate X+4. That is, with the offset pattern group applied to cyclic shift amount candidates 4 to 7 of the antenna port with identification number 0, all offset patterns are common in that the difference in the cyclic shift amount applied to the antenna port with identification number 0 and the antenna port with identification number 1, and the difference in the cyclic shift amount applied to the antenna port with identification number 2 and the antenna port with identification number 3 are 4. In contrast, with the offset pattern group applied to cyclic shift amount candidates 4 to 7 of the antenna port with identification number 0, there are a plurality of values in the difference in the cyclic shift amount applied to the antenna port with identification number 1 and the antenna port with identification number 2.']",19,310,diagram,H,"[{'element_identifier': '7', 'terms': ['Embodiment']}, {'element_identifier': '5', 'terms': ['Embodiment']}, {'element_identifier': '4', 'terms': ['cyclic shift amount candidates', 'cyclic shift amount candidate']}, {'element_identifier': '2', 'terms': ['than']}, {'element_identifier': '6', 'terms': ['Embodiment']}, {'element_identifier': '21', 'terms': ['antenna ports', 'andFIG.']}, {'element_identifier': '3', 'terms': ['Embodiment']}]","['1. An integrated circuit located in an apparatus, said integrated circuit comprising circuitry, which, in operation, is configured to perform a process, said process comprising the steps of: generating, for each of a plurality of antenna ports, respective reference signals using information relating to a first cyclic shift index, the first cyclic shift index being associated with a first antenna port of the plurality of antenna ports; and mapping, for each of the plurality of antenna ports, the respective reference signals to frequency resources, wherein, when the first cyclic shift index is less than half of a total number of cyclic shift indexes, the respective reference signals of each of the plurality of antenna ports are mapped to a first frequency resource; and when the first cyclic shift index is greater than or equal to half of the total number of cyclic shift indexes, the respective reference signals of a half of the plurality of antenna ports are mapped to the first frequency resource and the respective reference signals of the remaining half of the plurality of antenna ports are mapped to a second frequency resource that is different from the first frequency resource; and transmitting the mapped respective reference signals.']",False,"['41', '21', '4', '5', '6', '42', '2', '3', '4', '5', '5', '6', '43', '7', '2', '3', '4', '5', '34', '2', '65', '6', '14']" 48,EP_3515701_B1 (3).png,EP3515701B1,DURABLE PROTECTIVE COVERS WITH STIFFENING RODS FOR PREVENTING SPILLED LIQUIDS FROM FLOWING INTO DRAINS OR HOLES,['FIG4'],['FIG4 is an exploded isometric view of a protective cover in accordance with another embodiment of the present invention'],"['FIG4 illustrates an alternative embodiment of the protective cover 10 in which mechanical fasteners 25, such as rivets, snaps, or screws are used to form the first and second pockets 17 and 18. As shown, the upper durable backing layer 12 is folded over upon itself to form the first and second pockets 17 and 18, and the fasteners 25 are used to securely maintain the pockets.']",19,74,exploded isometric view,B,"[{'element_identifier': '17', 'terms': ['pockets', 'pocket']}, {'element_identifier': '14', 'terms': ['layer', 'layers']}, {'element_identifier': '12', 'terms': ['layer', 'layers']}, {'element_identifier': '19', 'terms': ['hand holes']}, {'element_identifier': '22', 'terms': ['stiffening rods', 'stiffening rod']}, {'element_identifier': '18', 'terms': ['pockets', 'pocket']}, {'element_identifier': '25', 'terms': ['fasteners']}, {'element_identifier': '10', 'terms': ['protective cover']}, {'element_identifier': '23', 'terms': ['stiffening rods', 'stiffening rod']}]","['1. A durable protective cover (10) for removable installation over a drain (16), the protective cover (10) comprising: a durable backing layer (12); and a pliable, tacky sealing layer (14) structured and arranged to block spills from entering the drain (16), wherein the protective cover (10) has a first end comprising a first stiffening rod (22) extending over at least a portion thereof and a second end opposing the first end comprising a second stiffening rod (23) extending over at least a portion thereof, wherein the first stiffening rod (22) is located at least partially within a first pocket (17) running along the first end of the protective cover (10), the second stiffening rod (23) is located at least partially within a second pocket (18) running along the second end of the protective cover (10), and a portion of each of the first and second stiffening rod (22, 23) is exposed outside of the first and second pockets (17, 18) to provide a handle.']",False,"['19', '23', '18', '23', '10', '19', '25', '12', '22', '17', '22', '19', '19', '25', '12', '14', '4']" 49,EP_3516778_B1 (2).png,EP3516778B1,CONFIGURABLE MIXER,['FIG3B'],['FIG3B is a schematic drawing of the low noise amplifier of FIG3A configured to operate in a single-ended mode'],"['FIG3B is a schematic drawing 302 of the LNA 300 configured to operate in a single-ended mode. In the example of FIG3B, the first switch 318 is open and the second switch 320 is closed to operate the LNA 300 in the single-ended mode. When the second switch 320 is closed, the second output terminal LNA2 is coupled to a reference potential, which may include ground.']",21,76,schematic,H,"[{'element_identifier': '314', 'terms': ['second inductive element']}, {'element_identifier': '301', 'terms': ['schematic drawing']}, {'element_identifier': '302', 'terms': ['schematic drawing']}, {'element_identifier': '300', 'terms': ['LNA']}, {'element_identifier': '318', 'terms': ['first switch']}, {'element_identifier': '320', 'terms': ['second switch']}, {'element_identifier': '316', 'terms': ['transistor']}, {'element_identifier': '312', 'terms': ['first inductive element']}, {'element_identifier': '322', 'terms': ['LNA input signal']}]","['1. A configurable mixer (600) comprising: a first transistor pair (620) configured to multiply a first signal by a first differential signal; a second transistor pair (622) configured to multiply a second signal by the first differential signal; and a second set of switches (626) configured to selectively couple respective gate terminals of the second transistor pair to a ground potential based, at least in part, on an operating mode of the configurable mixer.', '9. 9. The configurable mixer of claim 8, wherein the analog front end comprises a low noise amplifier, LNA, and a transconductance amplifier configured to receive an LNA output signal from the LNA, wherein the first signal comprises a first signal from the transconductance amplifier and the second signal comprises a second signal from the transconductance amplifier.']",True,"['300', '301', '314', '318', '312', '316', '322', '320', '300', '302', '314', '318', '312', '316', '322', '320', '18']" 50,EP_3517421_B1 (1).png,EP3517421B1,MOTORCYCLE COMPRISING A CUSHION CONNECTING ROD,['FIG2'],['FIG2 is a left side view showing an arrangement structure of the cushion connecting rod'],"['FIG2 is a left side view showing an arrangement structure of the cushion connecting rod 40, and shows a cut surface of the motorcycle 1 in approximately the center in the vehicle width direction. The rear cushion 15 having a spring 15a for generating the springing force and a damper mechanism 15b for generating the damping force is arranged in a position behind the pivot 14 while being directed in a vertical direction through a through hole formed in the swing arm 17. The link plate 30 is made of a pair of metallic plates such as aluminum, formed in the vehicle width direction.']",15,109,left side view,B,"[{'element_identifier': '14', 'terms': ['pivot']}, {'element_identifier': '40', 'terms': ['cushion connecting rod']}, {'element_identifier': '27', 'terms': ['pivot plates', 'pivot plate']}, {'element_identifier': '10', 'terms': ['front fender']}, {'element_identifier': '15', 'terms': ['rear cushion']}]","['1. A motorcycle (1) comprising a swing arm (17), a rear cushion (15), a link plate (30), and a cushion connecting rod (40), the swing arm (17) rotatably supporting a rear wheel (WR) and also being swingably attached to a vehicle body frame (2), the rear cushion (15) applying swinging reaction to the swing arm (17), the link plate (30) supporting the rear cushion (15) and the swing arm (17) in a mutually swingable manner, the cushion connecting rod (40) swingably supporting one end of the link plate (30) to the vehicle body frame (2), wherein the cushion connecting rod (40) is a long member applied with a load (F) when the swing arm (17) is swung against springing force of the rear cushion (15), the cushion connecting rod (40) is configured in such a manner that a part of a surface of a metallic member (60) is covered with an endless fiber-reinforced plastic (50), and the fiber-reinforced plastic (50) adheres to the surface of the metallic member (60) with a film adhesive (52).']",False,"['15', '40', '27', '14', '10']" 51,EP_3517421_B1 (4).png,EP3517421B1,MOTORCYCLE COMPRISING A CUSHION CONNECTING ROD,['FIG5'],['FIG5 is a side view of the cushion connecting rod'],"['FIG5 is a side view of the cushion connecting rod 40. Supporting portions 61 formed with the through holes 61a are provided at both the ends of the metallic member 60 of the cushion connecting rod 40. First lightening holes 65, second lightening holes 66 and third lightening holes 62 each having a vertically and bilaterally symmetrical shape are formed between the supporting portions 61 at both the ends.', 'As shown in FIG5, since the recessed portion C of the metallic member 60 is configured with the linear portion A and the inclined portions B, when the tensile load F exceeding the strength margin is applied to the cushion connecting rod 40, the forces Fw for separating the fiber-reinforced plastic 50 are generated. Thereby, the fiber-reinforced plastic 50 is easily separated from the positions of the points 100. As a result, since the separation of the fiber-reinforced plastic 50 can be visually easily recognized at the points 100, time for replacement of the cushion connecting rod 40 can be more easily recognized.']",10,192,side view,B,"[{'element_identifier': '69', 'terms': ['center rib']}, {'element_identifier': '100', 'terms': ['points']}, {'element_identifier': '64', 'terms': ['vertical ribs']}, {'element_identifier': '40', 'terms': ['cushion connecting rod']}, {'element_identifier': '66', 'terms': ['second lightening holes']}, {'element_identifier': '61', 'terms': ['supporting portions']}, {'element_identifier': '65', 'terms': ['lightening holes']}, {'element_identifier': '62', 'terms': ['lightening holes']}, {'element_identifier': '200', 'terms': ['dashed circle']}, {'element_identifier': '68', 'terms': ['second outer walls']}, {'element_identifier': '13', 'terms': ['exhaust pipe']}]","['1. A motorcycle (1) comprising a swing arm (17), a rear cushion (15), a link plate (30), and a cushion connecting rod (40), the swing arm (17) rotatably supporting a rear wheel (WR) and also being swingably attached to a vehicle body frame (2), the rear cushion (15) applying swinging reaction to the swing arm (17), the link plate (30) supporting the rear cushion (15) and the swing arm (17) in a mutually swingable manner, the cushion connecting rod (40) swingably supporting one end of the link plate (30) to the vehicle body frame (2), wherein the cushion connecting rod (40) is a long member applied with a load (F) when the swing arm (17) is swung against springing force of the rear cushion (15), the cushion connecting rod (40) is configured in such a manner that a part of a surface of a metallic member (60) is covered with an endless fiber-reinforced plastic (50), and the fiber-reinforced plastic (50) adheres to the surface of the metallic member (60) with a film adhesive (52).', '2. The motorcycle (1) according to claim 1, wherein the metallic member (60) has both ends in a longitudinal direction provided with respective supporting portions (61) applied with the load (F), a recessed portion (C) and a plurality of lightening holes (62, 65, 66) are formed between the supporting portions (61) at both the ends, the recessed portion (C) being configured in such a manner that a thickness dimension (T) of the metallic member (60) is set to be smaller than a thickness dimension (Ta) of the supporting portions (61), and the fiber-reinforced plastic (50) covers surfaces of at least the supporting portions (61) and the recessed portion (C).']",False,"['62', '89', '99', '100', '200', '62', '89', '99', '100', '65', '09', '69', '00', '40', '99', '68', '62', '61', '100', '64', '66', '68', '62', '13']" 52,EP_3517421_B1 (5).png,EP3517421B1,MOTORCYCLE COMPRISING A CUSHION CONNECTING ROD,['FIG6'],['FIG6 is an enlarged view of a portion of a dashed circle shown in FIG5'],"['The endless fiber-reinforced plastic 50 is configured as follows. The long beltlike material (see FIG6) formed by solidifying the fiber material such as carbon fibers and glass fibers by a synthetic resin is wound around the surface of the metallic member 60 by a plurality of times. The direction of the fiber material of the long beltlike material is formed along its longitudinal direction.', 'FIG6 is an enlarged view of a portion of a dashed circle 200 shown in FIG5. The fiber-reinforced plastic 50 is configured in such a manner that after a film adhesive 52 is put on the surface of the metallic member 60, the long beltlike material 51 is wound by a plurality of times (for example, 10 times) from a winding starting point S until a winding ending point G. In this way, since the fiber-reinforced plastic 50 is configured by winding the long beltlike material 51, the incisal edges of the material are less likely generated, and the yield in a manufacturing process of the fiber-reinforced plastic 50 can be improved. Also, a winding process is mechanized, thereby eliminating a process to manually putting the materials on. As a result, production man-hours can be reduced. After the beltlike material 51 is wound, the whole is heated, so that the thermosetting adhesive 52 is hardened, and each portion between the mutual beltlike materials 51 is fixed.']",15,264,enlarged view,B,"[{'element_identifier': '67', 'terms': ['outer walls']}, {'element_identifier': '51', 'terms': ['beltlike material', 'beltlike materials']}, {'element_identifier': '14', 'terms': ['pivot']}, {'element_identifier': '52', 'terms': ['adhesive']}, {'element_identifier': '50', 'terms': ['fiber-reinforced plastic']}, {'element_identifier': '60', 'terms': ['metallic member']}]","['1. A motorcycle (1) comprising a swing arm (17), a rear cushion (15), a link plate (30), and a cushion connecting rod (40), the swing arm (17) rotatably supporting a rear wheel (WR) and also being swingably attached to a vehicle body frame (2), the rear cushion (15) applying swinging reaction to the swing arm (17), the link plate (30) supporting the rear cushion (15) and the swing arm (17) in a mutually swingable manner, the cushion connecting rod (40) swingably supporting one end of the link plate (30) to the vehicle body frame (2), wherein the cushion connecting rod (40) is a long member applied with a load (F) when the swing arm (17) is swung against springing force of the rear cushion (15), the cushion connecting rod (40) is configured in such a manner that a part of a surface of a metallic member (60) is covered with an endless fiber-reinforced plastic (50), and the fiber-reinforced plastic (50) adheres to the surface of the metallic member (60) with a film adhesive (52).', '3. The motorcycle (1) according to claim 2, wherein the fiber-reinforced plastic (50) is configured in such a manner that long beltlike material (51) is wound around the surface of the metallic member (60) by a plurality of times.']",False,"['50', '51', '52', '67', '60', '14']" 53,EP_3517421_B1.png,EP3517421B1,MOTORCYCLE COMPRISING A CUSHION CONNECTING ROD,['FIG1'],['FIG1 is a left side view of a motorcycle applied with a cushion connecting rod according to one embodiment of the present invention'],['A preferred embodiment of the present invention will be detailedly described below with reference to drawings. FIG1 is a left side view of a motorcycle 1 applied with a cushion connecting rod 40 according to one embodiment of the present invention. A vehicle body frame 2 of the motorcycle 1 as a saddled vehicle has a pair of right and left main frames 24 extended to the rear of a vehicle body from a head pipe 6 and curved downward. A pair of right and left front forks 9 rotatably supporting a front wheel WF is supported by a steering stem (unillustrated) swingably journaled to the head pipe 6. A steering handlebar 3 is fixed to an upper portion of the front forks 9.'],23,131,left side view,B,"[{'element_identifier': '24', 'terms': ['main frames']}, {'element_identifier': '30', 'terms': ['link plate']}, {'element_identifier': '12', 'terms': ['cowl']}, {'element_identifier': '22', 'terms': ['rear frame']}, {'element_identifier': '21', 'terms': ['rear cowl']}, {'element_identifier': '26', 'terms': ['fuel tank']}, {'element_identifier': '15', 'terms': ['rear cushion']}, {'element_identifier': '23', 'terms': ['seat']}]","['1. A motorcycle (1) comprising a swing arm (17), a rear cushion (15), a link plate (30), and a cushion connecting rod (40), the swing arm (17) rotatably supporting a rear wheel (WR) and also being swingably attached to a vehicle body frame (2), the rear cushion (15) applying swinging reaction to the swing arm (17), the link plate (30) supporting the rear cushion (15) and the swing arm (17) in a mutually swingable manner, the cushion connecting rod (40) swingably supporting one end of the link plate (30) to the vehicle body frame (2), wherein the cushion connecting rod (40) is a long member applied with a load (F) when the swing arm (17) is swung against springing force of the rear cushion (15), the cushion connecting rod (40) is configured in such a manner that a part of a surface of a metallic member (60) is covered with an endless fiber-reinforced plastic (50), and the fiber-reinforced plastic (50) adheres to the surface of the metallic member (60) with a film adhesive (52).']",False,"['21', '22', '23', '15', '26', '24', '30', '12']" 54,EP_3517769_B1 (2).png,EP3517769B1,ENGINE INTAKE AND EXHAUST SYSTEM AND INTERNAL COMBUSTION ENGINE,['FIG3'],['FIG3 is a plan view of a part of an exhaust pipe to which an EGR cooler of the engine is coupled'],"['As illustrated in FIG3, the curved pipe 13 constitutes a curve of the exhaust passage which changes a flow direction of the exhaust gas passed through the filter device 12, from the cylinder lined-up direction to a rear direction of the automobile.', 'As illustrated in FIG3, the through-hole 18 communicating the internal space of the case of the EGR cooler 15 with the exhaust passage is formed into a long hole elongated in the flow direction of the exhaust gas in the curved pipe 13. Therefore, a portion of the exhaust gas, as the EGR gas, flows into the EGR cooler 15 at a relatively uniform flow rate, while spreading from the entire area of the long through-hole 18 in the flow direction of the exhaust gas, to flow through the heat exchanger. For this reason, compared to a simple circular through-hole having the same opening area, utilization efficiency of the EGR cooler 15 improves, which becomes advantageous for cooling the EGR gas. Further, since the filter 21 is provided in the through-hole 18, even if particulate matter, such as soot, within the exhaust gas flows thereto without being captured by the filter device 12 on the upstream side thereof, entrance of the soot, etc. into the EGR passage is blocked by the filter 21.']",22,249,plan view,F,"[{'element_identifier': '18', 'terms': ['through-hole']}, {'element_identifier': '14', 'terms': ['flexible exhaust pipe']}, {'element_identifier': '12', 'terms': ['filter device']}, {'element_identifier': '13', 'terms': ['curved pipe']}]","['1. An intake and exhaust system for an engine (1), comprising: an exhaust gas recirculation (EGR) passage (15, 16, 17) configured to recirculate a portion of exhaust gas as EGR gas, from an exhaust passage (2a, 11, 12, 13, 14) of the engine (1) to an intake passage (2b, 3, 4, 5, 8); and an EGR cooler (15) disposed in the EGR passage (15, 16, 17), the EGR cooler (15) being coupled to a passage wall of the exhaust passage (2a, 11, 12, 13, 14) at an EGR gas inlet side, and having a center line intersecting with a flow direction of exhaust gas in the exhaust passage (2a, 11, 12, 13, 14), wherein a through-hole (18) communicating the EGR cooler (15) with the exhaust passage (2a, 11, 12, 13, 14) is a long hole (18) elongated substantially in the flow direction in the exhaust passage (2a, 11, 12, 13, 14), wherein an exhaust gas purifier (12) is provided in an intermediate part of the exhaust passage (2a, 11, 12, 13, 14), wherein the exhaust gas passage (2a, 11, 12, 13, 14) has a curved pipe (13) on a downstream side of the exhaust gas purifier (12) in the flow direction to change the flow direction, wherein the through-hole (18) communicating the EGR cooler (15) with the exhaust passage (2a, 11, 12, 13, 14) opens to a passage wall of the curved pipe (13) of the exhaust passage (2a, 11, 12, 13, 14) at an outer circumferential side of the curve of the exhaust passage on an upper surface of the curved pipe (13), and the EGR cooler (15) is directly attached to the curved pipe (13).']",False,"['12', '18', '13', '10', '14']" 55,EP_3517769_B1 (5).png,EP3517769B1,ENGINE INTAKE AND EXHAUST SYSTEM AND INTERNAL COMBUSTION ENGINE,['FIG6'],['FIG6 is a side view of an upper part of the engine'],"['As illustrated in FIG6, the upstream-side intake pipe 3 constituting the intake passage has a declined part 3a obliquely inclining toward the compressor 2b of the turbocharger 2. Thus, the EGR pipe 16 constituting the EGR passage has a curve 16a in an intermediate part thereof and is connected to the obliquely declined part 3a of the upstream-side intake pipe 3 via the EGR valve 17. A blow-by gas introduction pipe 31 which introduces the blow-by gas of the engine into the intake passage is connected to the obliquely declined part 3a of the upstream-side intake pipe 3.']",12,113,side view,F,"[{'element_identifier': '24', 'terms': ['supply pipe']}, {'element_identifier': '17', 'terms': ['EGR valve']}, {'element_identifier': '31', 'terms': ['gas introduction pipe']}, {'element_identifier': '16', 'terms': ['EGR pipe']}, {'element_identifier': '3', 'terms': ['pipe']}, {'element_identifier': '13', 'terms': ['curved pipe']}]","['1. An intake and exhaust system for an engine (1), comprising: an exhaust gas recirculation (EGR) passage (15, 16, 17) configured to recirculate a portion of exhaust gas as EGR gas, from an exhaust passage (2a, 11, 12, 13, 14) of the engine (1) to an intake passage (2b, 3, 4, 5, 8); and an EGR cooler (15) disposed in the EGR passage (15, 16, 17), the EGR cooler (15) being coupled to a passage wall of the exhaust passage (2a, 11, 12, 13, 14) at an EGR gas inlet side, and having a center line intersecting with a flow direction of exhaust gas in the exhaust passage (2a, 11, 12, 13, 14), wherein a through-hole (18) communicating the EGR cooler (15) with the exhaust passage (2a, 11, 12, 13, 14) is a long hole (18) elongated substantially in the flow direction in the exhaust passage (2a, 11, 12, 13, 14), wherein an exhaust gas purifier (12) is provided in an intermediate part of the exhaust passage (2a, 11, 12, 13, 14), wherein the exhaust gas passage (2a, 11, 12, 13, 14) has a curved pipe (13) on a downstream side of the exhaust gas purifier (12) in the flow direction to change the flow direction, wherein the through-hole (18) communicating the EGR cooler (15) with the exhaust passage (2a, 11, 12, 13, 14) opens to a passage wall of the curved pipe (13) of the exhaust passage (2a, 11, 12, 13, 14) at an outer circumferential side of the curve of the exhaust passage on an upper surface of the curved pipe (13), and the EGR cooler (15) is directly attached to the curved pipe (13).']",False,"['3', '31', '17', '16', '24', '13']" 56,EP_3517769_B1 (6).png,EP3517769B1,ENGINE INTAKE AND EXHAUST SYSTEM AND INTERNAL COMBUSTION ENGINE,['FIG7'],"['FIG7 is a perspective view illustrating a connecting structure for an intake pipe, an EGR pipe and a blow-by gas introduction pipe of the engine']",['The blow-by gas introduction pipe 31 extends from an oil separator provided inside a cylinder head cover 32 of the engine illustrated in FIG7. The blow-by gas is separated from oil in the oil separator and introduced into the intake passage.'],28,47,perspective view,F,"[{'element_identifier': '17', 'terms': ['EGR valve']}, {'element_identifier': '14', 'terms': ['flexible exhaust pipe']}, {'element_identifier': '16', 'terms': ['EGR pipe']}, {'element_identifier': '15', 'terms': ['EGR cooler']}, {'element_identifier': '31', 'terms': ['gas introduction pipe']}, {'element_identifier': '32', 'terms': ['cylinder head cover']}]","['1. An intake and exhaust system for an engine (1), comprising: an exhaust gas recirculation (EGR) passage (15, 16, 17) configured to recirculate a portion of exhaust gas as EGR gas, from an exhaust passage (2a, 11, 12, 13, 14) of the engine (1) to an intake passage (2b, 3, 4, 5, 8); and an EGR cooler (15) disposed in the EGR passage (15, 16, 17), the EGR cooler (15) being coupled to a passage wall of the exhaust passage (2a, 11, 12, 13, 14) at an EGR gas inlet side, and having a center line intersecting with a flow direction of exhaust gas in the exhaust passage (2a, 11, 12, 13, 14), wherein a through-hole (18) communicating the EGR cooler (15) with the exhaust passage (2a, 11, 12, 13, 14) is a long hole (18) elongated substantially in the flow direction in the exhaust passage (2a, 11, 12, 13, 14), wherein an exhaust gas purifier (12) is provided in an intermediate part of the exhaust passage (2a, 11, 12, 13, 14), wherein the exhaust gas passage (2a, 11, 12, 13, 14) has a curved pipe (13) on a downstream side of the exhaust gas purifier (12) in the flow direction to change the flow direction, wherein the through-hole (18) communicating the EGR cooler (15) with the exhaust passage (2a, 11, 12, 13, 14) opens to a passage wall of the curved pipe (13) of the exhaust passage (2a, 11, 12, 13, 14) at an outer circumferential side of the curve of the exhaust passage on an upper surface of the curved pipe (13), and the EGR cooler (15) is directly attached to the curved pipe (13).']",False,"['31', '32', '17', '16', '14', '15']" 57,EP_3517769_B1.png,EP3517769B1,ENGINE INTAKE AND EXHAUST SYSTEM AND INTERNAL COMBUSTION ENGINE,['FIG1'],['FIG1 is a side view of an exhaust side of an engine according to one embodiment of the present disclosure'],"['In an intake and exhaust system for an engine of an automobile illustrated in FIG1, a reference number ""1"" is an engine body, and includes a cylinder block 1a, a cylinder head 1b fixed to an upper surface of the cylinder block 1a, and an oil pan 1c fixed to a lower surface of the cylinder block 1a.', 'As illustrated in FIG1, a downstream end side of the catalytic converter 11 is connected to a particulate matter removing device (hereinafter, referred to as ""filter device"") 12 as the exhaust gas purifier. The filter device 12 has a filter built therein to remove particulate matter (such as soot) within the exhaust gas, and has a center line substantially along the cylinder lined-up direction along the exhaust-side surface of the engine body 1. An upstream end side of the filter device 12 is disposed near the downstream end side of the catalytic converter 11 so that they are connected vertically.']",20,182,side view,F,"[{'element_identifier': '8', 'terms': ['surge tank']}, {'element_identifier': '24', 'terms': ['supply pipe']}, {'element_identifier': '17', 'terms': ['EGR valve']}, {'element_identifier': '14', 'terms': ['flexible exhaust pipe']}, {'element_identifier': '11', 'terms': ['catalytic converter']}, {'element_identifier': '1', 'terms': ['engine body']}, {'element_identifier': '25', 'terms': ['return pipe']}, {'element_identifier': '16', 'terms': ['EGR pipe']}, {'element_identifier': '27', 'terms': ['bracket']}, {'element_identifier': '26', 'terms': ['support plate']}, {'element_identifier': '13', 'terms': ['curved pipe']}]","['1. An intake and exhaust system for an engine (1), comprising: an exhaust gas recirculation (EGR) passage (15, 16, 17) configured to recirculate a portion of exhaust gas as EGR gas, from an exhaust passage (2a, 11, 12, 13, 14) of the engine (1) to an intake passage (2b, 3, 4, 5, 8); and an EGR cooler (15) disposed in the EGR passage (15, 16, 17), the EGR cooler (15) being coupled to a passage wall of the exhaust passage (2a, 11, 12, 13, 14) at an EGR gas inlet side, and having a center line intersecting with a flow direction of exhaust gas in the exhaust passage (2a, 11, 12, 13, 14), wherein a through-hole (18) communicating the EGR cooler (15) with the exhaust passage (2a, 11, 12, 13, 14) is a long hole (18) elongated substantially in the flow direction in the exhaust passage (2a, 11, 12, 13, 14), wherein an exhaust gas purifier (12) is provided in an intermediate part of the exhaust passage (2a, 11, 12, 13, 14), wherein the exhaust gas passage (2a, 11, 12, 13, 14) has a curved pipe (13) on a downstream side of the exhaust gas purifier (12) in the flow direction to change the flow direction, wherein the through-hole (18) communicating the EGR cooler (15) with the exhaust passage (2a, 11, 12, 13, 14) opens to a passage wall of the curved pipe (13) of the exhaust passage (2a, 11, 12, 13, 14) at an outer circumferential side of the curve of the exhaust passage on an upper surface of the curved pipe (13), and the EGR cooler (15) is directly attached to the curved pipe (13).']",False,"['11', '17', '16', '24', '25', '13', '8', '14', '27', '26', '1']" 58,EP_3518255_B1 (2).png,EP3518255B1,WIRE COATING TECHNIQUE,['FIG3'],['FIG3 shows a cross section through a wire coating apparatus according to an embodiment of the invention'],"['FIG3 shows three temperature zones within the coating apparatus 100. Temperature Zone 1, TZ1, comprises the upper cylindrical section 101 of the injection channel 107. Temperature Zone 2, TZ2, comprises the lower cylindrical section 102 of the injection channel 107. Temperature Zone 3, TZ3, comprises the coating chamber 103. Each temperature zone has a different temperature profile. It should be noted that the shown locations of the temperature zones are approximate. The temperature zones indicate different regions within the apparatus in which at least some, and preferably most, of the coating material in the region is heated to within a temperature range associated with the temperature zone. The desired temperature ranges within each temperature zone will depend on the specific coating material being used.']",17,140,cross-sectional view,B,"[{'element_identifier': '103', 'terms': ['coating chamber']}, {'element_identifier': '100', 'terms': ['coating apparatus']}, {'element_identifier': '3', 'terms': ['Temperature Zone']}, {'element_identifier': '403', 'terms': ['control system']}, {'element_identifier': '105', 'terms': ['wire']}, {'element_identifier': '402', 'terms': ['cooling chamber']}, {'element_identifier': '102', 'terms': ['lower cylindrical section']}, {'element_identifier': '101', 'terms': ['upper cylindrical section']}, {'element_identifier': '108', 'terms': ['coating nozzle']}, {'element_identifier': '106', 'terms': ['piston']}, {'element_identifier': '401', 'terms': ['oven']}]","['1. A coating apparatus (100) comprising: a coating chamber (103) for applying a plastic coating material to a wire (105) passing through the coating chamber; an elongate injection channel (107) for receiving plastic coating material input to the coating apparatus at a first end (101) of the injection channel through an inlet portion (104), and supplying the received plastic coating material to the coating chamber that is arranged at a second end (102) of the injection channel, wherein the inlet portion intersects a side wall of the elongate injection channel, the side wall extending between the first end and the second end of the elongate injection channel, the injection channel comprising a first cylindrical section at the first end of the injection channel and a second cylindrical section at the second end of the injection channel, wherein the diameter of the first cylindrical section is greater than the second cylindrical section; a piston (106) that is moveable along the length of the first cylindrical section of the injection channel, the piston configured to pressurise the contents of the injection channel and coating chamber, the applied pressure causing the plastic coating material to flow down the injection channel; and a number of heating elements (109, 111) controllable to progressively raise the temperature of the plastic coating material as the coating material flows through the coating apparatus to achieve a desired viscosity of the plastic coating material within the coating chamber.', '11. A coating system comprising the coating apparatus of any preceding claim, an oven (401), a cooling chamber (402) and a control system (403); wherein: the coating apparatus is arranged to receive wire and to apply a layer of plastic coating material, to the received wire; the oven is arranged to receive wire output from the coating apparatus and to heat the wire to a temperature at which the applied plastic coating material sets; the cooling chamber is arranged to receive wire output from the oven and to cool the wire such that the wire output from the cooling chamber can be wound or fed back into the coating apparatus for a further layer of plastic coating material to be applied; and the control system is configured to control the heating elements in the coating apparatus, the temperature of the oven and the speed of the wire through the coating apparatus, oven and cooling chamber.']",True,"['100', '101', '106', '102', '105', '108', '103', '3', '403', '100', '105', '401', '402', '4', '16']" 59,EP_3518377_B1.png,EP3518377B1,"ELECTRONIC CIGARETTE, AND POWER SUPPLY STRUCTURE THEREOF","['FIG1', ' FIG2']","['FIG2 is a block diagram of a power supply structure according to another embodiment ', 'FIG1 is a block diagram of a power supply structure according to an embodiment']","['In one embodiment, as shown in FIG2, the charging circuit 10 includes a charging interface 100, a boosting module 110, and a buck module 120. The charging interface 100 is connected to the battery pack 20 selectively through the boosting module 110 and the buck module 120, and the charging interface 100 is used to access an external power source to obtain a standard charging voltage. In one embodiment, the boosting module 110 and the buck module 120 may correspond to multiple batteries and a single battery, respectively. Specifically, assuming that the standard charging voltage is 5V and the standard voltage of one rechargeable battery is 4.2V, then when there is only one rechargeable battery in the circuit (the battery pack 20 has only one rechargeable battery) for charging, the buck module 120 is connected to the battery pack 20 for charging the battery; and when there are multiple rechargeable batteries in the circuit (the battery pack 20 includes a plurality of rechargeable batteries) for charging, the boosting module 110 is connected to the battery pack 20 for charging the multiple batteries. ', 'As shown in FIG1, it is a block diagram of a power supply structure according to an embodiment. The power supply structure includes a charging circuit 10, a battery pack 20 including at least two rechargeable batteries, and a switching circuit 30.']",28,249,block diagram,A,"[{'element_identifier': '30', 'terms': ['switching circuit']}, {'element_identifier': '100', 'terms': ['charging interface']}, {'element_identifier': '20', 'terms': ['battery pack']}, {'element_identifier': '10', 'terms': ['charging circuit']}, {'element_identifier': '110', 'terms': ['boosting module']}, {'element_identifier': '120', 'terms': ['module']}]","['1. A power supply structure, comprising at least two rechargeable batteries connected in series and a charging circuit (10) connected to the rechargeable batteries for charging the rechargeable batteries, the rechargeable batteries comprising a 1 st rechargeable battery and a 2 nd rechargeable battery; characterized in that the power supply structure further comprises a switching circuit (30) connected to the rechargeable batteries, the switching circuit (30) comprises a first mechanical switch (K5) connected in parallel with two ends of the 1 st rechargeable battery and a second mechanical switch (K6) connected in parallel with two ends of the 2 nd rechargeable battery, the first mechanical switch (K5) and the second mechanical switch (K6) are configured for regulating the number of the rechargeable batteries connected in series to form different battery series circuits; the charging circuit (10) comprises a charging interface (100), a boosting module (110) and a buck module (120), the charging interface (100) is configured for accessing an external power source to obtain a standard charging voltage, the charging interface (100) is respectively connected to the battery series circuits through the boosting module (110) and the buck module (120); the charging circuit (10) further comprises a controller (130) and a voltage sampling module (140), the controller (130) is respectively connected to the boosting module (110) and the buck module (120), the voltage sampling module (140) is connected between the controller (130) and the battery series circuits and configured for detecting the voltages of the battery series circuits and feeding the detected voltages back to the controller (130), so that according to the detected voltages, the controller (130) controls the boosting module (110) or the buck module (120) to operate for converting the standard charging voltage into different charging voltages to be supplied to the battery series circuits for charging.']",True,"['10', '30', '20', '1', '10', '110', '100', '120', '30', '20', '2']" 60,EP_3518453_B1 (2).png,EP3518453B1,"DEMODULATION REFERENCE SIGNAL TRANSMISSION APPARATUS, SYSTEM, AND METHOD",['FIG9'],['FIG9 is a schematic structural diagram of another universal transmission apparatus according to an embodiment of the present invention'],"['FIG9 is a schematic structural diagram of another universal transmission apparatus according to an embodiment of the present invention. Referring to FIG9, the universal transmission apparatus includes: a transmitter 300, a receiver 301, and a processor 302.']",19,43,schematic structural diagram,H,"[{'element_identifier': '100', 'terms': ['sending module']}, {'element_identifier': '301', 'terms': ['receiver']}, {'element_identifier': '302', 'terms': ['processor']}, {'element_identifier': '16', 'terms': ['andFIG.']}, {'element_identifier': '300', 'terms': ['transmitter']}, {'element_identifier': '102', 'terms': ['processing module']}, {'element_identifier': '101', 'terms': ['receiving module']}]","['1. A demodulation reference signal transmission apparatus, comprising: • a transmitter (300), configured to send a configuration indication to a user equipment UE, wherein the configuration indication is used to instruct the UE to send a demodulation reference signal, DMRS, before scheduling the UE to perform a transmission on a Physical Uplink Shared Channel, PUSCH, wherein the DMRS is a DMRS that does not depend on uplink data; and • a receiver (301), configured to receive the DMRS sent by the UE.']",True,"['300', '302', '9', '301', '100', '101', '10', '102', '101', '100', '11', '16']" 61,EP_3519079_B1.png,EP3519079B1,AUTOMATIC REPLACEMENT OF FILTER CARTRIDGE,['FIG2'],['FIG2 is a flow diagram describing the operation of the filtration unit of FIG1 (first exemplary embodiment)FIG3 is a perspective view of a filter cartridge'],"['At working position 70, a device 80 is provided for carrying out a step 181 of detecting (FIG2) a differential pressure between the inlet and the outlet of first cartridge 11, comprising. in particular. first and second pressure sensors 282,283 arranged at the inlet and at the outlet of first cartridge 11, respectively, in order to measure a pressure drop through first cartridge 11, and comprising also a logical unit 281 configured for receiving respective fluid pressure values from pressure sensors 282,283, and for generating a related differential pressure signal 286.']",26,102,flow diagram,B,"[{'element_identifier': '30', 'terms': ['filtration container']}, {'element_identifier': '12', 'terms': ['exchange mechanism']}, {'element_identifier': '80', 'terms': ['device']}, {'element_identifier': '11', 'terms': ['cartridge', 'cartridges']}, {'element_identifier': '287', 'terms': ['signal']}, {'element_identifier': '281', 'terms': ['logical unit']}, {'element_identifier': '90', 'terms': ['control unit']}, {'element_identifier': '183', 'terms': ['step']}, {'element_identifier': '181', 'terms': ['step']}, {'element_identifier': '182', 'terms': ['step']}, {'element_identifier': '10', 'terms': ['support']}, {'element_identifier': '184', 'terms': ['step']}, {'element_identifier': '286', 'terms': ['differential pressure signal']}, {'element_identifier': '31', 'terms': ['aperture']}, {'element_identifier': '75', 'terms': ['standby position', 'standby positions']}, {'element_identifier': '70', 'terms': ['position']}, {'element_identifier': '282', 'terms': ['pressure sensors']}]","['1. A filtration unit (1,501) comprising: - a rear conveying section (502) for the fluid to be filtered, a cartridge-load central section (503) and a filtration and discharge front section (504) which are serially connected to each other along a longitudinal axis (9), wherein said front and rear portions (502,504) are connected to an inlet duct (7\') and an outlet duct (8\'), respectively, said inlet duct (7\') and said outlet duct (8) are aligned along said longitudinal axis (9) and arranged at opposite ends, through which said filtration unit (501) can be connected to said ducts (7,8) of the fluid to be filtered/ filtered, wherein said cartridge-load central section (503) comprises a passage channel (541) that is open at rear and front end faces (542\',542"") of said cartridge-load central section (503), and that is arranged within said cartridge-load central section (503) along said longitudinal axis (9); said filtration unit (501) comprising - at least one filter cartridge (511,511\') with a cylindrical hollow filter portion (72) between a first and a second end portions (74\',74""), said first end portion (74\') protruding radially from said hollow filter portion (72) and having a through central hole (71\'), which is an opening towards outside of said filter portion (72), while said second end portion (74"") is closed, wherein said first end portion (74\') has at least one seal element (84) on its own outer surface in order to provide a seal element in said passage channel (541), to prevent a gas coming from said first end portion (74\') to flow beyond said filter cartridge (511,511\'); wherein said front filter section (504) comprises a filtration container (530) aligned along said longitudinal axis (9) which is configured for receiving a first cartridge (511) with said first end portion (74\') protruding outside and with said own filtering portion (72) and said second end portion (74"") cantilevered into said filtration container (530); wherein, in a filtration step, said filter cartridge (511) is located in a working position (70) with said own filtering portion (72) within said filtration container (530); wherein said filtration unit (501) comprises a cartridge retaining means (511) in order to keep said cartridge (511) in said working position (70), said cartridge-retaining means comprises a plurality of retractable holding rods (544) configured to translate according to a transversal direction with respect to said longitudinal axis (9), between a release retracted position, in which said retaining rods (544) do not engage with said cartridge (511), and a retaining advanced position, in which said retaining rods (544) engage with cartridge (511); wherein said filtration container (530) also comprises an outlet door (550) for expelling said cartridge (511), said outlet door having an actuator, said filtration unit (501) comprising: - a releasable loading device (520) for loading filter cartridges into said filtration unit (501), a filter cartridge (511\') being in a standby position in said load container (520); wherein said cartridge-load central section (503) also comprises a loading channel (543) for displacing said cartridge (511) to be loaded into said filtration unit (501), said loading channel (543) transversally arranged with respect to said longitudinal axis (9) and open at a side surface of said cartridge-load central section (503) and within said passage channel (541); - a door (560) provided in said filtration unit (501) for separating said loading channel (543) from said passage channel (541), in order to prevent/allow a cartridge movement from said loading channel (543) to said passage channel (541), wherein said door (560) is slidably arranged between a closed position, in which a gate closing element (561) of said door (560) is arranged at the exit of said loading channel (543) within said passage channel (541) to separate said loading channel (543) from said passage channel (541), and an open position, in which said closing element (561) clears the exit at the intersection between said loading channel (543) and said passage channel (541), which are therefore in communication with each other, wherein said door (560) has an actuator (562) and comprises a push unit (563) including at least one push member (564) for pushing said cartridge (511) through said loading channel (543) up to said working position (70), during an own slide movement from said open position to said closed position; said filtration unit (501) comprising: - a differential pressure sensor (80) arranged for measuring a pressure drop through said first filter cartridge (511) arranged in said working position (70) and configured for generating a differential pressure signal (286) responsive to said pressure drop; - a control unit (90) configured for receiving said differential pressure signal (286) and for providing an actuation signal (287) to sequentially operate a step of discharging first filter cartridge (511) from working position (70), and a step of moving said second cartridge (511\') from said standby position (75) in load container (520) to said working position (70) within said filtration container (530); - a program means resident in said control unit (90) and configured for generating said actuation signal when said differential pressure signal indicates a value of said pressure drop higher than a predetermined differential pressure threshold value; wherein in said filtration step, the filter cartridge (511) is in working position (70) with said own filtering portion (72) within said filtration container (530) and is blocked in said working position by said retaining rods (544) arranged at an advanced position, while said outlet door (550) of filtration container (530) is closed, and said gate door (560) is in said closed position below said loading channel (543) of said cartridge load central section (503); wherein in said discharging step of said first filter cartridge (511) from said working position (70), said control unit (90) is configured for bringing said retaining rods (544) from said advanced position to a retracted position, thus unlocking said filter cartridge (511) as a used cartridge, and for bringing said outlet door (550) from said closed position to said open position, said used cartridge (511) being pushed and fully introduced into said filtration chamber (530) by said the process fluid that continues to enter into said filtration unit (501), and then being expelled by gravity through said outlet door (550); wherein said step of moving a second cartridge (511\') from said standby position (75) in said load container (520) to said working position (70) within said filtration container (530), said control unit (90) is configured for moving door (560) from said closed position to said open position causing said second cartridge (511\') to fall down into said passage channel (541), wherein said control unit (90) is configured for returning said door (560) in said closed position by actuators (562), causing said push unit (563) to abut against said second cartridge (511\'), and push it up to said working position (70), where said filter portion (72) and said second end portion (74"") are located in said filtration and discharge front section (504), while said first end portion (74\') stays within said cartridge load central section (503), - wherein said control unit (90) is configured for locking said second cartridge (511\') in said working position (70).']",False,"['10', '30', '75', '70', '11', '71', '12', '31', '282', '283', '287', '281', '80', '286', '90', '181', '2', '182', '183', '184', '23']" 62,EP_3519342_B1 (5).png,EP3519342B1,EQUIPMENT FOR HANDLING A WIND TURBINE COMPONENT AND METHOD OF ASSEMBLING SUCH EQUIPMENT AND HANDLING A WIND TURBINE COMPONENT USING SUCH EQUIPMENT,['FIG8'],['FIG8 is a disassembled perspective view of the mounting block shown in FIG7'],"['The assembly of a sling 90 in accordance with the invention is shown in FIG8, which illustrates the mounting block 94 being positioned on the lifting cable 92. First, an end 150 of the lifting cable 92 is inserted into and through apertures 140 of both bushings 118 and 120 of the mounting block 94 such that the noses 132 of the bushings 118, 120 face each other and the outer faces 144 of the bushings 118, 120 face away from each other. This threading of the bushings 118, 120 is illustrated in FIG8. The bushings 118, 120, which may be generally slidable on the lifting cable 92 are spaced apart by an amount that permits the block main body 96 to be positioned therebetween. In this regard, the block main body 96 may be lowered such that a length of cable 92 between the two bushings 118, 120 passes through the gaps 152 in the side surfaces 102, 104 adjacent the lower surface 100 so as to be positioned within cable passage 116 of the block main body 96. With the block main body so positioned, the bushings 118, 120 may be positioned within the openings 122 in the side surfaces 102, 104 of the block main body 96. More particularly, the bushings 118, 120 may be moved in a direction generally parallel to the lifting cable 92 and toward one another so that the nose 132 of each bushing 118, 120 extends through the openings 122 and the shoulder 134 engages an abutting surface 156 to seat the bushings 118, 120 within the block main body 96.']",13,293,perspective view,B,"[{'element_identifier': '94', 'terms': ['mounting block', 'mounting blocks']}, {'element_identifier': '96', 'terms': ['body']}]","['1. Equipment for handling a wind turbine component, comprising: a lifting cable (92); and a mounting block (94) for coupling the lifting cable (92, 172) to the wind turbine component, the mounting block (94) comprising: a block main body (96) having a cable passage (116) defined therethrough; a pair of bushings (118, 120) coupled to the block main body (96) in the cable passage (116), each bushing (118, 120) having an outer face (144), an inner face (146) and an aperture (140), going through said bushing, defined by an aperture wall (142), wherein the lifting cable (36) extends through the aperture (140) of each of the bushings (62), characterised in that at least an outer region of the aperture wall (142), adjacent the outer face (144) of the bushing, forms a closed loop about the lifting cable (92, 172) and is substantially circumferentially continuous.']",False,"['94', '96', '104', '904', '8', '19']" 63,EP_3519856_B1 (1).png,EP3519856B1,SYSTEM FOR DETERMINING A DISTANCE TO AN OBJECT,['FIG2'],['FIG2 schematically represents an embodiment of the system according to the present invention'],"['FIG2 schematically represents an embodiment of the system according to the present invention, in relation to an object 99 in the scenery of interest. The system 200 comprises a solid-state light source 210 for projecting a pattern of a sequence of spots, which may be repeated periodically, onto the object 99. A detector 220 is arranged near the light source and configured to detect light reflected by the object.']",13,77,embodiment,G,"[{'element_identifier': '210', 'terms': ['light source']}, {'element_identifier': '230', 'terms': ['synchronization means']}, {'element_identifier': '220', 'terms': ['detector']}, {'element_identifier': '240', 'terms': ['Appropriate processing means']}, {'element_identifier': '99', 'terms': ['object']}, {'element_identifier': '200', 'terms': ['system']}]","['1. A system (200) for determining a distance to an object comprising: - a solid-state light source (210) arranged for projecting a pattern of discrete spots of laser light towards said object in a sequence of pulses; - a detector (220) comprising a plurality of picture elements, said detector (220) being configured for detecting light representing said pattern of discrete spots as reflected by said object in synchronization with said sequence of pulses; and - processing means (240) configured to calculate said distance to said object as a function of exposure values generated by said picture elements in response to said detected light based on the amount of temporal overlap between the pulse emission window and the arrival of the reflected pulse by applying range gating to said sequence of pulses; wherein said picture elements (220) are configured to generate said exposure values by accumulating, for all of the pulses of said sequence, a first amount of electrical charge representative of a first amount of light reflected by said object during a first predetermined time window (10) overlapping with the pulse emission time window and a second electrical charge representative of a second amount of light reflected by said object during a second predetermined time window (20), said second predetermined time window (20) occurring after said first predetermined time window (10) ; wherein each of said plurality of picture elements comprises at least two charge storage wells; wherein said detecting of said first amount of light and said detecting of said second amount of light occurs at respective ones of said at least two charge storage wells; and wherein the solid-state radiation source emits substantially monochromatic light having a wavelength spread of less than ±20 nm and the detector is equipped with a corresponding narrow bandpass filter (1060; 1160; 1260; 1360; 1460).']",False,"['210', '230', '99', '220', '240', '200', '17']" 64,EP_3519856_B1.png,EP3519856B1,SYSTEM FOR DETERMINING A DISTANCE TO AN OBJECT,['FIG1'],['FIG1 represents a flow chart of an embodiment of the method according to the present invention'],"['FIG1 represents a flow chart of an embodiment of the method according to the present invention. Without loss of generality, the ranging method is described with reference to a range gating algorithm. In a first time window 10, the method comprises projecting 110 a pattern of spots of laser light (e.g. a regular or an irregular spatial pattern of spots) from a light source comprising a solid-state light source 210 onto any objects in the targeted area of the scenery. The spatial pattern is repeatedly projected in a sequence of pulses.']",16,101,flowchart,G,"[{'element_identifier': '130', 'terms': ['detecting']}, {'element_identifier': '1', 'terms': ['x']}, {'element_identifier': '140', 'terms': []}, {'element_identifier': '110', 'terms': ['method comprises projecting']}, {'element_identifier': '120', 'terms': ['detecting']}]","['1. A system (200) for determining a distance to an object comprising: - a solid-state light source (210) arranged for projecting a pattern of discrete spots of laser light towards said object in a sequence of pulses; - a detector (220) comprising a plurality of picture elements, said detector (220) being configured for detecting light representing said pattern of discrete spots as reflected by said object in synchronization with said sequence of pulses; and - processing means (240) configured to calculate said distance to said object as a function of exposure values generated by said picture elements in response to said detected light based on the amount of temporal overlap between the pulse emission window and the arrival of the reflected pulse by applying range gating to said sequence of pulses; wherein said picture elements (220) are configured to generate said exposure values by accumulating, for all of the pulses of said sequence, a first amount of electrical charge representative of a first amount of light reflected by said object during a first predetermined time window (10) overlapping with the pulse emission time window and a second electrical charge representative of a second amount of light reflected by said object during a second predetermined time window (20), said second predetermined time window (20) occurring after said first predetermined time window (10) ; wherein each of said plurality of picture elements comprises at least two charge storage wells; wherein said detecting of said first amount of light and said detecting of said second amount of light occurs at respective ones of said at least two charge storage wells; and wherein the solid-state radiation source emits substantially monochromatic light having a wavelength spread of less than ±20 nm and the detector is equipped with a corresponding narrow bandpass filter (1060; 1160; 1260; 1360; 1460).']",False,"['4', '110', '120', '130', '140', '1', '16']" 65,EP_3520565_B1 (5).png,EP3520565B1,ROTATING MAGNET HEAT INDUCTION,"['FIG23', ' FIG24']","['FIG23 is a chart depicting rotor speed and strip temperature of the rotor and metal strip of FIG22 under a first condition according to certain aspects of the present disclosure ', 'FIG24 is a chart depicting rotor speed and strip temperature of the rotor and metal strip of FIG22 under a second condition according to certain aspects of the present disclosure']","['FIG23 is a chart depicting rotor speed 2309 and strip temperature 2301 of the rotor 2208 and metal strip 2202 of FIG22 under a first condition according to certain aspects of the present disclosure. Line 2309 depicts non-dimensionalized rotor speed for each of the eleven sub-rotors 2209 of FIG22. For convenience, the chart of FIG23 is aligned vertically with the sub-rotors 2209 of FIG22. Dashed lines 2302 denote the edges of the metal strip 2202. Line 2301 depicts non-dimensionalized strip temperature across the width of the metal strip 2202 at or immediately after passing the rotor 2208. The lines 2309, 2301 are not necessarily drawn to scale, but shown as exaggerated for demonstrative purposes.', 'Under the second condition, each of the sub-rotors 2209 is driven at the same speed except for the penultimate sub-rotors 2209 adjacent the ends of the rotor 2208. The penultimate sub-rotors 2209 are shown as being driven at speeds greater than the remaining sub-rotors 2209. This condition generates similar moving magnetic fields to a single full-length rotor except near or slightly inwards of the edges of the metal strip 2202, where the amount of heating in increased. The strip temperature 2401 resulting from such moving magnetic fields shows a profile that is more uniform across the width of the metal strip 2202 than the strip temperature 2301 of the first condition depicted in FIG23. Thus, by adjusting the speed of particular sub-rotors 2209 in a rotor 2208 having sub-rotors 2209, temperature uniformity across the width of the metal strip 2202 can be improved. ', 'FIG24 is a chart depicting rotor speed 2409 and strip temperature 2401 of the rotor 2208 and metal strip 2202 of FIG22 under a second condition according to certain aspects of the present disclosure. Line 2409 depicts non-dimensionalized rotor speed for each of the eleven sub-rotors 2209 of FIG22. For convenience, the chart of FIG24 is aligned vertically with the sub-rotors 2209 of FIG22. Dashed lines 2402 denote the edges of the metal strip 2202. Line 2401 depicts non-dimensionalized strip temperature across the width of the metal strip 2202 at or immediately after passing the rotor 2208. The lines 2409, 2401 are not necessarily drawn to scale, but shown as exaggerated for demonstrative purposes.']",60,429,flowchart,C,"[{'element_identifier': '2409', 'terms': ['chart depicting rotor speed', 'present disclosure. Line']}, {'element_identifier': '2209', 'terms': ['sub-rotors']}, {'element_identifier': '2202', 'terms': ['metal strip']}, {'element_identifier': '2401', 'terms': ['strip temperature']}, {'element_identifier': '2302', 'terms': ['Dashed lines']}, {'element_identifier': '2309', 'terms': ['chart depicting rotor speed', 'present disclosure. Line']}, {'element_identifier': '2208', 'terms': ['rotor']}, {'element_identifier': '2224', 'terms': ['in direction']}, {'element_identifier': '2402', 'terms': ['Dashed lines']}, {'element_identifier': '2301', 'terms': ['strip temperature']}]","['1. A heating system, comprising: a magnetic heating apparatus (500; 600) for heating a metal article (502; 602) moving in a downstream direction (524; 224), wherein the magnetic heating apparatus (500; 600) includes a plurality of heaters for inducing a tailored temperature profile in the metal article (502; 602), the plurality of heaters comprising at least a first magnetic rotor (530, 532; 630, 632) and a second magnetic rotor (546, 548; 646, 648), each of the first magnetic rotor (530, 532; 630, 632) and the second magnetic rotor (546, 548; 646, 648) containing at least one magnetic source and being rotatable about an axis of rotation that is perpendicular to the downstream direction (524; 224) and parallel to a lateral width of the metal article (502; 602) to generate changing magnetic fields through the metal article (502; 602), characterized in that in order to facilitate inducing the tailored temperature profile in the metal article (502; 602), the first magnetic rotor (530, 532; 630, 632) is laterally positionable with respect to the second magnetic rotor (546, 548; 646, 648) to be laterally offset from a centerline of the metal article (502; 602) by an offset distance.']",True,"['2208', '2209', '2224', '2202', '2302', '2309', '2302', '2301', '23', '2402', '2402', '2409', '2401', '54']" 66,EP_3521068_B1 (1).png,EP3521068B1,TWO-WHEELED VEHICLE TIRE,['FIG2'],['FIG2 is an enlarged cross-sectional view of a bead portion '],"['FIG2 illustrates an enlarged cross-sectional view of one of the bead portions 4. As illustrated in FIG2, a radial height h2 of the second rubber portion 8B from the bead core 5 to the second end 8b is equal to or less than 25% of a radial height h1 of the first rubber portion 8A from the bead core 5 to the first end 8a. When the height h2 is more than 25% of the height h1, the effect that improves impact absorbing performance may be restricted since the rigidity of sidewall portions 3 may increase locally. In view of the above, the height h2 is preferably lower than a rim flange height of the rim (not illustrated) onto which the tire is mounted.']",12,137,cross-sectional view,B,"[{'element_identifier': '8', 'terms': ['bead apex rubber']}, {'element_identifier': '5', 'terms': ['bead core', 'bead cores']}, {'element_identifier': '4', 'terms': ['bead portions', 'bead portion']}, {'element_identifier': '10', 'terms': ['middle blocks']}, {'element_identifier': '3', 'terms': ['sidewall portions', 'sidewall portion']}]","['1. A two-wheeled vehicle tire (1) comprising: a carcass (6) extending between bead cores (5) each disposed in a respective one of bead portions (4) through a tread portion (2) and sidewall portions (3), the carcass (6) comprising at least one carcass ply (6A) having a ply main portion (6a) extending between the bead cores (5) through the tread portion (2); and a bead apex rubber (8) extending radially outwardly from each bead core (5), wherein the bead apex rubber (8) comprises a first rubber portion (8A) arranged adjacent to the ply main portion (6a), and a second rubber portion (8B) arranged axially outwardly of the first rubber portion (8A), the first rubber portion (8A) has a first end (8a) positioning radially outermost thereof, the second rubber portion (8B) has a second end (8b) positioning radially outermost thereof, and the first end (8a) is located radially outwardly of the second end (8b), and characterized in that a substantially constant-thickness region (R1) of the first rubber portion (8A) in which a difference between a maximum thickness (t1) and a minimum thickness (t2) is equal to or less than 20% of the minimum thickness (t2) has a length equal to or more than 80% of a radial height (h1) of the first rubber portion (8A) from the bead core (5) to the first end (8a).']",False,"['3', '8', '4', '5', '10']" 67,EP_3521068_B1.png,EP3521068B1,TWO-WHEELED VEHICLE TIRE,['FIG1'],['FIG1 illustrates a cross-sectional view of a two-wheeled vehicle tire in accordance with an embodiment of the disclosure'],"['FIG1 illustrates a cross-sectional view of a two-wheeled vehicle tire (hereinafter, simply referred to as ""tire"") 1 in accordance with an embodiment of the disclosure, wherein the tire is placed under a standard condition.', 'As illustrated in FIG1, the tire 1 according to the embodiment includes a carcass 6 extending between axially spaced bead cores 5 each disposed in a respective one of bead portions 4 through a tread portion 2 and sidewall portions 3, and a bead apex rubber 8 extending radially outwardly from each bead core 5. Note that in FIG1 the right half portion of the tire 1 is omitted since it has a substantially symmetrical structure as the left half portion.', 'As illustrated in FIG1, the tread portion 2 according to the embodiment includes rows of circumferentially arranged crown blocks 9, middle blocks 10, and shoulder blocks 11. Preferably, the tread portion 2 has a land ratio ranging from 14% to 35%. Such a tread portion 2 may be suitable for traveling on rough terrain, e.g., off-road bike competitions.', 'Bias tires for off-road bike having a basic structure as shown in FIG1 were prototyped based on the specification in Table 1. As a comparative example tire (Ref. 1), a tire for off-road bike having a pair of bead apex rubbers which are made of one kind of rubber was prototyped. Then, each test tire was installed to a motorcycle as a rear wheel to test.']",22,282,cross-sectional view,B,"[{'element_identifier': '8', 'terms': ['bead apex rubber']}, {'element_identifier': '11', 'terms': ['shoulder blocks', 'shoulder block']}, {'element_identifier': '9', 'terms': ['crown blocks']}, {'element_identifier': '2', 'terms': ['tread portion']}, {'element_identifier': '10', 'terms': ['middle blocks']}, {'element_identifier': '3', 'terms': ['sidewall portions', 'sidewall portion']}]","['1. A two-wheeled vehicle tire (1) comprising: a carcass (6) extending between bead cores (5) each disposed in a respective one of bead portions (4) through a tread portion (2) and sidewall portions (3), the carcass (6) comprising at least one carcass ply (6A) having a ply main portion (6a) extending between the bead cores (5) through the tread portion (2); and a bead apex rubber (8) extending radially outwardly from each bead core (5), wherein the bead apex rubber (8) comprises a first rubber portion (8A) arranged adjacent to the ply main portion (6a), and a second rubber portion (8B) arranged axially outwardly of the first rubber portion (8A), the first rubber portion (8A) has a first end (8a) positioning radially outermost thereof, the second rubber portion (8B) has a second end (8b) positioning radially outermost thereof, and the first end (8a) is located radially outwardly of the second end (8b), and characterized in that a substantially constant-thickness region (R1) of the first rubber portion (8A) in which a difference between a maximum thickness (t1) and a minimum thickness (t2) is equal to or less than 20% of the minimum thickness (t2) has a length equal to or more than 80% of a radial height (h1) of the first rubber portion (8A) from the bead core (5) to the first end (8a).', '7. The two-wheeled vehicle tire (1) according to any one of claims 1 to 6, the tread portion (2) further comprising a row of shoulder blocks (11) arranged in a tire circumferential direction to define a tread edge (Te), each shoulder block (11) connected to one of the sidewall portions (3) at a boundary location (3a), and the first end (8a) being located radially outwardly of the boundary location (3a).']",False,"['2', '10', '11', '9', '3', '8']" 68,EP_3521090_B1 (2).png,EP3521090B1,VEHICULAR COOLING DEVICE,['FIG5'],['FIG5 is a rear end elevational view of the cooling device of FIG2 as seen forwardly of the vehicle in the horizontal direction'],"['The undercover 28 has a front portion 92 which extends forwardly from the front end of the cooler body 24 to protect the cooler body 24, and downwardly from the lower end of the air outlet 82 so that the negative air pressure is generated within the air outlet 82, due to the air stream A generated during running of the vehicle 12. The undercover 28 further has a rear portion 94 which extends backwardly from the rear end of the cooler body 24 back to a position near the rear end of the vehicle 12, like the air inlet 50, to reduce the air resistance within the undercover 28 during running of the vehicle 12. The rear portion 94 has a part which projects upwardly and partially overlaps the cooler body 24 as seen forwardly of the vehicle 12 in the horizontal direction, namely, as seen in the rear end elevational view of FIG5. However, the above-indicated part of the rear portion 94 has only a small area of overlap with the cooler body 24, so that the undercover 28 can be moved forwardly relative to the cooler body 24 upon application of a load to the undercover 28, without damaging of the cooler body 24 due to deformation of the above-indicated part.']",23,231,elevational view,B,"[{'element_identifier': '28', 'terms': ['undercover']}, {'element_identifier': '72', 'terms': ['attaching arms']}, {'element_identifier': '22', 'terms': ['bracket']}, {'element_identifier': '64', 'terms': ['engaging jaws']}, {'element_identifier': '56', 'terms': ['partition plate']}, {'element_identifier': '104', 'terms': ['attaching bracket']}, {'element_identifier': '66', 'terms': ['resin clips']}, {'element_identifier': '102', 'terms': ['resin clip', 'resin clips']}, {'element_identifier': '50', 'terms': ['air inlet']}, {'element_identifier': '10', 'terms': ['cooling device']}, {'element_identifier': '26', 'terms': ['air intake duct']}, {'element_identifier': '58', 'terms': ['integrally formed mesh-type strainers']}, {'element_identifier': '70', 'terms': ['attaching brackets']}, {'element_identifier': '60', 'terms': ['air inlet portion']}, {'element_identifier': '68', 'terms': ['rear surface']}]","['1. A cooling device (10) of a vehicle (12) comprising a cooler body (24) of a heat exchanging type and an air intake duct (26) which are disposed in a rear portion of the vehicle, and wherein a coolant flows through the cooler body, and an ambient air for cooling the coolant with heat exchanging between the coolant and the ambient air is introduced through the air intake duct into the cooler body, and the air intake duct extends backwardly from the cooler body in a longitudinal direction of the vehicle, and the cooling device being characterized in that the air intake duct is disposed such that it is displaceable relative to the cooler body forwardly of the vehicle upon application of an impact load to the air intake duct; and the cooler body is attached to a body (20) of the vehicle, while the air intake duct is attached to the cooler body, such that a strength of attachment of the air intake duct to the cooler body is lower than a strength of attachment of the cooler body to the body of the vehicle.', '3. The cooling device according to claim 1 or 2, wherein the air intake duct comprises an air inlet portion (60) through which the ambient air is introduced into the cooler body, and is attached to the cooler body such that the air inlet portion is held in fluid-tight contact with the cooler body.']",True,"['22', '58', '56', '50', '58', '26', '70', '64', '68', '104', '70', '102', '28', '60', '66', '72', '10', '58', '64', '50', '0', '66', '72', '58', '64', '60', '26', '72', '66', '64', '50', '17']" 69,EP_3521545_B1 (2).png,EP3521545B1,CLUTCH FOR BLINDS,"['FIG4', ' FIG5']","['FIG4 is a side view of the chain guard housing and clutch assembly of FIG1 in the engaged state ', 'FIG5 is a side view of the chain guard housing and clutch assembly of FIG1 in the disengaged state']","['FIG4 is a side view of the chain guard housing and clutch assembly 100 in the engaged state. In the engaged state the rim 132 of the wheel cover 130 covers a portion of the chain wheel 120, such that the chain cannot become disengaged from the teeth 123 during rotation. In the engaged state, the cylindrical body 131 of the wheel cover 130 is fully inserted into the chain wheel 120. ', 'FIG5 shows the disengaged state, in which the rim 132 of the chain wheel cover 130 does not cover the teeth 123. In this disengaged state, the chain may be inserted into or removed from the chain guard housing and clutch assembly 100.']",38,125,side view,E,"[{'element_identifier': '130', 'terms': ['cover']}, {'element_identifier': '123', 'terms': ['teeth']}, {'element_identifier': '100', 'terms': ['clutch assembly']}, {'element_identifier': '132', 'terms': ['rim']}, {'element_identifier': '110', 'terms': ['drive spline']}, {'element_identifier': '120', 'terms': ['chain wheel']}]","['1. A chain guard housing and clutch assembly (100, 200) for a blind comprising, a first end (100\', 200\') which is inserted into a roller blind tube; a second end (100"", 200"") engageable with a wall mounting bracket; a drive spline (110, 210) forming the outer part of the chain guard housing and clutch assembly which engages with the inside of a roller blind tube; a chain wheel (120, 220), connected to the drive spline (110, 210); a chain cover module (130, 230) comprising a rim (132, 232), the rim covering part of the chain wheel (120, 220); a central pin (114, 214) extending from the drive spline at the first end, the central pin comprising at least one deformable leg (115, 215) engaged with the chain cover (131, 231) via an outward facing catch face (116, 216) on the leg, thus preventing axial movement of the chain cover module relative to the drive spline; characterized in that a quick release actuator (140, 240) is located at a second end of the assembly comprising an inner annular abutment surface (145, 245) in contact with the at least one leg (115, 215).']",True,"['100', '130', '100', '130', '132', '132', '13', '545', '110', '110', '123', '120', '123', '120', '4', '5']" 70,EP_3521545_B1 (6).png,EP3521545B1,CLUTCH FOR BLINDS,"['FIG11', ' FIG12']","['FIG11 is a side view of the chain guard housing and clutch assembly of FIG8 in the engaged state ', 'FIG12 is a side view of the chain guard housing and clutch assembly of FIG8 in the disengaged state']","['FIG11 is a side view of the chain guard housing and clutch assembly 200 in the engaged state. In the engaged state the rim 232 of the wheel cover 230 covers a portion of the chain wheel 220, such that the chain cannot become disengaged from the teeth 223 during rotation. In the engaged state, the cylindrical body 231 of the wheel cover 230 is fully inserted into the chain wheel 220. ', 'FIG12 shows the disengaged state, in which the rim 232 of the chain wheel cover 230 does not cover the teeth 223. In this disengaged state, the chain may be inserted into or removed from the chain guard housing and clutch assembly 200.']",38,125,side view,E,"[{'element_identifier': '210', 'terms': ['drive spline']}, {'element_identifier': '230', 'terms': ['cover']}, {'element_identifier': '223', 'terms': ['teeth']}, {'element_identifier': '220', 'terms': ['chain wheel']}, {'element_identifier': '232', 'terms': ['rim']}, {'element_identifier': '200', 'terms': ['clutch assembly']}]","['1. A chain guard housing and clutch assembly (100, 200) for a blind comprising, a first end (100\', 200\') which is inserted into a roller blind tube; a second end (100"", 200"") engageable with a wall mounting bracket; a drive spline (110, 210) forming the outer part of the chain guard housing and clutch assembly which engages with the inside of a roller blind tube; a chain wheel (120, 220), connected to the drive spline (110, 210); a chain cover module (130, 230) comprising a rim (132, 232), the rim covering part of the chain wheel (120, 220); a central pin (114, 214) extending from the drive spline at the first end, the central pin comprising at least one deformable leg (115, 215) engaged with the chain cover (131, 231) via an outward facing catch face (116, 216) on the leg, thus preventing axial movement of the chain cover module relative to the drive spline; characterized in that a quick release actuator (140, 240) is located at a second end of the assembly comprising an inner annular abutment surface (145, 245) in contact with the at least one leg (115, 215).']",True,"['200', '200', '230', '232', '230', '232', '20', '210', '220', '220', '210', '223', '230', '12', '223', '11']" 71,EP_3522439_B1 (4).png,EP3522439B1,SYSTEM AND METHOD FOR COMMUNICATING AN ORTHOGONAL FREQUENCY DIVISION MULTIPLEXED FRAME FORMAT,['FIG8'],['FIG8 illustrates embodiment tone plans for a 40 MHz OFDMA frame'],"['FIG8 illustrates tone plans 850 for a 40 MHz transmission for OFDMA and SU frames. There are 484 tones for data, pilot, and leftover tones, and 28 tones for DC and edge tones. Tone plans 850 includes the OFDMA tone plan 870 and the SU tone plan 872. The tones in the OFDMA tone plan 870 are sent to or received from multiple STAs. The tones in the SU tone plan 872 are sent to or received from a single STA.']",11,89,embodiment,H,"[{'element_identifier': '8', 'terms': ['there are']}, {'element_identifier': '5', 'terms': ['there are', 'includes']}, {'element_identifier': '12', 'terms': ['includes']}, {'element_identifier': '11', 'terms': ['other edge includes', 'other edge are']}, {'element_identifier': '242', 'terms': ['pilot regions each carry']}, {'element_identifier': '16', 'terms': ['edge']}, {'element_identifier': '26', 'terms': ['RUs may contain']}]","['1. A method implementing orthogonal frequency division multiple access, OFDMA, communication according to Institute of Electrical and Electronics Engineers, IEEE, 802.11 ax standard comprising: transmitting or receiving a downlink or uplink frame; wherein the IEEE 802.1lax standard adopts one or more tone plans, each of which comprises a first set of data and pilot tones, a second set of data and pilot tones, and a direct current,DC, region positioned between the first set of data and pilot tones and the second set of data and pilot tones, wherein the DC region consists of five DC tones; and, the tone plan further comprises a first edge region, and a second edge region, the first set of data and pilot tones positioned between the first edge region and the DC region, and second set of data and pilot tones positioned between the DC region and the second edge region, wherein the first edge region includes 12 guard tones and the second edge region include 11 guard tones; wherein the tone plan is a tone plan of 40MHz channel; and wherein the first set of data and pilot tones consists of nine 26-tone resource units, RUs, and the second set of data and pilot tones consists of nine 26-tone RUs; or the first set of data and pilot tones consists of one 242-tone RUs and the second set of data and pilot tones consists of one 242-tone RUs.']",False,"['750', '5', '752', '8754', '754758', '11', '762', '763', '12', '756758', '60', '761', '772', '12', '758', '26', '26', '26', '26', '26', '26', '26', '26', '26', '26', '26', '26', '26', '26', '26', '26', '26', '26', '16', '242', '764', '242', '764', '11', '762', '5', '8']" 72,EP_3522439_B1 (5).png,EP3522439B1,SYSTEM AND METHOD FOR COMMUNICATING AN ORTHOGONAL FREQUENCY DIVISION MULTIPLEXED FRAME FORMAT,['FIG9'],['FIG9 illustrates embodiment tone plans for 80 MHz OFDMA and SU frames'],"['FIG9 illustrates the 80 MHz tone plans 950 for OFDMA and SU frames. There are 994 data, pilot, and leftover tones, and 30 DC and edge tones. The tone plans 950 include the OFDMA tone plan 979 and the SU tone plan 978. The tones in the OFDMA tone plan 979 are sent to or received from multiple STAs. The tones in the SU tone plan 978 are sent to or received from a single STA. The RUs for the OFDMA tone plan 979 are aligned with the RUs of the SU tone plan 978.']",12,104,embodiment,H,"[{'element_identifier': '978', 'terms': ['SU tone plan']}, {'element_identifier': '12', 'terms': ['includes']}, {'element_identifier': '242', 'terms': ['pilot regions each carry']}, {'element_identifier': '975', 'terms': ['edge tones']}, {'element_identifier': '979', 'terms': ['OFDMA tone plan']}, {'element_identifier': '967', 'terms': ['edge']}, {'element_identifier': '968', 'terms': ['RU']}, {'element_identifier': '6', 'terms': ['MHz includes']}, {'element_identifier': '970', 'terms': ['tones in RU']}, {'element_identifier': '965', 'terms': ['edge tones']}, {'element_identifier': '959', 'terms': ['tones']}, {'element_identifier': '954', 'terms': ['RU']}, {'element_identifier': '26', 'terms': ['RUs may contain']}, {'element_identifier': '963', 'terms': ['edge', 'leftover tones']}, {'element_identifier': '950', 'terms': ['tone plans']}, {'element_identifier': '13', 'terms': ['that is split into', 'RUs.', 'includes', 'include', 'with']}]","['1. A method implementing orthogonal frequency division multiple access, OFDMA, communication according to Institute of Electrical and Electronics Engineers, IEEE, 802.11 ax standard comprising: transmitting or receiving a downlink or uplink frame; wherein the IEEE 802.1lax standard adopts one or more tone plans, each of which comprises a first set of data and pilot tones, a second set of data and pilot tones, and a direct current,DC, region positioned between the first set of data and pilot tones and the second set of data and pilot tones, wherein the DC region consists of five DC tones; and, the tone plan further comprises a first edge region, and a second edge region, the first set of data and pilot tones positioned between the first edge region and the DC region, and second set of data and pilot tones positioned between the DC region and the second edge region, wherein the first edge region includes 12 guard tones and the second edge region include 11 guard tones; wherein the tone plan is a tone plan of 40MHz channel; and wherein the first set of data and pilot tones consists of nine 26-tone resource units, RUs, and the second set of data and pilot tones consists of nine 26-tone RUs; or the first set of data and pilot tones consists of one 242-tone RUs and the second set of data and pilot tones consists of one 242-tone RUs.']",False,"['954', '950', '13', '96', '979', '963', '978', '97', '13', '58', '26', '26', '26', '242', '970', '26', '26', '242', '970', '968', '968', '996', '17', '959', '6', '12', '965', '967', '975', '12', '242', '970', '242', '970', '9']" 73,EP_3522439_B1 (6).png,EP3522439B1,SYSTEM AND METHOD FOR COMMUNICATING AN ORTHOGONAL FREQUENCY DIVISION MULTIPLEXED FRAME FORMAT,['FIG10'],['FIG10 illustrates additional embodiment tone plans for 80 MHz OFDMA and SU frames'],"['FIG10 illustrates 80 MHz tone plans 1080 for OFDMA frames and SU frames. There are 294 data, pilot, and leftover tones, and 30 DC and edge tones. The tone plans 1080 include the OFDMA tone plan 1006 and the SU tone plan 1008. The tones in the OFDMA tone plan 1006 are sent to or received from multiple STAs. The tones in the SU tone plan 1008 are sent to or received from a single STA. The RUs, DC tones, and edge tones of the OFDMA tone plan 1006 are aligned with the RUs, DC tones, and edge tones of the SU tone plan 1008, respectively.']",13,120,embodiment,H,"[{'element_identifier': '242', 'terms': ['pilot regions each carry']}, {'element_identifier': '1095', 'terms': ['edge tones']}, {'element_identifier': '1080', 'terms': ['tone plans']}, {'element_identifier': '1006', 'terms': ['OFDMA tone plan']}, {'element_identifier': '1092', 'terms': ['tones']}, {'element_identifier': '1000', 'terms': ['RUs']}, {'element_identifier': '1008', 'terms': ['SU tone plan']}, {'element_identifier': '12', 'terms': ['includes']}, {'element_identifier': '1004', 'terms': ['edge tones']}, {'element_identifier': '11', 'terms': ['other edge includes', 'other edge are']}, {'element_identifier': '1082', 'terms': ['DC tones']}, {'element_identifier': '18', 'terms': ['tones are distributed over']}, {'element_identifier': '1090', 'terms': ['RUs']}, {'element_identifier': '1098', 'terms': ['RU']}, {'element_identifier': '1089', 'terms': ['tones']}, {'element_identifier': '1093', 'terms': ['edge', 'leftover tones']}, {'element_identifier': '7', 'terms': ['contains', 'includes']}, {'element_identifier': '1088', 'terms': ['tones']}, {'element_identifier': '1096', 'terms': ['DC tones']}, {'element_identifier': '1094', 'terms': ['edge tones']}]","['1. A method implementing orthogonal frequency division multiple access, OFDMA, communication according to Institute of Electrical and Electronics Engineers, IEEE, 802.11 ax standard comprising: transmitting or receiving a downlink or uplink frame; wherein the IEEE 802.1lax standard adopts one or more tone plans, each of which comprises a first set of data and pilot tones, a second set of data and pilot tones, and a direct current,DC, region positioned between the first set of data and pilot tones and the second set of data and pilot tones, wherein the DC region consists of five DC tones; and, the tone plan further comprises a first edge region, and a second edge region, the first set of data and pilot tones positioned between the first edge region and the DC region, and second set of data and pilot tones positioned between the DC region and the second edge region, wherein the first edge region includes 12 guard tones and the second edge region include 11 guard tones; wherein the tone plan is a tone plan of 40MHz channel; and wherein the first set of data and pilot tones consists of nine 26-tone resource units, RUs, and the second set of data and pilot tones consists of nine 26-tone RUs; or the first set of data and pilot tones consists of one 242-tone RUs and the second set of data and pilot tones consists of one 242-tone RUs.']",False,"['1082', '1090', '1090', '1090', '1090', '1090', '1086', '1086', '1086', '1086', '10841', '1080', '108', '84', '12', '1092', '1090', '1090', '1090', '1090', '1088', '1086', '1086', '1086', '1086', '1094', '1006', '1093', '1008', '12', '242', '1000', '242', '1000', '1098', '1098', '1096', '7', '18', '1087', '1087', '1087', '1087', '1091', '1091', '1091', '1091', '1093', '1087', '1087', '1087', '1087', '1089', '1091', '1091', '1091', '1091', '1091', '11', '1095', '1093', '1004', '11', '242', '1000', '242', '1000', '10']" 74,EP_3522965_B1 (1).png,EP3522965B1,INTERFACE DEVICE FORMABLE BY ADDITIVE MANUFACTURING PROCESS,['FIG2'],"['FIG2 is a side view, partially in section, of an interface device in accordance with a second embodiment']","['An interface device 104 in accordance with a second embodiment is depicted generally in FIG2. Interface device 104 is similar to interface device 4 in that it includes a support 124, a deformable portion 128, and an interface portion 132 that are similar to that of interface device 4. However, interface portion 132 additionally includes a flap 150 that extends from a wall 148 of interface portion 132. While flap 150 is provided as a part of interface device 104, it is noted that flap 150 can be optional in other embodiments.']",20,100,side view,A,"[{'element_identifier': '154', 'terms': ['pocket']}, {'element_identifier': '248', 'terms': ['wall']}, {'element_identifier': '204', 'terms': ['interface device']}, {'element_identifier': '232', 'terms': ['interface portion']}, {'element_identifier': '104', 'terms': ['interface device']}, {'element_identifier': '224', 'terms': ['support']}, {'element_identifier': '132', 'terms': ['interface portion']}, {'element_identifier': '150', 'terms': ['flap']}, {'element_identifier': '124', 'terms': ['support']}]","['1. An interface device (304) structured to be connected in fluid communication with a source of pressurized breathing gas and to provide a flow of pressurized breathing gas to the airways of a patient (12), the interface device comprising: a support (324); a deformable portion (328) situated on the support, the deformable portion having at least one high pressure side situated in a high pressure side of the interface device configured, in use, to be in contact with the flow of pressurized breathing gas; and an interface portion (332) situated on the deformable portion and being structured to be engaged with the patient in the vicinity of the airways, the deformable portion comprising a plurality of deformable elements (336) that form a lattice structure and that are connected with the support at a plurality of spaced apart points of connection on the support, the deformable portion further comprising a plurality of interstices situated between the plurality of deformable elements; wherein at least some of the deformable elements of the plurality of deformable elements are mutually interconnected with one another; wherein the interface portion comprises a wall (348), the plurality of deformable elements being connected with the wall at a plurality of spaced apart additional points of connection on the wall; wherein the interface portion further comprises a barrier apparatus (356) that includes a barrier (360) that extends between the support and the wall and that is formed by providing material within the interstices between some of the plurality of deformable elements at the at least one high pressure side of the deformable portion and is thus structured to resist the flow of pressurized breathing gas from flowing into contact with the plurality of deformable elements and to resist the flow of pressurized breathing gas from flowing into the interstices between the plurality of deformable elements; and wherein the barrier extends along the entirety of the exterior of the deformable portion and thus serves as a membrane that encapsulates the plurality of deformable elements and the plurality of interstices.', '4. The interface device of claim 3, wherein at least a portion of the flap is spaced from the wall to form a pocket (154) that is structured to receive against it the flow of breathing gas as positive fluid pressure that is structured to deform at least a portion of the flap into engagement with the face of the patient.']",True,"['104', '124', '126', '154', '146', '150', '132', '2', '224', '204', '226', '248', '3', '232', '13']" 75,EP_3522965_B1 (2).png,EP3522965B1,INTERFACE DEVICE FORMABLE BY ADDITIVE MANUFACTURING PROCESS,['FIG5'],"['FIG5 is a side view, partially in section, of an interface device in accordance with a fourth embodiment']","['An interface device 304 in accordance with a fourth embodiment, falling within the scope of the present invention is depicted generally in FIG5. Interface device 304 is similar to interface device 4 in that it includes a support 324, a deformable portion 328, and an interface portion 332 that are configured in a fashion similar to that of interface device 4. It is noted, however, that while deformable portion 328 includes a plurality of deformable elements 336 that are mutually interconnected and form a lattice structure that is connected between a base 340 of support 324 and a wall 348 of interface portion 332, interface portion 332 additionally includes a barrier apparatus 356 having a barrier 360 that is connected with deformable elements 336. In so doing, barrier 360 is formed by providing material within the interstices between some of the plurality of deformable element 336 in such a fashion that barrier 360 is formed at the high pressure side of deformable portion 328, which is at the inboard side of deformable portion 328. Barrier 360 thus resists the flow of breathing gas from flowing from the high pressure side of interface device 304 into the interstices between the plurality of deformable elements 336. In so doing, barrier 360 will deform together with the plurality of deformable elements 336, and thus the effect of barrier 360 on the deformation of the individual deformable elements 336 with which barrier 360 is connected, and vice-versa, must be considered in designing the overall deformation characteristics of interface device 304.', 'In the embodiment depicted generally in FIG5, barrier 360 extends along the entirety of the exterior of deformable portion 328 and thus can be said to serve as a membrane that encapsulates deformable elements 336 therein. Alternatively, and in other embodiments, barrier 360 may extend along less than the entirety of the exterior of deformable portion 328 to thereby only partially encapsulate deformable portion 328 therein. Other variations and advantages will be apparent.']",20,356,side view,A,"[{'element_identifier': '304', 'terms': ['interface device']}, {'element_identifier': '348', 'terms': ['wall']}, {'element_identifier': '328', 'terms': ['deformable portion']}, {'element_identifier': '204', 'terms': ['interface device']}, {'element_identifier': '232', 'terms': ['interface portion']}, {'element_identifier': '228', 'terms': ['deformable portion']}, {'element_identifier': '4', 'terms': ['interface device']}, {'element_identifier': '324', 'terms': ['support']}, {'element_identifier': '332', 'terms': ['interface portion']}, {'element_identifier': '356', 'terms': ['barrier apparatus']}, {'element_identifier': '360', 'terms': ['barrier']}, {'element_identifier': '256', 'terms': ['barrier apparatus']}, {'element_identifier': '240', 'terms': ['base']}, {'element_identifier': '248', 'terms': ['wall']}, {'element_identifier': '340', 'terms': ['base']}, {'element_identifier': '336', 'terms': ['deformable elements', 'deformable element']}, {'element_identifier': '224', 'terms': ['support']}]","['1. An interface device (304) structured to be connected in fluid communication with a source of pressurized breathing gas and to provide a flow of pressurized breathing gas to the airways of a patient (12), the interface device comprising: a support (324); a deformable portion (328) situated on the support, the deformable portion having at least one high pressure side situated in a high pressure side of the interface device configured, in use, to be in contact with the flow of pressurized breathing gas; and an interface portion (332) situated on the deformable portion and being structured to be engaged with the patient in the vicinity of the airways, the deformable portion comprising a plurality of deformable elements (336) that form a lattice structure and that are connected with the support at a plurality of spaced apart points of connection on the support, the deformable portion further comprising a plurality of interstices situated between the plurality of deformable elements; wherein at least some of the deformable elements of the plurality of deformable elements are mutually interconnected with one another; wherein the interface portion comprises a wall (348), the plurality of deformable elements being connected with the wall at a plurality of spaced apart additional points of connection on the wall; wherein the interface portion further comprises a barrier apparatus (356) that includes a barrier (360) that extends between the support and the wall and that is formed by providing material within the interstices between some of the plurality of deformable elements at the at least one high pressure side of the deformable portion and is thus structured to resist the flow of pressurized breathing gas from flowing into contact with the plurality of deformable elements and to resist the flow of pressurized breathing gas from flowing into the interstices between the plurality of deformable elements; and wherein the barrier extends along the entirety of the exterior of the deformable portion and thus serves as a membrane that encapsulates the plurality of deformable elements and the plurality of interstices.', '6. The interface device of claim 1, wherein the support includes a base (240) and at least a first platform (242A, 242B), a portion of the plurality of deformable elements being situated between the base and the at least first platform, another portion of the plurality of deformable element being situated between the at least first platform and the wall.']",True,"['204', '224', '240', '228', '232', '256', '248', '4', '324', '340', '304', '328', '336', '332', '336', '360', '336', '356', '348', '5', '14']" 76,EP_3523893_B1.png,EP3523893B1,METHOD AND RADIO NETWORK NODE FOR DETERMINING TOTAL RADIATED POWER FROM A PLURALITY OF ANTENNAS,"['FIG1', ' FIG2']","['FIG2 is a schematic drawing illustrating downlink transmissions from the radio network node of FIG1 where multiple antennas are deployed ', 'FIG1 is a schematic diagram illustrating a cellular communication network where embodiments presented herein may be applied']","['FIG2 is a schematic drawing illustrating downlink transmissions from the radio network node 1 of FIG1 where multiple antennas are deployed. Specifically, it is here shown how the radio network node 1 comprises an AAS (Active Antenna System) and thus comprises a plurality of antennas. In this example, the radio network node 1 comprises eight antennas 6a-h. It is to be noted, however, that the radio network node can comprise any suitable number of antennas. The antennas 6a-h are here shown how they are used for downlink communication 4a from the radio network node to the wireless device 2, but the antennas can also be used for uplink communication, i.e. in the opposite direction. ', 'FIG1 is a schematic diagram illustrating a cellular communication network 8 where embodiments presented herein may be applied. The cellular communication network 8 comprises a core network 3 and one or more radio network nodes 1, here in the form of radio base stations being evolved Node Bs, also known as eNode Bs or eNBs. The radio network node 1 could also be in the form of Node Bs, BTSs (Base Transceiver Stations) and/or BSSs (Base Station Subsystems), etc. The radio network node 1 provides radio connectivity over a wireless interface 4a-b to a plurality of wireless devices 2. The term wireless device is also known as mobile communication terminal, user equipment (UE), mobile terminal, user terminal, user agent, wireless terminal, machine-to-machine device etc., and can be, for example, what today are commonly known as a mobile phone, smart phone or a tablet/laptop with wireless connectivity. The term wireless is here to be construed as having the ability to perform wireless communication. More specifically, the wireless device 2 can comprise a number of wires for internal and/or external purposes.']",37,346,"schematic, schematic diagram",H,"[{'element_identifier': '3', 'terms': ['core network']}, {'element_identifier': '2', 'terms': ['wireless device', 'wireless devices']}, {'element_identifier': '1', 'terms': ['radio network node', 'radio network nodes']}]","['1. A method for determining total radiated power from a plurality of antennas (6a-h) belonging to a radio network node, the method being performed in the radio network node (1) and comprising the step of: obtaining (44) an intermediate power value based on a sum of signals from couplers provided by each antenna of the plurality of antennas; characterized in the further steps of: obtaining (40) antenna data affecting transmission weights applied for each individual antenna of the plurality of antennas; determining (46) a power factor based on the antenna data; and calculating (48) the total radiated power based on the intermediate power value and the power factor.']",True,"['3', '1', '3', '2', '18']" 77,EP_3524007_B1 (4).png,EP3524007B1,METHODS AND NODES FOR ESTABLISHING A NEIGHBOUR RELATION IN A WIRELESS NETWORK,['FIG7'],"['FIG7 is a block diagram illustrating a first network node, a second network node and a control node in more detail, according to further possible embodiments ']","['It should be noted that FIG7 illustrates various functional units in the control node 700, the first network node 702 and the second network node 704, respectively, and the skilled person is able to implement these functional units in practice using suitable software and hardware. Thus, the solution is generally not limited to the shown structures of the control node 700, the first network node 702 and the second network node 704, and the functional units 700A-C, 702A-D and 704A-D therein may be configured to operate according to any of the features and embodiments described in this disclosure, where appropriate.']",28,116,block diagram,H,"[{'element_identifier': '702', 'terms': ['first network node']}, {'element_identifier': '704', 'terms': ['second network node']}, {'element_identifier': '700', 'terms': ['control node']}]","['1. A method performed by a first network node (102) in a wireless network, for establishment of a neighbour relation with a second network node (104) in the wireless network, wherein the first network node (102) and the second network node (104) perform radio communication with wireless devices, the method comprising: - obtaining (200, 1:1), from a control node (100), a set of reference signals reserved for neighbour relation establishment, wherein the neighbour relation is a direct connection between network nodes, - receiving (204, 1:4), from a wireless device (D1) served by the first network node (102), a measurement report indicating at least one detected reference signal that is recognized by the first network node (102) as belonging to the set of reserved reference signals, - identifying (206, 1:5) the second network node (104) based on the at least one detected reserved reference signal indicated in the received measurement report, wherein identifying the second network node (104) comprises: i) sending an identification request to the control node (100) based on the at least one detected reference signal indicated in the received measurement report, and obtaining, from the control node (100), an identity of the second network node (104), or ii) identifying the second network node from an IP address or global identity of the second network node indicated in an allocation message received from the control node, after receiving the set of reference signals reserved for neighbour relation establishment, and wherein the allocation message indicates one or more reference signals allocated to the second network node from the set of reserved reference signals; and - establishing (208, 1:6) a neighbour relation with the second network node (104).']",False,"['700', '702', '704', '7', '21']" 78,EP_3524399_B1 (5).png,EP3524399B1,FENCE ASSEMBLY FOR TABLE SAW AND TABLE SAW,['FIG7'],"['FIG7 is a perspective view of the fence assembly of FIG1, illustrating the secondary fence formed by a truss']","['FIG7 illustrates an alternative secondary fence 185 according to another embodiment of the invention. Secondary fence 185 includes an alternative second elongated body 189 defined by a truss 180 having a plurality of truss members 182 made of a first material (e.g., aluminum). In some embodiments, a second material 184 is provided within the spaces defined between the truss members 182. In further embodiments, the first material may have a first density that is greater than a second density of the second material 184.']",20,93,perspective view,B,"[{'element_identifier': '185', 'terms': ['secondary fence']}, {'element_identifier': '189', 'terms': ['alternative second elongated body']}, {'element_identifier': '182', 'terms': ['truss members']}, {'element_identifier': '184', 'terms': ['second material']}]","['1. A fence assembly (100) for a table saw (10), the fence assembly comprising: a primary fence (105) including a first elongated body (102) having a first body first side (110), a first body second side (112), a first body top side (114), and a first body bottom side (116), a first height (H1) measured between the first body top side and the first body bottom side, and a secondary fence (115) including a second elongated body (108) having a second body top side (126) and a second body bottom side (128), a second height (H2) measured between the second body top side and the second body bottom side, wherein the second height is less than the first height; and wherein the secondary fence is pivotally mounted to the primary fence and pivotable between a deployed position adjacent one of the first body first side or the first body second side, and a stowed position adjacent the other of the first body first side or the first body second side, characterised in that the primary fence comprises a threaded bore (144) on each of the first body first side and the first body second side, and the secondary fence comprises a threaded shaft (166), the threaded shaft being selectively received by one of the threaded bores in the primary fence.', '5. The fence assembly (100) of any one of claims 1 to 4, wherein the second elongated body (108) comprises a truss (180) having a plurality of truss members (182).']",False,"['182', '182', '80', '184', '185', '189', '15']" 79,EP_3525255_B1 (2).png,EP3525255B1,BATTERY MODULE,"['FIG5', ' FIG6']","['FIG5 is a schematic structural diagram of a first end plate shown in FIG2 ', 'FIG6 is a schematic structural diagram of a blocking member shown in FIG2']","['Referring to FIG5, it shows a schematic structural diagram of the first end plate 30 in FIG2. Each of the first end plate 30 and the second end plate 40 includes a body portion 33 in a plate-like form and connection portions 34 positioned at both ends of the body portion 33 and connected to the body portion 33 in the second direction Y. The battery module can be connected to an outside part (e.g. a bottom of a battery box) via the connection portions 34. The main body portions 33 of the first end plate 30 and the second end plate 40 are respectively disposed in the two openings 11 of the housing 10 and connected to the housing 10. The connection is preferably a sealed connection, such as a welding connection, a bonding connection, or the like. ', 'Referring to FIG6, it shows a schematic structural diagram of the blocking member 50 in FIG2. In an optional embodiment, the blocking member 50 includes an abutment portion 51 and an adapter portion 52 connected to each other. The abutment portion 51 is disposed opposite to the second vent plate 212 of each battery cell 21, and the adapter portion 52 is connected with the second end plate 40. The blocking member 50 with the above structure is easy to process and has a low cost.']",27,244,schematic structural diagram,H,"[{'element_identifier': '51', 'terms': ['abutment portion']}, {'element_identifier': '30', 'terms': ['first end plate']}, {'element_identifier': '511', 'terms': ['first surface']}, {'element_identifier': '521', 'terms': ['end']}, {'element_identifier': '34', 'terms': ['connection portions']}, {'element_identifier': '513', 'terms': ['open notch']}, {'element_identifier': '50', 'terms': ['blocking member']}, {'element_identifier': '32', 'terms': ['deformable plate', 'deformable plates']}]","['1. A battery module, characterized by comprising: a housing (10) having two oppositely disposed openings (11) and a hollow chamber communicating with the two openings (11) in a first direction (X); a battery stack (20) disposed in the hollow chamber and comprising two or more battery cells (21) stacked in a second direction (Y) and electrically connected to each other, wherein each of the two or more battery cells (21) has a first vent plate (211) and a second vent plate (212) disposed opposite to each other in the first direction (X); a first end plate (30) corresponding to one of the two openings (11) and connected to the housing (10), wherein the first end plate (30) is provided with a module output pole (31) electrically connected to the battery stack (20) and a deformable plate (32) disposed opposite to the module output pole (31), and the deformable plate (32) faces the first vent plate (211) such that the deformable plate (32) deforms and is electrically connected to the module output pole (31) when the first vent plate (211) is opened; a second end plate (40) corresponding to the other of the two openings (11) and connected to the housing (10); and a blocking member (50) disposed between the second end plate (40) and the battery stack (20) such that a pressure for opening the second vent plate (212) is greater than a pressure for opening the first vent plate (211).', '2. The battery module of claim 1, wherein the blocking member (50) comprises an abutment portion (51) and an adapter portion (52) connected to each other; the abutment portion (51) is disposed opposite to the second vent plate (212) of each of the two or more battery cells (21); and the adapter portion (52) is connected with the second end plate (40).', '3. The battery module of claim 2, wherein the abutment portion (51) comprises a plate-like structure extending in the second direction (Y); the plate-like structure has a first surface (511) and a second surface (512) disposed opposite to each other in a thickness direction of the plate-like structure; the first surface (511) faces the second end plate (40); the second surface (512) faces the second vent plate (212); and the first direction (X) is perpendicular to the second direction (Y).', '6. The battery module of claim 3, wherein the plate-like structure is provided with an open notch (513) that penetrates the plate-like structure in the thickness direction.']",True,"['30', '3', '3', '34', '32', '3', '5', '50', '51', '511', '513', '51', '29', '521', '513', '6', '13']" 80,EP_3525255_B1 (3).png,EP3525255B1,BATTERY MODULE,"['FIG7', ' FIG8']","['FIG7 is a schematic structural diagram of a blocking member according to another embodiment of the present disclosure ', 'FIG8 is a schematic structural diagram of a blocking member according to yet another embodiment of the present disclosure ']","['FIG7 shows a schematic structural diagram of a blocking member 50 according to another embodiment of the present disclosure. The orthographic projection of the adapter portion 52 of the blocking member 50 on the plate-like structure in the above embodiments is not limited to a square. As shown in FIG7, in an example, the orthographic projection of the adapter portion 52 on the plate-like structure may also be a circle. Of course, it may be an ellipse, a lumbar circle, or other irregular shapes, etc., as long as the requirements of the connection with the second end plate 40 and the plate-like structure can be satisfied. The position and size of the open notch 513 can also be adjusted according to the installation requirements. ', 'Referring to FIG8, a schematic structural diagram of a blocking member 50 according to yet another embodiment of the present disclosure is shown. The blocking member 50 in each of the above embodiments includes two adapter portions 52. It can be understood that that is an alternative embodiment, but is not limited to the foregoing structures. As shown in FIG8, the blocking member 50 may include only one adapter portion 52, and the one adapter portion 52 is preferably connected at a center position or an area close to the center position of the abutment portion 51. In order to ensure the strength of the connection with the second end plate 40, the extending length of the adapter portion 52 in the first direction X may be longer in the embodiment. Of course, in some embodiments, there may be a plurality of adapter portions 52 as needed, e.g. three or more adapter portions. The plurality of adapter portions 52 are spaced apart from each other on the abutment portion 51 in the first direction X. The interval can be set according to the size of the battery module, etc., which will not be described here.']",37,356,schematic structural diagram,H,"[{'element_identifier': '51', 'terms': ['abutment portion']}, {'element_identifier': '521', 'terms': ['end']}, {'element_identifier': '522', 'terms': ['recess']}, {'element_identifier': '513', 'terms': ['open notch']}, {'element_identifier': '52', 'terms': ['adapter portion', 'adapter portions']}, {'element_identifier': '50', 'terms': ['blocking member']}, {'element_identifier': '512', 'terms': ['second surface']}]","['1. A battery module, characterized by comprising: a housing (10) having two oppositely disposed openings (11) and a hollow chamber communicating with the two openings (11) in a first direction (X); a battery stack (20) disposed in the hollow chamber and comprising two or more battery cells (21) stacked in a second direction (Y) and electrically connected to each other, wherein each of the two or more battery cells (21) has a first vent plate (211) and a second vent plate (212) disposed opposite to each other in the first direction (X); a first end plate (30) corresponding to one of the two openings (11) and connected to the housing (10), wherein the first end plate (30) is provided with a module output pole (31) electrically connected to the battery stack (20) and a deformable plate (32) disposed opposite to the module output pole (31), and the deformable plate (32) faces the first vent plate (211) such that the deformable plate (32) deforms and is electrically connected to the module output pole (31) when the first vent plate (211) is opened; a second end plate (40) corresponding to the other of the two openings (11) and connected to the housing (10); and a blocking member (50) disposed between the second end plate (40) and the battery stack (20) such that a pressure for opening the second vent plate (212) is greater than a pressure for opening the first vent plate (211).', '2. The battery module of claim 1, wherein the blocking member (50) comprises an abutment portion (51) and an adapter portion (52) connected to each other; the abutment portion (51) is disposed opposite to the second vent plate (212) of each of the two or more battery cells (21); and the adapter portion (52) is connected with the second end plate (40).', '3. The battery module of claim 2, wherein the abutment portion (51) comprises a plate-like structure extending in the second direction (Y); the plate-like structure has a first surface (511) and a second surface (512) disposed opposite to each other in a thickness direction of the plate-like structure; the first surface (511) faces the second end plate (40); the second surface (512) faces the second vent plate (212); and the first direction (X) is perpendicular to the second direction (Y).', '6. The battery module of claim 3, wherein the plate-like structure is provided with an open notch (513) that penetrates the plate-like structure in the thickness direction.', '8. The battery module of claim 7, wherein the columnar structure is provided with a recess (522) along its axial direction.']",True,"['50', '52', '521', '522', '52', '513', '513', '512', '7', '50', '51', '513', '512', '513', '8', '14']" 81,EP_3525553_B1.png,EP3525553B1,"CONTROL DEVICE FOR LIGHT EMITTING ELEMENT, CONTROL METHOD FOR LIGHT EMITTING ELEMENT, LIGHTING APPARATUS",['FIG1'],['FIG1 is a diagram showing a configuration of a driving device of a light emitting element according to one embodiment'],"['FIG1 is a diagram showing a configuration of a driving device of a light emitting element according to one embodiment. The driving device (control device) of the light emitting element shown in the figure controls the lighting state of the light emitting element by receiving power from the power source 1, and is configured to includes a DC-DC converter 2, a control unit 3, a light emitting element 4, and a current detection resistance element 5. Here, resistance 6 in the circuit represents a parasitic resistance, and capacitor 7 represents a parasitic capacitance.']",20,106,diagram,H,"[{'element_identifier': '12', 'terms': ['memory']}, {'element_identifier': '11', 'terms': ['signal generation unit']}, {'element_identifier': '2', 'terms': ['DC-DC converter']}, {'element_identifier': '3', 'terms': ['control unit']}, {'element_identifier': '13', 'terms': ['unit']}]","['1. A control device for controlling a light emitting element by performing pulse width modulation comprising: a DC-DC converter (2) for supplying voltage to the light emitting element, a setting unit (11) that sets a control value for the pulse width modulation, a detection unit (13) that detects an actual value of an ON time period which is a period during which the current flowing through the light emitting element is relatively high, and a correction unit (14) for correcting the control value set by the setting unit so as to reduce the difference between a specified value of the ON time period corresponding to the control value and the actual value of the ON time period detected by the detection unit, characterised in that the pulse width modulation is in the DC-DC converter.', '2. The control device for controlling the light emitting element according to claim 1, further comprising a memory (12) which stores data indicating the correspondence between the control value and the specified value of the ON time period, wherein the correction unit corrects the control value by obtaining the specified value of the ON time period from the memory.']",False,"['2', '3', '11', '12', '13']" 82,EP_3527174_B1 (3).png,EP3527174B1,PROSTHESIS INCLUDING BALL AND SOCKET ARRANGEMENT,['FIG7A'],['FIG7A is a section view along line 7A-7A of FIG7'],"['A closer look at FIG7A shows that the sides of the legs 52, 54 taper outwardly and that the sides of the grooves 62, 64, which receive the legs 52, 54, taper inwardly with a mating taper. When the legs 52, 54 are received in the grooves 62, 64, as shown in FIG7A, the tapered surfaces of the grooves 62, 64 partially overlie and contact the mating outer surfaces of the legs 52, 54, which prevents the legs 52, 54 from moving outwardly, in the ""Y"" direction, away from their respective grooves 62, 64. As soon as the legs 52, 54 are received in the grooves 62, 64, the legs 52, 54 are prevented from moving in any direction other than the X direction relative to the grooves. And once the fastener pin 78 is threaded into the prosthesis 10*, the legs 52, 54 also are prevented from moving in the first direction ""X"", thereby fixing the cap 48 relative to the base 50* in every direction.']",10,200,section view,A,"[{'element_identifier': '80', 'terms': ['openings']}, {'element_identifier': '48', 'terms': ['cap']}, {'element_identifier': '18', 'terms': ['ball']}, {'element_identifier': '62', 'terms': ['grooves']}, {'element_identifier': '34', 'terms': ['mounting leg']}, {'element_identifier': '52', 'terms': ['legs', 'leg']}, {'element_identifier': '78', 'terms': ['pin']}, {'element_identifier': '66', 'terms': ['inner surface']}, {'element_identifier': '50', 'terms': ['base']}, {'element_identifier': '54', 'terms': ['second leg']}, {'element_identifier': '60', 'terms': ['projections', 'grooves']}, {'element_identifier': '68', 'terms': ['pin']}]","['1. A prosthesis (10) for replacing a mammalian joint, comprising: a first body (16), including a ball (18) mounted on a shaft; a second body (12), including a base (50) and a cap (48) which secures to the base, said base and cap each having an inner surface (56, 66) and an outer surface, with the inner surfaces of the base and cap together defining a socket which receives and traps the ball and supports the ball for rotation relative to the second body; characterized in that one of said inner and outer surfaces of said base defines a first groove (62), and said cap has a first leg (52) projecting in a first direction and being received in said first groove by sliding into said first groove in said first direction; and further in comprising a second leg (54) and a second groove (64) lying parallel to and directly opposite said first leg and said first groove, wherein said first leg defines a first leg opening (74) having an axis extending in a direction that is cross-wise to the first direction, said second leg defines a second leg opening (76) coaxial with the first leg opening, and said base defines a base opening which is aligned with said first leg opening when the base and cap are assembled together; and a pin (78) received in said first leg opening, said second leg opening, and said base opening and extending in the cross-wise direction to secure the cap and base together so that an attempt to slide the cap and base apart from each other in the first direction applies shear forces to the pin; and means for preventing the first leg from moving outwardly away from the first groove in the cross-wise direction when the first leg is received in the first groove; wherein said means for preventing the first leg from moving outwardly away from the first groove includes at least a portion of said base contacting the outer surface of the first leg.', '7. A prosthesis for replacing a mammalian joint as recited in claim 4, 5 or 6, wherein the base defines a mounting leg (34) projecting away from the socket for mounting the socket on a bone, the first and second leg openings are adjacent to said mounting leg, and the remainder of the outer surfaces of said base and cap are smooth and nearly continuous, in order to minimize the opportunity for the prosthesis to catch on or interfere with ligaments when the prosthesis is installed.', '8. A prosthesis for replacing a mammalian joint as recited in any preceding claim, wherein each of said first and second grooves lies on the inner surface of the respective cap or base member on which the respective groove is located.']",True,"['60', '62', '60', '62', '80', '66', '68', '62', '48', '52', '85', '18', '78', '80', '54', '18', '48', '64', '68', '50', '34', '13']" 83,EP_3527174_B1 (4).png,EP3527174B1,PROSTHESIS INCLUDING BALL AND SOCKET ARRANGEMENT,['FIG7B'],"['FIG7B is a section view, similar to that of FIG7A, but for an alternate embodiment']","['FIG7B shows a second embodiment of the prosthesis 10\'. In this embodiment, the legs 52\', 54\' of the cap 48\' are received in grooves 62\', 64\' formed on the inner surface of the base. In this case, the space between the legs 52\', 54\' is less than in the previous embodiment, and the inner surfaces of the legs 52\', 54\' have a partial spherical shape and become part of the socket that is in contact with the ball 18. In this case, the ball 18 prevents the legs 52\', 54\' from moving inwardly, and the inner surface of the cap base 50\' that contacts the outer surface of the legs 52\', 54\' prevents the legs 52\', 54\' from moving apart outwardly, in the ""Y"" direction. The edges of the grooves 62\', 64\' prevent the legs from moving in the ""Z"" direction.']",17,183,section view,A,"[{'element_identifier': '52', 'terms': ['legs', 'leg']}, {'element_identifier': '84', 'terms': []}, {'element_identifier': '14', 'terms': ['screws']}, {'element_identifier': '50', 'terms': ['base']}]","['1. A prosthesis (10) for replacing a mammalian joint, comprising: a first body (16), including a ball (18) mounted on a shaft; a second body (12), including a base (50) and a cap (48) which secures to the base, said base and cap each having an inner surface (56, 66) and an outer surface, with the inner surfaces of the base and cap together defining a socket which receives and traps the ball and supports the ball for rotation relative to the second body; characterized in that one of said inner and outer surfaces of said base defines a first groove (62), and said cap has a first leg (52) projecting in a first direction and being received in said first groove by sliding into said first groove in said first direction; and further in comprising a second leg (54) and a second groove (64) lying parallel to and directly opposite said first leg and said first groove, wherein said first leg defines a first leg opening (74) having an axis extending in a direction that is cross-wise to the first direction, said second leg defines a second leg opening (76) coaxial with the first leg opening, and said base defines a base opening which is aligned with said first leg opening when the base and cap are assembled together; and a pin (78) received in said first leg opening, said second leg opening, and said base opening and extending in the cross-wise direction to secure the cap and base together so that an attempt to slide the cap and base apart from each other in the first direction applies shear forces to the pin; and means for preventing the first leg from moving outwardly away from the first groove in the cross-wise direction when the first leg is received in the first groove; wherein said means for preventing the first leg from moving outwardly away from the first groove includes at least a portion of said base contacting the outer surface of the first leg.']",True,"['50', '52', '84', '14']" 84,EP_3527466_B1 (4).png,EP3527466B1,UPPER BODY STRUCTURE OF VEHICLE,['FIG6'],['FIG6 is a cross-sectional view showing main components of the upper body structure of the vehicle when taken along line B-B of FIG2'],"['As shown in FIG6, the rail skeletal member 22 has an approximately rectangular closed cross-section, with one side of the rectangle inside the vehicle being formed by the rail inner member 20 and the other three sides being formed by the rail outer member 18. The one side of the closed cross-section inside the vehicle is referred to as an inner wall 42. The inner wall 42 is formed by the rail inner member 20. Among the walls forming the other three sides, two walls directed approximately outside of the vehicle are referred to as an upper outer wall 44 and a lower outer wall 46, and the last wall directed upward is referred to as a ceiling wall 48. The upper outer wall 44 and the lower outer wall 46 are curved and bent to protrude to the outside of the vehicle, and form a ridgeline 50 extending longitudinally along a boundary of the upper outer wall 44 and the lower outer wall 46.']",27,179,cross-sectional view,B,"[{'element_identifier': '20', 'terms': ['rail inner member']}, {'element_identifier': '42', 'terms': ['inner wall']}, {'element_identifier': '66', 'terms': ['upper edge line']}, {'element_identifier': '46', 'terms': []}, {'element_identifier': '36', 'terms': ['side member outer panel']}, {'element_identifier': '68', 'terms': ['lower edge line', 'lower edge lines']}, {'element_identifier': '30', 'terms': ['pillar outer member']}, {'element_identifier': '12', 'terms': ['roof side rail', 'roof side rails']}, {'element_identifier': '48', 'terms': ['ceiling wall']}, {'element_identifier': '18', 'terms': ['rail outer member']}, {'element_identifier': '32', 'terms': ['pillar inner member']}, {'element_identifier': '24', 'terms': ['reinforcing member']}, {'element_identifier': '22', 'terms': ['rail skeletal member']}, {'element_identifier': '44', 'terms': ['upper outer wall']}, {'element_identifier': '62', 'terms': ['upper edge line']}, {'element_identifier': '14', 'terms': ['roof cross member', 'roof cross members']}, {'element_identifier': '64', 'terms': ['lower edge line']}, {'element_identifier': '56', 'terms': ['base']}, {'element_identifier': '50', 'terms': ['ridgeline']}, {'element_identifier': '58', 'terms': ['facing plates', 'facing plate']}, {'element_identifier': '60', 'terms': []}]","['1. An upper body structure of a vehicle, comprising: left and right roof side rails (12) each including a rail outer member (18) located laterally outside the vehicle and a rail inner member (20) located laterally inside the vehicle and forming a closed cross-section structure with the rail outer member (18), the left and right roof side rails (12) extending in a longitudinal direction along left and right sides of a roof of the vehicle; a roof cross member (14) extending across the left and right roof side rails (12), with both ends of the roof cross member (14) connected individually to the left and right roof side rails (12); and a reinforcing member (24) disposed in the closed cross-section structure of the left and right roof side rails (12) at a position where each roof side rail (12) is connected to the roof cross member (12), wherein the rail outer member (18) includes an upper outer wall (44) and a lower outer wall (46) which are curved and bent to protrude laterally to the outside of the vehicle to form a ridgeline (50) extending longitudinally along a boundary between the upper outer wall (44) and the lower outer wall said upper body structure of a vehicle being characterized in that the reinforcing member (24) includes a base (56) bonded to the upper outer wall (44) and the lower outer wall (46), a facing plate (58) facing the rail inner member (20), and a supporting wall (60) standing on the base (56) to support the facing plate (58), and the facing plate (58) is at least partially located on the laterally inside of a plane (P) passing through two edge lines (62, 64) of the upper outer wall (44) and the lower outer wall (46), each edge line opposing the ridgeline (50).', '3. The upper body structure of the vehicle according to claim 2, wherein the facing plate (58) is connected to the base (56) either on an upper edge line (66) or a lower edge line (68) of the facing plate (58).']",True,"['36', '22', '48', '66', '62', '12', '24', '44', '09', '50', '56', '46', '18', '30', '14', '20', '42', '58', '68', '64', '32', '24', '36', '30', '18', '60', '14', '60', '20', '60', '09', '58', '58', '12']" 85,EP_3527466_B1.png,EP3527466B1,UPPER BODY STRUCTURE OF VEHICLE,['FIG1'],['FIG1 is a schematic view of a frame structure of a vehicle'],"['An embodiment of the present disclosure is described below in detail with reference to the drawings. FIG1 is a schematic view of the structure of a frame 10 of a vehicle. In FIG1, the front side of the vehicle is indicated by an arrow FR, the upper side of the vehicle is indicated by an arrow UP, and the left side of the vehicle is indicated by an arrow LH. The terminology used herein for describing directions and orientation, such as front, rear, left, right, upper, lower, and like terms, are used to indicate the directions and orientation of the vehicle unless otherwise specified. Further, the front-rear direction of the vehicle is referred to as a longitudinal direction, and the left-right direction of the vehicle is referred to as a lateral direction. Lastly, in the lateral direction of the vehicle, the side of the vehicle closer to the center line of the vehicle extending in the longitudinal direction is referred to as inside of the vehicle, and the side of the vehicle away from the center line is referred to as outside of the vehicle.']",12,211,schematic view,B,"[{'element_identifier': '28', 'terms': ['roof cross gusset']}, {'element_identifier': '14', 'terms': ['roof cross member', 'roof cross members']}, {'element_identifier': '12', 'terms': ['roof side rail', 'roof side rails']}, {'element_identifier': '30', 'terms': ['pillar outer member']}, {'element_identifier': '1', 'terms': ['PATENT DOCUMENT']}, {'element_identifier': '20', 'terms': ['rail inner member']}, {'element_identifier': '16', 'terms': ['center pillar', 'center pillars']}, {'element_identifier': '10', 'terms': ['frame']}, {'element_identifier': '26', 'terms': ['beam member']}, {'element_identifier': '36', 'terms': ['side member outer panel']}, {'element_identifier': '32', 'terms': ['pillar inner member']}]","['1. An upper body structure of a vehicle, comprising: left and right roof side rails (12) each including a rail outer member (18) located laterally outside the vehicle and a rail inner member (20) located laterally inside the vehicle and forming a closed cross-section structure with the rail outer member (18), the left and right roof side rails (12) extending in a longitudinal direction along left and right sides of a roof of the vehicle; a roof cross member (14) extending across the left and right roof side rails (12), with both ends of the roof cross member (14) connected individually to the left and right roof side rails (12); and a reinforcing member (24) disposed in the closed cross-section structure of the left and right roof side rails (12) at a position where each roof side rail (12) is connected to the roof cross member (12), wherein the rail outer member (18) includes an upper outer wall (44) and a lower outer wall (46) which are curved and bent to protrude laterally to the outside of the vehicle to form a ridgeline (50) extending longitudinally along a boundary between the upper outer wall (44) and the lower outer wall said upper body structure of a vehicle being characterized in that the reinforcing member (24) includes a base (56) bonded to the upper outer wall (44) and the lower outer wall (46), a facing plate (58) facing the rail inner member (20), and a supporting wall (60) standing on the base (56) to support the facing plate (58), and the facing plate (58) is at least partially located on the laterally inside of a plane (P) passing through two edge lines (62, 64) of the upper outer wall (44) and the lower outer wall (46), each edge line opposing the ridgeline (50).']",True,"['10', '14', '12', '14', '12', '16', '1', '26', '28', '36', '12', '20', '32', '14', '16', '30']" 86,EP_3527472_B1 (1).png,EP3527472B1,STRADDLED VEHICLE,['FIG2'],"['FIG2 is a side view showing an opening/closing mechanism, a lock mechanism, and a seat']","['The lock mechanism 23 locks the seat 6 to a closed position. FIG2 is a side view showing the opening/closing mechanism 22, the lock mechanism 23, and the seat 6. In FIG2 the solid line shows the seat 6 located in the closed position. In FIG2 the broken line shows the seat 6 located in a fully-opened position.', 'As shown in FIG2, the vehicle main body 2 includes a vehicle body frame 9. The vehicle body frame 9 includes a seat frame 17 and a center frame 18. The seat frame 17 is disposed under the seat 6. A bracket 19 is mounted on the seat frame 17. The lock mechanism 23 is mounted on the seat frame 17 via the bracket 19.']",19,140,side view,B,"[{'element_identifier': '24', 'terms': ['locking member']}, {'element_identifier': '17', 'terms': ['seat frame']}, {'element_identifier': '12', 'terms': ['leg shield']}, {'element_identifier': '19', 'terms': ['bracket']}, {'element_identifier': '22', 'terms': ['opening/closing mechanism']}, {'element_identifier': '18', 'terms': ['center frame']}, {'element_identifier': '2', 'terms': ['vehicle main body']}, {'element_identifier': '25', 'terms': ['cable']}, {'element_identifier': '31', 'terms': ['first stay']}, {'element_identifier': '33', 'terms': ['first spring unit']}, {'element_identifier': '23', 'terms': ['lock mechanism']}, {'element_identifier': '32', 'terms': ['second stay']}]","['1. A straddled vehicle (1), comprising: a seat (6); a storage box (21) disposed under the seat (6); and an opening/closing mechanism (22) movably supporting the seat (6) between a closed position where the storage box (21) is closed and a fully-opened position where the storage box (21) is opened, the opening/closing mechanism (22) including a tension coil spring (61, 71), characterised in that the tension coil spring (61, 71) is configured to assist a driver in opening the seat (6), the tension coil spring (61, 71) including a coil portion (63, 73); and an elastic member (62, 72) located on an outer periphery of the coil portion (63, 73), the tension coil spring (61, 71) being disposed so as to contract as the seat (6) moves toward the fully-opened position, the outer periphery of the coil portion (63, 73) and an inner periphery of the elastic member (62, 72) being disposed so as to come into contact with each other at least before the seat reaches the fully-opened position.', '5. The straddled vehicle (1) according to any one of claims 1 to 4, further comprising: a vehicle body frame (9); a first stay (31) mounted on the vehicle body frame (9); and a second stay (32) mounted on the seat (6) and supported so as to be rotatable with respect to the first stay (31), wherein the tension coil spring (61, 71) includes a first end portion (64, 74) connected to the firststay (31) and a second end portion (65, 75) connected to the second stay (32).']",False,"['24', '19', '23', '25', '22', '12', '32', '33', '17', '18', '31', '2']" 87,EP_3527472_B1 (6).png,EP3527472B1,STRADDLED VEHICLE,['FIG9'],['FIG9 is a perspective view of a first spring unit'],"['FIG9 is a perspective view of the first spring unit 33. The first spring unit 33 includes a first tension coil spring 61 and a first elastic member 62. When opening the seat 6, the first tension coil spring 61 applies to the second stay 32 an elastic force in the direction of opening the seat 6, to assist the driver in opening the seat 6.']",10,71,perspective view,B,"[{'element_identifier': '19', 'terms': ['bracket']}, {'element_identifier': '9', 'terms': ['vehicle body frame']}, {'element_identifier': '63', 'terms': ['coil portion', 'coil portions']}, {'element_identifier': '64', 'terms': ['first end portion']}, {'element_identifier': '61', 'terms': ['tension coil spring', 'tension coil springs']}, {'element_identifier': '33', 'terms': ['first spring unit']}, {'element_identifier': '65', 'terms': ['second end portion']}, {'element_identifier': '62', 'terms': ['first elastic member']}]","['1. A straddled vehicle (1), comprising: a seat (6); a storage box (21) disposed under the seat (6); and an opening/closing mechanism (22) movably supporting the seat (6) between a closed position where the storage box (21) is closed and a fully-opened position where the storage box (21) is opened, the opening/closing mechanism (22) including a tension coil spring (61, 71), characterised in that the tension coil spring (61, 71) is configured to assist a driver in opening the seat (6), the tension coil spring (61, 71) including a coil portion (63, 73); and an elastic member (62, 72) located on an outer periphery of the coil portion (63, 73), the tension coil spring (61, 71) being disposed so as to contract as the seat (6) moves toward the fully-opened position, the outer periphery of the coil portion (63, 73) and an inner periphery of the elastic member (62, 72) being disposed so as to come into contact with each other at least before the seat reaches the fully-opened position.', '5. The straddled vehicle (1) according to any one of claims 1 to 4, further comprising: a vehicle body frame (9); a first stay (31) mounted on the vehicle body frame (9); and a second stay (32) mounted on the seat (6) and supported so as to be rotatable with respect to the first stay (31), wherein the tension coil spring (61, 71) includes a first end portion (64, 74) connected to the firststay (31) and a second end portion (65, 75) connected to the second stay (32).']",False,"['33', '62', '63', '61', '64', '65', '9', '19']" 88,EP_3527472_B1.png,EP3527472B1,STRADDLED VEHICLE,['FIG1'],['FIG1 is a side view of a straddled vehicle according to an embodiment'],"['A straddled vehicle according to an embodiment is now described hereinafter with reference to the drawings. FIG1 is a side view of a straddled vehicle 1 according to an embodiment. The straddled vehicle 1 according to the present embodiment is a scooter type vehicle. As shown in FIG1, the straddled vehicle 1 includes a vehicle main body 2, handlebars 3, a steering device 4, a front wheel 5, a seat 6, a rear wheel 7, and an engine 8.']",13,90,side view,B,"[{'element_identifier': '14', 'terms': ['rear cover']}, {'element_identifier': '12', 'terms': ['leg shield']}, {'element_identifier': '11', 'terms': ['front cover']}, {'element_identifier': '1', 'terms': ['straddled vehicle']}, {'element_identifier': '22', 'terms': ['opening/closing mechanism']}, {'element_identifier': '21', 'terms': ['storage box']}, {'element_identifier': '16', 'terms': ['operation switch']}, {'element_identifier': '15', 'terms': ['center tunnel portion']}, {'element_identifier': '23', 'terms': ['lock mechanism']}, {'element_identifier': '13', 'terms': ['foot board']}]","['1. A straddled vehicle (1), comprising: a seat (6); a storage box (21) disposed under the seat (6); and an opening/closing mechanism (22) movably supporting the seat (6) between a closed position where the storage box (21) is closed and a fully-opened position where the storage box (21) is opened, the opening/closing mechanism (22) including a tension coil spring (61, 71), characterised in that the tension coil spring (61, 71) is configured to assist a driver in opening the seat (6), the tension coil spring (61, 71) including a coil portion (63, 73); and an elastic member (62, 72) located on an outer periphery of the coil portion (63, 73), the tension coil spring (61, 71) being disposed so as to contract as the seat (6) moves toward the fully-opened position, the outer periphery of the coil portion (63, 73) and an inner periphery of the elastic member (62, 72) being disposed so as to come into contact with each other at least before the seat reaches the fully-opened position.', '11. The straddled vehicle (1) according to any one of claims 1 to 10, further comprising: an operation switch (16) for opening the seat (6).']",False,"['23', '21', '14', '16', '12', '22', '15', '11', '11', '13', '1']" 89,EP_3531288_B1 (1).png,EP3531288B1,"DATA STORAGE METHOD, DEVICE, AND SYSTEM",['FIG2'],['FIG2 is a schematic structural diagram of DHT-based distributed data routing in the prior art'],"['FIG2 is a schematic structural diagram of distributed data routing based on a distributed hash table (Distributed Hash Table, DHT) in the prior art. One DHT ring corresponds to one storage resource pool, the DHT ring includes a plurality of partitions, and each partition includes N+M storage nodes in the storage resource pool. plog is a data unit, each data unit corresponds to one partition, and each data unit is mapped to a segment of storage space on the storage nodes included in the partition. When the storage client 100 stores to-be-written data, the management server assigns a data unit (plog) for the to-be-written data and sends an identifier of the data unit to the storage client. The storage client calculates a hash value of the identifier of the data unit, determines, based on the calculated hash value, a partition corresponding to the data unit, queries a partition view to determine a list of storage nodes corresponding to the partition, performs EC coding on the to-be-written data, and stores generated EC blocks into storage nodes included in the list of storage nodes. The list of storage nodes is also referred to as a DHT partition table.']",17,230,schematic structural diagram,G,"[{'element_identifier': '2', 'terms': ['Table', 'be generated is', 'quantity']}]","['1. A data storage system, wherein the data storage system comprises a storage client (100, 800) and a distributed storage system (200), the distributed storage system uses an erasure coding, EC, technology to store data, the distributed storage system comprises a management server (201) and a plurality of storage nodes (202), and a storage node group consisting of N+M storage nodes corresponds to one partition, wherein N storage nodes are configured to store data blocks, M storage nodes are configured to store parity blocks generated based on the data blocks, and N and M are positive integers greater than 2; the storage client (100, 800) is configured to request the management server (201) to assign a data unit for to-be-written data; the management server (201) is configured to: assign a first data unit for the to-be-written data in a first partition, and return an identifier of the first data unit and a status of the first data unit to the storage client (100, 800), wherein the status of the first data unit indicates storage nodes that the storage client is allowed to use in the first partition, and a quantity of the storage nodes that the storage client is allowed to use is less than N+M; the storage client (100, 800) is further configured to obtain the identifier of the first data unit, the status of the first data unit, and a first partition view of the first partition, wherein the first partition view indicates a list of storage nodes comprised in the first partition; the storage client (100, 800) is further configured to: determine, based on the status of the first data unit, quantities of data blocks and parity blocks that need to be generated, and perform EC coding on the to-be-written data, to generate data blocks and parity blocks corresponding to the to-be-written data, wherein a sum of quantities of the generated data blocks and parity blocks is equal to the quantity of the storage nodes that the storage client is allowed to use; and the storage client (100, 800) is further configured to store, based on the first partition view and the status of the first data unit, the generated data blocks and parity blocks into the storage nodes that the storage client is allowed to use in the first partition, wherein each node stores one data block or parity block.']",False,"['2', '29']" 90,EP_3531772_B1 (2).png,EP3531772B1,"DATA TRANSMISSION METHOD, TERMINAL DEVICE AND NETWORK SIDE DEVICE",['FIG6'],['FIG6 is a structural block diagram of a network side device according to an embodiment of this application'],"['FIG6 is a structural block diagram of a network side device according to an embodiment of this application. As shown in FIG6, the network side device 600 includes a processing unit 601, a sending unit 602, and a receiving unit 603.']",18,46,structural block diagram,H,"[{'element_identifier': '601', 'terms': ['processing unit']}, {'element_identifier': '5', 'terms': ['January']}, {'element_identifier': '502', 'terms': ['sending unit']}, {'element_identifier': '600', 'terms': ['network side device']}, {'element_identifier': '501', 'terms': ['receiving unit']}, {'element_identifier': '500', 'terms': ['terminal device']}, {'element_identifier': '504', 'terms': ['second processing unit']}, {'element_identifier': '602', 'terms': ['sending unit']}, {'element_identifier': '505', 'terms': ['third processing unit']}, {'element_identifier': '503', 'terms': ['processing unit']}, {'element_identifier': '603', 'terms': ['receiving unit']}]","['6. A terminal device (120, 500, 700), wherein the terminal device (120, 500, 700) comprises a receiving unit and a sending unit, wherein the receiving unit is configured to receive a first identifier ID, wherein the first ID is an ID allocated by a first network side device (110, 600, 800) to the terminal device (120, 500, 700), the terminal device (120, 500, 700) is located in a first area, the first area is an area in which the first network side device (110, 600, 800) provides a service, and the first ID is valid in the first area; the sending unit is configured to indicate mobility information of the terminal device (120, 500, 700) to the first network side device (110, 600, 800); and the receiving unit is further configured to receive target grant free information indicated by the first network side device (110, 600, 800) based on the mobility information, wherein the target grant free information is a dedicated grant free resource or a universal grant free resource, data information sent by the sending unit to the first network side device (110, 600, 800) by using the dedicated grant free resource comprises data sent by the terminal device (120, 500, 700), and data information sent by the sending unit to the first network side device (110, 600, 800) by using the universal grant free resource comprises data sent by the terminal device (120, 500, 700) and the first ID.', '7. The terminal device (120, 500, 700) according to claim 6, wherein the terminal device (120, 500, 700) further comprises: a first processing unit, configured to determine the mobility information; and the sending unit is configured to send the mobility information determined by the first processing unit to the first network side device (110, 600, 800).']",True,"['500', '501', '504', '505', '503', '502', '5', '600', '602', '601', '603', '6', '25']" 91,EP_3531772_B1 (3).png,EP3531772B1,"DATA TRANSMISSION METHOD, TERMINAL DEVICE AND NETWORK SIDE DEVICE","['FIG7', ' FIG8']","['FIG8 is a structural block diagram of a network side device according to an embodiment of this application ', 'FIG7 is a structural block diagram of a terminal device according to an embodiment of this application']","['FIG8 is a structural block diagram of a network side device according to an embodiment of this application. The network side device 800 shown in FIG8 includes a processor 801, a memory 802, and a transceiver 803.', 'It may be understood that, in addition to the processor 801, the memory 802, and the transceiver 803 shown in FIG8, the network side device 800 should further include some necessary apparatuses such as an antenna, a cyclic prefix remover, and a fast Fourier transformation processor. To avoid redundancy, the foregoing apparatuses are not shown in FIG8. ', 'FIG7 is a structural block diagram of a terminal device according to an embodiment of this application. The terminal device 700 shown in FIG7 includes a processor 701, a memory 702, and a transceiver 703.', 'It may be understood that, in addition to the processor 701, the memory 702, and the transceiver 703 shown in FIG7, the terminal device 700 should further include some necessary apparatuses such as an antenna, a display, and an input apparatus. To avoid redundancy, the foregoing apparatuses are not shown in FIG7.']",35,209,structural block diagram,H,"[{'element_identifier': '8', 'terms': ['andFIG.']}, {'element_identifier': '801', 'terms': ['processor']}, {'element_identifier': '803', 'terms': ['transceiver']}, {'element_identifier': '701', 'terms': ['processor']}, {'element_identifier': '702', 'terms': ['memory']}, {'element_identifier': '802', 'terms': ['memory']}, {'element_identifier': '703', 'terms': ['transceiver']}, {'element_identifier': '800', 'terms': ['network side device']}, {'element_identifier': '700', 'terms': ['terminal device']}]","['1. A data transmission method, wherein the method comprises: receiving, by a terminal device (120, 500, 700), a first identifier ID, wherein the first ID is an ID allocated by a first network side device (110, 600, 800) to the terminal device (120, 500, 700), the terminal device (120, 500, 700) is located in a first area, the first area is an area in which the first network side device (110, 600, 800) provides a service, and the first ID is valid in the first area; indicating, by the terminal device (120, 500, 700), mobility information of the terminal device (120, 500, 700) to the first network side device (110, 600, 800); and receiving, by the terminal device (120, 500, 700), target grant free information indicated by the first network side device (110, 600, 800) based on the mobility information, wherein the target grant free information is a dedicated grant free resource or a universal grant free resource, data information sent by the terminal device (120, 500, 700) to the first network side device (110, 600, 800) by using the dedicated grant free resource comprises data sent by the terminal device (120, 500, 700), and data information sent by the terminal device (120, 500, 700) to the first network side device (110, 600, 800) by using the universal grant free resource comprises data sent by the terminal device (120, 500, 700) and the first ID, wherein the indicating, by the terminal device (120, 500, 700), mobility information of the terminal device (120, 500, 700) to the first network side device (110, 600, 800) comprises: determining, by the terminal device (120, 500, 700), the mobility information, and sending the mobility information to the first network side device (110, 600, 800); or sending, by the terminal device (120, 500, 700), first data information to the first network side device (110, 600, 800), wherein the first data information comprises the first ID and data sent by the terminal device (120, 500, 700), wherein the terminal device (120, 500, 700) provides the mobility information for the network side device (110, 600, 800), so that the network side device (110, 600, 800) determines, based on the mobility information, a grant free resource available for the terminal device (120, 500, 700).']",True,"['700', '701', '702', '703', '7', '800', '801', '802', '803', '8', '26']" 92,EP_3532143_B1 (5).png,EP3532143B1,CATHETER DEVICES WITH VALVES AND RELATED METHODS,['FIG5D'],['FIG5D is a schematic cross-sectional side view of the catheter assembly of FIG1 in which the catheter hub is now connected with a male Luer and the valve actuator is advanced distally to push open the valve'],"['The distally directed force moves the valve opener 150 in the distal direction until the geometries of the male tip 220 and the proximal opening of the catheter hub stop further distal advancement of the male tip, which is shown in FIG5D. In an example, a female Luer taper of the catheter hub 102 and a male Luer taper of the male tip 220 register and block distal advancement of the male tip further into the opening of the catheter hub. A seal is provided by the Luer engagement to prevent fluid from leaking out the proximal opening of the catheter hub.']",39,106,schematic cross-sectional view,A,"[{'element_identifier': '150', 'terms': ['actuator']}, {'element_identifier': '155', 'terms': ['arms']}, {'element_identifier': '138', 'terms': ['bushing']}, {'element_identifier': '102', 'terms': ['catheter hub']}]","['1. A needle assembly (100) comprising: a needle hub (106) with a needle (108) extending from a distal end of the needle hub; a catheter hub (102) having an interior surface defining an interior cavity (130); a catheter tube (104) attached to the catheter hub (102) and having the needle (108) extending through the catheter tube (104) and having a needle tip (110) extending out a distal opening (112) of the catheter tube (104) in a ready to use position; a valve (136) positioned in the interior cavity (130) of the catheter hub (102), said valve (136) comprising a valve body (402) having an outer perimeter positioned in a bore section (146) of the catheter hub (102), a proximal receptacle (410) on a proximal end, a distal receptacle (415) on a distal end, and a valve disc (50) located between the proximal receptacle (410) and distal receptacle (415); an actuator (150) positioned in the interior cavity (130) of the catheter hub (102), the actuator (150) is configured to open the valve (136), the actuator (150) comprising: a body (151) having a nose section (161) and an activation end (315), the activation end (315) is located within the proximal receptacle (410) and is configured to push the valve disc (50) to open the valve (136); and an extension leg (152) on a proximal end of the actuator (150), the extension leg having an engagement section (330) having a surface for supporting; a safety clip (132) having a proximal wall (280), a proximal opening (284) on the proximal wall (280), a resilient arm (290) with an end (333); wherein the end (333) of the arm (290) is supported by the surface of the engagement section (330) when the safety clip (132) is in the interior cavity (130) of the catheter hub (102) in the ready to use position.', '4. The needle assembly of any preceding claim, wherein the actuator (150) further comprises: one or more guide arms (155) extending radially from the body (151) of the actuator (150), the one or more guide arms (155) configured to engage one or more slots (510) on the interior surface of the catheter hub (102), the engagement between the one or more guide arms (155) and the one or more slots (510) configured to prevent rotation of the actuator (150) within the catheter hub (102).', '10. A method of manufacturing a needle assembly (100) comprising: providing a catheter hub (102) with a catheter tube (104) with a distal opening (112), said catheter hub (102) comprising a hub body (102a) defining an interior cavity (130) and a proximal opening; positioning a bushing (138) inside the catheter hub (102) and against the catheter tube (104) and positioning a valve (136) proximal of the bushing (138); the valve comprising a valve body (402) having a distal valve section (406) and a proximal valve section (404) defining a proximal receptacle (410), and wherein the distal valve section (406) is located in a bore section (146) of the interior cavity (130) and the bore section (146) contacts the distal valve section (406) to secure the valve (136) inside the interior cavity (130); positioning a valve opener (150) adjacent the valve (136) and inside the interior cavity (130) of the catheter hub (102) so that a nose section (161) of the valve opener (150) is located inside the proximal receptacle (410), the valve opener (150) comprising an extension leg (152) on a proximal end of the valve opener (150), the extension leg having an engagement section (330); positioning a safety clip (132) in the interior cavity (130) of the catheter hub (102) so that an end (333) of an arm (290) of the safety clip (132) is located over the engagement section (330), the engagement section (330) having a surface to support the safety clip (132) when the safety clip (132) is in the interior cavity (130) of the catheter hub (102); placing a needle (108), which is attached to a needle hub (106), through the catheter hub (102), the valve (136), the valve opener (150), the safety clip (132) and the catheter tube (104) so that a tip (110) of the needle (108) extends out the distal opening (112) of the catheter tube (104).']",True,"['102', '150', '138', '155', '39']" 93,EP_3533231_B1 (1).png,EP3533231B1,ELECTRONIC APPARATUS AND OPERATING METHOD THEREOF,['FIG2'],['FIG2 is a block diagram illustrating an example electronic apparatus according to an example embodiment'],"['FIG2 is a block diagram illustrating the electronic apparatus 100 according to an example embodiment.', 'Referring to FIG2, the electronic apparatus 100 may include a broadcasting content receiver 110, a communication interface (e.g., including communication circuitry) 120, the ACR module (e.g., including ACR circuitry) 130, a display 140, a video processor (e.g., including video processing circuitry) 150, an audio output unit (e.g., including audio output circuitry) 160, an audio processor (e.g., including audio processing circuitry) 170, a controller (e.g., including processing circuitry)_180 and a memory 190.', 'In addition to the components illustrated in FIG2, the electronic apparatus 100 may further include an input/output unit configured to receive a video, an audio, and additional information from the outside of the electronic apparatus 100, and a sensor configured to sense an image of a user and an interaction of the user.', 'Meanwhile, the block diagram of the electronic apparatus 100 illustrated in FIG2 is merely an example embodiment. The components of the block diagram of FIG2 may be combined, added, or omitted according to the specification of the electronic apparatus 100 actually implemented. That is, two or more components may be combined into one component, or one component may be divided into two or more components, according to necessity. Also, a function performed by each block is for describing embodiments, and its specific operation or apparatus does not limit the scope of the present disclosure.']",15,282,block diagram,H,"[{'element_identifier': '150', 'terms': ['video processor']}, {'element_identifier': '160', 'terms': ['audio output interface']}, {'element_identifier': '130', 'terms': ['ACR module']}, {'element_identifier': '100', 'terms': ['electronic apparatus']}, {'element_identifier': '250', 'terms': ['server']}, {'element_identifier': '300', 'terms': ['content server']}, {'element_identifier': '190', 'terms': ['memory']}, {'element_identifier': '180', 'terms': ['controller']}, {'element_identifier': '260', 'terms': ['fingerprint DB']}, {'element_identifier': '140', 'terms': ['display']}, {'element_identifier': '110', 'terms': ['broadcasting content receiver']}, {'element_identifier': '200', 'terms': ['broadcasting content server']}, {'element_identifier': '170', 'terms': ['audio processor']}, {'element_identifier': '120', 'terms': ['communication interface']}]","['1. An electronic apparatus comprising: a communication interface comprising communication circuitry; a display; a memory configured to store one or more instructions; and a processor configured to execute the one or more instructions stored in the memory, the instructions, when executed by the processor, cause the electronic apparatus to: transmit, to an external server, information for recognition of content displayed on the display, receive, from the external server, in response to the transmission of the information for recognition of the content, address information of replacement content to be displayed in a replacement slot including a section between the content and next content displayed next to the content and information on the replacement slot including a length of the replacement slot, access a content server to download the replacement content based on the address information of the replacement content received from the external server, parse the replacement content downloaded from the content server to obtain information on a length of the replacement content, compare the length of the replacement slot received from the external server, with the length of the replacement content obtained by parsing the replacement content downloaded from the content server, and when the length of the replacement slot is not matched with the length of the replacement content, process the replacement content using one or more frames included in the replacement content, wherein: based on the length of the replacement content being less than the length of the replacement slot, a display time of one or more frames included in the replacement content is increased so that the replacement content is displayed for a period of time corresponding to the length of the replacement slot, and based on the length of the replacement content being greater than the length of the replacement slot, one or more frames included in the replacement content is periodically removed.']",False,"['2', '100', '140', '150', '160', '170', '180', '190', '110', '120', '130', '200', '300', '250', '260', '19']" 94,EP_3533231_B1.png,EP3533231B1,ELECTRONIC APPARATUS AND OPERATING METHOD THEREOF,['FIG1'],['FIG1 is a diagram illustrating an example network system according to various example embodiments of the present disclosure'],"['FIG1 is a diagram illustrating an example network system according to various example embodiments.', 'Referring to FIG1, the network system may include an electronic apparatus 100, a broadcasting content server 200, an automatic content recognition (ACR) server 250, a content server 300, and a network 350.']",18,56,diagram,H,"[{'element_identifier': '310', 'terms': ['content DB']}, {'element_identifier': '350', 'terms': ['network']}, {'element_identifier': '130', 'terms': ['ACR module']}, {'element_identifier': '100', 'terms': ['electronic apparatus']}, {'element_identifier': '250', 'terms': ['server']}, {'element_identifier': '300', 'terms': ['content server']}, {'element_identifier': '260', 'terms': ['fingerprint DB']}, {'element_identifier': '200', 'terms': ['broadcasting content server']}]","['1. An electronic apparatus comprising: a communication interface comprising communication circuitry; a display; a memory configured to store one or more instructions; and a processor configured to execute the one or more instructions stored in the memory, the instructions, when executed by the processor, cause the electronic apparatus to: transmit, to an external server, information for recognition of content displayed on the display, receive, from the external server, in response to the transmission of the information for recognition of the content, address information of replacement content to be displayed in a replacement slot including a section between the content and next content displayed next to the content and information on the replacement slot including a length of the replacement slot, access a content server to download the replacement content based on the address information of the replacement content received from the external server, parse the replacement content downloaded from the content server to obtain information on a length of the replacement content, compare the length of the replacement slot received from the external server, with the length of the replacement content obtained by parsing the replacement content downloaded from the content server, and when the length of the replacement slot is not matched with the length of the replacement content, process the replacement content using one or more frames included in the replacement content, wherein: based on the length of the replacement content being less than the length of the replacement slot, a display time of one or more frames included in the replacement content is increased so that the replacement content is displayed for a period of time corresponding to the length of the replacement slot, and based on the length of the replacement content being greater than the length of the replacement slot, one or more frames included in the replacement content is periodically removed.']",False,"['300', '310', '200', '210', '250', '260', '350', '100', '130', '18']" 95,EP_3533247_B1 (5).png,EP3533247B1,WIRELESS NETWORK TYPE DETECTION METHOD AND ELECTRONIC DEVICE,['FIG3'],['FIG3 is a structural hardware diagram illustrating an electronic device including a wireless network type detection apparatus of the present application'],"['The embodiment of the wireless network type detection apparatus of the present application can be applied to an electronic device. The apparatus embodiment can be implemented by using hardware, software, or a combination of hardware and software. For example, in a software implementation, the wireless network type detection apparatus is a logical apparatus, and is formed when a wireless network type detection processor of the wireless network type detection apparatus reads a corresponding computer program instruction in a nonvolatile memory and executes the computer program instruction in a memory. In a hardware aspect, FIG3 is a structural hardware diagram illustrating an electronic device including a wireless network type detection apparatus of the present application. In addition to a processor 310, a memory 330, a network interface 320, and a nonvolatile memory 340 shown in FIG3, in this embodiment, the electronic device where the apparatus 331 is located generally can further include other hardware based on an actual function of the computer device. Details are not repeated here.']",21,184,structural diagram,H,"[{'element_identifier': '310', 'terms': ['processor']}, {'element_identifier': '331', 'terms': ['apparatus']}, {'element_identifier': '320', 'terms': ['network interface']}, {'element_identifier': '340', 'terms': ['nonvolatile memory']}, {'element_identifier': '330', 'terms': ['memory']}]","['11. An electronic device, comprising: a processor; and a memory, configured to store an instruction that can be executed by the processor, wherein the processor is configured to: determine whether a currently connected wireless network requires a password for accessing a service through the wireless network based on the specified network address (202); after determining that no password is required, access at least one specified network address (204); determine whether the currently connected wireless network requires secondary login verification, by determining whether the specified network address can be successfully accessed (206) determine that the currently connected wireless network is an unsecured network if the currently connected wireless network does not require a password and does not require a secondary login verification; and providing a security risk warning to a user of the electronic device or automatically blocking access by the electronic device to the currently connected wireless network, if it is determined that the currently connected wireless network is an unsecured network.', '12. The device according to claim 11, wherein the memory comprises a wireless network type detection apparatus that is configured to perform the method according to any one of claims 1 to']",False,"['310', '320', '330', '340', '22', '331']" 96,EP_3533270_B1 (4).png,EP3533270B1,CONFIGURATION OF A RADIO EQUIPMENT OF AN ACCESS NODE,['FIG8'],['FIG8 is a schematic illustration of an Ethernet packet according to embodiments'],"['According to an embodiment the messages are transmitted as payload in Ethernet packets. The payload in each Ethernet packet comprises a header field defined by the REC-RE interface 700 and a payload field comprising the configuring information. FIG8 schematically illustrates an Ethernet packet 800. The Ethernet packet 800 has an Ethernet header field 810, an Ethernet payload field 820 and an Ethernet tail field 830. The Ethernet payload field 820 comprises an REC-RE interface header field 840 and an REC-RE interface payload field 850. The REC-RE interface payload field 850 comprises the actual data transferred on the REC-RE interface 700. The REC-RE interface header field 840, among other things, indicates the message identifier as well as the destination address which represented by a tuple of {MAC address, VLAN ID, CEP}, where MAC is short for medium access control, VLAN ID is short for virtual local area network identity, and CEP is short for connection end point. Hence, in a low load situation where there are just a few active terminal devices 600, only a limited set of the hardware resources may be active. Then the RE 300a, 300b may allocate the CEPs to the active hardware resources only.']",12,232,schematic,H,"[{'element_identifier': '850', 'terms': ['REC-RE interface payload field']}, {'element_identifier': '7', 'terms': ['MHz would require']}, {'element_identifier': '800', 'terms': ['Ethernet packet']}, {'element_identifier': '810', 'terms': ['Ethernet header field']}]","['9. The method according to claim 7 or 8, wherein the messages are transmitted as payload in Ethernet packets (800), wherein the payload in each Ethernet packet comprises a header field defined by the REC-RE interface (700) and a payload field comprising the configuring information.']",True,"['810', '850', '8', '800', '1', '7', '6', '24']" 97,EP_3535023_B1 (1).png,EP3535023B1,ATRIAL TRACKING IN AN INTRACARDIAC VENTRICULAR PACEMAKER,"['FIG2A', ' FIG2B']","['FIG2B is a conceptual diagram of another example of the intracardiac ventricular pacemaker shown in FIG1 ', 'FIG2A is a conceptual diagram of the intracardiac ventricular pacemaker shown in FIG1']","['FIG2B is a conceptual diagram of another example of RV pacemaker 14. In FIG2B, RV pacemaker 14 includes a proximal sensing extension 165 extending away from housing 150 and carrying a pair of sensing electrodes 167 and 168. The proximal sensing extension 165 may be coupled to the housing 150 for positioning a return sensing electrode 168 or 167 which may be paired with distal electrode 164 at an increased inter-electrode distance compared to the inter-electrode spacing of housing-based electrodes 162 and 164. The increased inter-electrode distance may facilitate sensing of far-field atrial signals such as P-waves attendant to atrial depolarization. ', 'FIG2A is a conceptual diagram of the intracardiac RV pacemaker 14 shown in FIG1. RV pacemaker 14 includes electrodes 162 and 164 spaced apart along the housing 150 of pacemaker 14 for sensing cardiac electrical signals and delivering pacing pulses. Electrode 164 is shown as a tip electrode extending from a distal end 102 of pacemaker 14, and electrode 162 is shown as a ring electrode along a mid-portion of housing 150, for example adjacent proximal end 104. Distal end 102 is referred to as ""distal"" in that it is expected to be the leading end as pacemaker 14 is advanced through a delivery tool, such as a catheter, and placed against a targeted pacing site.', 'Housing 150 is formed from a biocompatible material, such as a stainless steel or titanium alloy. In some examples, the housing 150 may include an insulating coating. Examples of insulating coatings include parylene, urethane, PEEK, or polyimide among others. The entirety of the housing 150 may be insulated, but only electrodes 162 and 164 uninsulated. Electrode 1 64 may serve as a cathode electrode and be coupled to internal circuitry, e.g., a pacing pulse generator and cardiac electrical signal sensing circuitry, enclosed by housing 150 via an electrical feedthrough crossing housing 150. Electrode 162 may be formed as a conductive portion of housing 150 as a ring electrode that is electrically isolated from the other portions of the housing 150 as generally shown in FIG2A. In other examples, the entire periphery of the housing 150 may function as an electrode that is electrically isolated from tip electrode 164, instead of providing a localized ring electrode such as anode electrode 162. Electrode 162 formed along an electrically conductive portion of housing 150 serves as a return anode during pacing and sensing.']",29,445,conceptual diagram,A,"[{'element_identifier': '166', 'terms': ['fixation tines']}, {'element_identifier': '160', 'terms': ['battery subassembly']}, {'element_identifier': '158', 'terms': ['delivery tool interface']}, {'element_identifier': '168', 'terms': ['electrodes', 'electrode']}, {'element_identifier': '104', 'terms': ['proximal end']}, {'element_identifier': '6', 'terms': ['U.S. Pat. No.']}, {'element_identifier': '162', 'terms': ['electrodes', 'electrode']}, {'element_identifier': '102', 'terms': ['distal end']}, {'element_identifier': '10', 'terms': ['system']}, {'element_identifier': '150', 'terms': ['housing']}]","['1. An intracardiac ventricular pacemaker, comprising: a pulse generator (202) configured to generate and deliver pacing pulses to a ventricle of a heart via electrodes coupled to the pacemaker; a motion sensor (212) configured to produce a motion signal comprising an atrial systolic event and at least one ventricular diastolic event; and a control circuit (206) coupled to the motion sensor and the pulse generator and configured to: set an atrial refractory period; determine a ventricular diastolic event metric from the motion signal; compare the ventricular diastolic event metric to change criteria to detect a change in the ventricular diastolic event metric compared to at least one previously determined ventricular diastolic event metric; adjust the atrial refractory period in response to detecting the change; detect the atrial systolic event from the motion signal; set an atrioventricular pacing interval in response to detecting the atrial systolic event after an expiration of the atrial refractory period; and control the pulse generator to deliver a pacing pulse to a ventricle of the heart in response to the atrioventricular pacing interval expiring.', '14. The pacemaker of any of claims 1-13, further comprising a housing (150) enclosing the pulse generator, the motion sensor, and the control circuit, wherein the electrodes are housing-based electrodes.']",True,"['10', '150', '104', '158', '160', '162', '166', '102', '104', '158', '160', '162', '65', '168', '6', '166', '25']" 98,EP_3536069_B1 (2).png,EP3536069B1,METHODS AND APPARATUSES FOR MANAGING PAGING IN A WIRELESS COMMUNICATION NETWORK,['FIG3'],['FIG3 is a signalling diagram illustrating a procedure for sending small data transmissions'],"['In the procedure discussed above and illustrated in FIG3, the UE starts with a random access procedure but the data included with message 3 is transmitted over an orthogonal scheme (e.g. PUSCH / PUCCH) thanks to the UL grants provided by the eNB. An alternative procedure would be to use a Contention-Based (CB) channel to directly send data with message 3 (possibly including on this channel the indication that the UE wishes to immediately return to the inactive state. In this case the UE either needs to be pre-configured as to how to use the CB channel or to read the configuration via system information. Another alternative procedure would be for the UE to transmit infrequent small data directly on a CB channel without any RRC signaling. A CB channel would therefore be defined that can be used for small infrequent data and that UEs can access in the inactive state.', 'In RAN2#95bis, one of the agreed design questions that the small data transmission solution needs to address is how downlink acknowledgements (e.g. from higher layer protocols) are addressed. In order to ensure reliability, it is quite likely that acknowledgement of UL transmissions may need to be provided on many layers e.g. HARQ, RLC, TCP and the Application layer. If the UE immediately returns to the RRC_Inactive state after an UL transmission (i.e. multiplexed with or following the RRCConnectionResumeRequest message in FIG3), these acknowledgments would trigger paging and lead to significant inefficiencies. For example, there may be a long delay until the DL data can be delivered, since the paging occasions, i.e. the time instances when paging messages can be sent to the UE, are typically configured at relatively long intervals to enable power saving in the UE. Further, there may be additional signaling overhead due to the RRC signaling needed to put the UE back into RRC_Connected mode in order to receive the acknowledgement messages.', 'Although the concepts outlined herein are applicable in a number of different scenarios, two particular use cases are outlined below as examples. In the first use case, a wireless terminal device follows the procedure outlined in FIG3 for transmitting a small data packet while in the RRC_Inactive state (i.e. waking from the RRC_Inactive state temporarily to transmit the small data packet before reverting to the RRC_Inactive state).']",13,425,diagram,H,"[{'element_identifier': '3', 'terms': ['message']}]","['7. The method according to any one of the preceding claims, wherein the step of configuring (504) the terminal device with one or more second paging occasions comprises broadcasting system information indicating the second paging occasions, or transmitting to the terminal device a dedicated control message indicating the second paging occasions.']",False,"['3', '16']" 99,EP_3536588_B1 (5).png,EP3536588B1,STRADDLED VEHICLE,['FIG9'],"['FIG9 is a plan view showing the leg shield, the main switch, and the electric power supply socket']","['As shown in FIG9, any portion of the terminal insertion hole 62 overlaps the right front wall 76 in a plan view, and is hidden by the right front wall 76 in a plan view. A portion of the switch panel 52 overlaps the right front wall 76 in a plan view and is hidden by the right front wall 76 in a plan view. The rear end of the switch panel 52 is located farther to the rear than the rear edge of the upper end surface of the leg shield 29 in a plan view (the rear edge of the upper end surface of the upper wall 71) and visible in a plan view. The rear end of the switch panel 52 may be located farther to the front than the rear edge of the upper end surface of the leg shield 29 in a plan view.']",20,157,plan view,B,"[{'element_identifier': '67', 'terms': ['electrical wiring']}, {'element_identifier': '51', 'terms': ['main switch']}, {'element_identifier': '72', 'terms': ['center wall']}, {'element_identifier': '75', 'terms': ['base']}, {'element_identifier': '62', 'terms': ['terminal insertion hole']}, {'element_identifier': '63', 'terms': ['cap']}, {'element_identifier': '2', 'terms': ['frame']}, {'element_identifier': '52', 'terms': ['switch panel']}, {'element_identifier': '76', 'terms': ['right front wall']}, {'element_identifier': '89', 'terms': ['housing']}, {'element_identifier': '50', 'terms': ['main key']}, {'element_identifier': '88', 'terms': ['lock nut']}, {'element_identifier': '41', 'terms': ['center shield']}, {'element_identifier': '47', 'terms': ['outer portion']}, {'element_identifier': '46', 'terms': ['storage portion']}, {'element_identifier': '31', 'terms': ['underside covers']}, {'element_identifier': '74', 'terms': ['right inner wall']}]","['1. A straddled vehicle (1) comprising: a prime mover (16) configured to generate power to run the straddled vehicle (1); a frame (2) including a head pipe (3) disposed at a vehicle center (WO) in a width direction of the vehicle (1); a seat (6) located behind the head pipe (3) for a rider to sit on; a leg shield (29) which is located between the head pipe (3) and the seat (6) in a front-rear direction of the vehicle (1) and located in front of the legs of the rider sitting on the seat (6); a main switch (51) which is configured to be operated by the rider to start the prime mover (16); and an electric power supply socket (61) that includes a terminal insertion hole (62) configured for inserting a terminal of an electric device (64), wherein the leg shield (29) includes a base (75), and a front wall (76) which extends upward from the base (75), and to which the electric power supply socket (61) is mounted, wherein the main switch (51) is located on a right or left side of the head pipe (3) in the width direction of the vehicle (1); and the electric power supply socket (61) being disposed on the same side as the main switch (51) relative to the head pipe (3) in the width direction of the vehicle (1), characterized in that the main switch (51) is mounted to the base (75) of the leg shield (29), and the front wall (76) is located farther to the front than a rear end (51r) of the main switch (51),the main switch (51) and the electric power supply socket (61) are located on an outer surface of the leg shield (29), the terminal insertion hole (62) of the electric power supply socket (61) is located above the main switch (51), at least a portion of the terminal insertion hole (62) is located farther to the front than the rear end (51r) of the main switch (51) in a side view of the vehicle (1), at least a portion of the terminal insertion hole (62) overlaps the front wall (76) in a plan view of the vehicle (1), a center line (Le) of the electric power supply socket (61) extends horizontally or rearward and upward in a side view of the vehicle (1), and the front wall (76) of the leg shield (29) includes a ceiling wall (76B) which has a rear end (76r) disposed farther to the rear than the electric power supply socket (61) and which is located above the electric power supply socket (61).', '5. A straddled vehicle (1) according to any one of claims 1 to 4, characterized in that the electric power supply socket (61) includes a cap (63) configured to open or close the terminal insertion hole (62) and a hinge (86) to be bent as the cap (63) is opened or closed, and at least a portion of the hinge (86) is disposed above the center line (Le) of the electric power supply socket (61).', '6. A straddled vehicle (1) according to any one of claims 1 to 5, characterized in that the electric power supply socket (61) includes a tubular housing (89) that surrounds the terminal insertion hole (62), and the housing (89) includes a cylindrical portion (89t) that surrounds the terminal insertion hole (62), a bottom portion (89b) that closes a bottom of the cylindrical portion (89t), and a drain hole (93) that passes through at least one of the cylindrical portion (89t) and the bottom portion (89b) and extends from the terminal insertion hole (62) to a space outside the electric power supply socket (61).', '13. A straddled vehicle (1) according to any one of claims 1 to 12, characterized in that the leg shield (29) further includes a storage portion (46) configured to accommodate an article, and the storage portion (46) is disposed on the same side as the main switch (51) and the electric power supply socket (61) relative to the head pipe (3) in the width direction of the vehicle (1) and includes an opening portion (46o) located below the terminal insertion hole (62).']",False,"['2', '67', '89', '88', '63', '62', '76', '75', '50', '52', '47', '2', '46', '460', '51', '74', '72', '41', '31']" 100,EP_3536588_B1 (6).png,EP3536588B1,STRADDLED VEHICLE,['FIG10'],"['FIG10 is a right side view showing the leg shield, the main switch, and the electric power supply socket']","['As shown in FIG10, at least a portion of the terminal insertion hole 62 overlaps the right front wall 76 in a side view and is hidden by the right front wall 76 in a side view. The cap 63 also overlaps the right front wall 76 in a side view and is hidden by the right front wall 76 in a side view. In contrast to this, the switch panel 52 is not covered with the right front wall 76 in a side view and visible in a side view. The switch panel 52 is located on the right side of the right inner wall 74 of the leg shield 29 and overlaps the right inner wall 74 in a side view.']",21,129,right side view,B,"[{'element_identifier': '51', 'terms': ['main switch']}, {'element_identifier': '63', 'terms': ['cap']}, {'element_identifier': '52', 'terms': ['switch panel']}, {'element_identifier': '76', 'terms': ['right front wall']}, {'element_identifier': '61', 'terms': ['electric power supply socket']}, {'element_identifier': '29', 'terms': ['leg shield']}, {'element_identifier': '57', 'terms': ['select switch']}, {'element_identifier': '78', 'terms': ['right outer wall']}, {'element_identifier': '32', 'terms': ['lower cover']}, {'element_identifier': '72', 'terms': ['center wall']}, {'element_identifier': '73', 'terms': ['right recess']}, {'element_identifier': '89', 'terms': ['housing']}, {'element_identifier': '88', 'terms': ['lock nut']}, {'element_identifier': '75', 'terms': ['base']}, {'element_identifier': '71', 'terms': ['upper wall']}, {'element_identifier': '56', 'terms': ['latch']}, {'element_identifier': '85', 'terms': ['recess']}, {'element_identifier': '50', 'terms': ['main key']}, {'element_identifier': '74', 'terms': ['right inner wall']}]","['1. A straddled vehicle (1) comprising: a prime mover (16) configured to generate power to run the straddled vehicle (1); a frame (2) including a head pipe (3) disposed at a vehicle center (WO) in a width direction of the vehicle (1); a seat (6) located behind the head pipe (3) for a rider to sit on; a leg shield (29) which is located between the head pipe (3) and the seat (6) in a front-rear direction of the vehicle (1) and located in front of the legs of the rider sitting on the seat (6); a main switch (51) which is configured to be operated by the rider to start the prime mover (16); and an electric power supply socket (61) that includes a terminal insertion hole (62) configured for inserting a terminal of an electric device (64), wherein the leg shield (29) includes a base (75), and a front wall (76) which extends upward from the base (75), and to which the electric power supply socket (61) is mounted, wherein the main switch (51) is located on a right or left side of the head pipe (3) in the width direction of the vehicle (1); and the electric power supply socket (61) being disposed on the same side as the main switch (51) relative to the head pipe (3) in the width direction of the vehicle (1), characterized in that the main switch (51) is mounted to the base (75) of the leg shield (29), and the front wall (76) is located farther to the front than a rear end (51r) of the main switch (51),the main switch (51) and the electric power supply socket (61) are located on an outer surface of the leg shield (29), the terminal insertion hole (62) of the electric power supply socket (61) is located above the main switch (51), at least a portion of the terminal insertion hole (62) is located farther to the front than the rear end (51r) of the main switch (51) in a side view of the vehicle (1), at least a portion of the terminal insertion hole (62) overlaps the front wall (76) in a plan view of the vehicle (1), a center line (Le) of the electric power supply socket (61) extends horizontally or rearward and upward in a side view of the vehicle (1), and the front wall (76) of the leg shield (29) includes a ceiling wall (76B) which has a rear end (76r) disposed farther to the rear than the electric power supply socket (61) and which is located above the electric power supply socket (61).', '5. A straddled vehicle (1) according to any one of claims 1 to 4, characterized in that the electric power supply socket (61) includes a cap (63) configured to open or close the terminal insertion hole (62) and a hinge (86) to be bent as the cap (63) is opened or closed, and at least a portion of the hinge (86) is disposed above the center line (Le) of the electric power supply socket (61).', '6. A straddled vehicle (1) according to any one of claims 1 to 5, characterized in that the electric power supply socket (61) includes a tubular housing (89) that surrounds the terminal insertion hole (62), and the housing (89) includes a cylindrical portion (89t) that surrounds the terminal insertion hole (62), a bottom portion (89b) that closes a bottom of the cylindrical portion (89t), and a drain hole (93) that passes through at least one of the cylindrical portion (89t) and the bottom portion (89b) and extends from the terminal insertion hole (62) to a space outside the electric power supply socket (61).']",False,"['29', '76', '71', '85', '63', '61', '72', '73', '74', '51', '50', '620', '52', '75', '89', '88', '78', '56', '57', '32']" 101,EP_3537059_B1 (1).png,EP3537059B1,HEAT PUMP WATER HEATER UNIT AND CONTROL METHOD AND DEVICE THEREOF,['FIG4'],['FIG4 is a diagram illustrating the logic of a control method of a heat pump water heater unit according to another embodiment of the present disclosure'],"[""As illustrated in FIG4, when TS≥Tstop, the case that that the water of the water tank can be heated to the set temperature TS within the total time period H of the off-peak electricity when the heat pump host is turned on alone may not occur, and a case that, when both the heat pump host and the electric auxiliary heater is turned on, the water temperature of the water tank has not reached the set temperature TS while a temperature of the heat pump host has reached Tstop. At this time, the electric auxiliary heater is required to be turned on alone to continue heating the water in the water tank, such that the water temperature of the water tank can be heated to the set temperature TS within the total time period H of the off-peak electricity. That is, when TS≥Tstop, there may be two kinds of heating conditions. One is turning on the heat pump host alone for a while, then turning on both the electric auxiliary heater and the heat pump host. The other is turning on the heat pump host alone for a while, then turning on both the electric auxiliary heater and the heat pump host for a while, and finally controlling the electric auxiliary heater alone to be turned on for a while. Therefore, in this case, when calculating the first time period t, the heating condition when the electric auxiliary heater is turned on alone may be taken into consideration. For example, the remaining total time period H' of the off-peak electricity can be calculated according to a time period tde required for the water temperature of the water tank to rise by the first pre-set temperature when the electric auxiliary heater is turned on alone. For example, the remaining total time period H' of the off-peak electricity=H∗60- tde∗(TS-Tstop)-n∗TM. Then, the first time period t can be calculated according to the remaining total time period H' of the off-peak electricity, the maximum heating temperature Tstop of the heat pump host at the current outdoor ambient temperature, the water temperature T5 of the water tank. For example, the first time period t=H'/(Tstop-T5)=[H∗60-tde∗(TS-Tstop)-n∗TM]/(Tstop-T5).""]",26,420,diagram,F,"[{'element_identifier': '5', 'terms': ['difference temperature can be']}, {'element_identifier': '2', 'terms': ['pages']}, {'element_identifier': '10', 'terms': ['heat pump host']}, {'element_identifier': '20', 'terms': ['electric auxiliary heater']}]","['1. A control method of a heat pump water heater unit, wherein the heat pump water heater unit comprises a heat pump host (10), an electric auxiliary heater (20) and a water tank (30), the control method comprises: after receiving an off-peak electricity signal, obtaining a water temperature of the water tank (30) and determining whether the water temperature of the water tank (30) is less than a set temperature; when the water temperature is less than the set temperature, controlling the heat pump host (10) to be in a turned-on state; calculating, every first pre-set time period, a time period required for the water temperature of the water tank (30) to rise by a first pre-set temperature when both the heat pump host (10) and the electric auxiliary heater (20) are turned on, and recording the time period as a first time period; determining whether the first time period is less than a second pre-set time period; and when the first time period is less than the second pre-set time period, controlling the electric auxiliary heater (20) to be in the turned-on state; characterized in that the control method comprises: calculating, every first pre-set time period, the time period required for the water temperature of the water tank (30) to rise by the first pre-set temperature when both the heat pump host (10) and the electric auxiliary heater (20) are turned on comprises: determining whether the set temperature is less than a maximum heating temperature of the heat pump host (10) at a current outdoor ambient temperature; when the set temperature is less than the maximum heating temperature of the heat pump host (10) at the current outdoor ambient temperature, calculating a remaining total time period of the off-peak electricity according to the first pre-set time period, and calculating the first time period according to the remaining total time period of the off-peak electricity, the set temperature, and the water temperature of the water tank (30); when the set temperature is greater than or equal to the maximum heating temperature of the heat pump host (10) at the current outdoor ambient temperature, calculating the remaining total time period of the off-peak electricity according to the first pre-set time period and a time period required for the water temperature of the water tank (30) to rise by the first pre-set temperature when the electric auxiliary heater (20) is turned on alone, and calculating the first time period according to the remaining total time period of the off-peak electricity, the maximum heating temperature of the heat pump host (10) at the current outdoor ambient temperature, and the water temperature of the water tank (30).']",True,"['2', '5', '10', '15', '20', '10', '15', '20', '4', '22']" 102,EP_3537590_B1 (4).png,EP3537590B1,"HALF-BRIDGE DRIVER CIRCUIT, RELATED INTEGRATED CIRCUIT AND SYSTEM","['FIG8', ' FIG9']","['FIG8 shows an embodiment of a digital processing circuit of the half-bridge driver of FIG7, wherein the digital processing circuit comprises a synchronization circuit ', 'FIG9 shows an embodiment of the synchronization circuit of the digital processing circuit of FIG8']","['For example, FIG8 shows an embodiment of the processing circuit 208.', 'Generally, the signals CS10, CS20 and CS30 may be provided at output as digital signals, e.g. via the communication interface 210. Conversely, in the embodiment shown in FIG8, the processing circuit 208 comprises three digital-to-analog converters 216 (and optionally respective driver circuits 218), in order to generate analog signal CS10, CS20 and CS30, each indicative of the amplitude of a respective phase current, wherein the analog signals CS10, CS20 and CS30 are provided to respective pins of the driver circuit 22a. In various embodiments, the number of output signals (CS10, CS20 and CS30) corresponds thus to the number of phases of the motor to be driven. Moreover, when using analog output signals, the number of digital-to-analog converters 216 (and respective driver circuits 218) corresponds to the number of output signals. ', 'FIG9 shows an embodiment of the block of/the steps performed by the synchronization circuit 220.', 'For example, FIG9 shows that the digital processing circuit 214 may comprise three hardware or software modules, wherein:', 'Specifically, FIG9 shows the blocks of the synchronization circuit 220 configured to generate a single control signal T for one motor phase by monitoring a respective control signal IN (e.g. the control signal for the high side switch), and the same blocks may be repeated also for the other motor phases.', 'Generally, in case of a fixed switching duration TPWM the value/signal CPWM may also be set, e.g. via the interface 210 (see also FIG9).', 'In various embodiments, instead of monitoring a high side control signal (e.g. IN1, IN3 and IN5 for the example considered), each synchronization circuit 220 shown in FIG9 may monitor a low side control signals (e.g. IN2, IN4 and IN6 for the example considered).']",42,358,embodiment,H,"[{'element_identifier': '236', 'terms': ['control circuit']}, {'element_identifier': '210', 'terms': ['interface']}, {'element_identifier': '214', 'terms': ['processing circuit']}, {'element_identifier': '216', 'terms': ['converters']}, {'element_identifier': '218', 'terms': ['respective driver circuits']}, {'element_identifier': '230', 'terms': ['digital comparator circuit', 'comparators']}, {'element_identifier': '8', 'terms': ['equation']}, {'element_identifier': '220', 'terms': ['synchronization circuit', 'synchronization circuits']}, {'element_identifier': '208', 'terms': ['circuit']}, {'element_identifier': '206', 'terms': ['differential amplifiers', 'differential amplifier']}, {'element_identifier': '228', 'terms': ['circuit']}, {'element_identifier': '232', 'terms': ['counter']}, {'element_identifier': '226', 'terms': ['sample circuit']}, {'element_identifier': '234', 'terms': ['comparator', 'comparators']}, {'element_identifier': '224', 'terms': ['counter', 'counters']}, {'element_identifier': '212', 'terms': ['converter', 'converters']}]","['1. A half-bridge driver circuit (22a) comprising: - two input terminals for receiving a high side control signal ( IN 1 ) and a low side control signal ( IN 2 ), wherein said high side control signal ( IN 1 ) is a center aligned pulse-width-modulated signal having a given switching period ( T PWM ) and a given switch-on duration ( T ON ) , and said low side control signal ( IN 2 ) corresponds to an inverted version of said high side control signal ( IN 1 ) with a first delay ( T ONDT ) between a falling edge of said low side control signal ( IN 2 ) and a following rising edge of said high side control signal ( IN 1 ) and with a second delay ( T OFFDT ) between a falling edge of said high side control signal ( IN 1 ) and a following rising edge of said low side control signal ( IN 2 ); - two output terminals for providing a high side drive signal ( DRV 1 ) for a high side switch (SW 1 ) and a low side drive signal ( DRV 2 ) for a low side switch (SW 2 ) ; - a high side driver circuit (200 1 ) configured to generate said high side drive signal ( DRV 1 ) as a function of said high side control signal ( IN 1 ) , and a low side driver circuit (200 2 ) configured to generate said low side drive signal ( DRV 2 ) as a function of said low side control signal ( IN 2 ); - two measurement terminals ( CS1P, CS1N ) configured to be connected to the terminals of a shunt resistor (RS 1 ); and - an amplifier (206 1 ) configured to amplify the signal applied to said two measurement terminals ( CS1P, CS1N ) , thereby generating a measurement signal ( CS ) indicative of the current flowing through said shunt resistor (RS 1 ); wherein said half-bridge driver circuit (22a) comprises: - an analog-to-digital converter (212); - a processing circuit (214) configured to selectively acquire a digital sample of said measurement signal ( CS ) via said analog-to-digital converter (212) in response to a trigger signal ( T1 ); - a synchronization circuit (220) configured to generate said trigger signal ( T1 ) by: - determining via a first digital counter (224) a first value ( C1 ) indicative of said switch-on duration ( T ON ) of said high side control signal ( IN 1 ) by monitoring the rising and falling edges either of said high side control signal ( IN 1 ) or of said low side control signal ( IN 1 ); - determining a second value ( CPWM ) indicative of said switching period ( T PWM ) of said high side control signal ( IN 1 ); - computing a third value (C3) indicative of the first count value ( CNT1 ) of said first digital counter (224) when a next switching period of said high side control signal ( IN 1 ) starts as a function of said first value ( C1 ) and said second value ( CPWM ); - comparing said third value ( C3 ) with said first count value ( CNT1 ) of said first digital counter (224), thereby generating a third signal ( ST ) when the next switching period of said high side control signal ( IN 1 ) starts; - starting a second digital counter (232) in response to said third signal ( ST ); - comparing the count value ( CNT2 ) of said second digital counter (232) with a reference value ( REF ), thereby generating a fourth signal ( T ); and - generating said trigger signal ( T1 ) as a function of said fourth signal ( T ).', '5. The half-bridge driver circuit (22a) according to Claim 4, wherein said third value (C3) is computed according to the following equation: C 3 = C 1 + CPWM − C 1 − C ONDT + C OFFDT / 2 where C1 is said first value ( C1 ) , CPWM is said second value ( C1 ) , C3 is said third value ( C3 ) , and C ONDT and C OFFDT are indicative of said first delay ( T ONDT ) and said second delay ( T OFFDT ) , respectively, wherein the value C ONDT and C OFFDT are preferably programmable via a communication interface (210) of said half-bridge driver circuit (22a).']",True,"['208', '220', '214', '216', '206', '212', '218', '8', '210', '224', '226', '228', '230', '220', '232', '234', '236', '214', '9', '23']" 103,EP_3539927_B1 (1).png,EP3539927B1,"ACTIVE MATERIAL, ELECTRODE, SECONDARY BATTERY, BATTERY PACK, AND VEHICLE",['FIG4'],['FIG4 is an enlarged cross-sectional view of section A of the secondary battery shown in FIG3'],"['The negative electrode 3 includes a negative electrode current collector 3a and a negative electrode active material-containing layer 3b. At the portion of the negative electrode 3 positioned outermost among the wound electrode group 1, the negative electrode active material-containing layer 3b is formed only on an inner surface of the negative electrode current collector 3a, as shown in FIG4. For the other portions of the negative electrode 3, negative electrode active material-containing layers 3b are formed on both of reverse surfaces of the negative electrode current collector 3a.']",18,101,cross-sectional view,B,"[{'element_identifier': '5', 'terms': ['positive electrodes', 'positive electrode']}, {'element_identifier': '100', 'terms': ['single-batteries', 'single-battery']}, {'element_identifier': '2', 'terms': ['container member']}, {'element_identifier': '4', 'terms': ['Example', 'Examples']}, {'element_identifier': '3', 'terms': ['Example', 'Examples']}, {'element_identifier': '32', 'terms': ['lid']}]","['10. A secondary battery (100) comprising: a positive electrode (5); a negative electrode (3); and an electrolyte, wherein the negative electrode (3) is the electrode according to claim 8 or']",True,"['100', '2', '3', '5', '3', '5', '4', '4', '32']" 104,EP_3539927_B1 (2).png,EP3539927B1,"ACTIVE MATERIAL, ELECTRODE, SECONDARY BATTERY, BATTERY PACK, AND VEHICLE",['FIG6'],['FIG6 is an enlarged cross-sectional view of section B of the secondary battery shown in FIG5'],"['As shown in FIG6, the electrode group 1 is a stacked electrode group. The stacked electrode group 1 has a structure in which and negative electrodes 3 and positive electrodes 5 are alternately stacked with separator(s) 4 sandwiched therebetween.', 'The negative electrode current collector 3a of each of the negative electrodes 3 includes at one end, a portion 3c where the negative electrode active material-containing layer 3b is not supported on either surface. This portion 3c serves as a negative electrode tab. As shown in FIG6, the portions 3c serving as the negative electrode tabs do not overlap the positive electrodes 5. The plural negative electrode tabs (portions 3c) are electrically connected to the strip-shaped negative electrode terminal 6. A tip of the strip-shaped negative electrode terminal 6 is drawn to the outside from the container member 2.']",18,158,cross-sectional view,B,"[{'element_identifier': '5', 'terms': ['positive electrodes', 'positive electrode']}, {'element_identifier': '100', 'terms': ['single-batteries', 'single-battery']}, {'element_identifier': '2', 'terms': ['container member']}, {'element_identifier': '4', 'terms': ['Example', 'Examples']}, {'element_identifier': '6', 'terms': ['≤']}, {'element_identifier': '33', 'terms': ['sheets']}, {'element_identifier': '3', 'terms': ['Example', 'Examples']}]","['10. A secondary battery (100) comprising: a positive electrode (5); a negative electrode (3); and an electrolyte, wherein the negative electrode (3) is the electrode according to claim 8 or']",True,"['2', '6', '100', '5', '3', '4', '33']" 105,EP_3539927_B1 (5).png,EP3539927B1,"ACTIVE MATERIAL, ELECTRODE, SECONDARY BATTERY, BATTERY PACK, AND VEHICLE",['FIG10'],['FIG10 is a cross-sectional view schematically showing an example of a vehicle according to an approach'],"['FIG10 is a cross-sectional view schematically showing an example of a vehicle according to the sixth approach.', 'A vehicle 400, shown in FIG10 includes a vehicle body 40 and a battery pack 300 according to the fifth approach. In the example shown in FIG10, the vehicle 400 is a four-wheeled automobile.', 'In FIG10, the battery pack 300 is installed in an engine compartment located at the front of the vehicle body 40. As mentioned above, for example, the battery pack 300 may be alternatively installed in rear sections of the vehicle body 40, or under a seat. The battery pack 300 may be used as a power source of the vehicle 400. The battery pack 300 can also recover regenerative energy of motive force of the vehicle 400.']",18,147,cross-sectional view,B,"[{'element_identifier': '35', 'terms': ['wires']}, {'element_identifier': '22', 'terms': ['positive electrode-side lead']}, {'element_identifier': '1', 'terms': ['≤']}, {'element_identifier': '100', 'terms': ['single-batteries', 'single-battery']}, {'element_identifier': '346', 'terms': ['wirings', 'wiring']}, {'element_identifier': '345', 'terms': ['wirings', 'wiring']}, {'element_identifier': '342', 'terms': ['negative electrode-side connector']}, {'element_identifier': '400', 'terms': ['vehicle']}, {'element_identifier': '344', 'terms': ['protective circuit']}, {'element_identifier': '347', 'terms': ['external power distribution terminal']}, {'element_identifier': '300', 'terms': ['battery pack', 'battery packs']}, {'element_identifier': '10', 'terms': ['obtained in each example.']}, {'element_identifier': '23', 'terms': ['x ≤']}, {'element_identifier': '200', 'terms': ['battery module', 'battery modules']}, {'element_identifier': '343', 'terms': ['thermistor']}]","['14. The battery pack (300) according to claim 11, further comprising: an external power distribution terminal (347); and a protective circuit (344).', '16. A vehicle (400) comprising the battery pack (300) according to any one of claims 11 to']",True,"['22', '345', '344', '100', '100', '200', '100', '100', '347', '35', '346', '342', '23', '343', '100', '400', '1', '300', '10', '36']" 106,EP_3540730_B1.png,EP3540730B1,SPEECH SERVICE CONTROL APPARATUS AND METHOD THEREOF,['FIG1'],['FIG1 is a schematic diagram of a speech service system according to an embodiment of the disclosure'],"['FIG1 is a schematic diagram of a speech service system 1 according to an embodiment of the disclosure. Referring to FIG1, the speech service system 1 includes a speech service control apparatus 110 and a speech service providing server 150.']",17,43,schematic diagram,G,"[{'element_identifier': '1', 'terms': ['between']}, {'element_identifier': '113', 'terms': ['processor']}, {'element_identifier': '2', 'terms': ['following equations']}, {'element_identifier': '111', 'terms': ['speech receiving device']}, {'element_identifier': '110', 'terms': ['speech service control apparatus']}, {'element_identifier': '150', 'terms': ['speech service providing server']}, {'element_identifier': '114', 'terms': ['memory']}]","['9. A speech service control apparatus (110) comprising: a speech receiving device (111), receiving speech data; and a processor (113), coupled to the speech receiving device (111), and configured to: recognize a keyword in the speech data to determine a confidence value corresponding to the keyword, wherein the confidence value is a match level of the keyword relative to a wakeup keyword to request for a speech service; determine a number of cumulative failures in response to a determination that the confidence value is inferior to a recognition threshold, wherein the speech service is requested when the confidence value greater than the recognition threshold is determined, and the number of cumulative failures is a cumulative number accumulated when the confidence values of the speech data and at least one previous speech data are inferior to the recognition threshold within a time period; and modify the recognition threshold according to the number of cumulative failures and a calculation relationship of the confidence values of the speech data and the previous speech data.']",True,"['110', '111', '113', '114', '150', '1', '2', '14']" 107,EP_3540791_B1 (6).png,EP3540791B1,"FLUX COATING DEVICE AND METHOD FOR SOLAR CELL PANEL, AND APPARATUS FOR ATTACHING INTERCONNECTOR OF SOLAR CELL PANEL",['FIG9'],"['FIG9 is a schematic view showing a flux bath included in the flux portion and a wiring material passing through the flux bath, which are shown in FIG8']","['For example, as shown in FIG9, the inlet 222a or the outlet 222b may be formed of a hole formed at the first surface 222c or at the second surface 222d of the flux bath 222 below the surface 220b of the flux 220a. Then, a whole portion of the hole is positioned below the surface 220b of the flux 220a. Thus, the wiring material 142 moves through the inlet 222a and the outlet 222b, the wiring material 142 can stably move below the surface 222b of the flux 220a inside the flux 220a. In this instance, when a front end of the wiring material 142 is positioned at the inlet 222a, the wiring material 142 is pushed from a rear side of the wiring material 142 and the wiring material 142 passes through the inlet 222a and then the outlet 222b, and thereafter, the wiring material 142 may move in a desired direction by fixing the wiring material 142 again at a side of the outlet 222b.']",29,181,schematic view,B,"[{'element_identifier': '222', 'terms': ['flux bath']}, {'element_identifier': '142', 'terms': ['material', 'materials']}]","['1. A flux coating device for a solar cell panel, comprising: a flux bath (222) configured to receive flux (220a) and having an inlet (222a) and an outlet (222b), wherein the inlet (222a) and the outlet (222b) of the flux bath (222) are configured to pass an interconnector (142) below a surface (220b) of the flux (220a), characterized in that a supplying member (222e) or a spouting member is formed at a lower portion of the flux bath (222) configured to supply, jet, spray, eject, or spout the flux (220a) in an upward direction, and the supplying member (222e) is configured to only operate when the interconnector passes.', '10. The flux coating device of one of preceding claim, wherein the interconnector (142) comprises a wiring material, and wherein the wiring material includes: a rounded portion or a circular cross-section, a core layer (142a), and a solder layer (142b) formed on a surface of the core layer (142a).']",False,"['222', '142', '142', '28']" 108,EP_3540881_B1 (1).png,EP3540881B1,PARTICLE COLLECTING DEVICE AND IMAGE FORMING APPARATUS,['FIG2'],['FIG2 is a schematic diagram illustrating a particle collecting device of the first embodiment'],"['FIG2 is a schematic diagram illustrating a particle collecting device of the first embodiment.', 'The particle collecting device 200 illustrated in FIG2 includes a duct 201, a blower 202, an ionizing device 203, two electrodes 204, a power supply 205, and a controller 206. The controller 206 can be a processor including a central processing unit (CPU) and associated memory units such as a read only memory (ROM), a random access memory (RAM), etc. The processor performs various types of control processing by executing programs stored in the memory.']",14,107,schematic diagram,A,"[{'element_identifier': '201', 'terms': ['duct']}, {'element_identifier': '202', 'terms': ['blower']}, {'element_identifier': '12', 'terms': ['secondary transfer backup roller']}, {'element_identifier': '203', 'terms': ['ionizing device']}, {'element_identifier': '304', 'terms': ['electrode', 'electrodes']}, {'element_identifier': '206', 'terms': ['controller']}, {'element_identifier': '204', 'terms': ['electrodes']}, {'element_identifier': '301', 'terms': ['duct']}, {'element_identifier': '300', 'terms': ['particle collecting device', 'particle collecting devices']}, {'element_identifier': '205', 'terms': ['power supply']}, {'element_identifier': '3', 'terms': ['exposure device']}, {'element_identifier': '200', 'terms': ['particle collecting device', 'particle collecting devices']}]","['1. A particle collecting device (200) comprising: a duct (201); a blower (202) configured to cause air to flow in a predetermined blowing direction (D11) inside the duct (201); an ionizing device (203) disposed inside the duct (201) and configured to ionize particles contained in the air inside the duct (201); at least two electrodes (204; 301a,304) extending along the predetermined blowing direction (D11) and facing each other, the at least two electrodes (204; 301a,304) disposed downstream from the ionizing device (203) inside the duct (201) in the predetermined blowing direction (D11); a power supply (205) configured to charge at least one of the at least two electrodes (204; 301a,304) to cause a potential difference between the at least two electrodes (204; 301a,304); characterized by a controller (206) configured to: control the blower (202), the ionizing device (203), and the power supply (205); and stop the blower (202) in response to an ionization operation by the ionizing device (203).']",True,"['2', '204', '205', '200', '202', '203', '201', '206', '3', '300', '202', '203', '301', '304', '205', '206', '12']" 109,EP_3540972_B1 (1).png,EP3540972B1,"MULTI-WAY SWITCH, RADIO FREQUENCY SYSTEM, AND WIRELESS COMMUNICATION DEVICE","['FIG2', ' FIG3']","['FIG3 is a schematic structural diagram illustrating a 4P6T switch according to an embodiment of the disclosure ', 'FIG2 is a schematic structural diagram illustrating a simplified 4P6T switch according to an embodiment of the disclosure']","['In one possible implementation, in addition to the two first T ports, the six T ports further include four second T ports. Each of the four second T ports is individually coupled with a corresponding P port of the four P ports. That is, the four second T ports are coupled with the four P ports in one-to-one correspondence. T ports at the same frequency band among the four second T ports are coupled with different P ports. Each of the four P ports is configured to be coupled with a corresponding antenna of the four antennas, that is, one P port is coupled with one antenna and any two P ports are configured to be coupled with different antennas. As illustrated in FIG3, the two first T ports can support a transmission function (that is, a signal transmission function) and the four second T ports can support only a reception function (that is, a signal reception function). ', '""P port"" in embodiments of the disclosure is the abbreviation of ""pole port"", which refers to ports coupled with antennas of the multi-way switch. ""T port"" in embodiments of the disclosure is the abbreviation of ""throw port"", which refers to ports coupled with radio frequency modules of the multi-way switch. The multi-way switch is a 4P6T switch for example. ""Module"" herein can refer to circuits and any combination of related components. As illustrated in FIG2 for example, the four P ports are embodied as P port 1, P port 2, P port 3, and P port 4, and the six T ports are embodied as T port 1, T port 2, T port 3, T port 4, T port 5, and T port 6. Specifically, as illustrated in FIG2, T port 1 extends to the right via a first horizontal line and intersects with a third vertical line at a real point a, and then via real point a, T port 1 is respectively coupled with P port 1, P port 2, P port 3, and P port 4. Correspondingly, T port 2 extends to the right via a second horizontal line and intersects with a second vertical line at a real point b, and then via real point b, T port 2 is respectively coupled with P port 1, P port 2, P port 3, and P port 4.', 'For example, assume that the multi-way switch includes six T ports, m=2 (that is, the six T ports include two first T ports), and the multi-way switch includes field-effect transistors; among the six T ports, if each of the two first T ports is fully coupled with the four P ports, and each of four second T ports is coupled with one corresponding P port, as illustrated in FIG2 of a schematic structural diagram of the multi-way switch, the number of the MOS transistors of the multi-way switch is 6+(2∗4+(6-2)∗1)∗3+4=46.']",37,576,schematic structural diagram,H,"[{'element_identifier': '2', 'terms': ['port']}]","['1. A multi-way switch (10), comprising: six T ports and four P ports, the six T ports comprising two first T ports, and each of the two first T ports being coupled with all of the four P ports; the two first T ports supporting only a transmission function; and the multi-way switch (10) being configured to be coupled, through said T ports, with a radio frequency circuit (30) and, through said P ports, with an antenna system (20) of a wireless communication device (100) operable in a dual-frequency dual-transmit mode, and the antenna system (20) comprising four antennas corresponding to the four P ports, each of the four P ports being configured to be coupled with a corresponding antenna of the four antennas; characterized in that the six T ports further comprise four second T ports; each of the four second T ports is individually coupled with only one corresponding P port of the four P ports, and T ports at the same frequency band among the four second T ports are coupled with different P ports; and the second T ports support only a reception function.']",True,"['2', '17']" 110,EP_3540972_B1 (5).png,EP3540972B1,"MULTI-WAY SWITCH, RADIO FREQUENCY SYSTEM, AND WIRELESS COMMUNICATION DEVICE",['FIG6'],['FIG6 is a schematic structural diagram illustrating an antenna system of a wireless communication device according to an embodiment of the disclosure'],"['In one possible implementation, as illustrated in FIG6, the antenna system further includes a first combiner and a second combiner. The first combiner has a first port configured to be coupled with the first antenna, a second port configured to be coupled with a first receive path in LTE 4x4 multiple-input multiple-output (MIMO) configuration of the wireless communication device 100, and a third port configured to be coupled with a corresponding P port of the multiway switch 10. The second combiner has a first port configured to be coupled with the fourth antenna, a second port configured to be coupled with a second receive path in the LTE 4x4 MIMO of the wireless communication device 100, and a third port configured to be coupled with a corresponding P port of the multiway switch 10.']",22,149,schematic structural diagram,H,"[{'element_identifier': '5', 'terms': ['T port']}, {'element_identifier': '6', 'terms': ['T port']}]","['6. The radio frequency system of claim 4, wherein each first port is configured to be coupled with one corresponding first T port; and each second port is configured to be coupled with one corresponding second T port.']",True,"['840', '5', '6', '23']" 111,EP_3541261_B1.png,EP3541261B1,APPLICATOR DEVICE FOR FLUIDS,['FIG1B'],['FIG1B shows a cross-sectional view of the applicator device of FIG1A in a closed position '],"['When a user stops pressing or rubbing device 10 as shown in FIG1B, the resilience member 32 and bellows 46 return to their initial state, in which the first gasket 34 closes the dispensing opening 20 and the top 28 of plunger 24 re-engages with the base of the air chamber 19, thereby causing fluid dispensing to stop.']",17,64,cross-sectional view,A,"[{'element_identifier': '28', 'terms': ['top']}, {'element_identifier': '17', 'terms': ['air vent']}, {'element_identifier': '46', 'terms': ['bellows']}, {'element_identifier': '19', 'terms': ['air chamber']}, {'element_identifier': '38', 'terms': ['dispensing head']}, {'element_identifier': '39', 'terms': ['outlets']}, {'element_identifier': '18', 'terms': ['second side']}, {'element_identifier': '40', 'terms': ['activators']}, {'element_identifier': '42', 'terms': ['Activator caps']}, {'element_identifier': '16', 'terms': ['first side']}, {'element_identifier': '26', 'terms': ['base']}, {'element_identifier': '44', 'terms': ['activator legs', 'activator leg']}, {'element_identifier': '36', 'terms': ['second gasket']}, {'element_identifier': '23', 'terms': ['Fluid inlet']}, {'element_identifier': '13', 'terms': ['compartment']}]","['1. A device (10) for applying a fluid to a surface, the device comprising: a container (12) comprising: a first side (16) defining a first substantially planar surface, a second side (18) defining a second substantially planar surface opposed to the first side and comprising a dispensing opening (20), and a compartment (13) between the first and second sides for housing a fluid; a fluid dispensing system (14) for dispensing the fluid from the second side (18), the fluid dispensing system comprising and one or more activators (40) extending outside of the second side for contacting the surface and a plunger (24) comprising a base (26) operably mated with the dispensing opening (20), a resilience member (32), characterised in that the fluid dispensing system (14) further comprises a top (28) which projects into an air chamber (19) for allowing air into the compartment (13) when fluid is being released, wherein the one or more activators are connected to the plunger; and a dispensing head (38) connected to the container (12) to receive flow from the dispensing opening (20), the dispensing head (38) comprising a plurality of flow paths leading to a plurality of outlets (39), wherein each outlet (39) is directed at an angle of zero degrees to sixty degrees with respect to the second side planar surface.', '2. The device (10) of claim 1, wherein the one or more activators (40) each comprise: an activator cap (42) for contacting the surface; an activator leg (44) connecting the activator cap (42) to the plunger (24) through an opening in the second side (18); and resilient sealing means (46) for sealing the opening into the compartment.', '3. The device (10) of claim 2, wherein the resilient sealing means comprises bellows (46).', '11. The device (10) of any of the preceding claims, and further comprising an air vent (17) leading to the air chamber (19), and sealing means (36) to seal between the air chamber (19) and the compartment (13), wherein the sealing means are opened to allow airflow into the compartment (13) from the air chamber (19) when the plunger (24) is moved upward.', '12. The device (10) of any of the preceding claims, wherein the container (12) further comprises a fluid inlet port (23) with a seal.']",True,"['17', '28', '19', '16', '36', '13', '23', '26', '18', '40', '39', '42', '39', '40', '46', '38', '17', '28', '19', '16', '36', '13', '23', '26', '39', '42', '39', '40', '46', '38', '44', '40', '11']" 112,EP_3543053_B1.png,EP3543053B1,POWER UNIT STRUCTURE FOR ELECTRICALLY DRIVEN VEHICLE,['FIG1'],['FIG1 is a perspective view showing the arrangement and outline configuration of a power unit structure for an electrically driven vehicle according to an embodiment of the present invention'],"['FIG1 is a perspective view showing the arrangement and outline configuration of a power unit structure 1 for an electrically driven vehicle 9 according to an embodiment of the present invention. As shown in FIG1, the power unit structure 1 for the electrically driven vehicle 9 according to the present embodiment is arranged at vehicle rearward (rear side) of the electrically driven vehicle 9. In addition, the power unit structure 1 for the electrically driven vehicle 9 according to the present embodiment is arranged above a rear frame 90 configuring a vehicle body rear of the electrically driven vehicle 9.', 'As shown in FIG1, the power unit structure 1 for the electrically driven vehicle 9 according to the present embodiment includes an electric motor unit 2, and control device unit 3. The electric motor unit 2 is arranged on the R direction side, and the control device unit 3 is arranged on the L direction side. The electric motor unit 2 is connected to an axle 82 connecting the pair of left and right drive wheels 81, and the control device unit 3 is mounted to this electric motor unit 2.']",29,206,perspective view,B,"[{'element_identifier': '92', 'terms': ['second rear frames']}, {'element_identifier': '11', 'terms': ['andFIG.']}, {'element_identifier': '1', 'terms': ['power unit structure']}, {'element_identifier': '93', 'terms': ['third rear frame']}, {'element_identifier': '90', 'terms': ['rear frame']}, {'element_identifier': '91', 'terms': ['first rear frame']}, {'element_identifier': '81', 'terms': ['right drive wheels']}, {'element_identifier': '82', 'terms': ['axle']}]","['1. A power unit structure (1) for an electrically driven vehicle (9), comprising: an electric motor unit (2) consisting of a central case (21), an electric motor case (22) which houses an electric motor (221) mounted on one side of the central case (21), and a transmission case (23) which houses a transmission (231) mounted at another side of the central case (21); and a control device unit (3) which controls the electric motor (221), characterized in that the control device unit (3) includes: a first mounting part (31) which is a mounting part of a power supply unit that supplies electric power to the electric motor (221), and a second mounting part (32) which fixes the control device unit (3) to the electric motor unit (2); and wherein the control device unit (3) is mounted from the other side of the electric motor unit (2) towards the one side, the first mounting part (31) is mounted to the central case (21), and the second mounting part (32) is mounted to the transmission case (23).']",False,"['1', '11', '91', '90', '92', '82', '81', '93']" 113,EP_3543775_B1 (4).png,EP3543775B1,DISPLAY SCREEN AND MOBILE TERMINAL,['FIG9'],['FIG9 is a schematic view of the mobile terminal according to a third embodiment of the present disclosure'],"['Referring to FIG9, FIG9 is a schematic view of the mobile terminal 10 according to a third embodiment of the disclosure. In the third embodiment of the present disclosure, the mobile terminal 10 may include the display screen 100 provided by the first embodiment or the second embodiment of the disclosure, and a non-display assembly 140. The non-display assembly 140 is mounted in the accommodation space 130 of the display screen 100.']",18,82,schematic view,G,"[{'element_identifier': '100', 'terms': ['display screen']}, {'element_identifier': '140', 'terms': ['non-display assembly']}, {'element_identifier': '130', 'terms': ['accommodation space']}]","['1. A display screen (100) comprising: a backlight module (120) comprising a backlight panel (121) and a backlight source (122) placed on one side of the backlight panel (121); an accommodation space (130) at least penetrating the backlight panel (121) and used to accommodate functional elements; and a display panel (110) comprising a non-display area (114) facing the accommodation space (130) in the backlight module (120), a first display area (115) being set on one side of the non-display area (114), which is further away from the backlight source (122) than the other side of the non-display area (114), and a second display area (116) surrounding the non-display area (114) and the first display area (115), wherein the pixels per inch, PPI, of the first display area (115) are smaller than the PPI of the second display area (116); wherein a shape of the backlight module (120) corresponds to a shape of the display panel (110), and the position of the non-display area (114) in the display panel (110) corresponds to the position of the accommodation space (130) in the backlight module (120).', '15. A mobile terminal (10), comprising: a display screen (100) of any one of claims 1-11; and a non-display assembly mounted in the accommodation space (130) and used to accommodate the functional elements.']",True,"['140', '100', '130', '140', '130', '18']" 114,EP_3544085_B1.png,EP3544085B1,BATTERY CONNECTING DEVICE AND BATTERY PACK HAVING SAME,['FIG2'],['FIG2 is a schematic diagram of a battery containing cell connection device 100 according to one embodiment of the present disclosure'],"['FIG2 is a schematic diagram of applying cell connection device 100 in a battery comprising cells 10, 20, 30, 40. As shown in FIG2, the battery comprises multiple cells in serial connection, including but not limit to cells 10, 20, 30, 40. The cell connection device 100 is connected between cell 30 and cell 40. The cell 10 is a sample cell. The first connecting terminal 151 of cell connection device 100 is electrically connected to the anode of cell 30. The second connecting terminal 153 is electrically connected to the cathode of cell 40. The cathode connection terminal 173 and the anode connection terminal 174 of the pressure changing unit 170 are respectively electrically connected to cathode and anode of sample cell 10, so the pressure changing unit 170 receives the sample voltage of sample cell 10.', 'In the system shown in FIG2, the operating principle of cell connection device 100 in the battery is: when the battery is in normal working condition, the current flows through cathode of cell 40, conductive lower cover 113, metal sheet 131, conductive upper cover 111, and anode of cell 30 in sequence, forming a loop. The cell connection device 100 is connected in the battery loop in series, functioned as electrically connection, and will not affect the charge or discharge of the battery. When the battery is in abnormal working condition, for example, overcharging, which is represented as the sample voltage of sample cell 10 is equal to or higher than a predetermined value, the pressure changing unit 170 of cell connection device 100 starts to work, so as to increase the pressure in the first space 101, causing a shape change of the metal sheet 131, thereby breaking down the electrical connection between the metal sheet 131 and the conductive upper cover 111 or the conductive lower cover 113 and cutting off the current of the battery, achieving a protection function.']",21,358,schematic diagram,H,"[{'element_identifier': '30', 'terms': ['cell']}, {'element_identifier': '174', 'terms': ['anode connection terminal']}, {'element_identifier': '151', 'terms': ['first connecting terminal']}, {'element_identifier': '100', 'terms': ['cell connection device']}, {'element_identifier': '173', 'terms': ['cathode connection terminal']}, {'element_identifier': '113', 'terms': ['conductive lower cover']}, {'element_identifier': '153', 'terms': ['second connecting terminal']}, {'element_identifier': '40', 'terms': ['cell']}, {'element_identifier': '111', 'terms': ['conductive upper cover']}, {'element_identifier': '102', 'terms': ['second space']}, {'element_identifier': '101', 'terms': ['first space']}, {'element_identifier': '131', 'terms': ['metal sheet']}, {'element_identifier': '170', 'terms': ['pressure changing unit']}]","['1. A cell connection device (100), configured to electrically connect a first cell and a second cell in a battery, comprising: a housing comprising a conductive upper cover (111), a conductive lower cover (113), and an electrically insulated side wall (115); a metal sheet (131) electrically connecting the conductive upper cover (111) and the conductive lower cover (113), and separating the housing into a first space (101) and a second space (102), a first connecting terminal (151), electrically connecting an anode of the first cell and the conductive upper cover (111); a second connecting terminal (153), electrically connecting a cathode of the second cell and the conductive lower cover (113); and at least one pressure changing unit (170) disposed in the first space (101), configured to receive a sample voltage of a sample cell (10) in the battery, wherein the pressure changing unit (170) comprises at least one electrochemical unit (171), wherein the electrochemical unit (171) comprises a cathode (175), an anode (176), an electrolyte solution and a shell (172) having at least one opening (179), wherein the cathode (175) and the anode (176) of the electrochemical unit (171) are respectively electrically connected to the anode and cathode of the sample cell (10), wherein the inner chamber of the electrochemical unit (171) communicates with the first space (101); wherein the electrochemical unit (171) is configured to start to work and produce at least one gas to increase the pressure within the first space (101) when the sample voltage is equal to or greater than a predetermined value, so as to break down the electrical connection between the metal sheet (131) and the conductive upper cover (111) or the conductive lower cover (113) and cut off the current of the battery.']",False,"['100', '151', '111', '131', '102', '115', '101', '173', '174', '170', '113', '131', '101', '115', '153', '20', '30', '151', '100', '40', '153', '173', '2', '12']" 115,EP_3545560_B1 (1).png,EP3545560B1,PHOTOVOLTAIC MODULE,['FIG7'],['FIG7 is a plan view of part of the photovoltaic module according to the invention'],"['The grooves un along the entirety of the covering layers 202. Thus, if the grooves were present on all four the sides of the cells, each groove would cross other grooves at the four edges which each cell forms by means of its edge. The reflective elements may also adopt the shape of their penetration, that is, occupying the entire inner space. An example is shown in FIG7. In this drawing it can be seen how it is possible to make all the reflective elements 101 to be placed in the grooves of a covering layer 202 with a single grille-shaped element, or make, equally, a reflective element of length equal to the length of the groove in which the reflective element will be housed. The reflective element can cross the others in a fitting 211 as shown in FIG7, forming a single reflective element which extends along the entire length of the groove regardless of the number of crossings to be made with other reflective elements, forming a chequerboard surface comprising square sections 210.']",15,192,plan view,H,"[{'element_identifier': '201', 'terms': ['cells', 'cell']}, {'element_identifier': '211', 'terms': ['fitting']}, {'element_identifier': '202', 'terms': ['covering layer', 'covering layers']}, {'element_identifier': '203', 'terms': ['gap layer']}, {'element_identifier': '210', 'terms': ['surface comprising square sections']}, {'element_identifier': '213', 'terms': ['but have bevelled corners']}, {'element_identifier': '400', 'terms': ['flat mirror']}, {'element_identifier': '204', 'terms': ['busbar']}, {'element_identifier': '104', 'terms': ['bottom wall']}, {'element_identifier': '300', 'terms': ['glue']}, {'element_identifier': '102', 'terms': ['sequence']}, {'element_identifier': '101', 'terms': ['reflective elements', 'reflective element']}, {'element_identifier': '401', 'terms': ['area']}, {'element_identifier': '200', 'terms': ['photovoltaic module']}]","['1. A photovoltaic module (200) comprising at least one photovoltaic cell (201), at least one electrical interconnecting connection (206, 204) and at least one solar deflector (100) the solar deflector (100) comprising a groove for containing at least the one electrical interconnecting connection (206, 204) or the photovoltaic cell (201), the groove having a main direction of extension and comprising at least bilateral containment means of the electrical interconnecting connection (206, 204) or the photovoltaic cell (201) along a direction transversal to the main direction of extension.']",True,"['200', '300', '104', '202', '202', '204', '104', '201', '6', '33', '102', '203', '300', '210', '101', '211', '400', '401', '201', '213', '213', '15']" 116,EP_3545560_B1.png,EP3545560B1,PHOTOVOLTAIC MODULE,"['FIG2', ' FIG4', ' FIG5']","['FIG2 is a cross section of a second embodiment of a solar deflector according to the invention ', 'FIG5 is a cross section of a fifth embodiment of a solar deflector according to the invention ', 'FIG4 is a cross section of a fourth embodiment of a solar deflector according to the invention']","['In the second embodiment of the deflector 100 according to the invention, illustrated in FIG2, on the other hand, the reflective surfaces 101 are oriented in opposite directions relative to each other, but not there is not the sequence 102 of reflective surfaces 103 which, on the other hand, is present in the first embodiment. Consequently, each of the two reflective surfaces 101 has a relative first end joined at an angular point with the first end of the reflective surface 101 opposite to it, and a second end which joins with a planar bottom wall 104 forming, the latter, a rear face of the solar deflector module.', 'The embodiment of the collector illustrated in FIG2 may also be made in such a way that the deflector 100 is formed by transparent material, since in this way the solar radiation may enter in the deflector 100 starting from the bottom wall 104 and then reflect on the reflective elements 101 and/or 103 from the side inside the deflector 100.', 'Moreover, it is necessary to emphasise that the use of transparent material also allows the use of the deflector 100 in the embodiment shown in FIG2 in a two-face module. ', 'Lastly, the fifth embodiment of the collector according to the invention is shown in FIG5. In this configuration, the sequence 102 of reflective surfaces 103 is joined with a planar bottom wall 104 substantially lying in contact with the angular points formed by the joints of the reflective surfaces.', 'The embodiment of the collector illustrated in FIG5 may also be made in an overturned manner, that is to say, with the bottom wall 104 glued or welded in the groove of the covering layer 202. In this case, it is necessary that the deflector 100 is formed by transparent material, since in this way the solar radiation may enter in the deflector 100 starting from the bottom wall 104 and then reflect on the reflective elements 101 and/or 103 from the side inside the deflector 100.', 'Moreover, it is necessary to emphasise that the use of transparent material also allows the use of the deflector 100 in the embodiment shown in FIG5 in a two-face module. ', 'A fourth embodiment of the deflector 100 according to the invention is illustrated in FIG4. The fourth embodiment is similar to the third embodiment described above. The fourth embodiment also has reflective surfaces 101 which are oriented in the opposite directions to each other, and each has a first end joined with the first end of the other reflective surface 101 so as to form an angle at the top which is convex and a second end which is joined with a first end of respective connecting surfaces 105, oriented in an oblique direction relative to the two main reflective surfaces 101, so as to form acute inner angles. The second end of the connecting surfaces 105 has reached the sequence 102 of reflective surfaces 103 lying at a lower height and which corresponds in use to the rear face of the photovoltaic module.']",51,552,cross-sectional view,H,"[{'element_identifier': '103', 'terms': ['reflective surfaces']}, {'element_identifier': '100', 'terms': ['deflector', 'deflectors']}, {'element_identifier': '104', 'terms': ['bottom wall']}, {'element_identifier': '105', 'terms': ['connecting surfaces', 'frame', 'frames']}, {'element_identifier': '102', 'terms': ['sequence']}, {'element_identifier': '101', 'terms': ['reflective elements', 'reflective element']}]","['1. A photovoltaic module (200) comprising at least one photovoltaic cell (201), at least one electrical interconnecting connection (206, 204) and at least one solar deflector (100) the solar deflector (100) comprising a groove for containing at least the one electrical interconnecting connection (206, 204) or the photovoltaic cell (201), the groove having a main direction of extension and comprising at least bilateral containment means of the electrical interconnecting connection (206, 204) or the photovoltaic cell (201) along a direction transversal to the main direction of extension.']",True,"['100', '103', '102', '101', '04', '100', '101', '104', '100', '102', '101', '103', '3', '100', '101', '102', '105', '102', '14']" 117,EP_3545597_B1.png,EP3545597B1,CIRCUIT AND METHOD FOR MANAGING AN INRUSH CURRENT,['FIG4'],['FIG4 illustrates a schematic diagram of another circuit for managing an inrush current'],"['FIG4 illustrates another circuit for managing the inrush current. In the circuit of FIG4, a first capacitor CL1 is coupled between the switch S1 and the terminal for negative supply potential GND. An inductance L1 is coupled between the load 2 and a common node between the switch S1 and the first capacitor CL1. A second capacitor CL2 is coupled in parallel to the load 2 between the inductance L1 and the terminal for negative supply potential GND. The inductance L1 and the second capacitor CL2 form an LC circuit (resonant circuit). The second capacitor CL2 may be an electrolytic capacitor, for example. The use of two load capacitors CL1, CL2 is only an example. Any other number of load capacitors CL1, CL2 may be used in the circuit, depending on the application.']",13,148,schematic diagram,H,"[{'element_identifier': '4', 'terms': ['control unit']}, {'element_identifier': '2', 'terms': ['load']}, {'element_identifier': '42', 'terms': ['sense unit']}, {'element_identifier': '44', 'terms': ['switching unit']}, {'element_identifier': '3', 'terms': ['560µF ∗', 'about']}]","['1. A circuit for managing an inrush current (ic) of a load (2), wherein the load (2) is coupled between a voltage source (V1) and a terminal for a negative supply potential (GND), the circuit comprising: a switch (S1) coupled between the voltage source (V1) and the load (2), and configured to connect the load (2) to or disconnect the load (2) from the voltage source (V1); at least one load capacitor (C L ) coupled in parallel to the load (2) between the switch (S1) and the terminal for negative supply potential (GND); and a control unit (4), wherein the control unit (4) comprises a sense unit (42) and a switching unit (44), the sense unit (42) is configured to determine the inrush current (ic) when the switch (S1) is closed to connect the load (2) to the voltage source (VI), the switching unit (44) is configured to control the switching of the switch (S1) depending on the inrush current (ic), characterised in that the sense unit (42) comprises a sense resistor (Rs), a sense capacitor (Cs), and a first operational amplifier (OpAmp1), the sense resistor (Rs) and the sense capacitor (Cs) are coupled in series between the switch (S1) and the terminal for negative supply potential (GND), in parallel to the load (2); and the first operational amplifier (OpAmp1) is configured to determine a current through the sense resistor (Rs) and to provide a sense voltage, wherein the current through the sense resistor (Rs) depends on the inrush current and the sense voltage depends on the current through the sense resistor (Rs).']",True,"['2', '2', '2', '42', '3', '2', '42', '44', '4', '10']" 118,EP_3546368_B1 (4).png,EP3546368B1,INLET DIFFUSER FOR JET ENGINE AND METHOD FOR DIFFUSING INCOMING AIR OF JET ENGINE,['FIG6'],['FIG6 is a composite diagram illustrating the performance of an inlet diffuser comprising a pair of elongate structures starting on an offset ramp surface of the inlet diffuser and having straight ramp edges'],"['As seen in FIG6, an inlet diffuser 600 is an example of inlet diffuser 10 for a jet engine 130 that includes a pair of elongate structures 30 starting at a location removed from the inlet aperture 12 and having curved ramp faces 320. Inlet diffuser 600 includes a diffuser body 14 that defines an internal volume 16, an inlet aperture 12 by which ambient air enters the internal volume 16, and an exit aperture 18 by which air passes from the internal volume 16 of the inlet diffuser 10 to a downstream portion of a jet engine 130 that is operatively engaged with the exit aperture 18.', 'The inlet diffuser 600 also includes the pair of elongate structures 30 extending longitudinally along an internal surface 20 of the diffuser body 14 that faces the internal volume 16. Each of the pair of elongate structures 30 includes a front end 32 that is located on a fore region 22 and a rear end 34 that is located on an aft region 24. In FIG6, the front end 32 is illustrated as being removed from the inlet aperture 12. The front end 32 is also illustrated in FIG6 as having a gradual increase 610 in altitude that splits the boundary layer air while reducing a size of a bow wave created by an interaction between the ambient air entering the inlet aperture 12 and the front end 32. FIG6 also shows the rear end 34 extending to a region upstream of exit aperture 18, and exhibiting a gradual decrease in altitude so as to reduce a wake coming off the rear end 34.', 'FIG6 also shows perpendicular cross sections 610-640 that show the operation of the inlet diffuser 600 at different locations within the inlet diffuser 600. For example, cross section 610 illustrates the operation of the inlet diffuser 600 at a location near the inlet aperture 12. Cross section 610 shows a boundary layer of air that has formed on the internal surface 20.']",33,354,diagram,B,"[{'element_identifier': '600', 'terms': ['inlet diffuser']}, {'element_identifier': '20', 'terms': ['surface']}, {'element_identifier': '36', 'terms': ['first portion']}, {'element_identifier': '330', 'terms': ['central sub volume']}, {'element_identifier': '30', 'terms': ['elongate structures', 'elongate structure']}, {'element_identifier': '12', 'terms': ['inlet aperture']}, {'element_identifier': '18', 'terms': ['exit aperture']}, {'element_identifier': '10', 'terms': ['inlet diffuser', 'inlet diffusers']}, {'element_identifier': '70', 'terms': ['channel']}, {'element_identifier': '32', 'terms': ['front end', 'front ends']}, {'element_identifier': '310', 'terms': ['wall face', 'wall faces']}, {'element_identifier': '16', 'terms': ['internal volume']}, {'element_identifier': '630', 'terms': ['Cross section']}, {'element_identifier': '610', 'terms': ['cross section']}, {'element_identifier': '620', 'terms': ['Cross section']}, {'element_identifier': '38', 'terms': ['second portions', 'second portion']}, {'element_identifier': '640', 'terms': ['Cross section']}, {'element_identifier': '34', 'terms': ['rear end', 'rear ends']}, {'element_identifier': '320', 'terms': ['ramp face', 'ramp faces']}, {'element_identifier': '26', 'terms': ['offset slope surface']}]","['1. An inlet diffuser (10) for a jet engine (130), the inlet diffuser (10) comprising: a diffuser body (14) defining an internal volume (16) facing outboard walls (230) and having an inlet (12) to the internal volume (16) for receiving incoming ambient air and an exit (18) from the internal volume (16) for delivering the air to a downstream portion of the jet engine (130), wherein the diffuser body (14) has an internal surface (20) facing the internal volume (16), the internal surface (20) comprising a fore region (22) proximate to the inlet (12) and an aft region (24) downstream of the fore region (22) and proximate to the exit (18), a pair of elongate structures (30) extending longitudinally along the internal surface (20) from the fore region (22) of the internal surface (20) to the aft region (24) of the internal surface (20), wherein the pair of elongate structure (30) defines a channel (70) of the internal volume (16) inboard of the elongate structures (30), wherein the pair of elongate structures (30) is configured to split a lower boundary of the air into a first portion (36) and a second portion (38) of boundary layer air such that the first portion (36) of the boundary layer air flows within the channel (70) between the pair of elongate structures (30) from the fore region (22) to the aft region (24), wherein a respective elongate structure (30) of the pair of elongate structures (30) comprises a wall face (310) extending substantially perpendicular to the internal surface (20) of the inlet diffuser (10) and extending along a longitudinal length of the respective elongate structure (30), wherein the wall face (310) is an inboard surface of the respective elongate structure (30) and is configured to restrict the first portion (36) of boundary layer air from flowing across the respective elongate structure (30), wherein the wall face (310) comprises an apex portion (64) opposite the internal surface (20), and wherein said respective elongate structure (30) of the pair of elongate structures (30) comprises a ramp face (320), said ramp face (320) is configured to: (i) extend from the apex portion (64) of the wall face (310) to a portion of the internal surface (20) of the inlet diffuser (10) that is outboard of the respective elongate structure (30), and (ii) extend along a longitudinal length of the respective elongate structure (30).', '8. The inlet diffuser (10) of any of claims 1-7, wherein the elongate structures (30) comprises a front end (32) located on the fore region (22), said front end (32) of each elongate structure (30) is configured to split said lower boundary of the air into the first portion (36) of boundary layer air and the second portion (38) of boundary layer air.', '11. The inlet diffuser (10) of any of claims 1-10, wherein each of the elongate structure (30) further comprises a rear end (34) located on the aft region (24).']",False,"['600', '610', '620', '32', '16', '610', '630', '640', '12', '18', '30', '34', '26', '20', '600', '610', '10', '600', '620', '330', '36', '70', '38', '310', '30', '600', '630', '320', '38', '30', '330', '38', '30', '30', '36', '600', '640', '38', '36', '21']" 119,EP_3546368_B1 (5).png,EP3546368B1,INLET DIFFUSER FOR JET ENGINE AND METHOD FOR DIFFUSING INCOMING AIR OF JET ENGINE,['FIG7'],['FIG7 is a composite diagram illustrating the performance of an inlet diffuser comprising two pairs of elongate structures having straight ramp edges'],"['As seen in FIG7, an inlet diffuser 700 is an example of inlet diffuser 10 for a jet engine 130 that includes multiple pairs of elongate structures 30. Inlet diffuser 700 includes a diffuser body 14 that defines an internal volume 16, an inlet aperture 12 by which ambient air enters the internal volume 16, and an exit aperture 18 by which air passes from the internal volume 16 of the inlet diffuser 700. Inlet diffuser 700 also includes an inner pair 710 of elongate structures 30 and an outer pair 720 of elongate structures 30. Inner pair 710 and outer pair 720 of elongate structures 30 extend longitudinally along an internal surface 20 of the diffuser body 14 that faces the internal volume 16.', 'FIG7 also shows perpendicular cross sections 710-740 that show the operation of the inlet diffuser 700 at different locations within the inlet diffuser 700. For example, cross section 710 illustrates the operation of the inlet diffuser 700 at a location near the inlet aperture 12. Cross section 710 shows inner pair 710 of elongate structures 30 and outer pair 720 of elongate structures 30. Each of the elongate structures 30 includes inboard wall faces 310 and outboard ramp faces 320 that have a straight slope. The wall faces 310 of the inner pair 710 of elongate structures 30 define the outboard boundaries of a channel 70. In cross section 710, it is seen how the elongate structures 30 split the incoming boundary layer air into a first portion 36 of boundary layer air that is located within channel 70 and multiple second portions 38 of boundary layer air that are located outboard of the inner pair 710 of elongate structures 30.']",22,304,diagram,B,"[{'element_identifier': '30', 'terms': ['elongate structures', 'elongate structure']}, {'element_identifier': '12', 'terms': ['inlet aperture']}, {'element_identifier': '38', 'terms': ['second portions', 'second portion']}, {'element_identifier': '710', 'terms': ['inner pair']}, {'element_identifier': '22', 'terms': ['fore region']}, {'element_identifier': '18', 'terms': ['exit aperture']}, {'element_identifier': '740', 'terms': ['Cross section']}, {'element_identifier': '20', 'terms': ['surface']}, {'element_identifier': '16', 'terms': ['internal volume']}, {'element_identifier': '320', 'terms': ['ramp face', 'ramp faces']}, {'element_identifier': '10', 'terms': ['inlet diffuser', 'inlet diffusers']}, {'element_identifier': '720', 'terms': ['outer pair', 'Cross section']}, {'element_identifier': '36', 'terms': ['first portion']}, {'element_identifier': '70', 'terms': ['channel']}, {'element_identifier': '330', 'terms': ['central sub volume']}, {'element_identifier': '700', 'terms': ['inlet diffuser']}]","['1. An inlet diffuser (10) for a jet engine (130), the inlet diffuser (10) comprising: a diffuser body (14) defining an internal volume (16) facing outboard walls (230) and having an inlet (12) to the internal volume (16) for receiving incoming ambient air and an exit (18) from the internal volume (16) for delivering the air to a downstream portion of the jet engine (130), wherein the diffuser body (14) has an internal surface (20) facing the internal volume (16), the internal surface (20) comprising a fore region (22) proximate to the inlet (12) and an aft region (24) downstream of the fore region (22) and proximate to the exit (18), a pair of elongate structures (30) extending longitudinally along the internal surface (20) from the fore region (22) of the internal surface (20) to the aft region (24) of the internal surface (20), wherein the pair of elongate structure (30) defines a channel (70) of the internal volume (16) inboard of the elongate structures (30), wherein the pair of elongate structures (30) is configured to split a lower boundary of the air into a first portion (36) and a second portion (38) of boundary layer air such that the first portion (36) of the boundary layer air flows within the channel (70) between the pair of elongate structures (30) from the fore region (22) to the aft region (24), wherein a respective elongate structure (30) of the pair of elongate structures (30) comprises a wall face (310) extending substantially perpendicular to the internal surface (20) of the inlet diffuser (10) and extending along a longitudinal length of the respective elongate structure (30), wherein the wall face (310) is an inboard surface of the respective elongate structure (30) and is configured to restrict the first portion (36) of boundary layer air from flowing across the respective elongate structure (30), wherein the wall face (310) comprises an apex portion (64) opposite the internal surface (20), and wherein said respective elongate structure (30) of the pair of elongate structures (30) comprises a ramp face (320), said ramp face (320) is configured to: (i) extend from the apex portion (64) of the wall face (310) to a portion of the internal surface (20) of the inlet diffuser (10) that is outboard of the respective elongate structure (30), and (ii) extend along a longitudinal length of the respective elongate structure (30).']",False,"['700', '30', '18', '710', '30', '30', '20', '16', '12', '720', '720', '700', '38', '30', '30', '30', '720', '710', '720', '700', '16', '10', '330', '38', '38', '38', '38', '36', '330', '35', '38', '320', '36', '70', '38', '320', '38', '16', '38', '36', '6', '38', '36', '7', '740', '22']" 120,EP_3546368_B1 (6).png,EP3546368B1,INLET DIFFUSER FOR JET ENGINE AND METHOD FOR DIFFUSING INCOMING AIR OF JET ENGINE,['FIG8'],['FIG8 is a flowchart depicting methods of diffusing incoming air according to the present disclosure '],"['FIG8 schematically provides a flowchart that represents illustrative, non-exclusive examples of methods according to the present disclosure. In FIG8, some steps are illustrated in dashed boxes indicating that such steps may be optional or may correspond to an optional version of a method according to the present disclosure. That said, not all methods according to the present disclosure are required to include the steps illustrated in solid boxes. Additionally, the order of steps illustrated in FIG8 is exemplary, and in different embodiments the steps in FIG8 may be performed in a different order. The methods and steps illustrated in FIG8 are not limiting and other methods and steps are within the scope of the present disclosure, including methods having greater than or fewer than the number of steps illustrated, as understood from the discussions herein.', 'FIG8 is a flowchart depicting methods 800, according to the present disclosure, of mixing boundary layer air in an inlet diffuser of a jet engine. Methods 800 include receiving air into an internal volume (e.g., internal volume 16) defined by a body (e.g., diffuser body 14) of the inlet diffuser at 802. For example, the air may correspond to ambient air outside of the inlet diffuser that flows into the internal volume via an inlet aperture (e.g., inlet aperture 12). According to the present disclosure, the inlet aperture may have a high aspect ratio.']",15,261,flowchart,B,"[{'element_identifier': '812', 'terms': ['inboard direction at']}, {'element_identifier': '810', 'terms': ['at']}, {'element_identifier': '804', 'terms': ['splitting at']}, {'element_identifier': '816', 'terms': ['jet engine at']}, {'element_identifier': '802', 'terms': ['inlet diffuser at']}, {'element_identifier': '814', 'terms': ['at']}, {'element_identifier': '800', 'terms': ['Methods']}, {'element_identifier': '808', 'terms': ['boundary layer air in']}, {'element_identifier': '806', 'terms': ['at']}]","['2. The inlet diffuser (10) of claim 1, wherein said inlet (12) is defined as having a maximum width (40) and a maximum height (50), wherein the maximum width (40) is at least 2, at least 3, at least 4, or at least 5 times the maximum height (50).', '9. The inlet diffuser (10) of claim 1, wherein a perpendicular distance (62) between the internal surface (20) and the apex portion (64) of the wall face (310) at a particular location of the wall face (310) is greater than an expected thickness (56) of the first portion (36) of boundary layer air in a channel region (70) proximate to the particular location of the wall face (310) when the first portion (36) of boundary layer air flows within the channel (70) at normal operating velocities.']",False,"['800', '802', '804', '806', '808', '810', '812', '814', '816', '23']" 121,EP_3547487_B1 (1).png,EP3547487B1,"A TESTING DEVICE FOR TESTING A WIRELESS POWER TRANSMITTER DEVICE, AND AN ASSOCIATED METHOD",['FIG3'],['FIG3 is a schematic block diagram of a testing device for use in testing of a wireless power transmitter device according to an alternative embodiment'],"['FIG3 is a schematic block diagram that shows a testing device 50 according to another embodiment. The testing device 50 comprises processing means 52 for processing the data received from the testing device 50. The processing means 52 may comprise a programmable device, such as a microcontroller, central processing unit (CPU), digital signal processor (DSP) or field-programmable gate array (FPGA) with appropriate software and/or firmware, and/or dedicated hardware such as an application-specific integrated circuit (ASIC).']",25,94,schematic block diagram,G,"[{'element_identifier': '24', 'terms': ['transmitter coil']}, {'element_identifier': '51', 'terms': ['communication interface']}, {'element_identifier': '30', 'terms': ['testing device']}, {'element_identifier': '55', 'terms': []}, {'element_identifier': '22', 'terms': ['wireless power transmitter']}, {'element_identifier': '18', 'terms': ['magnetic induction']}, {'element_identifier': '2', 'terms': ['base station. Documents EP']}, {'element_identifier': '20', 'terms': ['transmitter device']}, {'element_identifier': '34', 'terms': ['power receiver coil']}, {'element_identifier': '52', 'terms': ['processing means']}, {'element_identifier': '40', 'terms': ['host device']}, {'element_identifier': '53', 'terms': ['reporting means']}, {'element_identifier': '50', 'terms': ['testing device']}, {'element_identifier': '33', 'terms': ['interfaces', 'interface']}, {'element_identifier': '44', 'terms': ['memory']}, {'element_identifier': '36', 'terms': ['suitable load']}, {'element_identifier': '32', 'terms': ['wireless power receiver']}]","['1. A testing device (30; 50) for testing a wireless power transmitter device (20) having at least one transmitter coil (24a-f), wherein the testing device (30; 50) comprises at least one wireless power receiver coil (34) and wherein the testing device (30; 50) is in operative communication with a processing means (42; 52) having an associated memory (44; 54), wherein the testing device (30; 50) is configured to: receive a power signal applied by the wireless power transmitter device (20); transmit a first packet, wherein the first packet is a signal strength packet, to the wireless power transmitter device (20) in response to receiving said power signal; transmit a second packet to the wireless power transmitter device (20) when the wireless power transmitter device (20) continues to transmit the power signal to the testing device (30; 50) in response to receiving the signal strength packet, characterized in that the processing means (42; 52) is configured to: store the signal strength packet or store signal strength value(s) thereof in the memory (44; 54) if the transmitter device (20), in response to said signal strength packet, continues to transmit the power signal to the testing device (30; 50); or else, if the wireless power transmitter device (20) aborts the power signal during or before the second packet is completely transmitted, disregard the signal strength packet or value(s) thereof.', '6. The testing device as defined in any of claims 1 to 4, wherein the processing means (42) and its associated memory (44) are arranged in a host device (40) being in communication with the testing device (30).']",True,"['30', '33', '32', '34', '18', '24', '22', '20', '40', '35', '44', '2', '50', '52', '36', '32', '34', '18', '24', '22', '20', '53', '51', '7', '55', '3', '15']" 122,EP_3547715_B1 (2).png,EP3547715B1,"METHOD AND APPARATUS FOR REDUCING CONTINUOUS-WAKEUP DELAY OF BLUETOOTH LOUDSPEAKER, AND BLUETOOTH LOUDSPEAKER",['FIG4'],['FIG4 depicts a structural block diagram of an apparatus for reducing continuous-wakeup delay of Bluetooth loudspeaker according to the present application'],"['FIG4 depicts a schematic structural block diagram of an apparatus for reducing continuous-wakeup delay of a Bluetooth loudspeaker according to embodiments of the present invention, for the convenience of description, the part related to embodiments of the present invention is merely shown.']",23,47,structural block diagram,G,"[{'element_identifier': '51', 'terms': ['memory']}, {'element_identifier': '5', 'terms': ['Bluetooth loudspeaker']}, {'element_identifier': '42', 'terms': ['andan execution module', 'modules', 'module']}, {'element_identifier': '52', 'terms': ['computer program']}, {'element_identifier': '50', 'terms': ['processor']}, {'element_identifier': '41', 'terms': ['reset module']}]","['7. An apparatus for reducing continuous-wakeup delay of a Bluetooth loudspeaker, the apparatus comprises: a reset module (41) configured to reset a wakeup flag bit to wait for a next wakeup when a stop-recording instruction sent by a terminal equipment through a Bluetooth serial port communication protocol is received; an execution module (42) configured to execute a wakeup-interruption operation when a preset wakeup keyword is received by the Bluetooth loudspeaker; and a playing module configured to play voice data when the voice data as fed back by the terminal equipment is received, wherein the voice data is a response data of voice data collected when the Bluetooth loudspeaker is previously awakened.', '8. A Bluetooth loudspeaker (5), comprising: a memory (51), a processor (50) and a computer program (52) stored in the memory (51) and executable by the processor (50), characterized in that , when the computer program is executed by the processor (50), the processor (50) is configured to implement steps of the method according to any one of claims 1 to']",True,"['41', '42', '4', '5', '50', '52', '51', '5', '17']" 123,EP_3548255_B1.png,EP3548255B1,PROCESS FOR THE SEALING OF PLASTIC PROFILED ELEMENTS,['FIG1'],['FIG1 is an axonometric view of a machine for the sealing of plastic profiled elements'],"['As can be seen in FIG1, the machinery 1 is equipped with a containment presser 13, but it cannot be ruled out that two containment pressers 13 be arranged facing one another and both moveable in reciprocal approach to abut on opposite sides of the areas to be sealed 3.']",15,54,axonometric view,B,"[{'element_identifier': '13', 'terms': ['containment presser', 'containment pressers']}, {'element_identifier': '10', 'terms': ['one displacing assembly']}, {'element_identifier': '11', 'terms': ['removal means']}, {'element_identifier': '1', 'terms': ['machinery']}]","['1. A process for the sealing of plastic profiled elements, comprising: - at least one step of supply of at least a machinery (1) for the sealing of plastic profiled elements comprising: - at least a base frame (2); - retaining means (6, 7) associated with said base frame (2) and adapted to retain at least one profiled element (P) having at least one area to be sealed (3) and a lateral surface (4) at least in part covered with a film (S) to be removed; - sliding means (8, 9) adapted to move said retaining means (6, 7) between a mutual spacing configuration, in which said areas to be sealed (3) are mutually spaced apart, and a mutual approach configuration, in which said areas to be sealed (3) are mutually approached; - heat-sealing means with a heated plate (5) associated with said base frame (2) and adapted to seal said pair of profiled elements (P); - at least one step of mutual movement of said retaining means (6, 7) adapted to arrange the areas to be sealed (3) of each of said profiled elements (P) facing each other; - at least one step of arrangement of said heat-sealing means with a heated plate (5) in contact with said areas to be sealed (3); - at least one step of sealing said areas to be sealed (3); characterized by the fact that it comprises at least a step of heat shrinking of at least an ending portion (14) of each of said films (S) arranged at the respective area to be sealed (3), said film (S) being made of a heat-shrink material.']",False,"['11', '1', '10', '13']" 124,EP_3548386_B1.png,EP3548386B1,SYSTEM FOR MEASURING OUT AND CUTTING COMPACTED POWDERS,['FIG1'],['FIG1 schematically shows a system for packaging compacted powders in three-dimensional view according to an embodiment of the present invention'],"['FIG1 schematically shows a system for packaging compacted powders 100 according to an embodiment of the present invention. As shown in the figure, the powder packaging system 100 comprises a hopper T having an inlet TP through which powders are conveyed inside the hopper T. In the lower part of the hopper T is placed a screw conveyor C which, due to the rotation around its own axis ac, conveys the powders inside a tube positioned in the lower part of the hopper T and through which the powders are conveyed.', 'As shown in FIG1, the packaging system 100 further comprises a vertical packager which comprises a forming tube TF to make it possible to receive a film coming from a reel B. Like all vertical packagers, also in this case, there is a vertical welder (not represented in FIG1) that allows the vertical welding of the packages and there are members (not present in FIG1) capable of making the film slide towards the lower part of the forming tube TF. The forming tube TF internally contains the second tube TR and consequently also the first tube TC. Therefore, a gap is thus formed between the second tube TR and the forming tube TF. Moreover, the axis of the forming tube TF coincides with the axis of the first tube TC.']",22,240,schematic,B,"[{'element_identifier': '100', 'terms': ['packaging system']}]","['1. Compacted powders packaging system (100), comprising a first tube (TC), wherein said first tube (TC) comprises a screw conveyor (C) configured to rotate about an axis (ac) inside said first tube (TC) so as to convey the powders towards an outlet (UT) of said first tube (TC), said system (100) comprises a rotatable terminal (TI, TIC) in proximity to said outlet (UT); said rotatable terminal (TI, TIC) comprising internal cutting means (F) configured to cut the compacted powders going out from said first tube (TC) when said rotatable terminal (TI, TIC) rotates, wherein said rotatable terminal (TI, TIC) is positioned so as to contact the end portion of said first tube (TC) which defines said outlet (UT); wherein said rotatable terminal (TI, TIC) includes an internal opening (AP) which is concentric with said first tube (TC) so as to convey the powders through said opening (AP); wherein said cutting means (F) are positioned within said opening (AP); said system (100) being characterized in that said internal opening (AP) has a diameter at said outlet (UT) of said first tube (TC) which is equal to the inner diameter of said first tube (TC) at said outlet (UT).']",False,"['100', '1', '14']" 125,EP_3549794_B1 (4).png,EP3549794B1,TYRE,['FIG18'],['FIG18 is an enlarged view of a second shoulder land portion of FIG7'],"['FIG18 illustrates an enlarged view of the second shoulder land portion 38. As illustrated in FIG18, the second shoulder land portion 38 has a width W37 in the tyre axial direction in a range of from 0.25 to 0.35 times the tread width TW.']",13,47,enlarged view,B,"[{'element_identifier': '35', 'terms': ['second crown main groove']}, {'element_identifier': '38', 'terms': ['second shoulder land portion']}, {'element_identifier': '56', 'terms': ['first portion']}, {'element_identifier': '57', 'terms': ['second portion']}, {'element_identifier': '33', 'terms': ['main grooves', 'main groove']}, {'element_identifier': '58', 'terms': ['second shoulder lateral grooves']}, {'element_identifier': '59', 'terms': ['second shoulder sipes', 'second shoulder sipe']}, {'element_identifier': '55', 'terms': ['longitudinal narrow groove']}]","['13. The tyre (1, 31) according to any one of claims 1 to 12, wherein the tread portion (2, 32) comprises a second shoulder land portion (38) having a second tread edge (T2) located on a side toward the center of a vehicle body when the tyre (1, 31) is mounted to a vehicle, the second shoulder land portion (38) is provided with second shoulder lateral grooves (58) extending inwardly in the tyre axial direction from the second tread edge (T2) and terminating within the second shoulder land portion (38), and the second shoulder lateral grooves (58) do not include any widening-width portions (3A, 13A, 23A, 60).']",False,"['38', '56', '57', '33', '35', '59', '58', '55', '59', '58', '59', '58', '59', '58', '33']" 126,EP_3549794_B1.png,EP3549794B1,TYRE,['FIG1'],['FIG1 is a side view of a tyre according to a first embodiment of the disclosure'],"['FIG1 illustrates a side view of a tyre 1 according to a first embodiment of the disclosure.', 'The tyre 1 according to the present disclosure can be used for various kinds of tyres, e.g., pneumatic tyres for passenger car and heavy-duty vehicle, and non-pneumatic tyres that can support the tyre load by structural members without being inflated with a pressurized air. As illustrated in FIG1, the tyre 1 according to the first embodiment includes a tread portion 2 with a tread surface 2a provided with grooves 3. Preferably, at least one of the grooves 3, at least partially, includes a widening-width portion 3A.']",16,120,side view,B,"[{'element_identifier': '3', 'terms': ['grooves', 'groove']}]","['1. A tyre (1, 31) comprising: a tread portion (2, 32) comprising a tread surface (2a) provided with grooves (3, 13, 23, 33, 50); at least one of the grooves (3, 13, 23, 33, 50) comprising a widening-width portion (3A, 13A, 23A, 60) at least partially; the widening-width portion (3A, 13A, 23A, 60) comprising a first groove portion (4, 14, 24, 61) extending inwardly in a tyre radial direction from the tread surface (2a), and a second groove portion (5, 15, 25, 62) located inwardly in the tyre radial direction of the first groove portion (4, 14, 24, 61) and having a groove (W2, W12, W22, W41) width greater than that (W1, W11, W21, W40) of the first groove portion (4, 14, 24, 61), and the tread portion (2, 32) comprising a first shoulder land portion (37) having a first tread edge (T1), characterized in that the first shoulder land portion (37) is provided with first shoulder lateral grooves (50) extending inwardly in a tyre axial direction from the first tread edge (T1) and terminating within the first shoulder land portion (37), and the grooves (3, 13, 23, 33, 50) are the first shoulder lateral grooves (50), the tread portion (2, 32) has a designated mounting direction to a vehicle, and the first tread edge (T1) is located on a side away from the center of a vehicle body when the tyre (1, 31) is mounted to a vehicle, wherein the first tread edge (T1) is defined as one of axially outermost edges of the ground contacting patch of the tread portion which occurs under normal state with a standard tyre load when the camber angle of the tyre is zero.']",False,"['18', '3', '3', '3']" 127,EP_3550093_B1.png,EP3550093B1,MOBILE RETRACTABLE WATCHTOWER,['FIG1'],"['FIG1 from the rear, FIG3 is a perspective view of an erected and completed mobile retractable watchtower, and FIG4 is a perspective view of a lifting device for lifting a telescopic superstructure of the watchtower ']","['FIG1 is a perspective view of a container 2 which is a part of the mobile retractable watchtower 1. In the container 2 a telescopic superstructure 3 is provided in a folded state. The container is a standard ISO container. The container 2 has a detachable one-piece top cover 7, which is versatile and has a further function as a roof of the watchtower 1, which will be discussed later. The container 2 is provided on the front wall with the entrance 22.']",37,92,perspective view,E,"[{'element_identifier': '17', 'terms': ['ladder']}, {'element_identifier': '7', 'terms': ['top cover']}, {'element_identifier': '11', 'terms': ['upper edges']}, {'element_identifier': '22', 'terms': ['entrance']}, {'element_identifier': '1', 'terms': ['watchtower']}, {'element_identifier': '2', 'terms': ['container']}]","['1. Mobile retractable watchtower, wherein it comprises a container (2) having a detachable top cover (7) and provided inside with a lifting device (24), the platform of which also creates a floor (4) of the retractable watchtower (1), whereas on the floor (4) of the lifting device (24) a telescopic superstructure (3) is provided, which comprises armored sheets (5) arranged in a rectangular structure, under the armored sheets (5) there are hinged sheets (6) which are pivotally mounted in hinges (16) on the lateral sides of the floor (4), whereas after the lifting of retractable superstructure (3) the top cover (7) is arranged above the armored sheets (5) and a manual jack (15) is arranged between the floor (4) and the top cover (7), wherein a lower end of the jack (15) is arranged on the floor (4) and the upper end on the upper cover (7).', '2. Mobile retractable watchtower according to claim 1, characterized in that at the lateral edges of the floor (4) upper anchorages (14) are provided and at the upper edges (11) of the container (2) lower anchorages (13) are provided for fastening lower and upper ends of locking rods (8).', '8. Mobile retractable watchtower according to claims 1 to 7, characterized in that it is provided with a ladder (17).']",True,"['11', '2', '22', '1', '7', '2', '17', '2']" 128,EP_3550735_B1 (4).png,EP3550735B1,"CHANNEL INFORMATION FEEDBACK METHOD, CHANNEL INFORMATION DETERMINING METHOD, RECEIVE-END DEVICE, AND TRANSMIT-END DEVICE",['FIG6'],['FIG6 is a schematic diagram of a logical structure of a transmit end device according to an embodiment of the present invention'],"['FIG6 is a schematic diagram of a logical structure of a transmit end device 600 according to an embodiment of the present invention. As shown in FIG6, the device 600 includes a receiving module 602 and a determining module 604.']",22,43,schematic diagram,H,"[{'element_identifier': '704', 'terms': ['transceiver']}, {'element_identifier': '712', 'terms': ['bus']}, {'element_identifier': '710', 'terms': ['interface']}, {'element_identifier': '7044', 'terms': ['receiver']}, {'element_identifier': '7084', 'terms': ['data']}, {'element_identifier': '706', 'terms': ['antennas']}, {'element_identifier': '600', 'terms': ['device']}, {'element_identifier': '708', 'terms': ['memory']}, {'element_identifier': '702', 'terms': ['processor']}, {'element_identifier': '604', 'terms': ['determining module']}, {'element_identifier': '602', 'terms': ['receiving module']}, {'element_identifier': '7042', 'terms': ['transmitter']}, {'element_identifier': '7082', 'terms': ['instruction']}, {'element_identifier': '700', 'terms': ['device']}]","['3. A receive end device (500), comprising: a generation module (502), configured to generate at least one piece of description information for each of a plurality of subbands comprised in a wideband, wherein each piece of description information is used to describe a description vector of a channel matrix corresponding to the subband, each piece of the description information comprises at least one of a vector parameter and a weighting parameter, the vector parameter is used to indicate at least two component vectors of the description vector, the weighting parameter is used to indicate a weight of each of the at least two component vectors, and the at least two component vectors are selected from a base codebook; and a sending module (504), configured to send the at least one piece of description information, wherein the base codebook comprises a plurality of basic vectors, each component vector is one of the plurality of basic vectors, and the basic vector is: c x,y = v x ⊗ u y , wherein v x = 1 e j 2 πx O 1 N 1 ⋯ e j 2 πx O 1 N 1 N 1 − 1 u y = 1 e j 2 πy O 2 N 2 ⋯ e j 2 πy O 2 N 2 N 2 − 1 wherein ( x, y ) represents a basic vector parameter, O 1 , N 1 , O 2 and N 2 are preset positive integers, 0 ≤ x ≤ O 1 N 1 - 1, and 0 ≤ y ≤ O 2 N 2 - 1, the at least two component vectors comprise a starting vector and at least one offset vector, characterized in that the vector parameter comprises a basic vector parameter ( l , m ) of the starting vector, an offset step ( L , M ), and an offset parameter ( a , b ) of each offset vector, a basic vector parameter of each offset vector is ( l + aL , m + bM ), the offset step ( L , M ) is one of a plurality of preset groups of offset steps, 1 ≤ L ≤ O 1 ,1 ≤ M ≤ O 2 , 0 ≤ l ≤ O 1 N 1 - 1, 0 ≤ m ≤ O 2 N 2 - 1, 0 ≤ a ≤ O 1 N 1 − 1 − l L , 0 ≤ b ≤ O 2 N 2 − 1 − m M , and a and b are both integers and are not 0 at the same time; and the offset step ( L , M ) is an offset step corresponding to the basic vector parameter ( l , m) of the starting vector in the plurality of preset groups of offset steps.', '4. A transmit end device (600), comprising: a receiving module (602), configured to receive at least one piece of description information generated for each of a plurality of subbands comprised in a wideband, wherein each piece of description information is used to describe a description vector of a channel matrix corresponding to the subband, each piece of the description information comprises at least one of a vector parameter and a weighting parameter, the vector parameter is used to indicate at least two component vectors of the description vector, the weighting parameter is used to indicate a weight of each of the at least two component vectors, and the at least two component vectors are selected from a base codebook; and a determining module (604), configured to determine, based on each piece of description information, the description vector corresponding to the description information, wherein the base codebook comprises a plurality of basic vectors, each component vector is one of the plurality of basic vectors, and the basic vector is: c x,y = v x ⊗ u y , wherein v x = 1 e j 2 πx O 1 N 1 ⋯ e j 2 πx O 1 N 1 N 1 − 1 u y = 1 e j 2 πy O 2 N 2 ⋯ e j 2 πy O 2 N 2 N 2 − 1 wherein ( x , y ) represents a basic vector parameter, O 1 , N 1 , O 2 and N 2 are preset positive integers, 0 ≤ x ≤ O 1 N 1 -1, and 0 ≤ y ≤ O 2 N 2 - 1, the at least two component vectors comprise a starting vector and at least one offset vector, characterized in that the vector parameter comprises a basic vector parameter ( l , m ) of the starting vector, an offset step ( L , M ), and an offset parameter ( a , b ) of each offset vector, a basic vector parameter of each offset vector is ( l + aL , m + bM ), the offset step ( L , M ) is one of a plurality of preset groups of offset steps, 1 ≤ L ≤ O 1 ,1 ≤ M ≤ O 2 , 0 ≤ l ≤ O 1 N 1 - 1, 0 ≤ m ≤ O 2 N 2 - 1, 0 ≤ a ≤ O 1 N 1 − 1 − l L , 0 ≤ b ≤ O 2 N 2 − 1 − m M , and a and b are both integers and are not 0 at the same time; and the offset step ( L , M ) is an offset step corresponding to the basic vector parameter ( l , m) of the starting vector in the plurality of preset groups of offset steps.']",True,"['600', '602', '604', '6', '700', '706', '706', '704', '7042', '7044', '702', '712', '710', '708', '7082', '7084', '7', '30']" 129,EP_3552248_B1 (5).png,EP3552248B1,ACTUATOR DEVICE AND METHOD,['FIG12'],['FIG12 schematically illustrates a further example actuator member comprising soft magnetic particles'],"['This is illustrated schematically in FIG12 which shows an example actuator member 12 having a plurality of dispersed soft magnetic particles 82. Upon application of an electric field between the electrodes 26, the actuator member is induced to contract in thickness, thereby resulting in the actuated state shown in the right-hand image of FIG12. As shown, the inter-spatial gap d between the particles is significantly reduced.', 'The actuator device of FIG12 further comprises a controller (not shown) to which the magnetic sensor (and optionally the magnetic field generation means) is operatively coupled. The controller may be configured to control the sensor to monitor the magnetic permeability of the actuator member or to monitor the magnetic field strength across the actuator member. Based on a measured magnetic field strength, the controller may be configured to calculate a change in, or an absolute value of, the magnetic permeability across the actuator member.']",12,171,schematic,H,"[{'element_identifier': '12', 'terms': ['member']}, {'element_identifier': '16', 'terms': ['thickness']}, {'element_identifier': '10', 'terms': ['carrier layer', 'within approximately', 'printing. Layer thicknesses between']}, {'element_identifier': '26', 'terms': ['electrodes']}, {'element_identifier': '82', 'terms': ['d']}]","['1. An actuator device, comprising: an actuator member (12), comprising an electroactive material being adapted to deform in response to application of an electrical stimulus; and particles (42) of a hard magnetic material dispersed within the electroactive material, and ordered such that at least a section of the actuator member exhibits a magnetization in a given direction; a magnetic field generation means (22) operable to generate a magnetic field (32) of a controllable field strength pattern for application across at least a section of the actuator member; an electrical stimulus generation means; characterised by a controller (30) operable to control the magnetic field generation means and the electrical stimulus generation means in a coordinated manner to thereby realize one or more deformation patterns in the actuator member.']",True,"['16', '10', '26', '26', '82', '26', '26', '26', '11', '82', '26', '12', '37']" 130,EP_3553199_B1.png,EP3553199B1,A METHOD OF PREPARING MAGNESIUM-ZINC-YTTRIUM QUASICRYSTAL AND BORON CARBIDE MIXED REINFORCED MAGNESIUM-BASED COMPOSITE MATERIAL,"['FIG1', ' FIG2']","['FIG1 is the smelting state diagram of the Mg-based composite materials ', 'FIG2 is the metallographic structure diagram of Mg-based composite materials']","['Now the present invention will be further described in combination with the figures:As shown in FIG1, it shows the smelting state diagram of the Mg-based composite materials, wherein the location and connection relationship of each part should be correct and the ratio is conducted according to the amount and the process should be conducted according to the sequence. ', 'As shown in FIG2, it shows the metallographic structure diagram of Mg-based composite materials, wherein there are no defects such as inclusion and air holes in the metallographic structure diagram and the quascicrystal phase Mg3Zn6Y and boron carbide particles can be evenly distributed in particles.']",25,115,diagram,B,"[{'element_identifier': '15', 'terms': ['argon bottle']}]","['2. The method of preparing magnesium-zinc-yttrium quasicrystal and boron carbide mixed reinforced Mg-based composite materials according to claim 1, characterized in that the smelting of Mg-based composite materials are conducted in the vacuum medium frequency induction melting furnace and completed through the process of the medium frequency induction heating, bottom blowing argon and mechanical stirring; the vacuum medium frequency induction melting furnace is a vertical one; The bottom of the vacuum medium frequency induction melting furnace (1) is nconfigured with a furnace base (2), and inside of the vacuum medium frequency induction melting furnace (1) is a furnace chamber (3); a worktable (6) is configured in the bottom of the furnace chamber (3) and a graphite melting crucible (7) is put on the worktable (6); The outside of the graphite melting crucible (7) is surrounded by the medium frequency induction heater (8) and the inside of the graphite melting crucible (7) is the alloy melt (9); an outlet pipe (4) is configured on the top right of the vacuum medium frequency induction melting furnace (1) and it is controlled by the outlet valve (5); the argon bottle (15) is configured on the top left of the vacuum medium frequency induction melting furnace (1) and an argon pipe (16) and an argon valve (17) are configured on the argon bottle (15). The argon pipe (16) is connected to the bottom blow motor (11). The bottom blow motor (11) is connected to the bottom blow pipe (12). The bottom blow pipe (12) communicates to the graphite melting crucible (7) through the furnace base(2) and worktable (6) and bottom blows the alloy melt (9); a vacuum pump (13) is configured in the bottom right of the furnace base (2) and communicates to the furnace chamber (3) through a vacuum pipe (14); a feed pipe (27), a feed valve (28) and a mechanical agitator (29) are configured on the top of the vacuum medium frequency induction melting furnace (1) and the feed pipe (27) and the mechanical agitator (29) extends to the graphite melt crucible (7) through the furnace top base; a electric cabinet (18) is configured on the right of the vacuum medium frequency induction melting furnace (1) and a display screen (19), an indicator light (20), a power switch (21), a medium frequency induction heating controller (22), a bottom blow motor controller (23) and a vacuum pump controller (24) are configured on the electric cabinet (18); the electric cabinet (18) is connected to the medium frequency induction heater (8) through a first cable (25); The electric cabinet (18) is connected to the bottom blow motor (11) and a vacuum pump (13) through the second cable (26); the furnace cavity (3) is filled with argon (10).']",True,"['200', '15']" 131,EP_3553541_B1 (5).png,EP3553541B1,DEVICE AND METHOD FOR LOCATING EARTH FAULTS IN ELECTRICAL DISTRIBUTION GRIDS,['FIG12'],"['FIG12: Schematic representation of results of an embodiment of repetition of the similarity calculation for the EF between BB 6 and 7 as in FIG8, but now for a time interval of only 1ms after the fault ']","['FIG12 shows that the choice sim2 for the similarity metric, as the squared difference between the two curves, keeps the minimum at BB6 and even shows a clearer result on the faulty-phase for the second lowest value at BB7. Hence this choice of the similarity metric clearly shows the fault-location between BB6 and BB7. Again, the disclosed approach is rather robust, even if a similarity metric, as the squared difference between the two curves, provides improved results.']",39,90,schematic,G,"[{'element_identifier': '11', 'terms': ['at Busbar', 'fault at Bus-Bar']}, {'element_identifier': '1', 'terms': ['-', 'left graph zooms into', 'Steps', 'Step', 'Example']}, {'element_identifier': '2', 'terms': ['at Busbar', 'Bus-Bar']}, {'element_identifier': '6', 'terms': ['between BB']}, {'element_identifier': '10', 'terms': ['Busbar']}, {'element_identifier': '3', 'terms': ['impedances there are']}]","['1. Device for locating earth faults in a compensated electrical distribution grid comprising an electronic data processor configured for: waiting until an earth fault detection signal that an earth fault has occurred; obtaining a time-domain captured voltage or current signal wherein said time-domain comprises a time period ensuing said earth fault; calculating the correlation of said time-domain captured signal with a database comprising a plurality of time-domain, voltage or current respectively, signature signals, wherein each signature signal is a time-domain signal corresponding to an earth fault location from a plurality of predetermined locations in said electrical distribution grid; outputting the earth fault location corresponding the signature signal from said plurality of signature signals which has the highest correlation with the captured signal; characterized in that the time-domain captured voltage or current signal is obtained at only one operational location of the electrical distribution grid; and in that the operational location of the electrical distribution grid is a substation of said electrical distribution grid, the substation being where the time-domain captured voltage or current signal is captured.']",False,"['1', '186', '3', '10', '11', '2', '2', '2', '3', '186', '6', '12', '10', '11', '23']" 132,EP_3554253_B1 (1).png,EP3554253B1,AERATED FOOD PRODUCTS,['FIG1'],"['FIG1 shows Mastersizer plots showing the particle size distribution for the fat droplets in the emulsions of the pea control, and the tested mushroom extracts ']","['As can be seen from Table 3 and in FIG1, the extracts of BI24389 (Volvariella volvacea), BI24395 (Hyspatys marrcus), and BI24800 (Ganoderma lucidium) provided stable emulsions, comparable to pea whereas the remaining mushroom extracts did not.']",26,47,plot,A,"[{'element_identifier': '8', 'terms': ['pH']}, {'element_identifier': '24', 'terms': ['after']}, {'element_identifier': '5', 'terms': ['Chapter']}, {'element_identifier': '1', 'terms': ['will contain less than', 'DNA sequence analysis.TABLE', 'Samples were diluted', 'after']}, {'element_identifier': '2', 'terms': ['are shown in Table', '40mN/m after']}, {'element_identifier': '10', 'terms': ['milkshakes is typically from', 'in']}, {'element_identifier': '3', 'terms': ['against about']}]",['3. An aerated food product according to claim 1 or claim 2 comprising Volvariella volvacea extract wherein the Volvariella volvacea extract is prepared by: - Freeze drying the mushroom fruiting body then grinding; - Rehydrating the ground mushroom in a buffer; - Clarifying soluble material by centrifugation; - Salting out soluble extracts out; - Centrifuging precipitates and then solubilising the pellets in distilled water; - Dialysing soluble protein; - Freeze drying the dialysed material to provide the Volvariella volvacea extract.'],False,"['8', '5', '3', '2', '1', '14', '10', '100', '1000', '3000', '29', '2015', '24', '30', '2015', '05', '2015', '14', '14', '2015', '21', '20', '2015']" 133,EP_3554253_B1 (2).png,EP3554253B1,AERATED FOOD PRODUCTS,['FIG1'],"['FIG1 shows Mastersizer plots showing the particle size distribution for the fat droplets in the emulsions of the pea control, and the tested mushroom extracts ']","['As can be seen from Table 3 and in FIG1, the extracts of BI24389 (Volvariella volvacea), BI24395 (Hyspatys marrcus), and BI24800 (Ganoderma lucidium) provided stable emulsions, comparable to pea whereas the remaining mushroom extracts did not.']",26,47,plot,A,"[{'element_identifier': '5', 'terms': ['Chapter']}, {'element_identifier': '1', 'terms': ['will contain less than', 'DNA sequence analysis.TABLE', 'Samples were diluted', 'after']}, {'element_identifier': '4', 'terms': ['Following centrifugation at']}, {'element_identifier': '2', 'terms': ['are shown in Table', '40mN/m after']}, {'element_identifier': '10', 'terms': ['milkshakes is typically from', 'in']}, {'element_identifier': '26', 'terms': ['glass cell containing about']}, {'element_identifier': '15', 'terms': ['another']}, {'element_identifier': '3', 'terms': ['against about']}]",['3. An aerated food product according to claim 1 or claim 2 comprising Volvariella volvacea extract wherein the Volvariella volvacea extract is prepared by: - Freeze drying the mushroom fruiting body then grinding; - Rehydrating the ground mushroom in a buffer; - Clarifying soluble material by centrifugation; - Salting out soluble extracts out; - Centrifuging precipitates and then solubilising the pellets in distilled water; - Dialysing soluble protein; - Freeze drying the dialysed material to provide the Volvariella volvacea extract.'],False,"['5', '4', '3', '2', '1', '15', '10', '100', '1000', '3000', '13', '2015', '14', '2015', '20', '2015', '14', '26', '2015', '21', '02', '201']" 134,EP_3554253_B1 (3).png,EP3554253B1,AERATED FOOD PRODUCTS,['FIG1'],"['FIG1 shows Mastersizer plots showing the particle size distribution for the fat droplets in the emulsions of the pea control, and the tested mushroom extracts ']","['As can be seen from Table 3 and in FIG1, the extracts of BI24389 (Volvariella volvacea), BI24395 (Hyspatys marrcus), and BI24800 (Ganoderma lucidium) provided stable emulsions, comparable to pea whereas the remaining mushroom extracts did not.']",26,47,plot,A,"[{'element_identifier': '24', 'terms': ['after']}, {'element_identifier': '7', 'terms': ['in buffer at pH']}, {'element_identifier': '1', 'terms': ['will contain less than', 'DNA sequence analysis.TABLE', 'Samples were diluted', 'after']}, {'element_identifier': '2', 'terms': ['are shown in Table', '40mN/m after']}, {'element_identifier': '10', 'terms': ['milkshakes is typically from', 'in']}, {'element_identifier': '26', 'terms': ['glass cell containing about']}, {'element_identifier': '3', 'terms': ['against about']}]",['3. An aerated food product according to claim 1 or claim 2 comprising Volvariella volvacea extract wherein the Volvariella volvacea extract is prepared by: - Freeze drying the mushroom fruiting body then grinding; - Rehydrating the ground mushroom in a buffer; - Clarifying soluble material by centrifugation; - Salting out soluble extracts out; - Centrifuging precipitates and then solubilising the pellets in distilled water; - Dialysing soluble protein; - Freeze drying the dialysed material to provide the Volvariella volvacea extract.'],False,"['6', '3', '2', '1', '6', '10', '100', '1000', '3000', '13', '2015', '24', '14', '2015', '7', '20', '2015', '14', '26', '2015', '21', '02']" 135,EP_3554253_B1 (4).png,EP3554253B1,AERATED FOOD PRODUCTS,['FIG1'],"['FIG1 shows Mastersizer plots showing the particle size distribution for the fat droplets in the emulsions of the pea control, and the tested mushroom extracts ']","['As can be seen from Table 3 and in FIG1, the extracts of BI24389 (Volvariella volvacea), BI24395 (Hyspatys marrcus), and BI24800 (Ganoderma lucidium) provided stable emulsions, comparable to pea whereas the remaining mushroom extracts did not.']",26,47,plot,A,"[{'element_identifier': '24', 'terms': ['after']}, {'element_identifier': '5', 'terms': ['Chapter']}, {'element_identifier': '4', 'terms': ['Following centrifugation at']}, {'element_identifier': '2', 'terms': ['are shown in Table', '40mN/m after']}, {'element_identifier': '10', 'terms': ['milkshakes is typically from', 'in']}, {'element_identifier': '3', 'terms': ['against about']}]",['3. An aerated food product according to claim 1 or claim 2 comprising Volvariella volvacea extract wherein the Volvariella volvacea extract is prepared by: - Freeze drying the mushroom fruiting body then grinding; - Rehydrating the ground mushroom in a buffer; - Clarifying soluble material by centrifugation; - Salting out soluble extracts out; - Centrifuging precipitates and then solubilising the pellets in distilled water; - Dialysing soluble protein; - Freeze drying the dialysed material to provide the Volvariella volvacea extract.'],False,"['6', '5', '4', '3', '2', '21', '10', '100', '1000', '3000', '29', '2015', '24', '30', '2015', '6', '05', '2015', '14', '14', '2015', '21', '20', '2015']" 136,EP_3554253_B1 (5).png,EP3554253B1,AERATED FOOD PRODUCTS,['FIG1'],"['FIG1 shows Mastersizer plots showing the particle size distribution for the fat droplets in the emulsions of the pea control, and the tested mushroom extracts ']","['As can be seen from Table 3 and in FIG1, the extracts of BI24389 (Volvariella volvacea), BI24395 (Hyspatys marrcus), and BI24800 (Ganoderma lucidium) provided stable emulsions, comparable to pea whereas the remaining mushroom extracts did not.']",26,47,plot,A,"[{'element_identifier': '24', 'terms': ['after']}, {'element_identifier': '5', 'terms': ['Chapter']}, {'element_identifier': '1', 'terms': ['will contain less than', 'DNA sequence analysis.TABLE', 'Samples were diluted', 'after']}, {'element_identifier': '2', 'terms': ['are shown in Table', '40mN/m after']}, {'element_identifier': '10', 'terms': ['milkshakes is typically from', 'in']}, {'element_identifier': '3', 'terms': ['against about']}]",['3. An aerated food product according to claim 1 or claim 2 comprising Volvariella volvacea extract wherein the Volvariella volvacea extract is prepared by: - Freeze drying the mushroom fruiting body then grinding; - Rehydrating the ground mushroom in a buffer; - Clarifying soluble material by centrifugation; - Salting out soluble extracts out; - Centrifuging precipitates and then solubilising the pellets in distilled water; - Dialysing soluble protein; - Freeze drying the dialysed material to provide the Volvariella volvacea extract.'],False,"['5', '3', '2', '1', '22', '10', '100', '1000', '3000', '29', '2015', '24', '30', '2015', '6', '05', '2015', '14', '14', '2015', '21', '20', '2015']" 137,EP_3554253_B1 (6).png,EP3554253B1,AERATED FOOD PRODUCTS,['FIG1'],"['FIG1 shows Mastersizer plots showing the particle size distribution for the fat droplets in the emulsions of the pea control, and the tested mushroom extracts ']","['As can be seen from Table 3 and in FIG1, the extracts of BI24389 (Volvariella volvacea), BI24395 (Hyspatys marrcus), and BI24800 (Ganoderma lucidium) provided stable emulsions, comparable to pea whereas the remaining mushroom extracts did not.']",26,47,plot,A,"[{'element_identifier': '7', 'terms': ['in buffer at pH']}, {'element_identifier': '5', 'terms': ['Chapter']}, {'element_identifier': '4', 'terms': ['Following centrifugation at']}, {'element_identifier': '2', 'terms': ['are shown in Table', '40mN/m after']}, {'element_identifier': '0', 'terms': ['supernatants were filtered through', 'Protein was', '±', 'frequency range between']}, {'element_identifier': '10', 'terms': ['milkshakes is typically from', 'in']}, {'element_identifier': '26', 'terms': ['glass cell containing about']}, {'element_identifier': '3', 'terms': ['against about']}]",['3. An aerated food product according to claim 1 or claim 2 comprising Volvariella volvacea extract wherein the Volvariella volvacea extract is prepared by: - Freeze drying the mushroom fruiting body then grinding; - Rehydrating the ground mushroom in a buffer; - Clarifying soluble material by centrifugation; - Salting out soluble extracts out; - Centrifuging precipitates and then solubilising the pellets in distilled water; - Dialysing soluble protein; - Freeze drying the dialysed material to provide the Volvariella volvacea extract.'],False,"['5', '4', '3', '2', '0', '23', '10', '100', '1000', '3000', '13', '2015', '14', '2015', '7', '20', '2015', '14', '26', '2015', '21', '02', '201']" 138,EP_3554253_B1.png,EP3554253B1,AERATED FOOD PRODUCTS,['FIG1'],"['FIG1 shows Mastersizer plots showing the particle size distribution for the fat droplets in the emulsions of the pea control, and the tested mushroom extracts ']","['As can be seen from Table 3 and in FIG1, the extracts of BI24389 (Volvariella volvacea), BI24395 (Hyspatys marrcus), and BI24800 (Ganoderma lucidium) provided stable emulsions, comparable to pea whereas the remaining mushroom extracts did not.']",26,47,plot,A,"[{'element_identifier': '24', 'terms': ['after']}, {'element_identifier': '5', 'terms': ['Chapter']}, {'element_identifier': '2', 'terms': ['are shown in Table', '40mN/m after']}, {'element_identifier': '10', 'terms': ['milkshakes is typically from', 'in']}, {'element_identifier': '3', 'terms': ['against about']}]",['3. An aerated food product according to claim 1 or claim 2 comprising Volvariella volvacea extract wherein the Volvariella volvacea extract is prepared by: - Freeze drying the mushroom fruiting body then grinding; - Rehydrating the ground mushroom in a buffer; - Clarifying soluble material by centrifugation; - Salting out soluble extracts out; - Centrifuging precipitates and then solubilising the pellets in distilled water; - Dialysing soluble protein; - Freeze drying the dialysed material to provide the Volvariella volvacea extract.'],False,"['5', '5', '3', '2', '13', '10', '100', '1000', '3000', '29', '2015', '24', '30', '2015', '05', '2015', '14', '14', '2015', '21', '20', '2015']" 139,EP_3556178_B1 (2).png,EP3556178B1,INTELLIGENT TRANSPORT SYSTEM TECHNOLOGY CO-EXISTENCE METHOD AND ARRANGEMENT,"['FIG4', ' FIG5']","['FIG5 is a schematic drawing of parts of another embodiment of a node for communication within a cooperative intelligent transport system ', 'FIG4 is a schematic drawing of parts of an embodiment of a node for communication within a cooperative intelligent transport system']","['FIG5 is a schematic block diagram illustrating another example of a node 100 for communication within a cooperative intelligent transport system, based on a hardware circuitry implementation according to an embodiment. Particular examples of suitable hardware (HW) circuitry include one or more suitably configured or possibly reconfigurable electronic circuitry, e.g. Application Specific Integrated Circuits (ASICs), Field Programmable Gate Arrays (FPGAs), or any other hardware logic such as circuits based on discrete logic gates and/or flip-flops interconnected to perform specialized functions in connection with suitable registers (REG), and/or memory units (MEM). ', 'FIG4 is a schematic block diagram illustrating an example of a node 100 for communication within a cooperative intelligent transport system, based on a processor-memory implementation according to an embodiment. In this particular example, the node 100 comprises a processor 110 and a memory 120, the memory 120 comprising instructions executable by the processor 110, whereby the processor is operative to identify the technology status of the above mentioned other node.']",42,188,schematic,H,"[{'element_identifier': '130', 'terms': ['communication circuitry']}, {'element_identifier': '100', 'terms': ['node']}, {'element_identifier': '4', 'terms': ['vehicles']}, {'element_identifier': '110', 'terms': ['processor']}, {'element_identifier': '120', 'terms': ['memory']}]","['3. The node according to claim 2, characterised in that said node comprises a processor (110) and a memory (120), said memory (120) comprising instructions executable by the processor (110), whereby the processor is operative to identify said technology status of said another node.', '4. The node according to claim 2 or 3, characterised in that said node (100) comprises communication circuitry (130) configured to receive said first intelligent transport system message from said another node of said cooperative intelligent transport system.']",True,"['130', '110', '120', '100', '4', '100', '5', '23']" 140,EP_3556178_B1 (3).png,EP3556178B1,INTELLIGENT TRANSPORT SYSTEM TECHNOLOGY CO-EXISTENCE METHOD AND ARRANGEMENT,"['FIG6', ' FIG8']","['FIG6 is a schematic drawing of parts of yet another embodiment of a node for communication within a cooperative intelligent transport system ', 'FIG8 is a schematic drawing of an embodiment of a road side unit comprising a node for communication within a cooperative intelligent transport system']","['FIG6 is a schematic block diagram illustrating yet another example of a node 100 for communication within a cooperative intelligent transport system, based on combination of both processor(s) 310-1, 310-2 and hardware circuitry 330-1, 330-2 in connection with suitable memory unit(s) 320. The node 100 comprises one or more processors 310-1, 310-2, memory 320 including storage for software and data, and one or more units of hardware circuitry 330-1, 330-2 such as ASICs and/or FPGAs. The overall functionality is thus partitioned between programmed software (SW) for execution on one or more processors 310-1, 310-2, and one or more pre-configured or possibly reconfigurable hardware circuits 330-1, 330-2 such as ASICs and/or FPGAs. The actual hardware-software partitioning can be decided by a system designer based on a number of factors including processing speed, cost of implementation and other requirements. ', 'FIG8 is a schematic block diagram illustrating an example of a road side unit 20 comprising a node 100 according to any of the embodiments. With reference to the different embodiments mentioned above, either of, or both, of the node receiving the first ITS message and the node transmitting the first ITS message may be a road side unit.']",46,248,schematic,H,"[{'element_identifier': '100', 'terms': ['node']}, {'element_identifier': '320', 'terms': ['memory']}, {'element_identifier': '20', 'terms': ['RSUs']}, {'element_identifier': '40', 'terms': ['OBU']}]","['3. The node according to claim 2, characterised in that said node comprises a processor (110) and a memory (120), said memory (120) comprising instructions executable by the processor (110), whereby the processor is operative to identify said technology status of said another node.']",True,"['320', '9', '100', '100', '8', '20', '100', '6', '40', '24']" 141,EP_3556697_B1 (1).png,EP3556697B1,"PROCESS AND DEVICE FOR LOADING, UNLOADING AND CONTINOUS WINDING OF PRODUCT ON A REEL",['FIG2'],['FIG2 shows an expanded side view of the transport means in a forward position'],"['Transport means (15) are used to move the movable reel (4) in the direction of the first shaft (6), in one direction or another, between the mobile station (1) and a loading position, as indicated by the horizontal double arrow of FIG2.', 'As indicated above, the gripping means (10) take and release the movable reel (4) from one single side, called loading side, which is the side closest to the mobile station (1), specifically to the first shaft (6). According to a preferred embodiment, shown in the figures, the gripping means (10) are assembled on the first shaft, preferably on the end of the first shaft (6), for example on a head (11), to be able to be inserted in a central axial gap (7) of the movable reel (4). Preferably, the gripping means (10) can include extendable and retractable clamps, for example in a pneumatic or hydraulic manner, as schematically illustrated by means of vertical double arrows in FIG2.']",14,208,side view,B,"[{'element_identifier': '10', 'terms': ['gripping means']}, {'element_identifier': '13', 'terms': ['housings', 'housing']}]","['1. A process for loading, unloading and winding of product on a reel, that comprises the following steps: a) arranging in a loading position at least one movable reel (4), already loaded with a first product (2),facing a first shaft (6) of a mobile station (1) of a device for loading, unloading and winding of product on reels, wherein a loading side of the movable reel (4) closer to the first shaft (6), faces the first shaft (6); b) transporting gripping means (10) from the mobile station (1) by means of transport means (15); c) gripping the movable reel (4), from one single side, the loading side, with the gripping means (10); d) the movable reel (4) being gripped, moving, by means of the transport means (15), the gripping means (10) together with the movable reel (4) towards the mobile station (1) in the direction of the first shaft (6); e) assembly the movable reel (4) on the first shaft (6) in the mobile station (1), characterized in that it further comprises the following steps: e1) hooking the first product (2) of the movable reel (4) on a non-movable reel (9) next to the movable reel (4), and start to transfer the first product (2) from the movable reel (4) to the non-movable reel (9) until completely emptying the movable reel (4); and e2) continuously providing a second product (3) on the movable reel (4), to simultaneously transfer the first product (2) back to the movable reel (4) from the non-movable reel (9) ; and f) the gripping means (10) being holding the winded movable reel (4) on the loading side, actuate the transport means (15) to move the gripping means (10) together with the movable reel (4) toward the loading position.']",False,"['10', '13', '71']" 142,EP_3556747_B1.png,EP3556747B1,COMPOUND FOR ENHANCING THE COUPLING DEGREE OF COMPLEX TRPV4-KCA2.3 ^AND ANTI-HYPERTENSION APPLICATIONS THEREOF,['FIG1'],['FIG1 is a schematic diagram of the three-dimensional structures and functional zones of the protein TRPV4 and the protein KCa2 3'],"[""Experimental method: Possible binding sites (as shown in FIG1) are selected according to the three-dimensional structures and functional characteristics of the protein TRPV4 and the protein KCa2.3. The selected structural domains are mainly used to adjust the protein-protein relation, and are platforms where the proteins interact with each other. The selected binding sites are mutated such that the binding sites are lost. The used primers can be seen in Table 1.Table 1Gene namePrimer sequenceTRPV4ΔAR15'-gccaccccccatcctcaaaacggggaaga-3'5'-tcttccccgttttgaggatggggggtggc-3'TRPV4ΔAR25'-cgggagccgtcccgaggccagaca-3'5'-tgtctggcctcgggacggctcccg-3'TRPV4ΔAR35'-cagagacatctactactttggggagctgccct-3'5'-agggcagctccccaaagtagtagatgtctctg-3'TRPV4ΔAR45'-gggaggctacttctacagggggaacacggtg-3'5'-caccgtgttccccctgtagaagtagcctccc-3'TRPV4ΔAR55'-ggcgacaggactcggatggcctttcgcc-3'5'-ggcgaaaggccatccgagtcctgtcgcc-3'TRPV4ΔAR65'-acctggagacagttctcaacaatgatgaggacaccc-3'5'-gggtgtcctcatcattgttgagaactgtctccaggt-3'TRPV4ΔCaMBD5'-ctaccagtactatggcttcgagctgaacaagaactcaa-3'5'-ttgagttcttgttcagctcgaagccatagtactggtag-3'KCa2.3Δ17c5'-tggtgagctgagtgtcaaccacagctaccacaa-3'5'-catgtgcacaacttcatgatgctaaagaagattgaccatgcc-3'KCa2.3Δα15'-ggcatggtcaatcttctttagcatcatgaagttgtgcacatg-3'5'-gctccgtgattaagtcatacatgtcaatcttctttagcagcttt-3'Kca2.3Δloop5'-gtctataaacatacaaagctgcatgccaaagtcaggaaacac-3'5'-gtgtttcctgactttggcatgcagctttgtatgtttatagac-3'KCa2.3Δα25'-aaagctgctaaagaagattgacatgtatgacttaatcacggagc-3'5'-gctccgtgattaagtcatacatgtcaatcttctttagcagcttt-3'KCa2.3ΔCaMBD5'-ctccgtgattaagtcatacatcatcatgaagttgtgcacatg-3'5'-catgtgcacaacttcatgatgatgtatgacttaatcacggag-3'""]",23,86,schematic diagram,A,"[{'element_identifier': '3', 'terms': ['compound']}, {'element_identifier': '13', 'terms': ['diphenylacetyl chloride']}]","['2. A preparation method of a compound for enhancing the space coupling degree of an endothelial cell ion channel complex TRPV4- KCa2.3 according to Claim 1, characterized by comprising the following steps: (1) providing propane diamine with t-butyloxycarboryl to protect a single amino first: (2) another exposed amino reacting with diphenylacetyl chloride to generate an amide: (3) removing a t-butyloxycarboryl protection from the amide under an acidic condition: (4) a compound obtained after removing the t-butyloxycarboryl protection performing an amino-ester exchange with 4-quinazolone-2-carboxylic acid ethyl ester to obtain a target compound:']",True,"['3', '20000', '13']" 143,EP_3557345_B1 (2).png,EP3557345B1,"CONTROL APPARATUS, SYSTEM PROGRAM, AND CONTROL METHOD",['FIG3'],['FIG3 is a schematic diagram showing an example of a hardware configuration of a computation unit constituting the control apparatus according to the present embodiment'],"['Referring to FIG3, the computation unit 13 includes a processor 100, a chipset 102, a main memory 104, a nonvolatile memory 106, a system timer 108, a PLC system bus controller 120, a field network controller 140, and a USB connector 110. The chip set 102 is connected to other components through various buses.', 'Although FIG3 illustrates one processor 100 for convenience of description, a plurality of processors 100 may be provided or a plurality of cores may be mounted in one processor 100. The performance and configuration of the processor 100 may be determined according to required computing resources.']",25,114,schematic diagram,G,"[{'element_identifier': '142', 'terms': ['DMA control circuit']}, {'element_identifier': '130', 'terms': ['PLC system bus connector']}, {'element_identifier': '100', 'terms': ['processor', 'processors']}, {'element_identifier': '126', 'terms': ['buffer memory']}, {'element_identifier': '104', 'terms': ['main memory']}, {'element_identifier': '20', 'terms': ['ms', 'operation per']}, {'element_identifier': '144', 'terms': ['field network control circuit']}, {'element_identifier': '146', 'terms': ['buffer memory']}, {'element_identifier': '102', 'terms': ['chipset']}, {'element_identifier': '108', 'terms': ['system timer']}, {'element_identifier': '106', 'terms': ['nonvolatile memory']}, {'element_identifier': '140', 'terms': ['field network controller']}, {'element_identifier': '110', 'terms': ['USB connector']}, {'element_identifier': '124', 'terms': ['system bus control circuit']}, {'element_identifier': '120', 'terms': ['PLC system bus controller']}, {'element_identifier': '13', 'terms': ['computation unit']}]","['1. A control apparatus (1) for controlling a control object, comprising: a processor (100); a first program (240) which is repeatedly executed by the processor and has a highest execution priority; a second program having a lower execution priority than the first program; a third program having a lower execution priority than the second program; and a scheduler program which manages programs executed by the processor, wherein the second program includes a notification command (224) for outputting a start notification (270) according to start of execution in the processor and outputting an end notification (272) according to completion of execution in the processor, and the scheduler program (212) includes a command (2120) for causing the processor to execute the second and third programs such that execution of the first program is not obstructed, and a command (2122) for determining an execution state of the second program in each predetermined monitoring cycle (262) on the basis of the start notification and the end notification from the second program; characterized by a fourth program (242) having a higher execution priority than the second program, wherein the scheduler program includes a command (2124) for temporarily interrupting execution of the fourth program when the execution state of the second program does not satisfy predetermined settings, the command for determining the execution state includes a command for determining an execution state of the third program in the monitoring cycle, and the scheduler program includes a command (2124) for temporarily interrupting execution of the second program when the execution state of the third program does not satisfy predetermined settings.']",False,"['100', '13', '106', '110', '144', '140', '150', '104', '108', '124', '120', '130', '142', '146', '102', '126', '20']" 144,EP_3557345_B1 (3).png,EP3557345B1,"CONTROL APPARATUS, SYSTEM PROGRAM, AND CONTROL METHOD",['FIG7'],['FIG7 is a diagram for explaining an intervention function in the computation unit according to the present embodiment'],"['FIG7 is a diagram for explaining the intervention function 2124 in the computation unit 13 according to the present embodiment. Referring to FIG7, the intervention function 2124 is provided in association with the monitoring function 2122. The monitoring function 2122 and the intervention function 2124 are implemented as a part of the scheduler program 212 or an additional function of the scheduler program 212.', 'FIG7 shows a case in which the execution time of the secondary task 242 is long and the high-priority service 252 cannot be executed as an example. In such an execution state, the monitoring function 2122 checks an execution state of the system service task 250 in each monitoring cycle 262 and, when it is determined that the system service task 250 cannot operate in a predetermined proportion of time, outputs an intervention request 274 to the intervention function 2124.']",18,158,diagram,G,"[{'element_identifier': '274', 'terms': ['intervention request']}, {'element_identifier': '7', 'terms': ['relay']}, {'element_identifier': '280', 'terms': ['resumption instruction']}, {'element_identifier': '242', 'terms': ['secondary task']}, {'element_identifier': '262', 'terms': ['monitoring cycle']}, {'element_identifier': '278', 'terms': ['intervention end request']}, {'element_identifier': '252', 'terms': ['high-priority service', 'high-priority services']}, {'element_identifier': '250', 'terms': ['system service task']}, {'element_identifier': '2124', 'terms': ['intervention function']}, {'element_identifier': '254', 'terms': ['function', 'functions']}, {'element_identifier': '276', 'terms': ['interruption instruction']}, {'element_identifier': '256', 'terms': ['low-priority service']}, {'element_identifier': '240', 'terms': ['task']}, {'element_identifier': '270', 'terms': ['notification']}, {'element_identifier': '2122', 'terms': ['function']}, {'element_identifier': '260', 'terms': ['control cycle', 'control cycles']}, {'element_identifier': '212', 'terms': ['scheduler program']}, {'element_identifier': '264', 'terms': ['service cycle']}]","['1. A control apparatus (1) for controlling a control object, comprising: a processor (100); a first program (240) which is repeatedly executed by the processor and has a highest execution priority; a second program having a lower execution priority than the first program; a third program having a lower execution priority than the second program; and a scheduler program which manages programs executed by the processor, wherein the second program includes a notification command (224) for outputting a start notification (270) according to start of execution in the processor and outputting an end notification (272) according to completion of execution in the processor, and the scheduler program (212) includes a command (2120) for causing the processor to execute the second and third programs such that execution of the first program is not obstructed, and a command (2122) for determining an execution state of the second program in each predetermined monitoring cycle (262) on the basis of the start notification and the end notification from the second program; characterized by a fourth program (242) having a higher execution priority than the second program, wherein the scheduler program includes a command (2124) for temporarily interrupting execution of the fourth program when the execution state of the second program does not satisfy predetermined settings, the command for determining the execution state includes a command for determining an execution state of the third program in the monitoring cycle, and the scheduler program includes a command (2124) for temporarily interrupting execution of the second program when the execution state of the third program does not satisfy predetermined settings.', '3. The control apparatus according to claim 1 or 2, wherein the scheduler program repeatedly executes the first program in each predetermined control cycle (260).']",False,"['212', '278', '280', '274', '276', '212', '260', '262', '264', '240', '242', '250', '252', '256', '254', '2124', '2122', '24', '270', '7']" 145,EP_3557345_B1 (5).png,EP3557345B1,"CONTROL APPARATUS, SYSTEM PROGRAM, AND CONTROL METHOD",['FIG9'],['FIG9 is a diagram showing an example of an execution state in a case in which a primary task and a secondary task are set in the computation unit according to the present embodiment'],"['FIG9 is a diagram showing an example of an execution state in a case in which the primary task 240 and the secondary task 242 are set in the computation unit 13 according to the present embodiment. FIG9 shows an example in which the primary task 240, the secondary task 242 and the system service task 250 (the high-priority service 252 and the low-priority service 256) are assigned priorities in this order and executed.', 'When the start notification 270 is not output from the high-priority service 252 in the execution state shown in FIG9, it is detected that the high-priority service 252 was not be able to be executed within the monitoring cycle 262 at the end time of the monitoring cycle 262, interruption of execution is indicated for the secondary task 242 having a higher priority than the high-priority service 252 in order to execute the high-priority service 252.']",34,171,diagram,G,"[{'element_identifier': '242', 'terms': ['secondary task']}, {'element_identifier': '262', 'terms': ['monitoring cycle']}, {'element_identifier': '252', 'terms': ['high-priority service', 'high-priority services']}, {'element_identifier': '250', 'terms': ['system service task']}, {'element_identifier': '256', 'terms': ['low-priority service']}, {'element_identifier': '240', 'terms': ['task']}, {'element_identifier': '260', 'terms': ['control cycle', 'control cycles']}, {'element_identifier': '264', 'terms': ['service cycle']}]","['1. A control apparatus (1) for controlling a control object, comprising: a processor (100); a first program (240) which is repeatedly executed by the processor and has a highest execution priority; a second program having a lower execution priority than the first program; a third program having a lower execution priority than the second program; and a scheduler program which manages programs executed by the processor, wherein the second program includes a notification command (224) for outputting a start notification (270) according to start of execution in the processor and outputting an end notification (272) according to completion of execution in the processor, and the scheduler program (212) includes a command (2120) for causing the processor to execute the second and third programs such that execution of the first program is not obstructed, and a command (2122) for determining an execution state of the second program in each predetermined monitoring cycle (262) on the basis of the start notification and the end notification from the second program; characterized by a fourth program (242) having a higher execution priority than the second program, wherein the scheduler program includes a command (2124) for temporarily interrupting execution of the fourth program when the execution state of the second program does not satisfy predetermined settings, the command for determining the execution state includes a command for determining an execution state of the third program in the monitoring cycle, and the scheduler program includes a command (2124) for temporarily interrupting execution of the second program when the execution state of the third program does not satisfy predetermined settings.', '3. The control apparatus according to claim 1 or 2, wherein the scheduler program repeatedly executes the first program in each predetermined control cycle (260).']",False,"['260', '262', '264', '240', '242', '250', '252', '256', '9']" 146,EP_3557345_B1 (6).png,EP3557345B1,"CONTROL APPARATUS, SYSTEM PROGRAM, AND CONTROL METHOD",['FIG10'],['FIG10 is a diagram showing an example of an execution state in a case in which only a primary task is set in the computation unit according to the present embodiment'],"['FIG10 is a diagram showing an example of an execution state in a case in which only the primary task 240 is set in the computation unit 13 according to the present embodiment. FIG10 shows an example in which the primary task 240 and the system service task 250 (the high-priority service 252 and the low-priority service 256) are assigned priorities in this order and executed.', 'FIG10 shows an execution state in which a process set in the primary task 240 cannot end within the control cycle 260. In such an execution state, it is also detected that the high-priority service 252 was not be able to be executed within the monitoring cycle 262 at the end time of the monitoring cycle 262 because the start notification 270 is not output from the high-priority service 252. However, in this execution state, it is not possible to instruct the primary task 240 to interrupt execution.', 'The example of FIG10 shows an execution state in which the entire primary task 240 cannot be processed even using available computing resources within one control cycle 260. Accordingly, settings of the primary task 240 are reviewed basically.']",31,217,diagram,G,"[{'element_identifier': '262', 'terms': ['monitoring cycle']}, {'element_identifier': '252', 'terms': ['high-priority service', 'high-priority services']}, {'element_identifier': '250', 'terms': ['system service task']}, {'element_identifier': '256', 'terms': ['low-priority service']}, {'element_identifier': '240', 'terms': ['task']}, {'element_identifier': '10', 'terms': ['connection cable']}, {'element_identifier': '260', 'terms': ['control cycle', 'control cycles']}, {'element_identifier': '264', 'terms': ['service cycle']}]","['1. A control apparatus (1) for controlling a control object, comprising: a processor (100); a first program (240) which is repeatedly executed by the processor and has a highest execution priority; a second program having a lower execution priority than the first program; a third program having a lower execution priority than the second program; and a scheduler program which manages programs executed by the processor, wherein the second program includes a notification command (224) for outputting a start notification (270) according to start of execution in the processor and outputting an end notification (272) according to completion of execution in the processor, and the scheduler program (212) includes a command (2120) for causing the processor to execute the second and third programs such that execution of the first program is not obstructed, and a command (2122) for determining an execution state of the second program in each predetermined monitoring cycle (262) on the basis of the start notification and the end notification from the second program; characterized by a fourth program (242) having a higher execution priority than the second program, wherein the scheduler program includes a command (2124) for temporarily interrupting execution of the fourth program when the execution state of the second program does not satisfy predetermined settings, the command for determining the execution state includes a command for determining an execution state of the third program in the monitoring cycle, and the scheduler program includes a command (2124) for temporarily interrupting execution of the second program when the execution state of the third program does not satisfy predetermined settings.', '3. The control apparatus according to claim 1 or 2, wherein the scheduler program repeatedly executes the first program in each predetermined control cycle (260).']",False,"['260', '262', '264', '240', '250', '252', '256', '27', '10']" 147,EP_3557345_B1.png,EP3557345B1,"CONTROL APPARATUS, SYSTEM PROGRAM, AND CONTROL METHOD",['FIG1'],['FIG1 is a schematic diagram showing an example of program execution in a control apparatus according to the present embodiment'],"['FIG1 is a schematic diagram showing an example of program execution in a control apparatus 1 according to the present embodiment. Referring to FIG1, the control apparatus 1 is a computer for controlling any control object and has one or more processors.', 'FIG1 shows an example in which a primary task 240 and a system service task 250 are sequentially executed in the control apparatus 1. In the present description, the term ""task"" is a base unit which is a control object to which computing resources are allocated, and one or more programs to be executed are registered or set for each task. That is, computing resources are allocated to any task and, when the task enters a state in which it can be executed, execution of one or more programs registered or set for the task is started or resumed.', 'In the control apparatus 1 according to the present embodiment, it is possible to control appropriate allocation of computing resources, and the like even for a program included in the system service task 250, in which an operation time and the like cannot be guaranteed in conventional methods, by using the monitoring function 2122 shown in FIG1.']",20,219,schematic diagram,G,"[{'element_identifier': '1', 'terms': ['control apparatus']}, {'element_identifier': '262', 'terms': ['monitoring cycle']}, {'element_identifier': '252', 'terms': ['high-priority service', 'high-priority services']}, {'element_identifier': '250', 'terms': ['system service task']}, {'element_identifier': '254', 'terms': ['function', 'functions']}, {'element_identifier': '256', 'terms': ['low-priority service']}, {'element_identifier': '240', 'terms': ['task']}, {'element_identifier': '270', 'terms': ['notification']}, {'element_identifier': '272', 'terms': ['notification']}, {'element_identifier': '2122', 'terms': ['function']}, {'element_identifier': '212', 'terms': ['scheduler program']}]","['1. A control apparatus (1) for controlling a control object, comprising: a processor (100); a first program (240) which is repeatedly executed by the processor and has a highest execution priority; a second program having a lower execution priority than the first program; a third program having a lower execution priority than the second program; and a scheduler program which manages programs executed by the processor, wherein the second program includes a notification command (224) for outputting a start notification (270) according to start of execution in the processor and outputting an end notification (272) according to completion of execution in the processor, and the scheduler program (212) includes a command (2120) for causing the processor to execute the second and third programs such that execution of the first program is not obstructed, and a command (2122) for determining an execution state of the second program in each predetermined monitoring cycle (262) on the basis of the start notification and the end notification from the second program; characterized by a fourth program (242) having a higher execution priority than the second program, wherein the scheduler program includes a command (2124) for temporarily interrupting execution of the fourth program when the execution state of the second program does not satisfy predetermined settings, the command for determining the execution state includes a command for determining an execution state of the third program in the monitoring cycle, and the scheduler program includes a command (2124) for temporarily interrupting execution of the second program when the execution state of the third program does not satisfy predetermined settings.']",False,"['1', '212', '270', '272', '2122', '262', '250', '252', '256', '254', '240', '270', '272', '18', '1']" 148,EP_3557606_B1.png,EP3557606B1,METHOD OF CLAMPING A SUBSTRATE AND CLAMP PREPARATION UNIT,"['FIG1', ' FIG2']","['FIG2 is a sectional view schematically illustrating processes with a negative impact on the clamp stability of the capillary layer of FIG1 ', 'FIG1 is a sectional view schematically illustrating a capillary layer between two structures']","['FIG2 is a sectional view schematically illustrating processes with a negative impact on the stability of the clamping action performed by means of the capillary liquid layer 1 of FIG1. Hereafter, the expression ""clamp"" will be used for the arrangement where the substrate 2 is clamped to the substrate support structure 3 by means of the capillary layer 1.', 'If pre-existing bubbles are present in the liquid, introduction of the clamp into a vacuum environment will lead to expansion of such bubbles within the capillary layer. The size of initially small bubbles can grow by several orders of magnitude if ambient pressure decreases, e.g. from 1 bar to 10-6 mbar. As can be readily seen in FIG2, a bubble of the size of bubble 11 may seriously influence the clamping strength, at least locally, and may have a negative influence on the stability of the clamp.', 'Another mechanism that may lead to clamp instability is spontaneous void formation, for example caused by cavitation of or dissolved gas precipitation in the capillary liquid layer. An example of such a void has been denoted by reference numeral 13 in FIG2. Voids formed by cavitation may grow in a similar way as discussed before with respect to pre-existing bubbles if the clamp is brought into a vacuum environment. The resulting voids may have a negative influence on the clamp stability.', ""Besides decrease of the clamp stability due to the presence of bubbles and/or voids, the clamp stability will also be negatively affected by evaporation of liquid at the capillary layer interface, i.e. evaporation at the concave liquid surface. FIG2 schematically shows the effect of such evaporation. Due to evaporation, the position of the outer liquid surface 8 has shifted towards a new position to form outer liquid surface 8'. As a result of that shift, the surface area covered by the capillary layer, and thus the stability of the clamp, has decreased."", 'As mentioned earlier with reference to FIG2, the layer of capillary liquid evaporates in a vacuum environment. Experiments have shown that the remaining volume of the capillary liquid layer tends to accumulate at one side of the clamp. Due to this asymmetric distribution of the capillary layer, one side of the substrate ""peels off\' the table. Hereafter, the effect will be referred to as substrate peeling. ', 'FIG1 is a sectional view schematically illustrating a capillary liquid layer 1 of a capillary liquid, e.g. water, between a first substrate 2, e.g. a wafer, and a second substrate 3, e.g. a substrate support structure like a wafer table. The first and second substrates 2, 3 have a substantially flat surface 5, 6 respectively. The nominal distance between the opposing surfaces 5, 6 of the first and second substrates 2, 3 is given by height h. The capillary liquid layer 1 has an outer liquid surface 8, which is generally concavely shaped due to adhesive connection of the liquid to the first substrate 2 and the second substrate 3.']",35,556,sectional view,G,"[{'element_identifier': '28', 'terms': ['surface']}, {'element_identifier': '23', 'terms': ['substrate support structure']}, {'element_identifier': '11', 'terms': ['bubble']}, {'element_identifier': '1', 'terms': ['layer']}, {'element_identifier': '22', 'terms': ['substrate']}, {'element_identifier': '29', 'terms': ['sealing structure']}, {'element_identifier': '2', 'terms': ['substrate', 'substrates']}, {'element_identifier': '41', 'terms': ['reservoir']}, {'element_identifier': '31', 'terms': ['moat']}, {'element_identifier': '27', 'terms': ['contact elements', 'burls', 'burl']}, {'element_identifier': '43', 'terms': ['channels']}, {'element_identifier': '26', 'terms': ['surface']}, {'element_identifier': '21', 'terms': ['capillary layer']}, {'element_identifier': '44', 'terms': ['flow control unit']}, {'element_identifier': '3', 'terms': ['second substrate']}, {'element_identifier': '13', 'terms': ['reference numeral']}]","['7. Arrangement according to any one of the preceding claims, wherein the clamp preparation unit comprises a liquid dispensing unit (124) for applying liquid onto the surface of the substrate support structure, and wherein the substrate support structure comprises a substrate transfer unit for lowering the substrate onto a liquid layer formed on the surface of the substrate support structure, and for lifting the substrate from the liquid layer on the substrate support surface, wherein the substrate transfer unit comprises a plurality of separately controlled movable support pins (127).']",True,"['2', '3', '1', '11', '13', '2', '31', '28', '26', '27', '21', '22', '29', '43', '42', '44', '41', '23', '15']" 149,EP_3559332_B1 (3).png,EP3559332B1,STEAM IRON WITH INCREASED WATER HEAD,"['FIG2c', ' FIG2d']","['FIG2c shows a schematic side view of the embodiment shown in FIG2b having been moved into its operational orientation ', 'FIG2d shows a schematic side view of the embodiment shown in FIG2c after some of the water has been turned into steam']","['Referring to FIG2c, with the water inlet 29 sealed closed, the garment steaming device 1 is moved back into its operational orientation A in which the steam generator 5 extends horizontally. Because the orifice 21 connected to the second fluid path inlet 8 is below the water level in the first water chamber 2, the air in the first water chamber 2 becomes trapped. The air in the first water chamber 2 is sealed under pressure by the hydraulic head achieved by the water in the second water chamber 3 being at a greater vertical height from the steam generator 5 than the water in the first water chamber 2. The larger the height of the water level in the second water chamber 3 from the first fluid path 6 the larger the hydraulic head. As shown in FIG2c, water may be in the vent pipe 10 when the garment steaming device 1 has just been filled and will contribute to the overall water head. ', 'Referring now to FIG2d, as steaming continues water from the first water chamber 2 is directed through the first fluid path 6 and into the steam generator 5. The air in the first water chamber 2 remains sealed and under pressure caused by the hydraulic head achieved in the second water chamber 3. Therefore, the water that exits the first water chamber 2 into the steam generator 5 is replaced by water from the second water chamber 3. As steam is continually generated, the water level in the second water chamber 3 becomes lower which results in a lower hydraulic head and therefore, a slowing steam rate as the difference in pressure between the first fluid path 6 and the steam generator 5 decreases. As the water level in the second water chamber 3 becomes lower air enters via the vent pipe 10 at atmospheric pressure.']",41,329,schematic side view,D,"[{'element_identifier': '15', 'terms': ['first end']}, {'element_identifier': '5', 'terms': ['steam generator']}, {'element_identifier': '10', 'terms': ['pipe']}, {'element_identifier': '14', 'terms': ['plate']}]","['1. A steam iron (1) comprising: - a first water chamber (2); - a second water chamber (3) situated in a heel portion (4) of the steam iron (1); - a steam generator (5) situated below the first water chamber (2) in an operational orientation (A) of the steam iron (1); - a first fluid path (6) connecting the first water chamber (2) and the steam generator (5); and - a vent pipe (10) connected to a top part of the second water chamber (3) by its first end (11) and open to the atmosphere at its second end (12), the second end (12) of the vent pipe (10) extending at least as far as the maximum water level height of the first water chamber (2) when the steam iron (1) is in a non-operational orientation (B); - characterized in that a second fluid path (7) connects a bottom end of the first water chamber (2) to a lower part of the second water chamber (3) in the operational orientation (A), the cross-sectional diameter of the second fluid path (7) is in the range of 2 mm to 15 mm, and the second water chamber (3) is arranged wholly above the first water chamber (2) in the operational orientation (A), so that so long as there is water in the second water chamber (3) a water level height of the second water chamber (3) is higher than a water level height of the first water chamber (2) in said operational orientation (A), so that the water head in the first fluid path (6) generated by the fluid coupling the second water chamber (3) and the first water chamber (2) is increased to obtain an increased steam rate when the steam iron (1) is in the operational orientation (A).']",True,"['10', '5', '10', '14', '15']" 150,EP_3559332_B1 (6).png,EP3559332B1,STEAM IRON WITH INCREASED WATER HEAD,['FIG3b'],['FIG3b shows a schematic side view of the garment steaming device comprising the steam iron shown in FIG3a in its non-operational orientation'],"['Referring to FIG3b, it can be seen that the steam iron 35 is placed on its heel portion 4 during its non-operational orientation B. FIG3b also illustrates that the soleplate 36 extends at an angle to the horizontal when placed on its heel portion 4 in its non-operational orientation B.']",24,55,schematic side view,D,"[{'element_identifier': '35', 'terms': ['steam iron']}, {'element_identifier': '38', 'terms': []}, {'element_identifier': '18', 'terms': ['top wall']}, {'element_identifier': '10', 'terms': ['pipe']}, {'element_identifier': '41', 'terms': ['handle']}, {'element_identifier': '29', 'terms': ['water inlet']}, {'element_identifier': '36', 'terms': ['soleplate']}]","['1. A steam iron (1) comprising: - a first water chamber (2); - a second water chamber (3) situated in a heel portion (4) of the steam iron (1); - a steam generator (5) situated below the first water chamber (2) in an operational orientation (A) of the steam iron (1); - a first fluid path (6) connecting the first water chamber (2) and the steam generator (5); and - a vent pipe (10) connected to a top part of the second water chamber (3) by its first end (11) and open to the atmosphere at its second end (12), the second end (12) of the vent pipe (10) extending at least as far as the maximum water level height of the first water chamber (2) when the steam iron (1) is in a non-operational orientation (B); - characterized in that a second fluid path (7) connects a bottom end of the first water chamber (2) to a lower part of the second water chamber (3) in the operational orientation (A), the cross-sectional diameter of the second fluid path (7) is in the range of 2 mm to 15 mm, and the second water chamber (3) is arranged wholly above the first water chamber (2) in the operational orientation (A), so that so long as there is water in the second water chamber (3) a water level height of the second water chamber (3) is higher than a water level height of the first water chamber (2) in said operational orientation (A), so that the water head in the first fluid path (6) generated by the fluid coupling the second water chamber (3) and the first water chamber (2) is increased to obtain an increased steam rate when the steam iron (1) is in the operational orientation (A).', '9. The steam iron (1) according to any preceding claim, wherein the first water chamber (2) comprises a water inlet (29) and a sealing member (30) located on a sidewall thereof, the water inlet (29) being configured to allow the first water chamber (2) and the second water chamber (3) to be filled with water in the non-operational orientation (B), the sealing member (30) being configured to seal the water inlet (29) once the first water chamber (2) and second water chamber (3) have been filled and prior to the movement of the steam iron (1) into the operational orientation (A).', '12. The steam iron (1) according to any preceding claim, wherein the vent pipe (10) is arranged inside a handle (41) of the steam iron (35).', '13. The steam iron (1) according to any preceding claim, wherein there is a soleplate (36) situated against the steam generator (5) in which water is converted into steam, the soleplate (36) having multiple steam venting holes (38) thereon and facing the garment to be ironed once the garment steaming device (1) is moved into the operation orientation (A) from the non-operational orientation (B).']",True,"['41', '10', '29', '38', '36', '35', '36', '18']" 151,EP_3560240_B1 (2).png,EP3560240B1,A NODE AND A METHOD PERFORMED BY THE NODE OPERABLE IN A MESH COMMUNICATION NETWORK FOR ROUTING A RECEIVED PACKET TOWARDS A DESTINATION,['FIG1e'],"['FIG1e is a flowchart of a method performed by a node operable in a mesh communication network for routing a received packet towards a destination, according to yet a further exemplifying embodiment']","['The method may further comprise, as illustrated in FIG1e, receiving 170 a warning packet associated with a node in the mesh communication network for which there is an entry associated with the sender of the warning packet in the routing table, and deleting 175 the entry from the routing table.']",33,54,flowchart,H,"[{'element_identifier': '100', 'terms': ['ISA', 'method']}, {'element_identifier': '190', 'terms': ['broadcasting']}, {'element_identifier': '170', 'terms': ['receiving']}, {'element_identifier': '175', 'terms': ['deleting']}]","['1. A method (100) performed by a node in a mesh communication network for routing a received packet towards a destination, the method comprising: - receiving (100) a packet addressed to a destination node in the mesh network, the packet comprising information related to address of source node, last hop address, address of destination node, and a hop counter, - determining (120) whether the destination address is comprised in a routing table of the node in the mesh communication network, and when the destination address is comprised in a routing table: - forwarding (130) the received packet according to the routing table, or when the destination address is not comprised in a routing table: - flooding (140) the received packet by broadcasting it in the mesh communication network, characterized in that , the method further comprising: - updating (150) the routing table according to the received packet, wherein the updating (150) of the routing table according to the received packet comprises incrementing a counter indicative of the number of times packets have been received from the last hop address, having the same source address, when both the source address and the last hop address are comprised in the routing table.', '6. The method (100) according to any of claims 1-5, further comprising receiving (170) a warning packet associated with a node in the mesh communication network for which there is an entry associated with the sender of the warning packet in the routing table, and deleting (175) the entry from the routing table.']",True,"['100', '190', '100', '170', '175', '18']" 152,EP_3560650_B1 (2).png,EP3560650B1,ADDITIVE MANUFACTURING APPARATUS AND ADDITIVE MANUFACTURING METHOD,['FIG5'],['FIG5 is a view for explaining a stacking pitch of the beads when the beads illustrated in FIG2 are stacked and the amount of movement of a feeding position in a direction of a width of a bead'],"['FIG5 is a view for explaining a stacking pitch of the beads 22 when the beads 22 illustrated in FIG2 are stacked and the amount of movement of the feeding position in a direction of the width BW of the bead 22. The feeding position is a position to which the wire 7 is fed. A stacking pitch BP is an interval between the feeding positions in the vertical direction. The stacking pitch BP of the bead 22 stacked at an i-th time is denoted by a stacking pitch BPi. ""i"" is an arbitrary integer that is 1 or more. In the first embodiment, stacking pitches BP1, BP2, BP3, ... are equal to one another. The stacking pitch BPi is stored in the database in the storage device 5 in advance. The stacking pitch BPi is a parameter for building a deposit by stacking the beads 22 in the vertical direction.']",38,167,view,B,"[{'element_identifier': '2', 'terms': ['substrate']}, {'element_identifier': '22', 'terms': ['bead', 'beads']}]","['1. An additive manufacturing apparatus (1) for building a deposit on a substrate (2), the apparatus comprising: a feeding unit (6, 8) to feed a build material (7) to a feeding position; an irradiation unit (10, 11, 12) to irradiate the feeding position with a laser beam that melts the build material; a control unit (3) to perform control for building the deposit by stacking beads formed by movement of the feeding position with respect to the substrate and melting of the build material; and an arithmetic unit (4) to execute an arithmetic process of computing parameters for the control unit to perform the control, wherein the beads include two beads (22-1, 22-2) stacked on each other, the two beads are a first bead (22-1) and a second bead (22-2) stacked on the first bead, the first bead being formed earlier than the second bead, the feeding position being a first position (C1) in formation of the first bead, the feeding positon being a second position (C2) in formation of the second bead, characterized in that the arithmetic unit calculates an interval (KS) between the first position and the second position in a set direction on a basis of a width (BW) of the first bead and a diameter (LD) of the laser beam, the set direction being a direction of the width of the first bead, and the control unit performs control for setting the second position to a position shifted from the first position in the set direction by the interval, so as to allow a part of the second bead to protrude from the first bead in the set direction.']",True,"['22', '2', '22', '2', '19']" 153,EP_3560650_B1 (3).png,EP3560650B1,ADDITIVE MANUFACTURING APPARATUS AND ADDITIVE MANUFACTURING METHOD,['FIG12'],['FIG12 is a diagram for explaining the type L3 laser beam illustrated in FIG9'],"['FIG12 is a diagram for explaining the type L3 laser beam 20 illustrated in FIG9. In general, the diameter d of the laser beam 20 at the focus position located at a focal length ff from a light source is determined by specification parameters of an optical lens provided in the irradiation unit. It is desirable to measure in advance the diameter LD of the laser beam 20 at a distance Δf from the focus position. Assuming that the diameter LD is a diameter at which 86.5% of the beam intensity is focused, the diameter LD is roughly calculated by the formula LD=2×Δf×θf. Assuming that the diameter LD is a diameter at which 100% of the beam intensity is focused, the diameter LD is roughly calculated by the formula LD=2×(2×Δf×θf). θf is a maximum angle defined by a light flux and an optical axis X of the laser beam 20.']",14,162,diagram,B,"[{'element_identifier': '23', 'terms': ['spreading portion']}, {'element_identifier': '2', 'terms': ['substrate']}, {'element_identifier': '20', 'terms': ['laser beam']}]","['1. An additive manufacturing apparatus (1) for building a deposit on a substrate (2), the apparatus comprising: a feeding unit (6, 8) to feed a build material (7) to a feeding position; an irradiation unit (10, 11, 12) to irradiate the feeding position with a laser beam that melts the build material; a control unit (3) to perform control for building the deposit by stacking beads formed by movement of the feeding position with respect to the substrate and melting of the build material; and an arithmetic unit (4) to execute an arithmetic process of computing parameters for the control unit to perform the control, wherein the beads include two beads (22-1, 22-2) stacked on each other, the two beads are a first bead (22-1) and a second bead (22-2) stacked on the first bead, the first bead being formed earlier than the second bead, the feeding position being a first position (C1) in formation of the first bead, the feeding positon being a second position (C2) in formation of the second bead, characterized in that the arithmetic unit calculates an interval (KS) between the first position and the second position in a set direction on a basis of a width (BW) of the first bead and a diameter (LD) of the laser beam, the set direction being a direction of the width of the first bead, and the control unit performs control for setting the second position to a position shifted from the first position in the set direction by the interval, so as to allow a part of the second bead to protrude from the first bead in the set direction.']",True,"['20', '2', '2', '23']" 154,EP_3560650_B1 (4).png,EP3560650B1,ADDITIVE MANUFACTURING APPARATUS AND ADDITIVE MANUFACTURING METHOD,"['FIG14', ' FIG15', ' FIG16']","['FIG15 is a hardware configuration diagram of an arithmetic device of the additive manufacturing apparatus illustrated in FIG1 ', 'FIG16 is a view for explaining correction to parameters in the additive manufacturing apparatus according to a second embodiment of the present invention ', 'FIG14 is a hardware configuration diagram of a numerical control device of the additive manufacturing apparatus illustrated in FIG1']","['FIG15 is a hardware configuration diagram of the arithmetic device 4 of the additive manufacturing apparatus 1 illustrated in FIG1. An arithmetic function of the arithmetic device 4 is implemented by a processor 111 executing a program stored in a memory 112. The processor 111 is a CPU, a processing device, an arithmetic device, a microprocessor, a microcomputer, or a DSP. A function of the arithmetic device 4 is implemented by the processor 111, and software, firmware, or a combination of software and firmware. The software or the firmware is described as a program and stored in the memory 112. The memory 112 is a built-in memory, for example, a nonvolatile or volatile semiconductor memory such as a RAM, a ROM, a flash memory, an EPROM, or an EEPROM. A display 113 displays a display screen relating to an arithmetic process. ', 'In second and third embodiments, examples in which correction to parameters is made on the basis of measured values obtained by the measurement device 17 will be described. FIG16 is a view for explaining correction to parameters in the additive manufacturing apparatus 1 according to the second embodiment of the present invention. In the second embodiment, the measurement device 17 measures a value BWR/2 of the half width BW/2 of the bead 22 or a value OHR of the protrusion amount OH thereof. On the basis of the measured value BWR/2 or the measured value OHR of the protrusion amount OH, the movement amount KS is corrected. In the second embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and a difference of the second embodiment from the first embodiment will mainly be described.', ""In FIG16, the measured value BWR/2 of the bead 22-1 and the measured value OHR of the bead 22-3 are illustrated. When BW/2>BWR/2 holds, the arithmetic device 4 corrects the movement amount KS stored in the database, to KS'=KS+{(BW-BWR)/2}×α. Alternatively, when OH>OHR holds, the arithmetic device 4 corrects the movement amount KS stored in the database, to KS'=KS+(OH-OHR)×β. α and β are numerical values of 1 or more and 2 or less, and are arbitrarily set numerical values. The arithmetic device 4 stores in the database the corrected movement amount KS', and α and β set in calculating the movement amount KS'. The arithmetic device 4 may correct the movement amount KS through an arithmetic operation other than that in accordance with the above formula. "", 'FIG14 is a hardware configuration diagram of the numerical control device 3 of the additive manufacturing apparatus 1 illustrated in FIG1. A control function of the numerical control device 3 is implemented by a processor 101 executing a program stored in a memory 102. The processor 101 is a central processing unit (CPU), a processing device, an arithmetic device, a microprocessor, a microcomputer, or a digital signal processor (DSP). A function of the numerical control device 3 is implemented by the processor 101, and software, firmware, or a combination of software and firmware. The software or the firmware is described as a program and stored in the memory 102. The memory 102 is a built-in memory, for example, a nonvolatile or volatile semiconductor memory such as a random access memory (RAM), a read only memory (ROM), a flash memory, an erasable programmable read only memory (EPROM), or an electrically erasable programmable read only memory (EEPROM (registered trademark)). A display 103 displays a display screen relating to the control of the additive manufacturing apparatus 1.']",60,681,"diagram, view",B,"[{'element_identifier': '103', 'terms': ['display']}, {'element_identifier': '5', 'terms': ['storage device']}, {'element_identifier': '2', 'terms': ['substrate']}]","['1. An additive manufacturing apparatus (1) for building a deposit on a substrate (2), the apparatus comprising: a feeding unit (6, 8) to feed a build material (7) to a feeding position; an irradiation unit (10, 11, 12) to irradiate the feeding position with a laser beam that melts the build material; a control unit (3) to perform control for building the deposit by stacking beads formed by movement of the feeding position with respect to the substrate and melting of the build material; and an arithmetic unit (4) to execute an arithmetic process of computing parameters for the control unit to perform the control, wherein the beads include two beads (22-1, 22-2) stacked on each other, the two beads are a first bead (22-1) and a second bead (22-2) stacked on the first bead, the first bead being formed earlier than the second bead, the feeding position being a first position (C1) in formation of the first bead, the feeding positon being a second position (C2) in formation of the second bead, characterized in that the arithmetic unit calculates an interval (KS) between the first position and the second position in a set direction on a basis of a width (BW) of the first bead and a diameter (LD) of the laser beam, the set direction being a direction of the width of the first bead, and the control unit performs control for setting the second position to a position shifted from the first position in the set direction by the interval, so as to allow a part of the second bead to protrude from the first bead in the set direction.']",True,"['5102', '53', '5101', '5', '103', '5112', '54', '5113', '2', '2', '2', '24']" 155,EP_3560650_B1 (5).png,EP3560650B1,ADDITIVE MANUFACTURING APPARATUS AND ADDITIVE MANUFACTURING METHOD,"['FIG17', ' FIG18', ' FIG19']","['FIG18 is a view for explaining control in the additive manufacturing apparatus according to a fourth embodiment of the present invention ', 'FIG19 is a view for explaining building of a deposit by the additive manufacturing apparatus according to a fifth embodiment of the present invention ', 'FIG17 is a view for explaining correction to parameters in the additive manufacturing apparatus according to a third embodiment of the present invention']","['FIG18 is a view for explaining control in the additive manufacturing apparatus 1 according to a fourth embodiment of the present invention. In the fourth embodiment, a temperature of the substrate 2 or the first bead is measured, and building is stopped or conditions are changed on the basis of the measured temperature. In the fourth embodiment, the same components as those in the first to third embodiments are denoted by the same reference numerals, and a difference of the fourth embodiment from the first to third embodiments will mainly be described.', 'In the fourth embodiment, the measurement device 17 includes a temperature sensor. The temperature sensor is a laser device such as a non-contact pyrometer. The measurement device 17 measures a temperature LTR of the substrate 2 when the bead 22-1 as the first bead is formed. The measurement device 17 measures the temperature LTR of the first bead when the second bead is formed. FIG18 illustrates the temperature LTR of the substrate 2 and the temperature LTR of the bead 22-1 as the first bead when the bead 22-2 as the second bead is formed. The arithmetic device 4 compares a temperature LT stored in the database with the temperature LTR. In a case where a step of stacking the second bead on the first bead is performed successively, LTR becomes approximately equal to LT. ', 'FIG19 is a view for explaining building of a deposit by the additive manufacturing apparatus 1 according to a fifth embodiment of the present invention. In the fifth embodiment, the additive manufacturing apparatus 1 builds a lid-like deposit 32 on a cylindrical structure 31 by forming the bead 22 along a circle while gradually decreasing the diameter of the circle. In the fifth embodiment, the same components as those in the first to fourth embodiments are denoted by the same reference numerals, and a difference from the first to fourth embodiments will mainly be described. ', 'FIG17 is a view for explaining correction to parameters in the additive manufacturing apparatus 1 according to the third embodiment of the present invention. In the third embodiment, the measurement device 17 measures a value BHR of the height BH of the bead 22 or a value BTR of a stacking height of the bead 22 from the substrate 2. On the basis of the measured value BHR or the measured value BTR, the pitch KP is corrected. In the third embodiment, the same components as those in the first and second embodiments are denoted by the same reference numerals, and a difference of the third embodiment from the first and second embodiments will mainly be described.', ""FIG17 illustrates the measured value BHR of the bead 22-1 and the measured value BTR of the bead 22-3. When BH>BHR holds, the arithmetic device 4 corrects the pitch KP stored in the database, to KP'=KP+(BH-BHR)×γ. Alternatively, when the sum of the heights BH of the beads 22-1, 22-2 and 22-3 is expressed by BH+BHn and BTR>BH+BHn holds, the arithmetic device 4 corrects the pitch KP stored in the database, to KP'=KP+(BH+BHn-BTR)×δ. γ and δ are numerical values of 1 or more and 2 or less and are arbitrarily set numerical values. The arithmetic device 4 stores, in the database, the corrected pitch KP', and γ and δ set in calculating the pitch KP'.""]",68,629,view,B,"[{'element_identifier': '22', 'terms': ['bead', 'beads']}, {'element_identifier': '2', 'terms': ['substrate']}, {'element_identifier': '20', 'terms': ['laser beam']}, {'element_identifier': '21', 'terms': ['tip']}, {'element_identifier': '31', 'terms': ['structure']}, {'element_identifier': '32', 'terms': ['deposit']}]","['1. An additive manufacturing apparatus (1) for building a deposit on a substrate (2), the apparatus comprising: a feeding unit (6, 8) to feed a build material (7) to a feeding position; an irradiation unit (10, 11, 12) to irradiate the feeding position with a laser beam that melts the build material; a control unit (3) to perform control for building the deposit by stacking beads formed by movement of the feeding position with respect to the substrate and melting of the build material; and an arithmetic unit (4) to execute an arithmetic process of computing parameters for the control unit to perform the control, wherein the beads include two beads (22-1, 22-2) stacked on each other, the two beads are a first bead (22-1) and a second bead (22-2) stacked on the first bead, the first bead being formed earlier than the second bead, the feeding position being a first position (C1) in formation of the first bead, the feeding positon being a second position (C2) in formation of the second bead, characterized in that the arithmetic unit calculates an interval (KS) between the first position and the second position in a set direction on a basis of a width (BW) of the first bead and a diameter (LD) of the laser beam, the set direction being a direction of the width of the first bead, and the control unit performs control for setting the second position to a position shifted from the first position in the set direction by the interval, so as to allow a part of the second bead to protrude from the first bead in the set direction.', '8. The additive manufacturing method according to claim 7, comprising: a step of building a first deposit by stacking the beads when the set direction is a first set direction (A); a step of building a second deposit extending toward the first deposit by stacking the beads when the set direction is a second set direction (B); and a step of building a single structure by connecting the first deposit and the second deposit above the substrate.']",True,"['2', '2', '2', '20', '21', '2', '31', '20', '22', '31', '32', '2', '2', '25']" 156,EP_3560650_B1 (6).png,EP3560650B1,ADDITIVE MANUFACTURING APPARATUS AND ADDITIVE MANUFACTURING METHOD,"['FIG20', ' FIG21']","['FIG20 is a view for explaining building of a deposit by the additive manufacturing apparatus according to a sixth embodiment of the present invention ', 'FIG21 is a view for explaining building of a deposit by the additive manufacturing apparatus according to a first modification of the sixth embodiment of the present invention']","['FIG20 is a view for explaining building of a deposit by the additive manufacturing apparatus 1 according to a sixth embodiment of the present invention. In the sixth embodiment, the additive manufacturing apparatus 1 stacks beads 33A in the oblique direction while stacking beads 33B in the vertical direction. The additive manufacturing apparatus 1 stacks the beads 33A in the oblique direction such that a deposit of the bead 33A reaches a deposit of the bead 33B located ahead in the set direction. As a result, the additive manufacturing apparatus 1 can build a lid-like structure 34 extending from the substrate 2 to an upper surface of the deposit of the bead 33B. ', 'FIG21 is a view for explaining building of a deposit by the additive manufacturing apparatus 1 according to a first modification of the sixth embodiment of the present invention. In the first modification of the sixth embodiment, the additive manufacturing apparatus 1 stacks the beads 33A in the oblique direction such that a deposit of the bead 33A reaches a structure 34B located ahead in the set direction. The structure 34B may be a structure placed on the substrate 2 or may be an upward protruding portion of the substrate 2.']",52,215,view,B,"[{'element_identifier': '35', 'terms': ['lid-like structure']}, {'element_identifier': '2', 'terms': ['substrate']}, {'element_identifier': '34', 'terms': ['lid-like structure']}]","['1. An additive manufacturing apparatus (1) for building a deposit on a substrate (2), the apparatus comprising: a feeding unit (6, 8) to feed a build material (7) to a feeding position; an irradiation unit (10, 11, 12) to irradiate the feeding position with a laser beam that melts the build material; a control unit (3) to perform control for building the deposit by stacking beads formed by movement of the feeding position with respect to the substrate and melting of the build material; and an arithmetic unit (4) to execute an arithmetic process of computing parameters for the control unit to perform the control, wherein the beads include two beads (22-1, 22-2) stacked on each other, the two beads are a first bead (22-1) and a second bead (22-2) stacked on the first bead, the first bead being formed earlier than the second bead, the feeding position being a first position (C1) in formation of the first bead, the feeding positon being a second position (C2) in formation of the second bead, characterized in that the arithmetic unit calculates an interval (KS) between the first position and the second position in a set direction on a basis of a width (BW) of the first bead and a diameter (LD) of the laser beam, the set direction being a direction of the width of the first bead, and the control unit performs control for setting the second position to a position shifted from the first position in the set direction by the interval, so as to allow a part of the second bead to protrude from the first bead in the set direction.']",True,"['34', '2', '2', '35', '2', '26']" 157,EP_3560816_B1 (5).png,EP3560816B1,SAIL FAIRING EDGE HANDHOLD,['FIG7'],"['FIG7 is a simplified top view of an example rotorcraft having example fairing edge handholds on each side of the example rotorcraft, in accordance with certain embodiments ']","['Referring to FIG7, FIG7 is a simplified top view of an example rotorcraft having example fairing edge handholds on each side of the example rotorcraft, in accordance with certain embodiments. In particular, FIG7 illustrates a top view of a portion of a rotorcraft 700 and its rotor system 702. The rotorcraft 700 may include an upper fairing assembly 714a and a lower fairing assembly 714b. The upper fairing assembly 714a may include a first fairing edge handhold 730a on a first side 750a of the rotorcraft 700 and a second fairing edge handhold 730b on a second side 750b of the rotorcraft 700. The first and second fairing edge handholds 730a, 730b may be aft of at least a portion of the rotor system 702 (e.g., the rotor hub, certain rotating rotor flight controls, etc.) along the edges of the upper fairing 714a of the rotorcraft 700.']",28,162,simplified view,B,"[{'element_identifier': '702', 'terms': ['rotor system']}, {'element_identifier': '700', 'terms': ['rotorcraft']}]","['1. A sail fairing (114a) for a rotorcraft (100) comprising: a fairing edge (220) that includes: a first edge portion (220a) configured to provide a first clearance distance (222a) between the fairing (114a) and rotor controls (216) of the rotorcraft (100); and a second edge portion (220b) configured to provide a second clearance distance (222b) between the fairing (114a) and the rotor controls of the rotorcraft (100), wherein the second clearance distance (222b) is greater than the first clearance distance (222a) to provide a clearance width (232) that represents a cutout distance measured between the first edge portion (220a) and the second edge portion (220b) and that is sufficient for a person to engage one or more hands along the second edge portion (220b) while allowing the rotor controls (216) to rotate without contacting the one or more hands engaged along the second edge portion (220b); and a support structure (224) attached to an attachment interface (238) of the fairing (114a) below the second edge portion (220b); wherein the second edge portion (220b) and the support structure (224) provide a handhold (230) configured to support a hand traffic load on the fairing (114a).']",False,"['702', '700', '7', '18']" 158,EP_3562205_B1 (1).png,EP3562205B1,TECHNIQUES FOR HANDLING NETWORK TRAFFIC,['FIG2'],['FIG2 schematically illustrates an example of a data packet as used in an embodiment of the invention'],"['FIG2 schematically illustrates IP data packets of the IP version 4 type. As illustrated, a header section of the data packets includes several information fields, which are referred to as ""Version"", ""IHL (IP Header Length)"", ""Differentiated Services"", ""Total Length"", ""Identification"", ""Flags"", ""Fragment Offset"", ""Time to Live"", ""Protocol"", ""Header Checksum"" ""Source Address"", ""Destination Address"", ""Options"", and ""Padding"". Details concerning these fields are defined in the RFC 791 Specification. The information field termed as ""Differentiated Services"" is defined in the RFC 2475 Specification. In addition, the header section of an IP data packet will also include information fields which are referred to as ""Source Port"" and ""Destination Port"". Corresponding information fields are defined, for example, by the Transport Control Protocol (TCP) defined in the RFC 793 Specification and the User Datagram Protocol (UDP) as defined in the RFC 768 Specification.']",17,201,schematic,B,"[{'element_identifier': '24', 'terms': ['transport node']}, {'element_identifier': '8', 'terms': ['signalling path']}, {'element_identifier': '30', 'terms': ['policy controller']}, {'element_identifier': '5', 'terms': ['signalling path', 'signalling paths']}, {'element_identifier': '12', 'terms': ['client/peer applications']}, {'element_identifier': '14', 'terms': ['receiver']}, {'element_identifier': '22', 'terms': ['RAN']}, {'element_identifier': '4', 'terms': ['IP version', 'signalling path']}, {'element_identifier': '2', 'terms': ['path']}, {'element_identifier': '6', 'terms': ['signalling path', 'IP version']}, {'element_identifier': '16', 'terms': ['transmitter']}, {'element_identifier': '10', 'terms': ['user equipment']}, {'element_identifier': '26', 'terms': ['gateway']}, {'element_identifier': '23', 'terms': ['3GPP Technical Specification']}]","['1. A method of handling network traffic, the method carried out by a system with a communication device (10), a policy controller (30) and a gateway (26), wherein the method comprises: receiving (210), at the policy controller, packet inspection data indicating service-related data traffic of a user and/or a service; receiving (220), at the policy controller, policy data of said user and/or said service; determining (230), at the policy controller on the basis of said packet inspection data and said policy data, a packet filter (72, 74) configured to filter data traffic on the basis of an identifier included into data packets of said service-related data traffic in response to packet inspection; signalling, from the policy controller towards the gateway, the determined packet filter (72, 74); routing, from the gateway and using the packet filter, data packets with the identifier to one of a plurality of bearers (52, 54); receiving (310), at the communication device, incoming data packets from one of a plurality of bearers (52, 54), the data packets with the identifier and including a further first identifier; detecting (320), at the communication device, outgoing data packets including a further second identifier which is complementary with respect to the further first identifier; and routing (330), from the communication device, the detected outgoing data packets having the further second identifier to the same bearer (52, 54) from which the incoming data packets having the further first identifier are received.', '6. The method according to any one of claims 1 to 5, wherein the communication device is a user equipment, UE, (10).']",False,"['0', '1', '2', '3', '4', '5', '6', '7', '8', '10', '11', '12', '13', '14', '15', '16', '17', '18', '19', '20', '21', '22', '23', '24', '25', '26', '27', '28', '29', '30', '31', '15', '2']" 159,EP_3562205_B1 (2).png,EP3562205B1,TECHNIQUES FOR HANDLING NETWORK TRAFFIC,['FIG3'],['FIG3 schematically illustrates a further example of a data packet as used in an embodiment of the invention'],"['FIG3 schematically illustrates IP data packets according to the IP version 6 type. Again, the header section includes a number of information fields, which are referred to as ""Version"", ""Differentiated Services"", ""Flow Label"", ""Payload Length"", ""Next Header"", ""Hop Limit"", ""Source Address"", and ""Destination Address"". This structure of the header section is defined in the RFC 2460 Specification. In addition, the header section may also comprise information fields termed as ""Source Port"" and ""Destination Port"", e.g. as defined by the TCP or UDP. Again, the header section will typically be followed by a data section which may carry various types of payload data.']",18,139,schematic,B,"[{'element_identifier': '24', 'terms': ['transport node']}, {'element_identifier': '8', 'terms': ['signalling path']}, {'element_identifier': '30', 'terms': ['policy controller']}, {'element_identifier': '5', 'terms': ['signalling path', 'signalling paths']}, {'element_identifier': '12', 'terms': ['client/peer applications']}, {'element_identifier': '14', 'terms': ['receiver']}, {'element_identifier': '22', 'terms': ['RAN']}, {'element_identifier': '4', 'terms': ['IP version', 'signalling path']}, {'element_identifier': '2', 'terms': ['path']}, {'element_identifier': '6', 'terms': ['signalling path', 'IP version']}, {'element_identifier': '16', 'terms': ['transmitter']}, {'element_identifier': '10', 'terms': ['user equipment']}, {'element_identifier': '26', 'terms': ['gateway']}, {'element_identifier': '23', 'terms': ['3GPP Technical Specification']}]","['1. A method of handling network traffic, the method carried out by a system with a communication device (10), a policy controller (30) and a gateway (26), wherein the method comprises: receiving (210), at the policy controller, packet inspection data indicating service-related data traffic of a user and/or a service; receiving (220), at the policy controller, policy data of said user and/or said service; determining (230), at the policy controller on the basis of said packet inspection data and said policy data, a packet filter (72, 74) configured to filter data traffic on the basis of an identifier included into data packets of said service-related data traffic in response to packet inspection; signalling, from the policy controller towards the gateway, the determined packet filter (72, 74); routing, from the gateway and using the packet filter, data packets with the identifier to one of a plurality of bearers (52, 54); receiving (310), at the communication device, incoming data packets from one of a plurality of bearers (52, 54), the data packets with the identifier and including a further first identifier; detecting (320), at the communication device, outgoing data packets including a further second identifier which is complementary with respect to the further first identifier; and routing (330), from the communication device, the detected outgoing data packets having the further second identifier to the same bearer (52, 54) from which the incoming data packets having the further first identifier are received.', '6. The method according to any one of claims 1 to 5, wherein the communication device is a user equipment, UE, (10).']",False,"['2', '3', '4', '5', '6', '7', '8', '9', '10', '11', '12', '13', '14', '15', '16', '17', '18', '19', '20', '21', '22', '23', '24', '25', '26', '27', '28', '29', '30', '31', '16', '3']" 160,EP_3562642_B1 (1).png,EP3562642B1,DOUBLE SEAL VALVE PIN TIP WITH VENT,['FIG2'],['FIG2 is an enlarged fragmentary view of the tip of the nozzle and complementary mold aperture components of the FIG1 system'],"['As shown in FIG2, the apparatus 10 includes a nozzle assembly (200) that routs the injection fluid material (23) to the mold cavity (80). The nozzle assembly (200) comprises a nozzle tip (210) disposed and typically screwably attached to or at the distalmost end of the nozzle body 50. The assembly comprises a distal projection (220) having a downstream central bore (230) that communicates with the upstream fluid delivery channel (27). The central bore 230 has an inner surface (230is) adapted to slidably receive a complementary in shape outer surface (90os) of a distal end (90de) of the valve pin (90).']",21,130,enlarged view,B,"[{'element_identifier': '210', 'terms': ['nozzle tip']}, {'element_identifier': '230', 'terms': ['bore']}, {'element_identifier': '400', 'terms': ['flat', 'recess']}, {'element_identifier': '90', 'terms': ['pin']}, {'element_identifier': '300', 'terms': ['gate']}, {'element_identifier': '200', 'terms': ['assembly']}]","['1. An assembly (200) for routing an injection fluid (23) to a mold cavity (80) in an injection molding apparatus (10) comprised of an injection molding machine (20), a heated manifold (30) that receives the injection fluid (23), and a valve pin (90) drivable along an upstream and downstream path of travel (UD) through a fluid delivery channel (27) leading to a cavity (80) of a mold (310a, 310b), comprising: a distal nozzle tip (210) comprising a distal projection (220) having an outer circumferential surface (220ocs) and a central bore (230) that communicates with the fluid delivery channel (27) and having an inner surface (220is) adapted to receive a distal end (90de) of the valve pin (90), a mold (310a, 310b) having a cavity entrance aperture (300) forming a gate through which the injection fluid (23) is routed into the cavity (80), the cavity entrance aperture (300) having a downstream inner circumferential surface (300ics), characterised by the distal nozzle tip (210) being mounted such that the distal projection (220) is disposed in a stationary position within the cavity entrance aperture (300) wherein the outer circumferential surface (220ocs) of the distal nozzle tip (210) is disposed adjacent the downstream inner circumferential surface (300ics) forming a gap (Z) having a width sufficient to enable air or gas to flow upstream (AU1) through the gap (Z) upon downstream movement (D) of the distal end (90de) of the valve pin (90) through the central bore (230) of the distal projection (220).']",True,"['90', '310', '2', '200', '210', '90', '400', '22', '230', '300', '3', '11']" 161,EP_3563905_B1 (5).png,EP3563905B1,EXTERNAL CONTROLLER FOR AN IMPLANTABLE MEDICAL DEVICE WITH DUAL MICROCONTROLLERS FOR IMPROVED GRAPHICS RENDERING,['FIG6'],['FIG6 shows in flow chart form a technique for processing telemetry data in an external controller with dual microcontrollers according to one embodiment'],"['FIG6 summarizes the technique as discussed so far in flow chart form. The external controller 400 receives telemetry data from the implantable device, or user input from the user interface, at the low speed microcontroller 410 (step 630). The low speed microcontroller 410 then converts the received data into commands in accordance with a command protocol (step 640). The commands are then transmitted from the low speed microcontroller 410 to the high speed microcontroller 420 via the control bus 427(step 650). Once the high speed microcontroller 420 receives the commands, it interprets the commands, and retrieves the corresponding image files from the storage device 430 (step 660). The high speed microcontroller 420 then renders the images on the display screen 440 (block 670).', 'Therefore, in another embodiment of the technique, data received at the low speed microcontroller 410 is assessed to determine whether it requires further processing prior to command generation and rendering on the display 440. If so, i.e., if the telemetered data is relatively complicated and requires significant processing prior to rendering onto the display 440, such as with the resistance values discussed above, such data is sent by the low speed microcontroller 410 to the high speed microcontroller 420 for such processing, which processed data is then sent back to the low speed microcontroller 410 to be converted into graphical commands. By contrast, if the received data is relatively simple and is ready to be displayed to the patient with only minimal processing, such as IPG battery status, the low speed microcontroller 410 processes the data pursuant to the flow of FIG6 discussed above.', 'The data transmitted to the high speed microcontroller 420 is then processed (step 730), and transmitted back to the low speed microcontroller 410 via the data bus (step 740). At this point, it can be combined with any received data held at the low speed microcontroller 410 and converted to a graphics command (640); transmitted to the high speed microcontroller 420 (650); used to retrieve images at the high speed microcontroller 420 (660); and rendered on the display 440 (670), as described above with respect to FIG6. In the resistance value example discussed earlier, location data would comprise attributes accompanying the graphics command at step 640.']",23,429,in flowchart flowchart form,A,"[{'element_identifier': '640', 'terms': ['command']}, {'element_identifier': '6', 'terms': ['disclosed in U.S. Patent']}]","['1. A method for rendering graphics on a display (440) of an external medical device (400), comprising: (a) receiving at a first microcontroller (410) input data telemetered from an implantable medical device, the input data indicative of at least one graphic to be rendered on the display; (b) transmitting at least a first part of the input data from the first microcontroller to a second microcontroller (420); (c) processing the at least first part of the input data at the second microcontroller; (d) transmitting the processed data to the first microcontroller; (e) converting at least the processed data to a graphics command at the first microcontroller; (f) transmitting the graphics command to the second microcontroller; (g) retrieving at least one image file from a storage device using the graphics command; and (h) using the second microcontroller to render the at least one image file on the display.']",False,"['600', '630', '640', '650', '6', '660', '670', '15']" 162,EP_3564498_B1.png,EP3564498B1,TURBOFAN ENGINE WITH OIL TANK FILLING SYSTEM,['FIG1'],['FIG1 is a sectional side view of a gas turbine engine'],"['FIG1 illustrates a gas turbine engine 10, more particularly a turbofan engine, having a principal rotational axis 9. The engine 10 comprises an air intake 12 and a propulsive fan 23 that generates two airflows: a core airflow A and a bypass airflow B. The gas turbine engine 10 comprises a core 11 that receives the core airflow A. The engine core 11 comprises, in axial flow series, a low pressure compressor 14, a high pressure compressor 15, combustion equipment 16, a high-pressure turbine 17, a low pressure turbine 19 and a core exhaust nozzle 20. A fan nacelle 21 surrounds the fan case of the gas turbine engine 10 and defines a bypass duct 22 and a bypass exhaust nozzle 18. The bypass airflow B flows through the bypass duct 22. The fan 23 is attached to and driven by the low pressure turbine 19 via a shaft 26 and an epicyclic gearbox 30.', 'Other turbofan engines to which the present disclosure may be applied may have alternative configurations. For example, such engines may have an alternative number of compressors and/or turbines and/or an alternative number of interconnecting shafts. By way of further example, the gas turbine engine shown in FIG1 has a split flow nozzle 18, 20 meaning that the flow through the bypass duct 22 has its own nozzle 18 that is separate to and radially outside the core engine nozzle 20. However, this is not limiting, and any aspect of the present disclosure may also apply to engines in which the flow through the bypass duct 22 and the flow through the core 11 are mixed, or combined, before (or upstream of) a single nozzle, which may be referred to as a mixed flow nozzle. One or both nozzles (whether mixed or split flow) may have a fixed or variable area. In some arrangements, the gas turbine engine 10 may not comprise a gearbox 30.', 'The geometry of the gas turbine engine 10, and components thereof, is defined by a conventional axis system, comprising an axial direction (which is aligned with the rotational axis 9), a radial direction (in the bottom-to-top direction in FIG1), and a circumferential direction (perpendicular to the page in the FIG1 view). The axial, radial and circumferential directions are mutually perpendicular.']",11,434,sectional side view,F,"[{'element_identifier': '28', 'terms': ['sun gear']}, {'element_identifier': '30', 'terms': ['gearbox']}, {'element_identifier': '34', 'terms': ['planet carrier']}, {'element_identifier': '16', 'terms': ['combustion equipment']}, {'element_identifier': '10', 'terms': ['engine']}, {'element_identifier': '26', 'terms': ['shaft']}, {'element_identifier': '21', 'terms': ['fan nacelle']}, {'element_identifier': '36', 'terms': ['linkages']}, {'element_identifier': '23', 'terms': ['fan']}]","['1. A turbofan engine (10) that has a core (11), an aft core cowl, and an oil tank filling system (50), the oil tank filling system comprising: an oil tank (52) that has an oil tank top (66) and an oil tank bottom (68) and is located within the core (11) of the turbofan engine (10); and an oil access port (55); characterized in that : the oil access port (55) is located on the aft core cowl; and in that the oil tank filling system has an oil tank filling pipe (56) that leads from the oil access port (55) to a tank filling port (58) located at or adjacent the oil tank bottom (68), and oil that is supplied to the oil access port (55) flows to and into the oil tank (52) using gravitational force.', '12. The turbofan engine of any preceding claim wherein the core (11) comprises a turbine (17,19), a compressor (14,15), and a core shaft (26) connecting the turbine to the compressor; a fan (23) located upstream of the core, the fan comprising a plurality of fan blades and a gearbox (30) that receives an input from the core shaft and outputs drive to the fan so as to drive the fan at a lower rotational speed than the core shaft.']",True,"['10', '21', '23', '26', '23', '36', '30', '26', '28', '34', '16']" 163,EP_3564688_B1 (1).png,EP3564688B1,GROUND FAULT DETECTION APPARATUS,['FIG2'],['FIG2 is a diagram illustrating another example of an arrangement place of a positive-electrode-side C contact switch'],"['In the aforementioned embodiments, the common contact c of the positive-electrode-side C contact switch 111 is connected to the detection capacitor C1 via the parallel circuit of the path of the diode D1 and the resistor R1 and the path of the resistor R2 and the diode D2, but, as illustrated in FIG2, the common contact c of the positive-electrode-side C contact switch 111 may be directly connected to the detection capacitor C1. In this case, it is sufficient that the contact a is connected to the resistor Ra via the diode D1 and the resistor R1, the contact b is connected to the switching element Sa via the diode D2 and the resistor R2, and the path of the diode D2 and the path of the diode D11 whose direction is opposite to that of the diode D2 and the resistor R11 are connected in parallel to each other.']",21,167,diagram,B,"[{'element_identifier': '300', 'terms': ['high-voltage battery']}, {'element_identifier': '100', 'terms': ['ground fault detection apparatus']}, {'element_identifier': '302', 'terms': ['negative-electrode-side power supply line']}, {'element_identifier': '120', 'terms': ['control device']}]","['1. A ground fault detection apparatus that is connected to a non-grounded high-voltage battery (300) and detects a ground fault of a system provided with the high-voltage battery, the ground fault detection apparatus comprising: a control unit (120); a detection capacitor (C1) that operates as a flying capacitor; a positive-electrode-side first resistor (Ra) connected to a positive-electrode side of the high-voltage battery; a negative-electrode-side first resistor (Rb) connected to a negative-electrode side of the high-voltage battery; a positive-electrode-side second resistor (R3) having a first end grounded and a second end, a voltage of the second end being measured by the control unit; a negative-electrode-side second resistor (R4) having a first end grounded; a positive-electrode-side C contact switch (111) that is formed as a twin relay having relays (111a, 111b) operating in conjunction with each other and connected in parallel, and that is configured to alternatively switch a connection destination of a first end of the detection capacitor between a path including the positive-electrode-side first resistor and a path including the positive-electrode-side second resistor based on an instruction from the control unit; a negative-electrode-side C contact switch (112) that is formed as a twin relay having relays (112a, 112b) operating in conjunction with each other and connected in parallel, and that is configured to alternatively switch a connection destination of a second end of the detection capacitor between a path including the negative-electrode-side first resistor and a path including the negative-electrode-side second resistor based on an instruction from the control unit; and a path switching C contact switch (113) formed as a twin relay having relays configured to operate in conjunction with each other, one (113a) of the relays of the path switching C contact switch being configured to switch one of the relays of the positive-electrode-side C contact switch to the connection destination of the first end of the detection capacitor, and another one (113b) of the relays of the path switching C contact switch being configured to switch one of the relays of the negative-electrode-side C contact switch to a connection destination of the second end of the detection capacitor.']",False,"['100', '120', '300', '302', '15']" 164,EP_3564688_B1.png,EP3564688B1,GROUND FAULT DETECTION APPARATUS,['FIG1'],['FIG1 is a block diagram illustrating a configuration of a ground fault detection apparatus according to an embodiment of the present invention'],"['Embodiments of the present invention will be described in detail with reference to the drawings. FIG1 is a block diagram illustrating a configuration of a ground fault detection apparatus 100 according to an embodiment of the present invention. As shown, the ground fault detection apparatus 100 is a flying capacitor type apparatus which is connected to a non-grounded high-voltage battery 300 and detects a ground fault of a system provided with the high-voltage battery 300. Herein, an insulation resistor between a positive-electrode side of the high-voltage battery 300 and a ground is represented as RLp, and an insulation resistor between a negative-electrode side of the high-voltage battery 300 and the ground is represented as RLn. High voltage means a voltage higher than a low-voltage battery (generally 12 V) for driving various devices (lamps, wipers, etc.) in a vehicle, and the high-voltage battery 300 is a battery used for driving of a vehicle travelling.', 'As illustrated in FIG1, the positive-electrode-side C contact switch 111 and the negative-electrode-side C contact switch 112 are independently controlled and switched by the control device 120. The control device 120 switches the measurement path by controlling switching of the positive-electrode-side C contact switch 111, the negative-electrode-side C contact switch 112, and the switching element Sa independently, and performs charging and discharging of the detection capacitor C1 and measuring a charging voltage.', 'Further, in the example of this figure, a parallel resistor of the resistor Ra11 and the resistor Ra12 plays a role of the resistor Ra, and a parallel resistor of the resistor Rb11 and the resistor Rb12 plays the role of the resistor Rb. Therefore, in the case of using the same resistance as in FIG1, resistance Ra11 = resistance Ra12 = resistance Rb11 = resistance Rb12 = 2 × the resistance Ra = 2 × resistance Rb.']",22,368,block diagram,B,"[{'element_identifier': '100', 'terms': ['ground fault detection apparatus']}, {'element_identifier': '302', 'terms': ['negative-electrode-side power supply line']}, {'element_identifier': '300', 'terms': ['high-voltage battery']}, {'element_identifier': '112', 'terms': ['negative-electrode-side C contact switch']}, {'element_identifier': '120', 'terms': ['control device']}]","['1. A ground fault detection apparatus that is connected to a non-grounded high-voltage battery (300) and detects a ground fault of a system provided with the high-voltage battery, the ground fault detection apparatus comprising: a control unit (120); a detection capacitor (C1) that operates as a flying capacitor; a positive-electrode-side first resistor (Ra) connected to a positive-electrode side of the high-voltage battery; a negative-electrode-side first resistor (Rb) connected to a negative-electrode side of the high-voltage battery; a positive-electrode-side second resistor (R3) having a first end grounded and a second end, a voltage of the second end being measured by the control unit; a negative-electrode-side second resistor (R4) having a first end grounded; a positive-electrode-side C contact switch (111) that is formed as a twin relay having relays (111a, 111b) operating in conjunction with each other and connected in parallel, and that is configured to alternatively switch a connection destination of a first end of the detection capacitor between a path including the positive-electrode-side first resistor and a path including the positive-electrode-side second resistor based on an instruction from the control unit; a negative-electrode-side C contact switch (112) that is formed as a twin relay having relays (112a, 112b) operating in conjunction with each other and connected in parallel, and that is configured to alternatively switch a connection destination of a second end of the detection capacitor between a path including the negative-electrode-side first resistor and a path including the negative-electrode-side second resistor based on an instruction from the control unit; and a path switching C contact switch (113) formed as a twin relay having relays configured to operate in conjunction with each other, one (113a) of the relays of the path switching C contact switch being configured to switch one of the relays of the positive-electrode-side C contact switch to the connection destination of the first end of the detection capacitor, and another one (113b) of the relays of the path switching C contact switch being configured to switch one of the relays of the negative-electrode-side C contact switch to a connection destination of the second end of the detection capacitor.']",False,"['100', '14', '120', '300', '112', '302']" 165,EP_3566142_B1 (3).png,EP3566142B1,RUN-TIME INSTRUMENTATION OF GUARDED STORAGE EVENT PROCESSING,['FIG8'],"['FIG8 depicts one embodiment of a Load Guarded instruction, in accordance with a preferred embodiment of the present invention']","['One example of a Load Guarded (LGG) instruction is described with reference to FIG8. A Load Guarded instruction 800 includes, for instance, operation code (opcode) fields 802a, 802b to designate a load guarded operation; a register field (R1) 804; an index field (X2) 806; a base field (B2) 808; and a displacement field comprising a first displacement (DL2) field 810a and a second displacement (DH2) field 810b. The contents of the second displacement field and the first displacement field are concatenated to provide a displacement, which is treated as a 20-bit signed binary integer, in one example.']",20,125,embodiment,G,"[{'element_identifier': '704', 'terms': ['contents']}, {'element_identifier': '900', 'terms': ['Shift Guarded instruction']}, {'element_identifier': '908', 'terms': ['B2']}, {'element_identifier': '9', 'terms': ['April', 'control register']}, {'element_identifier': '63', 'terms': ['through']}, {'element_identifier': '706', 'terms': ['contents']}, {'element_identifier': '702', 'terms': ['includes contents']}, {'element_identifier': '0', 'terms': ['bit', 'bits']}, {'element_identifier': '906', 'terms': ['X2']}, {'element_identifier': '800', 'terms': ['Load Guarded instruction']}, {'element_identifier': '32', 'terms': ['bits', 'bit']}, {'element_identifier': '808', 'terms': ['B2']}, {'element_identifier': '806', 'terms': ['X2']}]","['2. The method of claim 1, wherein the instruction is a load guarded instruction(800), the load guarded instruction used to determine whether the guarded storage event exists.', '3. The method of either of the preceding claims, wherein the instruction is a load logical and shift guarded instruction (900), the load logical and shift guarded instruction used to determine whether the guarded storage event exists.']",True,"['700', '702', '704', '706', '63', '800', '12', '16', '20', '32', '40', '8', '47', '804', '806', '808', '900', '0', '8', '12', '16', '20', '32', '40', '9', '47', '904', '906', '908', '32']" 166,EP_3566409_B1 (2).png,EP3566409B1,PAGING IN A WIRELESS COMMUNICATION SYSTEM,['FIG5'],['FIG5 is a logic flow diagram of a method performed by a wireless device according to other embodiments'],"['Alternatively or additionally, when the wireless communication device 16 is configured for performing the processing described in FIG5, The receiving unit or module 800 may be for receiving a page 18 that includes a paging identifier 18A for the wireless device 16. The paging identifier 18A may identify as a target of the page 18 a wireless device 16 associated with a particular subscriber. In fact, in some embodiments, the paging identifier 18A is based on an encrypted subscription identifier for the wireless device 16 or is a pseudonym subscription identifier for the wireless device16. In any event, the transmitting unit or module 800 in this case may be for transmitting a response 22 to the page 18 that indicates the wireless device 16 was paged but that includes an identifier 22A for the wireless device 16 that is different than the paging identifier 18A included in the page 18.']",18,159,lflow diagram,H,"[{'element_identifier': '24', 'terms': ['as described in TS']}, {'element_identifier': '400', 'terms': ['encrypted UE_LTID is around', 'each']}, {'element_identifier': '4', 'terms': ['filed January']}, {'element_identifier': '20', 'terms': ['node']}, {'element_identifier': '16', 'terms': ['device', 'devices']}]","['1. A method performed by a wireless device (16), the method comprising: receiving (400) from a network node (20) a page (18) that includes a paging identifier (18A) for the wireless device (16), wherein the paging identifier (18A) either is based on an encrypted subscription identifier for the wireless device (16) or is a pseudonym subscription identifier for the wireless device (16); and transmitting (410) to the network node (20) a response (22) to the page (18) that indicates the wireless device (16) was paged, characterised in that the response includes an identifier (22A) for the wireless device (16) that is different than the paging identifier (18A) included in the page (18).']",True,"['20', '16', '400', '300', '24', '310', '410', '4', '5']" 167,EP_3566546_B1 (1).png,EP3566546B1,"A RETROFIT LIGHT EMITTING DIODE, LED, TUBE FOR REPLACING A FLUORESCENT TUBE",['FIG3'],['FIG3 shows a simplified block diagram of a lighting system according to the present disclosure'],"['FIG3 shows a simplified block diagram of a lighting system 21 according to the present disclosure.', 'The block diagram depicted in FIG3 may be implemented using a hardware only approach or a hardware / software combination approach. Preferably, a hardware software combination approach is used as this is beneficial for the accuracy of the measurements and as this is beneficial for the size of each of the components.']",15,73,simplified block diagram,F,"[{'element_identifier': '28', 'terms': ['LED array']}, {'element_identifier': '24', 'terms': ['matching circuit']}, {'element_identifier': '22', 'terms': ['ballast']}, {'element_identifier': '29', 'terms': ['load adaptor']}, {'element_identifier': '3', 'terms': ['horizontal axis']}, {'element_identifier': '25', 'terms': ['second matching circuit']}, {'element_identifier': '31', 'terms': ['current monitor']}, {'element_identifier': '33', 'terms': ['voltage monitor']}, {'element_identifier': '27', 'terms': ['power rectifier']}, {'element_identifier': '26', 'terms': ['bypass switch']}, {'element_identifier': '21', 'terms': ['lighting system']}, {'element_identifier': '23', 'terms': ['filament emulation circuit']}, {'element_identifier': '32', 'terms': ['network selector']}]","['1. A retrofit Light Emitting Diode, LED, tube for replacing a fluorescent tube, wherein said retrofit LED tube is arranged to be connected to a ballast, said retrofit LED tube comprising: - an LED array (28) for emitting light; characterised in that the retrofit LED tube further comprises - a configurable matching circuit (24, 25) for controlling input power from a connected ballast (22), when connected, towards said LED array (28); - a power rectifier (27) having an input connected to said matching circuit (24, 25) and an output connected to said LED array (28), wherein said power rectifier (27) is arranged to receive an AC supply voltage at its input, to convert said AC supply voltage to a DC voltage, and to provide said DC voltage, via its output, to said LED array (28); - a ballast determining unit (29, 30, 31, 32, 33) arranged for identifying a type of ballast connected to said retrofit LED tube by: - controlling an output voltage of said power rectifier (27) to a first voltage and measuring a first current provided by said power rectifier (27); - controlling said output voltage of said power rectifier (27) to a second voltage and measuring a second current provided by said power rectifier (27), wherein said second voltage differs from said first voltage; - determining said type of ballast based on said first and second output voltages and said measured first and second currents; wherein said ballast determining unit (29, 30, 31, 32, 33) is further arranged to configure said configurable matching circuit (24, 25) based on said determined type of ballast.', '3. A retrofit LED tube according to any of the previous claims, wherein said configurable matching circuit comprises two matching circuits: - a first matching circuit matched to a self-oscillating ballast, and - a second matching circuit matched to a Integrated Circuit, IC, controlled ballast, wherein said ballast determining unit is arranged to select one of said two matching circuits based on said determined type of ballast.', '15. A lighting system, comprising: - a retrofit LED lamp tube according to any of the claims 1 - 7, and - a ballast, wherein said ballast is connected to said retrofit LED tube.']",False,"['21', '24', '27', '28', '30', '33', '26', '29', '31', '22', '23', '25', '32', '3', '16']" 168,EP_3566653_B1 (1).png,EP3566653B1,MAMMOGRAPHY APPARATUS,['FIG4'],['FIG4 is a diagram illustrating an X-ray imaging panel or the like provided inside the imaging stand'],"['The column 11 fixes the X-ray imaging unit or the like at a predetermined position in a predetermined direction on a floor face. The X-ray irradiation section 12 includes an X-ray tube that generates X-rays, and irradiates an X-ray imaging panel 41 (see FIG4) provided inside the imaging stand 13 with X-rays.', 'As shown in FIG4, the imaging stand 13 includes the X-ray imaging panel 41, a switching circuit 42, a first reading circuit 43A, and a second reading circuit 43B.']",19,105,diagram,A,"[{'element_identifier': '17', 'terms': ['lifting section']}, {'element_identifier': '35', 'terms': ['recess']}, {'element_identifier': '46', 'terms': ['flexible board']}, {'element_identifier': '22', 'terms': ['lower face']}, {'element_identifier': '3', 'terms': ['larger than']}, {'element_identifier': '34', 'terms': ['fourth ridge portion']}, {'element_identifier': '31', 'terms': ['first ridge portion']}, {'element_identifier': '33', 'terms': ['third ridge portion']}, {'element_identifier': '42', 'terms': ['switching circuit']}, {'element_identifier': '41', 'terms': ['X-ray imaging panel']}, {'element_identifier': '21', 'terms': ['upper face']}, {'element_identifier': '36', 'terms': ['boundary line']}, {'element_identifier': '23', 'terms': ['contact face']}, {'element_identifier': '32', 'terms': ['second ridge portion']}]","['1. A mammography apparatus (10) comprising: an X-ray irradiation section (12) that irradiates an X-ray imaging panel (41) with X-rays; and an imaging stand (13) that includes the X-ray imaging panel and a control circuit (42, 43A, 43B) of the X-ray imaging panel, and is provided with an upper face (21) on which a breast of a subject is placed, a lower face (22) that is opposite to the upper face, a contact face (23) that is connected to the upper face and the lower face and comes in contact with a chest wall of the subject, a first side face (26A) and a second side face (26B) that are connected to the upper face, the lower face, and the contact face, and a recess (35) formed by cutting out at least a part of the contact face, wherein the recess has a shape in which among a first ridge portion (31) where the contact face and the upper face are connected to each other, a second ridge portion (32) where the contact face and the lower face are connected to each other, a third ridge portion (33) where the contact face and the first side face are connected to each other, and a fourth ridge portion (34) where the contact face and the second side face are connected to each other, characterized in that at least a part of the second ridge portion is cut out, and the first ridge portion, the third ridge portion, and the fourth ridge portion are not cut out.', '5. The mammography apparatus according to any one of claims 1 to 4, wherein a top of a boundary line between the recess and the contact face is disposed at the center between the first side face and the second side face, when seen from the contact face.', '13. The mammography apparatus according to any one of claims 1 to 12, wherein the recess in the contact face has a length that is equal to or larger than 15% of the X-ray imaging panel.']",True,"['3', '21', '31', '32', '23', '34', '35', '36', '33', '22', '4', '42', '46', '46', '41', '46', '17']" 169,EP_3566653_B1 (2).png,EP3566653B1,MAMMOGRAPHY APPARATUS,['FIG6'],['FIG6 is a diagram illustrating a disposition of an X-ray imaging panel or the like in the imaging stand'],"['As the first reading circuit 43A and the second reading circuit 43B are disposed on the rear side of the X-ray imaging panel 41, as shown in FIG6, the imaging stand 13 has a configuration in which an interval between the first side face 26A and the second side face 26B on the side of the contact face 23 (X-directional positive side) is narrower than that on the side of the column 11 (X-directional negative side). Accordingly, in the vicinity of the contact face 23 where the interval between the first side face 26A and the second side face 26B is narrow, the imaging stand 13 has a non-image region 49 of a small width (the length in the Y direction). The non-image region 49 is a region where an imaging face of the X-ray imaging panel 41 is not disposed, and thus, an X-ray image is not taken. In this embodiment, the width of the imaging stand 13 is about 360 mm, and the width of each of both the non-image regions 49 is about 30 mm. Further, in a portion of the imaging stand 13 on the side of the column 11, a support member (not shown) for connecting the imaging stand 13 to the column 11 and supporting the imaging stand 13 with respect to the column 11 is provided. Accordingly, the portion of the imaging stand 13 on the side of the column 11 has a wide interval between the first side face 26A and the second side face 26B further than that on the side of the contact face 23.']",21,306,diagram,A,"[{'element_identifier': '51', 'terms': ['region']}, {'element_identifier': '35', 'terms': ['recess']}, {'element_identifier': '46', 'terms': ['flexible board']}, {'element_identifier': '22', 'terms': ['lower face']}, {'element_identifier': '34', 'terms': ['fourth ridge portion']}, {'element_identifier': '31', 'terms': ['first ridge portion']}, {'element_identifier': '33', 'terms': ['third ridge portion']}, {'element_identifier': '42', 'terms': ['switching circuit']}, {'element_identifier': '49', 'terms': ['non-image region', 'non-image regions']}, {'element_identifier': '41', 'terms': ['X-ray imaging panel']}, {'element_identifier': '21', 'terms': ['upper face']}, {'element_identifier': '36', 'terms': ['boundary line']}, {'element_identifier': '23', 'terms': ['contact face']}, {'element_identifier': '32', 'terms': ['second ridge portion']}, {'element_identifier': '13', 'terms': ['imaging stand']}]","['1. A mammography apparatus (10) comprising: an X-ray irradiation section (12) that irradiates an X-ray imaging panel (41) with X-rays; and an imaging stand (13) that includes the X-ray imaging panel and a control circuit (42, 43A, 43B) of the X-ray imaging panel, and is provided with an upper face (21) on which a breast of a subject is placed, a lower face (22) that is opposite to the upper face, a contact face (23) that is connected to the upper face and the lower face and comes in contact with a chest wall of the subject, a first side face (26A) and a second side face (26B) that are connected to the upper face, the lower face, and the contact face, and a recess (35) formed by cutting out at least a part of the contact face, wherein the recess has a shape in which among a first ridge portion (31) where the contact face and the upper face are connected to each other, a second ridge portion (32) where the contact face and the lower face are connected to each other, a third ridge portion (33) where the contact face and the first side face are connected to each other, and a fourth ridge portion (34) where the contact face and the second side face are connected to each other, characterized in that at least a part of the second ridge portion is cut out, and the first ridge portion, the third ridge portion, and the fourth ridge portion are not cut out.', '5. The mammography apparatus according to any one of claims 1 to 4, wherein a top of a boundary line between the recess and the contact face is disposed at the center between the first side face and the second side face, when seen from the contact face.']",True,"['13', '34', '31', '46', '32', '33', '41', '23', '46', '22', '36', '35', '51', '13', '42', '46', '21', '31', '49', '23', '49', '18']" 170,EP_3566653_B1 (3).png,EP3566653B1,MAMMOGRAPHY APPARATUS,['FIG13'],['FIG13 is a diagram illustrating a position of a top of the recess'],"['In the first embodiment, when seen from the contact face 23, it is sufficient if the shape of the recess 35 is convex toward the upper face 21, but it is preferable that not only the shape of the recess 35 is convex toward the upper face 21, but also, as shown in FIG13, the top T1 of the recess 35 (that is the top T1 of the boundary line 36 between the recess 35 and the contact face 23) is disposed nearly at the center between the first side face 26A and the second side face 26B. That is, it is preferable that the top T1 is disposed on a line 77 on which the distance from the first side face 26A and the distance from the second side face 26B are approximately the same, on the contact face 23. In this way, in a case where the top T1 of the recess 35 is disposed at the center between the first side face 26A and the second side face 26B, as the chest wall 61 is in contact with the contact face 23, the subject 60 is easily guided (so-called centering) to the center of the imaging stand 13. Accordingly, in a case where the CC imaging and the MLO imaging are respectively performed with respect to the left and right breasts 62L and 62R, the subject 60 is placed at an approximately determined position with respect to the imaging stand 13 in any imaging.']",13,269,diagram,A,"[{'element_identifier': '35', 'terms': ['recess']}, {'element_identifier': '77', 'terms': ['line']}, {'element_identifier': '22', 'terms': ['lower face']}, {'element_identifier': '34', 'terms': ['fourth ridge portion']}, {'element_identifier': '31', 'terms': ['first ridge portion']}, {'element_identifier': '33', 'terms': ['third ridge portion']}, {'element_identifier': '81', 'terms': ['X-ray image']}, {'element_identifier': '21', 'terms': ['upper face']}, {'element_identifier': '36', 'terms': ['boundary line']}, {'element_identifier': '23', 'terms': ['contact face']}, {'element_identifier': '32', 'terms': ['second ridge portion']}, {'element_identifier': '13', 'terms': ['imaging stand']}]","['1. A mammography apparatus (10) comprising: an X-ray irradiation section (12) that irradiates an X-ray imaging panel (41) with X-rays; and an imaging stand (13) that includes the X-ray imaging panel and a control circuit (42, 43A, 43B) of the X-ray imaging panel, and is provided with an upper face (21) on which a breast of a subject is placed, a lower face (22) that is opposite to the upper face, a contact face (23) that is connected to the upper face and the lower face and comes in contact with a chest wall of the subject, a first side face (26A) and a second side face (26B) that are connected to the upper face, the lower face, and the contact face, and a recess (35) formed by cutting out at least a part of the contact face, wherein the recess has a shape in which among a first ridge portion (31) where the contact face and the upper face are connected to each other, a second ridge portion (32) where the contact face and the lower face are connected to each other, a third ridge portion (33) where the contact face and the first side face are connected to each other, and a fourth ridge portion (34) where the contact face and the second side face are connected to each other, characterized in that at least a part of the second ridge portion is cut out, and the first ridge portion, the third ridge portion, and the fourth ridge portion are not cut out.', '5. The mammography apparatus according to any one of claims 1 to 4, wherein a top of a boundary line between the recess and the contact face is disposed at the center between the first side face and the second side face, when seen from the contact face.']",True,"['13', '77', '13', '34', '31', '33', '21', '23', '36', '32', '35', '22', '14', '81', '22']" 171,EP_3566653_B1 (4).png,EP3566653B1,MAMMOGRAPHY APPARATUS,['FIG16'],['FIG16 is a plan view showing a straight portion of a first side face and a second side face'],"['In the first embodiment and the second embodiment, the shapes of the first side face 26A and the second side face 26B are nearly random, but as shown in FIG16, it is preferable that the first side face 26A and the second side face 26B include a straight portion 88 that crosses the contact face 23 at about 90 degrees, in at least a specific range from the contact face 23. In a case where the first side face 26A and the second side face 26B include the straight portion 88, the subject 60 can easily put an arm or the like on the first side face 26A or the second side face 26B in the MLO imaging. Specifically, there is a case where it is difficult for the subject 60 to raise the arm highly due to so-called frozen shoulder. However, even in the case of such a subject 60, in a case where the straight portion 88 is present in the first side face 26A and the second side face 26B, as long as the subject 60 can lift the arm and elbow up to about the height of the shoulder, it is possible for the subject 60 to put the arm and elbow on the first side face 26A and the second side face 26B. Further, after putting the arm and elbow on the first side face 26A and the second side face 26B, it is not necessary to continuously put excessive stress to the shoulder due to the presence of the straight portion 88, and thus, it is possible to enjoy imaging while holding the weight of the arm to the imaging stand 13. For example, in a case where the entirety of the first side face 26A and the second side face 26B are tilted toward the contact face 23 from the column 11, without the straight portion 88, it is necessary for the subject 60 to lift the arm and elbow up to the tilting angle, and thus, it is difficult to loosen tension of the shoulder in order to continuously put the arm and elbow on the first side face 26A and the second side face 26B.']",19,389,plan view,A,"[{'element_identifier': '21', 'terms': ['upper face']}, {'element_identifier': '16', 'terms': ['pressurizing plate']}, {'element_identifier': '23', 'terms': ['contact face']}, {'element_identifier': '88', 'terms': ['straight portion']}]","['1. A mammography apparatus (10) comprising: an X-ray irradiation section (12) that irradiates an X-ray imaging panel (41) with X-rays; and an imaging stand (13) that includes the X-ray imaging panel and a control circuit (42, 43A, 43B) of the X-ray imaging panel, and is provided with an upper face (21) on which a breast of a subject is placed, a lower face (22) that is opposite to the upper face, a contact face (23) that is connected to the upper face and the lower face and comes in contact with a chest wall of the subject, a first side face (26A) and a second side face (26B) that are connected to the upper face, the lower face, and the contact face, and a recess (35) formed by cutting out at least a part of the contact face, wherein the recess has a shape in which among a first ridge portion (31) where the contact face and the upper face are connected to each other, a second ridge portion (32) where the contact face and the lower face are connected to each other, a third ridge portion (33) where the contact face and the first side face are connected to each other, and a fourth ridge portion (34) where the contact face and the second side face are connected to each other, characterized in that at least a part of the second ridge portion is cut out, and the first ridge portion, the third ridge portion, and the fourth ridge portion are not cut out.', '12. The mammography apparatus according to any one of claims 1 to 11, wherein the first side face and the second side face include a straight portion that crosses the contact face at 90 degrees, in at least a specific range from the contact face.']",True,"['15', '16', '21', '88', '88', '23', '23']" 172,EP_3566653_B1 (5).png,EP3566653B1,MAMMOGRAPHY APPARATUS,"['FIG17', ' FIG18']","['FIG18 is a diagram illustrating an appropriate position of the top of the recess on the contact face ', 'FIG17 is a diagram illustrating a modification example in which a control circuit is disposed to be tilted inside the imaging stand']","['As in the first to fourth embodiments, in a case where the control circuits such as the first reading circuit 43A and/or the second reading circuit 43B are disposed on the lower face 22 side (rear side) of the X-ray imaging panel 41, it is preferable that the recess 35 is more convex toward the upper face 21 than the control circuits when looking at the imaging stand 13 from the contact face 23. Specifically, as shown in FIG18, when looking at the imaging stand 13 from the contact face 23, the recess 35 is formed so that the top T1 that is the point of the recess 35 that is the closest to the upper face 21 is disposed to be close to the upper face 21 side further than a line F1 that passes through points of the first reading circuit 43A and the second reading circuit 43B that are the closest to the lower face 22 and is parallel to the upper face 21. That is, when looking at the imaging stand 13 from the contact face 23, the recess 35 is formed to have a size that the recess 35 is inserted between the first reading circuit 43A and the second reading circuit 43B. With this configuration, it is possible to compactly form the imaging stand 13 while obtaining the action of the recess 35. Further, since the height of the recess 35 becomes high compared with a case where the top T1 is present on the lower face 22 side further than the line F1, it is possible to easily obtain the action of the recess 35 in the subject 60 of any physique. ', 'Specifically, as shown in FIG17, when looking at the imaging stand 13 from the contact face 23, by lifting an edge portion of the first reading circuit 43A on the side of the recess 35 toward the upper face 21, the edge portion on the side of the recess 35 is tilted to be close to the X-ray imaging panel 41, further than an edge portion to which the flexible board 46 is connected. Further, in the case of the second reading circuit 43B, by lifting the edge portion on the side of the recess 35 toward the upper face 21, the edge portion on the side of the recess 35 is tilted to be close to the X-ray imaging panel 41, further than an edge portion to which the flexible board 46 is connected.']",40,447,diagram,A,"[{'element_identifier': '17', 'terms': ['lifting section']}, {'element_identifier': '35', 'terms': ['recess']}, {'element_identifier': '22', 'terms': ['lower face']}, {'element_identifier': '34', 'terms': ['fourth ridge portion']}, {'element_identifier': '91', 'terms': ['region']}, {'element_identifier': '41', 'terms': ['X-ray imaging panel']}, {'element_identifier': '33', 'terms': ['third ridge portion']}, {'element_identifier': '46', 'terms': ['flexible board']}, {'element_identifier': '23', 'terms': ['contact face']}, {'element_identifier': '13', 'terms': ['imaging stand']}]","['1. A mammography apparatus (10) comprising: an X-ray irradiation section (12) that irradiates an X-ray imaging panel (41) with X-rays; and an imaging stand (13) that includes the X-ray imaging panel and a control circuit (42, 43A, 43B) of the X-ray imaging panel, and is provided with an upper face (21) on which a breast of a subject is placed, a lower face (22) that is opposite to the upper face, a contact face (23) that is connected to the upper face and the lower face and comes in contact with a chest wall of the subject, a first side face (26A) and a second side face (26B) that are connected to the upper face, the lower face, and the contact face, and a recess (35) formed by cutting out at least a part of the contact face, wherein the recess has a shape in which among a first ridge portion (31) where the contact face and the upper face are connected to each other, a second ridge portion (32) where the contact face and the lower face are connected to each other, a third ridge portion (33) where the contact face and the first side face are connected to each other, and a fourth ridge portion (34) where the contact face and the second side face are connected to each other, characterized in that at least a part of the second ridge portion is cut out, and the first ridge portion, the third ridge portion, and the fourth ridge portion are not cut out.']",True,"['17', '13', '34', '33', '41', '23', '46', '22', '46', '35', '91', '18', '13', '34', '33', '41', '23', '35', '22', '24']" 173,EP_3566653_B1 (6).png,EP3566653B1,MAMMOGRAPHY APPARATUS,['FIG19'],['FIG19 is a diagram illustrating an appropriate position of the top of the recess on the contact face in a case where the control circuit is disposed to be tilted'],"['As shown in FIG19, this is similarly applied to a case where the control circuits disposed on the lower face 22 of the X-ray imaging panel 41, such as the first reading circuit 43A and/or the second reading circuit 43B, are disposed to be tilted inside the imaging stand 13. In this case, an interval between the line F1 and the line F2 becomes larger than that in a case where the control circuits disposed on the lower face 22 side of the X-ray imaging panel 41 are disposed to be parallel to the X-ray imaging panel 41 and the upper face 21 (see FIG19). As a result, it is possible to form the recess 35 to be large compared with a case where the control circuits disposed on the lower face 22 side of the X-ray imaging panel 41 are disposed to be parallel to the X-ray imaging panel 41 and the upper face 21, and thus, it is possible to reduce stress applied to the subject 60 by reducing pressurization of the abdomen 63 due to the imaging stand 13 in the CC imaging.']",30,208,diagram,A,"[{'element_identifier': '35', 'terms': ['recess']}, {'element_identifier': '22', 'terms': ['lower face']}, {'element_identifier': '34', 'terms': ['fourth ridge portion']}, {'element_identifier': '42', 'terms': ['switching circuit']}, {'element_identifier': '41', 'terms': ['X-ray imaging panel']}, {'element_identifier': '33', 'terms': ['third ridge portion']}, {'element_identifier': '46', 'terms': ['flexible board']}, {'element_identifier': '23', 'terms': ['contact face']}, {'element_identifier': '13', 'terms': ['imaging stand']}]","['1. A mammography apparatus (10) comprising: an X-ray irradiation section (12) that irradiates an X-ray imaging panel (41) with X-rays; and an imaging stand (13) that includes the X-ray imaging panel and a control circuit (42, 43A, 43B) of the X-ray imaging panel, and is provided with an upper face (21) on which a breast of a subject is placed, a lower face (22) that is opposite to the upper face, a contact face (23) that is connected to the upper face and the lower face and comes in contact with a chest wall of the subject, a first side face (26A) and a second side face (26B) that are connected to the upper face, the lower face, and the contact face, and a recess (35) formed by cutting out at least a part of the contact face, wherein the recess has a shape in which among a first ridge portion (31) where the contact face and the upper face are connected to each other, a second ridge portion (32) where the contact face and the lower face are connected to each other, a third ridge portion (33) where the contact face and the first side face are connected to each other, and a fourth ridge portion (34) where the contact face and the second side face are connected to each other, characterized in that at least a part of the second ridge portion is cut out, and the first ridge portion, the third ridge portion, and the fourth ridge portion are not cut out.']",True,"['19', '13', '34', '33', '41', '23', '35', '22', '20', '42', '46', '41', '46', '25']" 174,EP_3566904_B1.png,EP3566904B1,IMAGE DISPLAY APPARATUS,['FIG2'],['FIG2 is a diagram illustrating an example of a mirror operator according to the embodiment'],"['The mirror operator 30 is provided, as illustrated in FIG2, with an L button 301 (i.e., a button for operating the left display 20L), an R button 302 (i.e., a button for operating the right display 20R), and a direction button 303. For example, if the direction button 303 is operated while the L button 301 is pressed down, the direction of the camera RL (particularly, the direction of an optical axis) is changed in accordance with the operation of the direction button 303. As a result, an imaging range of the camera RL is shifted in a direction corresponding to the operation of the direction button 303. In the same manner, if the direction button 303 is operated while the R button 302 is pressed down, the direction of the camera RR (particularly, the direction of an optical axis) is changed in accordance with the operation of the direction button 303. As a result, an imaging range of the camera RR is shifted in a direction corresponding to the operation of the direction button 303. Moreover, the mirror operator 30 is also operated to switch between image display modes (e.g., to switch between a standard mode and a wide angle mode), as described later.']",15,238,diagram,B,"[{'element_identifier': '30', 'terms': ['mirror operator']}, {'element_identifier': '1', 'terms': ['vehicle']}, {'element_identifier': '100', 'terms': ['image display apparatus']}, {'element_identifier': '303', 'terms': ['direction button']}, {'element_identifier': '2', 'terms': ['Patent Literatures']}, {'element_identifier': '301', 'terms': ['L button']}, {'element_identifier': '302', 'terms': ['R button']}, {'element_identifier': '40', 'terms': ['direction indicator']}, {'element_identifier': '10', 'terms': ['display controller']}]","['1. An image display apparatus (100) comprising: an imager (RL, RR) configured to image a scene in rear side surroundings of a vehicle (1); a display (20L, 20R) configured to display a captured image imaged by said imager (RL, RR); and a display controller (10) configured to switch between a first display mode in which a first image is displayed and a second display mode in which a second image is displayed, wherein the first image is the captured image showing a first range out of the rear side surroundings of the vehicle (1), characterised in that : the second image is the captured image including the first range and showing a second range, which is wider than the first range, out of the rear side surroundings of the vehicle (1), and in that said display controller (10) is configured to display the second image on said display (20L, 20R) in an aspect of clearly showing an area of the second image corresponding to the first image, in the second display mode.']",True,"['1', '40', '30', '10', '100', '2', '30', '303', '302', '301']" 175,EP_3567792_B1 (2).png,EP3567792B1,METHOD AND DEVICE FOR OPERATING MACHINE TYPE DEVICE IN WIRELESS COMMUNICATION SYSTEM,['FIG3'],['FIG3 is a diagram illustrating an L subframe structure that can be operated in an IoT communication system'],"['FIG3 is a diagram illustrating an L subframe structure that can be operated in an IoT communication system.', 'Referring to FIG3, an L subframe 310 that can be operated in an IoT communication system may include two L slots 315. Further, each L slot 315 may include two subframes 320. One subframe 320 may include two slots. Further, in the case of a normal CP, the slot 325 may include 6 symbols 334, whereas in the case of an extended CP, the slot 325 may include 5 symbols 344. The lengths of the respective symbols and CPs are the same as those as illustrated.']",18,117,diagram,H,"[{'element_identifier': '310', 'terms': ['L subframe', 'L-subframe']}, {'element_identifier': '325', 'terms': ['slot']}, {'element_identifier': '5', 'terms': ['may include', 'only']}, {'element_identifier': '4', 'terms': ['is']}, {'element_identifier': '2', 'terms': ['Table']}, {'element_identifier': '6', 'terms': ['may include']}, {'element_identifier': '0', 'terms': ['antenna ports', 'antenna port', 'SFN']}, {'element_identifier': '315', 'terms': ['include two L slots', 'each L slot']}, {'element_identifier': '320', 'terms': ['may include two subframes', 'One subframe']}]","['1. A method performed by a terminal in a wireless communication system, the method comprising: receiving, from a base station, a master information block, MIB, for a narrowband internet of things, NB-IoT, the MIB including at least one of first information on a sequence for a cell-specific reference signal and second information on a number of antenna ports for the cell-specific reference signal; receiving, from the base station, a system information block, SIB, for the NB-IoT, the SIB including third information on a power offset for a reference signal of the NB-IoT; and receiving, from the base station, at least one of the cell-specific reference signal and the reference signal of the NB-IoT based on at least one of the first information, the second information and the third information.', '3. The method of claim 1, wherein the second information indicates whether the number of antenna ports for the reference signal of the NB-IoT is either equal to a number of antenna ports for the cell specific reference signal or to']",False,"['3', '4', '315', '310', '2', '6', '325', '330', '0', '2', '3', '340', '0', '2', '320', '4', '5', '6', '3', '4', '15']" 176,EP_3567792_B1 (4).png,EP3567792B1,METHOD AND DEVICE FOR OPERATING MACHINE TYPE DEVICE IN WIRELESS COMMUNICATION SYSTEM,['FIG11'],['FIG11 is a diagram illustrating an example of one configuration of a downlink frame in an IoT communication system'],"['FIG11 is a diagram illustrating an example of one configuration of a downlink frame in an IoT communication system.', 'Referring to FIG11, a structure in which PBCH 1110, SIB1 1115, PSS 1120, and SSS 1125 are transmitted for the IoT terminal. In an embodiment, the frame structure in accordance with signal transmission and reception for the IoT terminal may be applied in a similar manner to that in the LTE system. In order to avoid potential collision with the MBSFN, the PSS 1120 may be transmitted on subframe 9, and may be repeatedly transmitted every 20 ms. Further, the PBCH 1110 may be transmitted on subframe 9, and may be repeatedly transmitted every 10 ms. If there is a dedicated resource for transmission of the SIB1 1115, it may be deployed in subframe 4 that is not occupied by the SSS. In the case of the above-described configuration, as a service method together with the MBSFN transmission of the LTE system, another deployment is also possible in consideration of the rule for avoiding collision with the existing LTE. Further, the resources remaining after the transmission may be shared for the PDCCH and PDSCH transmission.']",19,218,diagram,H,"[{'element_identifier': '1120', 'terms': ['PSS']}, {'element_identifier': '5', 'terms': ['may include', 'only']}, {'element_identifier': '1125', 'terms': ['SSS']}, {'element_identifier': '1', 'terms': ['Table']}, {'element_identifier': '9', 'terms': ['subframe']}, {'element_identifier': '1115', 'terms': ['SIB1']}, {'element_identifier': '2', 'terms': ['Table']}, {'element_identifier': '4', 'terms': ['is']}, {'element_identifier': '6', 'terms': ['may include']}, {'element_identifier': '0', 'terms': ['antenna ports', 'antenna port', 'SFN']}, {'element_identifier': '1110', 'terms': ['PBCH']}]","['1. A method performed by a terminal in a wireless communication system, the method comprising: receiving, from a base station, a master information block, MIB, for a narrowband internet of things, NB-IoT, the MIB including at least one of first information on a sequence for a cell-specific reference signal and second information on a number of antenna ports for the cell-specific reference signal; receiving, from the base station, a system information block, SIB, for the NB-IoT, the SIB including third information on a power offset for a reference signal of the NB-IoT; and receiving, from the base station, at least one of the cell-specific reference signal and the reference signal of the NB-IoT based on at least one of the first information, the second information and the third information.', '3. The method of claim 1, wherein the second information indicates whether the number of antenna ports for the reference signal of the NB-IoT is either equal to a number of antenna ports for the cell specific reference signal or to']",False,"['11', '1110', '1115', '1125', '1120', '2', '3', '4', '5', '6', '7', '8', '9', '0', '1', '2', '3', '4', '5', '6', '7', '8', '6', '0', '2', '3', '4', '5', '6', '7', '8', '9', '0', '1', '2', '3', '4', '5', '6', '7', '8', '9']" 177,EP_3569424_B1 (2).png,EP3569424B1,TIRE FOR MOTORCYCLE FOR UNEVEN GROUND TRAVELING,['FIG3'],['FIG3 is an enlarged perspective view of a first crown block in FIG2'],"['FIG3 shows an enlarged perspective view of one of the first crown blocks 10. As shown in FIG3, the first crown block 10 has a wheel tread 10a, a first side surface 11 disposed on one side of the wheel tread 10a in the tire circumferential direction, and a second side surface 12 disposed on the other side of the wheel tread 10a in the tire circumferential direction. In the embodiment, the first side surface 11 is disposed on a last-landing side of the wheel tread 10a in the rotational direction R. The second side surface 12 is disposed on a first-landing side of the wheel tread 10a in the rotational direction R.']",13,123,enlarged perspective view,B,"[{'element_identifier': '14', 'terms': ['second edges', 'second edge']}, {'element_identifier': '12', 'terms': ['second side surface']}, {'element_identifier': '11', 'terms': ['first side surface']}, {'element_identifier': '10', 'terms': ['first crown block', 'first crown blocks']}, {'element_identifier': '15', 'terms': ['concave part']}, {'element_identifier': '13', 'terms': ['first edges', 'first edge']}]","['1. A tire (1) for a motorcycle for uneven ground traveling, the tire (1) comprising: a tread part (2), a plurality of crown blocks (10) being formed thereon, wherein at least one of the plurality of crown blocks (10) has: a wheel tread (10a), a first side surface (11) disposed at one side of the wheel tread (10a) in a tire circumferential direction, a first edge (13) arranged between the wheel tread (10a) and the first side surface (11), a concave part (15) that opens on the wheel tread (10a) and the first side surface (11), and a second edge (14) arranged between the wheel tread (10a) and the concave part (15), and wherein the wheel tread (10a) has at least one external corner part (16) in which an angle (θ1) between the first edge (13) and the second edge (14) is an acute angle, characterized in that the first side surface (11) is curved to be recessed toward the other side in the tire circumferential direction in a plan view of a tread.', '2. The tire (1) according to claim 1, wherein the at least one of the plurality of crown blocks (10) has a second side surface (12) disposed on the other side of the wheel tread (10a) in the tire circumferential direction, and the concave part (15) also opens on the second side surface (12).']",False,"['12', '15', '14', '14', '10', '13', '13', '11', '13']" 178,EP_3569424_B1 (4).png,EP3569424B1,TIRE FOR MOTORCYCLE FOR UNEVEN GROUND TRAVELING,['FIG5'],['FIG5 is an enlarged plan view of a second crown block in FIG2'],"['FIG5 shows an enlarged plan view of the second crown block 20. Further, a configuration of the first crown block 10 described basically above can be applied to the second crown block 20. A further desirable aspect of the second crown block 20 will be described below.']",13,51,enlarged plan view,B,"[{'element_identifier': '24', 'terms': ['second edge']}, {'element_identifier': '20', 'terms': ['second crown block', 'second crown blocks']}, {'element_identifier': '25', 'terms': ['concave part']}, {'element_identifier': '21', 'terms': ['first side surface']}, {'element_identifier': '15', 'terms': ['concave part']}, {'element_identifier': '23', 'terms': ['first edge']}]","['1. A tire (1) for a motorcycle for uneven ground traveling, the tire (1) comprising: a tread part (2), a plurality of crown blocks (10) being formed thereon, wherein at least one of the plurality of crown blocks (10) has: a wheel tread (10a), a first side surface (11) disposed at one side of the wheel tread (10a) in a tire circumferential direction, a first edge (13) arranged between the wheel tread (10a) and the first side surface (11), a concave part (15) that opens on the wheel tread (10a) and the first side surface (11), and a second edge (14) arranged between the wheel tread (10a) and the concave part (15), and wherein the wheel tread (10a) has at least one external corner part (16) in which an angle (θ1) between the first edge (13) and the second edge (14) is an acute angle, characterized in that the first side surface (11) is curved to be recessed toward the other side in the tire circumferential direction in a plan view of a tread.']",False,"['24', '25', '24', '20', '06', '07', '21', '23', '05', '23', '15']" 179,EP_3570489_B1 (1).png,EP3570489B1,DEVICE AND METHOD FOR TRANSFORMING BLOCKCHAIN DATA BLOCKS,['FIG3'],['FIG3 schematically illustrates a second blockchain according to various examples'],"['FIG3 schematically illustrates a second blockchain 8 according to various examples. The second blockchain may comprise a plurality of different second data blocks 19a-19c, which may be chained by second has values 10-10b based on a second hash-function encryption mechanism. Hereby, the chaining request 15 may be sent by the request module 16 of the device 1, and may be received by the Blockchain network nodes 14b-14c of the blockchain network 2. In this context, the chaining request 15 may be adapted for chaining the single blockchain data block 7 with the second blockchain 8. Hereby, the single blockchain data block 7 may comprise at least two first data blocks 5a-5d of the first blockchain 4, wherein these at least two first data blocks 5a-5c may be chained by the first hash values 9a-9c based on the first hash-function encryption mechanism.']",10,158,schematic,H,"[{'element_identifier': '15', 'terms': ['chaining request']}, {'element_identifier': '12', 'terms': ['user command']}, {'element_identifier': '3', 'terms': ['receiving module']}, {'element_identifier': '2', 'terms': ['blockchain network']}]","['1. A device (1), which is adapted to be connected with a blockchain network (2), comprising: a receiving module (3), adapted to receive, from the blockchain network (2), a first blockchain (4) comprising a plurality of first data blocks (5a-5d), wherein chaining of the first blockchain (4) is based on a first hash-function encryption mechanism, a transformation module (6), adapted to transform at least two first data blocks (5a-5d) of the first blockchain (4) into a single blockchain data block (7), wherein the block chain data block (7) includes the at least two first data blocks (5a-5d) from the first block chain (4) which are chained based on the first hash-function encryption mechanism, and a request module (16), adapted to request, at the blockchain network (2), chaining of the single blockchain data block (7) with a second blockchain (8), wherein chaining of the second blockchain (8) is based on a second hash-function encryption mechanism different from the first hash-function encryption mechanism.', '5. The device (1) according to any of the preceding claims, further comprising a user interface (11), adapted to control the transformation module (6) to selectively activate said transforming based on a user command (12).']",True,"['2', '3', '50', '15', '12']" 180,EP_3572243_B1 (1).png,EP3572243B1,TIRE,['FIG2'],['FIG2 is an enlarged view of a first shoulder land portion and a first middle land portion shown in FIG1'],"['FIG2 is an enlarged view of the first shoulder land portion 6A and the first middle land portion 7A. As shown in FIG2, the first shoulder land portion 6A has a buttress surface 9A that is continuous outward of the first tread end Tel in the tire axial direction. The buttress surface 9A is tilted in the tire axially outward direction toward the tire radially inner side, and is continuous with the sidewall portion.', 'As shown in FIG2, for example, the second sipe 12 preferably reaches the center position of the first shoulder land portion 6A in the tire axial direction. The aforementioned center position is the center position in the tire axial direction on the tread surface from the first tread end Tel to the first shoulder main groove 4A. In a preferable mode, a length L4 of the second sipe 12 in the tire axial direction is, for example, 0.55 to 0.65 times the width W2 of the first shoulder land portion 6A in the tire axial direction. The second sipe 12 having such a structure allows steering stability to be improved while noise performance is maintained.', 'As shown in FIG2, the first shoulder land portion 6A preferably has a longitudinal narrow groove 15 that extends in the tire circumferential direction in a portion outward of the first tread end Tel in the tire axial direction. In the present embodiment, for example, the longitudinal narrow groove 15 extends linearly so as to be parallel to the tire circumferential direction. The longitudinal narrow groove 15 having such a structure contributes to improvement of anti-wandering performance.', 'As shown in FIG2, for example, the second middle sipe 27 reaches the center position of the first middle land portion 7A in the tire axial direction, and ends in a portion that is closer to the first tread end Tel than the center position is. The second middle sipe 27 ends, for example, in a portion that is closer to the tire equator C than the end of the middle lateral groove 20 is. Specifically, for example, a length L8 of the second middle sipe 27 in the tire axial direction is preferably 0.60 to 0.80 times the width W3 of the first middle land portion 7A in the tire axial direction.']",20,412,enlarged view,B,"[{'element_identifier': '17', 'terms': ['second longitudinal narrow groove']}, {'element_identifier': '12', 'terms': ['second sipe', 'second sipes']}, {'element_identifier': '11', 'terms': ['first sipe', 'first sipes']}, {'element_identifier': '2', 'terms': ['tread portion']}, {'element_identifier': '20', 'terms': ['middle lateral groove', 'middle lateral grooves']}, {'element_identifier': '16', 'terms': ['first longitudinal narrow groove']}, {'element_identifier': '27', 'terms': ['second middle sipe']}, {'element_identifier': '10', 'terms': ['shoulder lateral groove', 'shoulder lateral grooves']}, {'element_identifier': '26', 'terms': ['first middle sipe', 'first middle sipes']}, {'element_identifier': '15', 'terms': ['longitudinal narrow groove']}]","['1. A tire (1) comprising a tread portion (2), wherein the tread portion (2) includes a first shoulder main groove (4A) that extends near a first tread end (Tel) continuously in a tire circumferential direction, and a first shoulder land portion (6A) that is defined between the first shoulder main groove (4A) and the first tread end (Tel), the first shoulder land portion (6A) includes a shoulder lateral groove (10) that extends at least from the first tread end (Tel) toward the first shoulder main groove (4A), and ends in the first shoulder land portion (6A), a first sipe (11) that extends, from an end of the shoulder lateral groove (10) at which the shoulder lateral groove (10) ends, to the first shoulder main groove (4A), and a second sipe (12) that extends at least from the first tread end (Te1) toward the first shoulder main groove (4A), and ends in the first shoulder land portion (6A), said tire being characterized in that a length (L3) of the shoulder lateral groove (10) in a tire axial direction is 0.10 to 0.30 times a width (W2) of the first shoulder land portion (6A) in the tire axial direction and the tread end is defined to be the end in the tire axial direction of a ground contact portion of the tread portion in a normal running state where a normal load is applied to the tire, having a camber angle of 0° and the tire is mounted to a normal rim and inflated to a normal internal pressure.', '5. The tire (1) according to any one of claims 1 to 4, wherein the first shoulder land portion (6A) has a longitudinal narrow groove (15) that extends in the tire circumferential direction in a portion outward of the first tread end (Te1) in the tire axial direction.', '10. The tire (1) according to claim 8 or 9, wherein the first middle land portion (7A) has a middle lateral groove (20) that extends from the first shoulder main groove (4A) and ends in the first middle land portion (7A), and the middle sipe (25) includes a first middle sipe (26) that connects with an end of the middle lateral groove (20) at which the middle lateral groove (20) ends.']",False,"['17', '20', '10', '11', '12', '26', '11', '27', '15', '16', '12', '10', '2', '14']" 181,EP_3572243_B1 (4).png,EP3572243B1,TIRE,['FIG5'],['FIG5 is an enlarged view of a second shoulder land portion and a second middle land portion shown in FIG1'],"['FIG5 is an enlarged view of the second shoulder land portion 6B and the second middle land portion 7B. As shown in FIG5, the second shoulder land portion 6B has a buttress surface 9B that is continuous outward of the second tread end Te2 in the tire axial direction. The buttress surface 9B is tilted in the tire axially outward direction toward the tire radially inner side, and is continuous with the sidewall portion.', 'As shown in FIG5, the second shoulder land portion 6B does not have the longitudinal narrow grooves, which are disposed in the first shoulder land portion 6A. Thus, pitch sound generated by the shoulder lateral grooves 30 disposed in the second shoulder land portion 6B and pitch sound generated by the shoulder lateral groove 10 disposed in the first shoulder land portion 6A are allowed to become white noise, and noise performance is improved. Furthermore, in the present embodiment, when the tire 1 is mounted to a vehicle, since the second shoulder land portion 6B is disposed on the outer side of the vehicle, even if the longitudinal narrow grooves are not disposed in this land portion, anti-wandering performance is maintained.']",20,213,enlarged view,B,"[{'element_identifier': '17', 'terms': ['second longitudinal narrow groove']}, {'element_identifier': '5', 'terms': ['is not less than']}, {'element_identifier': '30', 'terms': ['shoulder lateral grooves']}, {'element_identifier': '40', 'terms': ['middle lateral grooves']}, {'element_identifier': '33', 'terms': ['third sipe']}, {'element_identifier': '46', 'terms': ['first middle sipe', 'first middle sipes']}, {'element_identifier': '31', 'terms': ['first sipes']}]","['9. The tire (1) according to claim 8, wherein a plurality of the first sipes (11) and a plurality of the second sipes (12) are disposed in the first shoulder land portion (6A), and the total number (Nm) of the middle sipes (25) disposed in the first middle land portion (7A) is less than the total number (Ns) of the first sipes (11) and the second sipes (12) disposed in the first shoulder land portion (6A).', '10. The tire (1) according to claim 8 or 9, wherein the first middle land portion (7A) has a middle lateral groove (20) that extends from the first shoulder main groove (4A) and ends in the first middle land portion (7A), and the middle sipe (25) includes a first middle sipe (26) that connects with an end of the middle lateral groove (20) at which the middle lateral groove (20) ends.']",False,"['3572243', '46', '40', '46', '40', '46', '40', '31', '30', '33', '30', '31', '30', '33', '5', '17']" 182,EP_3572243_B1 (6).png,EP3572243B1,TIRE,['FIG7'],['FIG7 is an enlarged view of a crown land portion in FIG1'],"['FIG7 is an enlarged view of the crown land portion 8. As shown in FIG7, the crown land portion 8 has, for example, a plurality of first crown lateral grooves 51 and a plurality of second crown lateral grooves 52. Each first crown lateral groove 51 extends from the first crown main groove 5A and ends in the crown land portion 8. Each second crown lateral groove 52 extends from the second crown main groove 5B and ends in the crown land portion 8.']",12,91,enlarged view,B,"[{'element_identifier': '51', 'terms': ['first crown lateral groove', 'first crown lateral grooves']}, {'element_identifier': '52', 'terms': ['second crown lateral groove', 'second crown lateral grooves']}, {'element_identifier': '27', 'terms': ['second middle sipe']}, {'element_identifier': '26', 'terms': ['first middle sipe', 'first middle sipes']}, {'element_identifier': '46', 'terms': ['first middle sipe', 'first middle sipes']}]","['10. The tire (1) according to claim 8 or 9, wherein the first middle land portion (7A) has a middle lateral groove (20) that extends from the first shoulder main groove (4A) and ends in the first middle land portion (7A), and the middle sipe (25) includes a first middle sipe (26) that connects with an end of the middle lateral groove (20) at which the middle lateral groove (20) ends.']",False,"['27', '52', '46', '46', '26', '51', '27', '51', '26', '52', '46', '46', '19', '27', '7', '19']" 183,EP_3572764_B1 (6).png,EP3572764B1,SHAPE MEASURING PROBE,['FIG8'],['FIG8 is a sectional view of a measuring probe according to Second exemplary embodiment'],"['Next, a second exemplary embodiment of the disclosure will be described with reference to FIG8. Since measuring probe 5 of the second exemplary embodiment has substantially the same configuration as that of measuring probe 5 of the first exemplary embodiment, the difference will be mainly described.']",14,50,sectional view,G,"[{'element_identifier': '8', 'terms': ['Z reference mirror']}, {'element_identifier': '24', 'terms': ['air bearing']}, {'element_identifier': '28', 'terms': ['groove']}, {'element_identifier': '22', 'terms': ['stylus']}, {'element_identifier': '29', 'terms': ['elastic material']}, {'element_identifier': '25', 'terms': []}, {'element_identifier': '27', 'terms': ['provided with air coupling']}, {'element_identifier': '26', 'terms': ['housing']}, {'element_identifier': '21', 'terms': ['movable member']}, {'element_identifier': '23', 'terms': ['reflection surface']}]","['1. A shape measuring probe (5) comprising: a rod-like movable member (21) having a reflection surface (23) for reflecting laser light at an upper end; a stylus (22) that is provided at a lower end of the movable member and comes into contact with an object; an air bearing (24) that has a shaft hole (24a), allows the movable member to penetrate the shaft hole, and supports the movable member to be movable in a first direction; a plate -like elastic material (29) that adheres to the upper end portion of the movable member (21) and is placed on a first supporter (30a) and a second supporter (30b), characterized in that it further comprises: a first magnet (31a) and a second magnet (31b) that are fixed to an upper end portion of the air bearing, the first magnet and the second magnet being substantially symmetrical with respect to a shaft center of the movable member, and wherein the spherical first supporter (30a) is a magnetic body connected to the first magnet with a magnetic force so as to be movable on the first magnet; the spherical second supporter (30b) is a magnetic body connected to the second magnet with a magnetic force so as to be movable on the second magnet.']",False,"['8', '29', '23', '26', '28', '27', '25', '24', '21', '22', '21']" 184,EP_3574519_B1.png,EP3574519B1,SUPPORT FOR A SEMICONDUCTOR STRUCTURE,['FIG1'],['FIG1 schematically shows a support for a semiconductor structure according to the invention'],"['FIG1 schematically shows a support 1 for a semiconductor structure according to the invention. The support 1 may take the form of a circular wafer of standardized size, for example of 200 mm or 300 mm or even 450 mm in diameter. However, the invention is in no way limited to these dimensions or to this shape.', 'Returning to the description of the support 1 shown in FIG1, it is optionally possible to provide a second insulating layer 4 on the trapping layer 2 and in direct contact therewith, in order to facilitate the assembly of the support 1 with a semiconductor structure. This second insulating layer 4 may be formed by deposition or by oxidation of the trapping layer 2. Provision may be made for a polishing step before and/or after the formation of the second insulating layer 4, in order to improve the quality of this assembly.']",13,161,schematic,H,"[{'element_identifier': '3', 'terms': ['base substrate']}, {'element_identifier': '2', 'terms': ['trapping layer']}, {'element_identifier': '6', 'terms': ['with another insulating layer']}]",['1. Support (1) for a semiconductor structure or a surface or bulk acoustic wave type device comprising: - a base substrate (3); - a first silicon dioxide insulating layer (2a) positioned on the base substrate (3) and having a thickness greater than 20 nm; - a charge trapping layer (2) having a resistivity higher than 1000 ohm.cm and a thickness greater than 5 microns positioned on the first insulating layer (2a).'],True,"['2', '3', '6', '2', '3']" 185,EP_3574715_B1.png,EP3574715B1,CONTROLLING A LIGHTING SYSTEM,['FIG2'],['FIG2 shows a schematic perspective view of a lighting system located in an environment'],['By way of example FIG2 shows a smart switch 5 disposed in the environment 2 along with the gateway 10 and router 9 with the user device 6 held by the user 8. However as will be appreciated this is merely an example for the purposes of illustration and various other arrangements and configurations are equally viable.'],14,59,schematic perspective view,H,"[{'element_identifier': '24', 'terms': ['network interface']}, {'element_identifier': '14', 'terms': []}, {'element_identifier': '22', 'terms': ['processor']}, {'element_identifier': '18', 'terms': ['network']}, {'element_identifier': '4', 'terms': ['luminaires', 'luminaire']}, {'element_identifier': '20', 'terms': ['external network']}, {'element_identifier': '10', 'terms': ['bridge']}, {'element_identifier': '3', 'terms': ['sensors', 'sensor']}]","['12. A lighting control system according to claim 2 and 11, wherein the trigger engine is configured to adapt the engagement threshold for the at least one luminaire based on whether the user reacts as intended to the rendering or suppressing of the lighting effect.']",True,"['3', '10', '4', '4', '4', '14', '22', '18', '24', '20', '19']" 186,EP_3576438_B1.png,EP3576438B1,"METHOD FOR ENHANCING THE SECURITY OF NAVIGATING A VEHICLE BY PROVIDING REAL-TIME NAVIGATION DATA TO THE VEHICLE VIA A MOBILE COMMUNICATION NETWORK, SYSTEM FOR ENHANCING THE SECURITY OF NAVIGATING A VEHICLE BY PROVIDING REAL-TIME NAVIGATION DATA TO THE VEHICLE VIA A MOBILE COMMUNICATION NETWORK, PROGRAM AND COMPUTER PROGRAM PRODUCT",['FIG1'],['FIG1 schematically illustrates a method for enhancing the security of navigating a vehicle by providing real-time navigation data to the vehicle via a mobile communication network mobile communication network'],"[""In FIG1, a method for enhancing the security of navigating a vehicle 10 by providing real-time navigation data to the vehicle 10 via a mobile communication network 100 is illustrated schematically. The mobile communication network 100 comprises a radio access network 110 and a core network 120. The mobile communication network 100 is preferably a cellular telecommunications network comprising typically a plurality of network cells, wherein a coverage region (or coverage area) of a network cell associated with a base station entity 111 is represented in FIG1 by means of reference sign 110'. The radio access network 110 comprises a base station entity 111 serving the radio cell associated with the coverage region 110'."", ""Preferably, the coverage region 110' (herein also called coverage area) is a three-dimensional region or space of the (radio access network associated with a base station entity of the) mobile communication network 100, wherein the coverage region 110' provides coverage to subscribers (especially in an helicopter 10) up to a certain ceiling (vertical direction) and out of the coast (horizontal direction). Preferably, the mobile communication network 100 is connected to a flight control entity which operates a remote sensing system 31 (e.g. a radar system or radar station), the remote sensing system 31 being associated with a remote sensing region (see reference numeral 31' in FIG1) at least partially overlapping (preferably fully overlapping with or including the) any coverage region (for example coverage region 110' shown in FIG1) of the mobile communication network 100. Preferably, the mobile communication network 100 is connected to all shipping offices with their respective radar-installations in harbours and on coasts and associated shipping-routes. Preferably, the system according to the present invention comprises a radar-installation for automotive corridors (for example highways) and traffic control entities (not shown). Thereby, it is advantageously possible to avoid failing night-vision ability, darkness, fog, poor visibility and other pre-sets for an unsafe voyage from becoming critical due to a real-time modus being realized by supplying the vehicle with the real-time navigation data (including radar-images), wherein the image information are displayed during travelling the vehicle 10.""]",31,423,schematic,G,"[{'element_identifier': '11', 'terms': ['aircraft']}, {'element_identifier': '1', 'terms': ['objects', 'object']}, {'element_identifier': '100', 'terms': ['mobile communication network']}, {'element_identifier': '113', 'terms': ['further base station entity']}, {'element_identifier': '110', 'terms': ['radio access network']}, {'element_identifier': '20', 'terms': ['server entity']}, {'element_identifier': '42', 'terms': ['storage means']}, {'element_identifier': '112', 'terms': ['base station entity']}, {'element_identifier': '41', 'terms': ['database']}, {'element_identifier': '10', 'terms': ['vehicle', 'vehicles']}, {'element_identifier': '50', 'terms': ['information delivery entity']}, {'element_identifier': '49', 'terms': ['comprises storage means']}, {'element_identifier': '43', 'terms': []}, {'element_identifier': '44', 'terms': ['fourth storage means']}, {'element_identifier': '31', 'terms': ['system', 'systems']}, {'element_identifier': '32', 'terms': ['remote sensing system']}, {'element_identifier': '120', 'terms': ['core network']}]","[""1. Method for enhancing the security of navigating a vehicle (10) by providing real-time navigation data to the vehicle (10) via a mobile communication network (100), wherein the mobile communication network (100) comprises a radio access network (110), the radio access network (110) comprising a coverage region (110'), wherein at least one remote sensing system (31, 32) is connected to the mobile communication network (100), the at least one remote sensing system (31, 32) comprising a remote sensing system (31), the remote sensing system (31) comprising a remote sensing region (31'), wherein the remote sensing region (31') at least partially overlaps with the coverage region (110'), wherein the mobile communication network (100) comprises a server entity (20), wherein the method comprises the following steps: -- the server entity (20) - in case of the vehicle (10) being located on a travelling path (10') of the vehicle (10) across the coverage region (110') of the radio access network (110) - obtaining travelling data related to the vehicle (10), the travelling data including a location information and a date information, the location information being related to a position of the vehicle (10) along the travelling path (10') of the vehicle (10) across the coverage region (10'), the date information indicating a date the vehicle (10) is located on the position along the travelling path (10') of the vehicle (10) across the coverage region (10'), -- the server entity (20) obtaining, based on the travelling data related to the travelling path (10') of the vehicle (10) across the coverage region (110'), remote sensing data from the remote sensing system (31), wherein the remote sensing data are related to the vehicle (10) and/or objects (1, 2, 3) being detected, by the remote sensing system (31), within the remote sensing region (31') during a time interval, the time interval including the date being indicated by the date information of the travelling data, -- determining, based on the remote sensing data obtained from the remote sensing system (31), the real-time navigation data for enhancing the security of navigating the vehicle (10), -- the server entity (20) transmitting the real-time navigation data to the vehicle (10), wherein the server entity (20) is connected to an information delivery entity (50), the information delivery entity (50) comprising storage means (49) storing assistance data related to the vehicle (10), the assistance data being configured for increasing the safety and the ability to provide important information in advance, wherein the method comprises the further step of: -- the server entity (20) including the assistance data with the real-time navigation data prior to transmitting the real-time navigation data to the vehicle (10), wherein the real-time navigation data include image information, wherein the remote sensing data are generated by the remote sensing system (31) upon detection of the objects (1, 2, 3) within the remote sensing region (31') during the time interval, wherein the objects (1, 2, 3) comprise other vehicles or other entities."", ""8. Method according to any one of the preceding claims, wherein the vehicle (10) - while travelling along the travelling path (10') - transmits the identifier for unique identification of the real-time navigation data to fourth storage means (44) of the mobile communication network (100), wherein the vehicle (10) transmits to the fourth storage means (44) -- only the identifier, -- or the identifier and vehicle information related to an operating status of the vehicle (10) while travelling along the travelling path (10'), wherein the fourth storage means (44) are preferably provided by a cloud service provider of the mobile communication network (100).""]",True,"['100', '120', '110', '41', '42', '20', '43', '44', '31', '10', '2', '110', '49', '50', '10', '49', '50', '49', '50', '32', '1', '32', '31', '112', '20', '113', '41', '11', '2', '25']" 187,EP_3576952_B1 (2).png,EP3576952B1,PRINTHEAD HAVING HEATED SHIELD PLATE,"['FIG5', ' FIG7B']","['FIG7B is a sectional perspective through a second channel of the fluid coupling ', 'FIG5 is an exploded perspective of a main body of the printhead with inlet and outlet couplings']","['Each ink entering the fluid coupling 8 has a carefully controlled respective hydrostatic pressure (e.g. by virtue of an upstream pressure regulator) and it is important that the relative hydrostatic pressures of the inks are not changed as the inks flow through the fluid coupling. For example, the four inks may enter the inlets ports 9A-9D with equal hydrostatic pressures and it is desirable that these inks exit the outlet ports 11A-11D into the manifold 25 with equal hydrostatic pressures. A degree of pressure drop is, to some extent, inevitable as each ink experiences flow resistance (i.e. viscous drag) through the fluid coupling 8; however, it is important that the pressure drops are equalized for all inks despite the longer fluidic paths for the two inks flowing through the two inner inlet ports 9B and 9C. Accordingly, as shown in FIG7B, a fluid channel 12B connecting the inlet port 9B with the outlet port 11B has a roof 13B sloped upwards from towards the inlet port 9B. A roof 13C of a corresponding fluidic channel connecting the inlet port 9C and the outlet port 11C is, likewise, sloped upwards towards the inlet port 9C. By contrast the fluid channel 12A connecting inlet port 9A with the outlet port 11A does not have a similarly sloped roof, requiring the fluid to turn through a tighter angle without assistance from a more curved fluid path. ', 'Referring to FIG5, the main body 17 is itself a two-part machined structure comprising an elongate manifold 25 and a complementary cover plate 27. The manifold 25 functions as a carrier having a unitary lower surface for mounting both the first and second rows 14 and 16 of printhead chips. The manifold 25 is received between a pair of opposed flanges 29, which extend downwardly from opposite longitudinal sides of the cover plate 27. The flanges 29 are configured for snap-locking engagement with complementary snap-locking features 26 of the manifold 25 to form the assembled main body 17.']",30,360,"exploded, perspective view, sectional view",B,"[{'element_identifier': '29', 'terms': ['flanges', 'flange']}, {'element_identifier': '5', 'terms': ['alignment notch']}, {'element_identifier': '10', 'terms': ['coupling body']}, {'element_identifier': '25', 'terms': ['manifold']}]","['1. An inkjet printhead (1) comprising: a manifold (25) having a plurality of ink outlets (50) defined in a manifold surface; a plurality of printhead chips (70) mounted to the manifold surface (52) via a shim (66), the printhead chips being aligned with the ink outlets; a PCB (18) mounted to the manifold surface and offset from the ink outlets, the PCB being electrically connected to the printhead chips, wherein a lower surface of the PCB is coplanar with a lower surface of the shim; and a shield plate (20) bonded to the PCB and part of the shim, the shield plate covering the PCB, wherein: the shield plate has one face in thermal contact with the PCB and an exposed opposite face defining a lower surface of the printhead; and the shim has at least one void region (68) offset from the printhead chips, the void region thermally isolating part of the shield plate from the manifold.']",True,"['29', '25', '5', '10', '9', '12']" 188,EP_3576952_B1 (3).png,EP3576952B1,PRINTHEAD HAVING HEATED SHIELD PLATE,['FIG11'],['FIG11 is a magnified cross-sectional perspective of the ink manifold with a shim and one row of printhead chips removed'],"['The longitudinal ink cavity 60 has cavity sidewalls 62, which extend downwardly from the cavity roof 55 to meet with the lower surface 52 of the manifold 25. A second portion 64 of each through-hole 50 extends beyond the cavity roof 55 to meet with the lower surface 52. In this way, the second portions 64 of the through-holes 50 form notches in the cavity sidewalls 62. Similarly, and as best shown in FIG11, at least part of the first portions 54 of the through-holes 50 form notches in opposite sides of the dividing wall 44.']",22,110,cross-sectional view,B,"[{'element_identifier': '14', 'terms': ['first row']}, {'element_identifier': '48', 'terms': []}, {'element_identifier': '45', 'terms': ['baffles']}, {'element_identifier': '41', 'terms': ['sidewalls']}, {'element_identifier': '25', 'terms': ['manifold']}, {'element_identifier': '40', 'terms': ['channels', 'channel']}, {'element_identifier': '52', 'terms': ['lower surface']}, {'element_identifier': '66', 'terms': ['shim']}, {'element_identifier': '10', 'terms': ['coupling body']}, {'element_identifier': '43', 'terms': ['bellows']}, {'element_identifier': '26', 'terms': ['with complementary snap-locking features']}, {'element_identifier': '50', 'terms': ['through-holes', 'through-hole']}, {'element_identifier': '44', 'terms': ['dividing wall']}, {'element_identifier': '46', 'terms': ['thicker longitudinal central wall']}, {'element_identifier': '31', 'terms': ['film']}, {'element_identifier': '58', 'terms': ['longitudinal rib', 'longitudinal ribs']}]","['1. An inkjet printhead (1) comprising: a manifold (25) having a plurality of ink outlets (50) defined in a manifold surface; a plurality of printhead chips (70) mounted to the manifold surface (52) via a shim (66), the printhead chips being aligned with the ink outlets; a PCB (18) mounted to the manifold surface and offset from the ink outlets, the PCB being electrically connected to the printhead chips, wherein a lower surface of the PCB is coplanar with a lower surface of the shim; and a shield plate (20) bonded to the PCB and part of the shim, the shield plate covering the PCB, wherein: the shield plate has one face in thermal contact with the PCB and an exposed opposite face defining a lower surface of the printhead; and the shim has at least one void region (68) offset from the printhead chips, the void region thermally isolating part of the shield plate from the manifold.', '6. The inkjet printhead of claim 5 comprising first and second rows of printhead chips, the first row of printhead chips having a respective first PCB and the second row of printhead chips having a respective second PCB, wherein the first and second PCBs are positioned at opposite distal longitudinal sides of the first and second rows of printhead chips.']",True,"['40', '43', '45', '26', '41', '40', '25', '26', '41', '44', '10', '46', '50', '46', '50', '44', '45', '45', '43', '31', '44', '41', '50', '48', '50', '52', '50', '58', '66', '11', '14']" 189,EP_3576952_B1 (5).png,EP3576952B1,PRINTHEAD HAVING HEATED SHIELD PLATE,['FIG14'],['FIG14 is a sectional bottom perspective of the shim and printhead chip mounting arrangement'],"['Use of a singular shim 66 having a pair of longitudinal shim sections 66A and 66B minimizes relative skew of the first row 14 and second row 16 of printhead chips 70 by ensuring parallelism between the two shim sections 66A and 66B. Alignment of the shim 66 relative to the manifold 25 is facilitated using mechanical alignment tabs 61 on the shim, which engage with alignment features 63 in the form of recesses defined in the lower surface (see FIG14). It will be appreciated that the shim 66 has a number of alignment tabs 61 positioned for engagement with a corresponding plurality of alignment features 63 in the manifold 63. A plurality of alignment tabs 61 ensures alignment in both x- and y-axes.']",14,132,sectional view,B,"[{'element_identifier': '67', 'terms': ['shim trusses']}, {'element_identifier': '14', 'terms': ['first row']}, {'element_identifier': '73', 'terms': ['respective bond pad']}, {'element_identifier': '63', 'terms': ['alignment features']}, {'element_identifier': '64', 'terms': ['second portions', 'second portion']}, {'element_identifier': '56', 'terms': ['ink feed channels']}, {'element_identifier': '16', 'terms': ['second row', 'second rows']}, {'element_identifier': '61', 'terms': ['alignment tabs']}, {'element_identifier': '70', 'terms': ['printhead chips', 'printhead chip']}, {'element_identifier': '68', 'terms': ['voids']}]","['1. An inkjet printhead (1) comprising: a manifold (25) having a plurality of ink outlets (50) defined in a manifold surface; a plurality of printhead chips (70) mounted to the manifold surface (52) via a shim (66), the printhead chips being aligned with the ink outlets; a PCB (18) mounted to the manifold surface and offset from the ink outlets, the PCB being electrically connected to the printhead chips, wherein a lower surface of the PCB is coplanar with a lower surface of the shim; and a shield plate (20) bonded to the PCB and part of the shim, the shield plate covering the PCB, wherein: the shield plate has one face in thermal contact with the PCB and an exposed opposite face defining a lower surface of the printhead; and the shim has at least one void region (68) offset from the printhead chips, the void region thermally isolating part of the shield plate from the manifold.', '6. The inkjet printhead of claim 5 comprising first and second rows of printhead chips, the first row of printhead chips having a respective first PCB and the second row of printhead chips having a respective second PCB, wherein the first and second PCBs are positioned at opposite distal longitudinal sides of the first and second rows of printhead chips.']",True,"['56', '64', '99', '68', '63', '70', '61', '67', '14', '70', '73', '15', '16']" 190,EP_3576952_B1 (6).png,EP3576952B1,PRINTHEAD HAVING HEATED SHIELD PLATE,['FIG16'],['FIG16 is a top perspective of part of the shim'],"['The Invar shim 66, shown in isolation in FIG16, provides a stable platform for each row of printhead chips 70 with negligible thermal expansion during use. The shim 66 has a comparable thickness to the printhead chips 70 (e.g. about 100 to 1000 microns in thickness). Effectively, the Invar shim 66 enables construction of long printheads based on a monolithic manifold to which a plurality of printhead chips can be mounted.']",10,79,perspective view,B,"[{'element_identifier': '20', 'terms': ['shield plate']}, {'element_identifier': '40', 'terms': ['channels', 'channel']}, {'element_identifier': '52', 'terms': ['lower surface']}, {'element_identifier': '29', 'terms': ['flanges', 'flange']}, {'element_identifier': '68', 'terms': ['voids']}, {'element_identifier': '30', 'terms': ['vent holes']}, {'element_identifier': '18', 'terms': ['PCB']}, {'element_identifier': '25', 'terms': ['manifold']}, {'element_identifier': '24', 'terms': ['lead retainer']}, {'element_identifier': '17', 'terms': ['main body']}, {'element_identifier': '72', 'terms': ['longitudinal shim rib']}, {'element_identifier': '80', 'terms': ['contact pads', 'contact pad']}, {'element_identifier': '22', 'terms': ['leads', 'lead']}, {'element_identifier': '16', 'terms': ['second row', 'second rows']}, {'element_identifier': '27', 'terms': ['cover plate']}, {'element_identifier': '41', 'terms': ['sidewalls']}, {'element_identifier': '44', 'terms': ['dividing wall']}, {'element_identifier': '75', 'terms': ['define opposite wings']}, {'element_identifier': '13', 'terms': ['contacts', 'contact']}, {'element_identifier': '67', 'terms': ['shim trusses']}, {'element_identifier': '69', 'terms': ['longitudinal shim slots']}, {'element_identifier': '79', 'terms': ['encapsulant']}, {'element_identifier': '3', 'terms': ['casing']}, {'element_identifier': '74', 'terms': ['step']}]","['1. An inkjet printhead (1) comprising: a manifold (25) having a plurality of ink outlets (50) defined in a manifold surface; a plurality of printhead chips (70) mounted to the manifold surface (52) via a shim (66), the printhead chips being aligned with the ink outlets; a PCB (18) mounted to the manifold surface and offset from the ink outlets, the PCB being electrically connected to the printhead chips, wherein a lower surface of the PCB is coplanar with a lower surface of the shim; and a shield plate (20) bonded to the PCB and part of the shim, the shield plate covering the PCB, wherein: the shield plate has one face in thermal contact with the PCB and an exposed opposite face defining a lower surface of the printhead; and the shim has at least one void region (68) offset from the printhead chips, the void region thermally isolating part of the shield plate from the manifold.', '6. The inkjet printhead of claim 5 comprising first and second rows of printhead chips, the first row of printhead chips having a respective first PCB and the second row of printhead chips having a respective second PCB, wherein the first and second PCBs are positioned at opposite distal longitudinal sides of the first and second rows of printhead chips.']",True,"['69', '69', '72', '67', '99', '68', '16', '30', '3', '29', '13', '24', '22', '41', '27', '44', '40', '99', '20', '25', '75', '74', '79', '52', '80', '20', '18', '17', '17']" 191,EP_3578903_B1 (1).png,EP3578903B1,CO2 REFRIGERATION SYSTEM WITH MAGNETIC REFRIGERATION SYSTEM COOLING,['FIG2'],"['FIG2 is a schematic diagram of the CO2 refrigeration system of FIG1 with a bypass line and control valve to bypass the after-cooler of the magnetic refrigeration system, according to an exemplary embodiment']","['Referring particularly to FIG2, in some embodiments, MRS 30 includes a bypass conduit connecting fluid conduits 35 and 36. Bypass conduit 39 may provide an alternative path for the coolant to flow from fluid conduit 35 to fluid conduit 36 without passing through heat exchanger 31. In some embodiments, a control valve 38 is located along bypass conduit 39 or at the intersection of bypass conduit 39 and fluid conduit 36. Control valve 38 can be operated to control the flow of coolant through bypass conduit 39 and/or the flow of coolant through heat exchanger 31. In some embodiments, control valve 38 is operated to limit the amount of heat gained by the coolant in heat exchanger 31. For example, control valve 38 can be operated to minimize the amount of heat gained by the coolant in heat exchanger 31 to prevent MRS 30 from being overwhelmed.']",36,158,schematic diagram,F,"[{'element_identifier': '30', 'terms': ['MRS']}, {'element_identifier': '38', 'terms': ['control valve']}, {'element_identifier': '9', 'terms': ['fluid conduit', 'fluid conduits']}, {'element_identifier': '37', 'terms': ['coolant circuit']}, {'element_identifier': '20', 'terms': ['subsystem']}, {'element_identifier': '21', 'terms': ['expansion valves']}, {'element_identifier': '25', 'terms': ['fluid conduit']}, {'element_identifier': '31', 'terms': ['heat exchanger']}, {'element_identifier': '10', 'terms': ['subsystem']}, {'element_identifier': '15', 'terms': ['vapor portion']}, {'element_identifier': '36', 'terms': ['fluid conduit', 'fluid conduits']}, {'element_identifier': '23', 'terms': ['refrigerant via fluid conduit', 'approximately']}]","['1. A refrigeration system (100) comprising: a refrigeration circuit comprising: a gas cooler/condenser (2) configured to remove heat from a refrigerant circulating within the refrigeration circuit and comprising an outlet through which the refrigerant exits the gas cooler/condenser (2); a receiver (6) comprising an inlet fluidly coupled to the outlet of the gas cooler/condenser (2) and configured to collect the refrigerant from the gas cooler/condenser (2), the receiver further comprising an outlet through which the refrigerant exits the receiver (6); and an evaporator (12) comprising an inlet fluidly coupled to the outlet of the receiver (6) and configured to receive the refrigerant from the receiver (6), the evaporator (12) configured to transfer heat into the refrigerant circulating within the refrigeration circuit; and a coolant circuit fluidly separate from the refrigeration circuit and comprising: a heat exchanger (31) configured to transfer heat from the refrigerant circulating within the refrigeration circuit into a coolant circulating within the coolant circuit, the heat exchanger (31) comprising a coolant inlet through which the coolant enters the heat exchanger (31) and a coolant outlet through which the coolant exits the heat exchanger (31); a heat sink (34) configured to remove heat from the coolant circulating within the coolant circuit, the heat sink (34) comprising an inlet fluidly coupled to the coolant outlet of the heat exchanger (31) and through which the coolant enters the heat sink (34), and comprising an outlet fluidly coupled to the coolant inlet of the heat exchanger (31) and through which the coolant exits the heat sink (34); and a magnetocaloric conditioning unit (32) configured to transfer heat from the coolant within a first fluid conduit of the coolant circuit into the coolant within a second fluid conduit of the coolant circuit, the first fluid conduit fluidly coupling the coolant outlet of the heat exchanger (31) to the inlet of the heat sink (34), and the second fluid conduit fluidly coupling the outlet of the heat sink (34) to the coolant inlet of the heat exchanger (31).', '7. The refrigeration system of Claim 1, wherein the coolant circuit comprises: a bypass conduit fluidly coupling the second fluid conduit of the coolant circuit to the first fluid conduit of the coolant circuit in parallel with the heat exchanger (31), thereby providing an alternative flow path for the coolant to travel from the second fluid conduit to the first fluid conduit without passing through the heat exchanger (31); a control valve (38) positioned along the bypass conduit and operable to control a flow of the coolant through at least one of the bypass conduit and the heat exchanger (31).']",False,"['30', '00', '36', '31', '38', '37', '15', '10', '25', '9', '21', '20', '23', '20']" 192,EP_3578945_B1 (1).png,EP3578945B1,METHOD OF FATIGUE TESTING A COMPLEX STRUCTURE,['FIG2'],['FIG2 is an oblique view of a complex structure of the aircraft of FIG1'],"['Referring to FIG2, an oblique view of a complex structure 200 is shown. Complex structure 200 generally comprises a truss structure that forms the airframe structure of aircraft 100. As such, complex structure 200 may form the airframe structure for fuselage 102, tail boom 104, and/or landing gear 114 of aircraft 100. Complex structure 200 may also provide the airframe structure or support structure for a combustion engine, a transmission, controls for the main rotor system 110, a main rotor gearbox, and/or a tail rotor gearbox of aircraft 100. Still further, complex structure 200 may provide the airframe structure for one or more vertical or horizontal stabilizers, wings, and/or other components of aircraft 100. Complex structure 200 is generally formed from a plurality of welded or otherwise joined components (e.g., members 202, 203, 204) and/or subassemblies. As such, complex structure 200 comprises multiple load paths throughout the complex structure 200.']",14,174,oblique view,B,"[{'element_identifier': '201', 'terms': ['joint', 'joints']}, {'element_identifier': '202', 'terms': ['members']}, {'element_identifier': '203', 'terms': ['member']}, {'element_identifier': '206', 'terms': ['displacement instrument', 'displacement instruments']}, {'element_identifier': '204', 'terms': ['member']}, {'element_identifier': '205', 'terms': ['strain gauges', 'strain gauge']}, {'element_identifier': '200', 'terms': ['complex structure']}]","['3. The method (800) of claim 2, wherein:- (i) the flight loads are determined based on at least one of measured displacements and measured strains experienced by the complex airframe structure (200); and/or (ii) wherein the fatigue sensitive points are grouped into families based on at least one of (1) the type of joint and (2) the response to the to the flight loads.']",False,"['200', '12', '204', '201', '203', '205', '202', '206', '2']" 193,EP_3578945_B1 (2).png,EP3578945B1,METHOD OF FATIGUE TESTING A COMPLEX STRUCTURE,['FIG3'],['FIG3 is an oblique view of a subassembly of the complex airframe structure of FIG2'],"['Referring to FIG3, an oblique view of a subassembly 210 of complex structure 200 is shown. In the embodiment shown, subassembly 210 comprises a control tower portion of the airframe structure configured to provide support to the transmission and controls for the main rotor system 110 of aircraft 100. Accordingly, subassembly 210 may comprise provisions for mounting the transmission, actuators for controlling the main rotor system 110, and/or other components of aircraft 100.']",15,81,oblique view,B,"[{'element_identifier': '201', 'terms': ['joint', 'joints']}, {'element_identifier': '210', 'terms': ['subassembly']}, {'element_identifier': '202', 'terms': ['members']}, {'element_identifier': '203', 'terms': ['member']}, {'element_identifier': '206', 'terms': ['displacement instrument', 'displacement instruments']}, {'element_identifier': '204', 'terms': ['member']}, {'element_identifier': '205', 'terms': ['strain gauges', 'strain gauge']}]","['3. The method (800) of claim 2, wherein:- (i) the flight loads are determined based on at least one of measured displacements and measured strains experienced by the complex airframe structure (200); and/or (ii) wherein the fatigue sensitive points are grouped into families based on at least one of (1) the type of joint and (2) the response to the to the flight loads.']",False,"['210', '204', '201', '205', '202', '206', '203', '3', '13']" 194,EP_3578945_B1.png,EP3578945B1,METHOD OF FATIGUE TESTING A COMPLEX STRUCTURE,['FIG1'],['FIG1 is a side view of an aircraft according to this disclosure'],"['Referring to FIG1, a side view of an aircraft 100 is shown. In the embodiment shown, aircraft 100 is a helicopter. However, in other embodiments, aircraft 100 may be any other rotorcraft, vertical take-off and landing (VTOL) aircraft, rotary-wing aircraft, fixed-wing aircraft, and/or other ""manned"" or ""un-manned"" aircraft. Aircraft 100 comprises a fuselage 102 and an empennage or tail boom 104. A tail rotor 106 comprising a plurality of tail rotor blades 108 is operatively coupled to the tail boom 104. Aircraft 100 further comprises a main rotor system 110 having a plurality of main rotor blades 112 that are selectively rotatable to provide lift to the aircraft 100. A skid or landing gear 114 is attached to the fuselage 102 and configured to support the aircraft 100 when the aircraft 100 is grounded. Aircraft 100 also comprises a pilot control system that includes controls for receiving inputs from a pilot or co-pilot to operate the aircraft 100, and a flight control system, which may, for example, include hardware and/or software for controlling the aircraft 100 in flight. Still further, aircraft 100 may also comprise a combustion engine configured to propel the aircraft 100 during forward flight.']",12,235,side view,B,"[{'element_identifier': '100', 'terms': ['aircraft']}, {'element_identifier': '104', 'terms': ['tail boom']}, {'element_identifier': '112', 'terms': ['main rotor blades']}, {'element_identifier': '102', 'terms': ['fuselage']}, {'element_identifier': '108', 'terms': ['tail rotor blades']}, {'element_identifier': '106', 'terms': ['tail rotor']}, {'element_identifier': '110', 'terms': ['main rotor system']}, {'element_identifier': '114', 'terms': ['landing gear']}]","['10. The method (800) of claim 1, or of any of claims 2 to 9, wherein the complex airframe structure (200) forms the airframe structure for at least one of a fuselage (102), tail boom (104), landing gear (114), combustion engine, transmission, and control system of an aircraft (100).']",False,"['100', '110', '112', '108', '106', '08', '11', '104', '102', '1', '114']" 195,EP_3579378_B1 (1).png,EP3579378B1,INTELLIGENT IN-VEHICLE WIRELESS CHARGING DEVICE,['FIG4'],['FIG4 is a block diagram showing the components of a signal modulation and demodulation unit according to an embodiment of the present invention'],"['As shown in FIG4, signal modulation and demodulation unit 3 is an interactive system of the wireless charging device and the electronic devices. Signal modulation and demodulation unit 3 includes multi-channel signal identification module 30, signal processing module 31, protocol module 32, and multi-channel signal transmission module 33 which are connected successively. Multi-channel signal identification module 30 demodulates multi-channel ASK signals simultaneously to realize the conversion from analog signal to digital signal. Signal processing module 31 is responsible for the routing management of the communication of multiple electronic devices, and encodes and encapsulates the digital signals of multi-channel signal identification module 30. The encapsulated signal is translated by protocol module 32 according to the QI standard or the PMA standard. Protocol module 32 passes the translated signal to control unit 2 for processing, and protocol module 32 transmits the control command signal from control unit 2 to multi-channel signal transmission module 33 according to the QI standard or the PMA standard. Multi-channel signal transmission module 33 simultaneously modulates the multi-channel signal according to the FSK mode and loads the modulated signal onto the specified coil of coil module unit 5.']",23,219,block diagram,H,"[{'element_identifier': '51', 'terms': ['Capacitor module']}, {'element_identifier': '5', 'terms': ['coil module unit']}, {'element_identifier': '30', 'terms': ['multi-channel signal identification module']}, {'element_identifier': '4', 'terms': ['driving unit']}, {'element_identifier': '50', 'terms': ['array signal antenna']}, {'element_identifier': '33', 'terms': ['multi-channel signal transmission module']}, {'element_identifier': '31', 'terms': ['signal processing module']}, {'element_identifier': '32', 'terms': ['protocol module']}]","['1. An intelligent in-vehicle wireless charging device, comprising an electric power supply unit (1), a control unit (2), a signal modulation and demodulation unit (3), a driving unit (4), a coil module unit (5), and a communication unit (6); wherein the control unit (2) is connected to the electric power supply unit (1), the control unit (2) is connected to the signal modulation and demodulation unit (3), the control unit (2) is connected to the driving unit (4), and the control unit (2) is connected to the communication unit (6); the driving unit (4) is connected to the coil module unit (5); the coil module unit (5) is connected to the signal modulation and demodulation unit (3); the electric power supply unit (1) is adapted to supply power to other units; the control unit (2) adapted to control the driving unit (4) to drive the coil module unit (5) to generate oscillation; the signal modulation and demodulation unit (3) adapted to demodulate information from electronic devices and simultaneously to modulate information sent by the control unit (2) onto the coil module unit (5); and the communication unit (6) adapted to interact and share information with devices internally on a vehicle or separated from the vehicle through the signal modulation and demodulation unit (3); the signal modulation and demodulation unit (3) comprises a multi-channel signal identification module (30), a signal processing module (31), a protocol module (32), and a multi-channel signal transmission module (33); the multi-channel signal identification module (30), the signal processing module (31), the protocol module (32), and the multi-channel signal transmission module (33) are connected successively; the multi-channel signal identification module (30) is adapted to demodulate multi-channel ASK signals simultaneously to realize a conversion from an analog signal to a digital signal; the signal processing module (31) is adapted to be responsible for a routing management of a communication of multiple electronic devices, and to encode and encapsulate digital signals of the multi-channel signal identification module (30); an encapsulated signal is translated by the protocol module (32) adapted accordingly according to an QI standard or a PMA standard; the protocol module (32) adapted to pass translated signal to the control unit (2) for processing, ; to transmit a control command signal from the control unit (2) to the multi-channel signal transmission module (33) according to the QI standard or the PMA standard; the multi-channel signal transmission module (33) adapted to simultaneously modulate the multi-channel signal according to a FSK mode and to load a modulated signal onto a specified coil of the coil module unit (5).', '5. The intelligent in-vehicle wireless charging device according to claim 1, wherein the coil module unit (5) comprises an array signal antenna (50) and a capacitor module (51); the array signal antenna (50) and the capacitor module (51) are connected to each other; the array signal antenna (50) comprises a plurality of sets of coils arranged according to a spatial distribution of a magnetic field; and the array signal antenna (50) is adapted to control an operation of corresponding single or multiple sets of array antennas through the control unit (2); the capacitor module (51) is an integrated circuit composed of a plurality of capacitors; and the capacitor module (51) is adapted to change capacitance values according to an instruction of the control unit (2) to match the array signal antenna (50) to generate different oscillation frequencies.']",True,"['30', '31', '33', '32', '4', '50', '51', '5']" 196,EP_3579378_B1.png,EP3579378B1,INTELLIGENT IN-VEHICLE WIRELESS CHARGING DEVICE,"['FIG2', ' FIG3']","['FIG3 is a block diagram showing the components of a control unit according to an embodiment of the present invention ', 'FIG2 is a block diagram showing the components of an electric power supply unit according to an embodiment of the present invention']","['As shown in FIG3, control unit 2 is a processing system of the wireless charging device. Control unit 2 includes learning module 20, storage module 21, and control module 22 which are connected successively. Learning module 20 uses a convolutional neural network algorithm to record the ID numbers of various electronic devices, analyzes the battery status of the electronic devices, and stores data in storage module 21. Control module 22 extracts the data from storage module 21, and then performs BMS management for an electronic device ever recorded. Meanwhile, control module 22 optimizes the traditional PID algorithm by using a fuzzy algorithm, which can control the driving operation of driving unit 4 more efficiently and achieve higher power conversion efficiency. ', 'As shown in FIG2, electric power supply unit 1 is a component for supplying power to the entire wireless charging device. Electric power supply unit 1 includes protection module 10, power management module 11, and power output module 12 which are connected successively. Protection module 10 plays a role of isolation to protect the wireless charging device from the impact of the power supply of the vehicle and to prevent the failed wireless charging device from affecting the vehicle. Power management module 11 is configured for a conversion of a wide voltage from 5 V to 25 V, which allows a voltage input in a range from 5 V to 25 V. Power output module 12 provides operating voltage for the wireless charging device.']",42,265,block diagram,H,"[{'element_identifier': '11', 'terms': ['power management module']}, {'element_identifier': '22', 'terms': ['control module']}, {'element_identifier': '2', 'terms': ['control unit']}, {'element_identifier': '20', 'terms': ['learning module']}, {'element_identifier': '6', 'terms': ['communication unit']}, {'element_identifier': '10', 'terms': ['protection module']}, {'element_identifier': '21', 'terms': ['storage module']}, {'element_identifier': '3', 'terms': ['demodulation unit']}]","['1. An intelligent in-vehicle wireless charging device, comprising an electric power supply unit (1), a control unit (2), a signal modulation and demodulation unit (3), a driving unit (4), a coil module unit (5), and a communication unit (6); wherein the control unit (2) is connected to the electric power supply unit (1), the control unit (2) is connected to the signal modulation and demodulation unit (3), the control unit (2) is connected to the driving unit (4), and the control unit (2) is connected to the communication unit (6); the driving unit (4) is connected to the coil module unit (5); the coil module unit (5) is connected to the signal modulation and demodulation unit (3); the electric power supply unit (1) is adapted to supply power to other units; the control unit (2) adapted to control the driving unit (4) to drive the coil module unit (5) to generate oscillation; the signal modulation and demodulation unit (3) adapted to demodulate information from electronic devices and simultaneously to modulate information sent by the control unit (2) onto the coil module unit (5); and the communication unit (6) adapted to interact and share information with devices internally on a vehicle or separated from the vehicle through the signal modulation and demodulation unit (3); the signal modulation and demodulation unit (3) comprises a multi-channel signal identification module (30), a signal processing module (31), a protocol module (32), and a multi-channel signal transmission module (33); the multi-channel signal identification module (30), the signal processing module (31), the protocol module (32), and the multi-channel signal transmission module (33) are connected successively; the multi-channel signal identification module (30) is adapted to demodulate multi-channel ASK signals simultaneously to realize a conversion from an analog signal to a digital signal; the signal processing module (31) is adapted to be responsible for a routing management of a communication of multiple electronic devices, and to encode and encapsulate digital signals of the multi-channel signal identification module (30); an encapsulated signal is translated by the protocol module (32) adapted accordingly according to an QI standard or a PMA standard; the protocol module (32) adapted to pass translated signal to the control unit (2) for processing, ; to transmit a control command signal from the control unit (2) to the multi-channel signal transmission module (33) according to the QI standard or the PMA standard; the multi-channel signal transmission module (33) adapted to simultaneously modulate the multi-channel signal according to a FSK mode and to load a modulated signal onto a specified coil of the coil module unit (5).', '2. The intelligent in-vehicle wireless charging device according to claim 1, wherein the electric power supply unit (1) comprises a protection module (10), a power management module (11), and a power output module (12); the protection module (10), the power management module (11), and the power output module (12) are connected successively; the power management module (11) is configured for a conversion of a wide voltage from 5 V to 25 V; and the power output module (12) is adapted to provide operating voltage for the wireless charging device.', '3. The intelligent in-vehicle wireless charging device according to claim 1, wherein the control unit (2) comprises a learning module (20), a storage module (21), and a control module (22); the learning module (20), the storage module (21), and the control module (22) are connected successively; the learning module (20) is adapted to use a convolutional neural network algorithm to record ID numbers of various electronic devices, to analyse battery status of the electronic devices, and to store data into the storage module (21); the control module (22) adapted to extract the data from the storage module (21), and then to perform a BMS (Battery Management System) management for an electronic device ever recorded; and to use a fuzzy algorithm to control a driving operation of the driving unit (4).']",True,"['3', '2', '6', '11', '2', '10', '20', '21', '3', '22', '8']" 197,EP_3580690_B1 (1).png,EP3580690B1,BAYESIAN METHODOLOGY FOR GEOSPATIAL OBJECT/CHARACTERISTIC DETECTION,['FIG2'],['FIG2 is a top-view illustration of example observations and non-observations according to aspects of the disclosure'],"['FIG2 is a top-view illustration of example observations and non-observations of a particular object 205. In this example, an image capture device moving along a roadway 210 captures images at each of a plurality of capture locations 221-225 along the roadway 210. Each image has an associated field of view 23-235. For example, based on a position and angle of the image capture device at capture location 221, it captures imagery of everything within field of view 231. Similarly, at subsequent capture location 223, the image capture device would capture imagery of objects within field of view 233. When searching for the particular object 205, fields of view 233 and 234, which include the object 205, are considered observations of that object. Fields of view 231, 232, and 235, which do not include the object 205, are considered non-observations.']",20,168,view,G,"[{'element_identifier': '233', 'terms': ['view']}, {'element_identifier': '210', 'terms': ['roadway']}, {'element_identifier': '221', 'terms': ['device at capture location']}, {'element_identifier': '223', 'terms': ['capture location']}, {'element_identifier': '234', 'terms': ['view']}, {'element_identifier': '231', 'terms': ['view']}, {'element_identifier': '205', 'terms': ['object']}, {'element_identifier': '224', 'terms': ['capture location']}]","['1. A method (1100) of determining a location of an object of interest (205, 305), the method comprising: identifying (1110), from a database of images, a set of plural images (341-345) that relate to a geographical region of interest, each of the plural images having associated therewith image capture information including at least an image capture location (221-225) and an image capture orientation; applying an image recognition tool to each image in the set of plural images; determining (1120, 1130), based on the applying of the image recognition tool, which of the images include the object of interest and which of the images do not include the object of interest; for each of multiple candidate locations in the geographical region of interest, each candidate location corresponding to a sub-division (455) of the geographical region of interest and having a prior likelihood that the object of interest is located at the candidate location, calculating (1140) a likelihood value representing a posterior probability of the object of interest existing at the candidate location using the image capture information for images in the set of plural images determined to include the object of interest and using the image capture information for images in the set of plural images determined not to include the object of interest; and determining (1150) the location of the object using the likelihood values for the multiple candidate locations.', '5. The method of claim 1, wherein the multiple candidate locations include locations contained in a field of view (231, 232, 235) of each image of the set of plural images.']",False,"['231', '235', '234', '233', '205', '232', '17', '225', '224', '223', '222', '221', '210', '2']" 198,EP_3580690_B1 (3).png,EP3580690B1,BAYESIAN METHODOLOGY FOR GEOSPATIAL OBJECT/CHARACTERISTIC DETECTION,['FIG6'],['FIG6 is a top-view illustration of another example of observations and non-observations according to aspects of the disclosure'],"[""FIG6 illustrates another example where directional information for the imagery is not used, though images captured from various angles are used. In this example, a first roadway 610 intersects with a second roadway 615. Images are captured from locations 621, 622 on the second roadway 615, and from locations 623-625 on the second roadway. Accordingly, while the fields of view 631-635 are radial, the positions of the capture locations 621-625 along different axes may further increase the accuracy of localization of object 605. For example, as shown, the object 605 is within the fields of view 632 and 633, but not fields of view 631, 634, 635. The confidence score computed for candidate locations within both fields of view 632, 633 should be greater than those computed for other locations. Accordingly, the normalized value for such candidate locations within both fields of view 632, 633, which factors in non-observations from adjacent fields of view 631, 634, 635 should indicate a high likelihood of the object's presence.""]",22,199,view,G,"[{'element_identifier': '605', 'terms': ['object']}, {'element_identifier': '633', 'terms': ['view']}, {'element_identifier': '632', 'terms': ['view']}, {'element_identifier': '621', 'terms': []}, {'element_identifier': '610', 'terms': ['first roadway']}, {'element_identifier': '615', 'terms': ['second roadway']}, {'element_identifier': '631', 'terms': ['view']}]","['1. A method (1100) of determining a location of an object of interest (205, 305), the method comprising: identifying (1110), from a database of images, a set of plural images (341-345) that relate to a geographical region of interest, each of the plural images having associated therewith image capture information including at least an image capture location (221-225) and an image capture orientation; applying an image recognition tool to each image in the set of plural images; determining (1120, 1130), based on the applying of the image recognition tool, which of the images include the object of interest and which of the images do not include the object of interest; for each of multiple candidate locations in the geographical region of interest, each candidate location corresponding to a sub-division (455) of the geographical region of interest and having a prior likelihood that the object of interest is located at the candidate location, calculating (1140) a likelihood value representing a posterior probability of the object of interest existing at the candidate location using the image capture information for images in the set of plural images determined to include the object of interest and using the image capture information for images in the set of plural images determined not to include the object of interest; and determining (1150) the location of the object using the likelihood values for the multiple candidate locations.', '5. The method of claim 1, wherein the multiple candidate locations include locations contained in a field of view (231, 232, 235) of each image of the set of plural images.']",False,"['615', '631', '621', '605', '624', '632', '622', '21', '625', '623', '634', '610', '635', '633', '6']" 199,EP_3580690_B1 (4).png,EP3580690B1,BAYESIAN METHODOLOGY FOR GEOSPATIAL OBJECT/CHARACTERISTIC DETECTION,['FIG7'],['FIG7 is a top-view illustration of an example focused observation using a bounding box according to aspects of the disclosure'],"['FIG7 illustrates another example using a bounding box to narrow the candidate locations for object 705. In this example, during review of image 743, which corresponds to field of view 733, a bounding box 760 is drawn around object of interest 705. In this example the object 705 is a fire hydrant. The bounding box 760 corresponds to a narrower slice 762 of the field of view 733. In this regard, candidate locations for which confidence score and normalized values are computed may be limited to locations within the narrower slice 762. Accordingly, locations outside of the slice 762 but still within the field of view 733 may be considered non-observations and used to more precisely locate the object 705. Moreover, computation may be expedited since a reduced number of candidate locations may be analyzed.']",22,150,view,G,"[{'element_identifier': '705', 'terms': ['object']}, {'element_identifier': '762', 'terms': ['slice']}, {'element_identifier': '743', 'terms': ['image']}, {'element_identifier': '760', 'terms': ['bounding box']}, {'element_identifier': '733', 'terms': ['view']}]","['1. A method (1100) of determining a location of an object of interest (205, 305), the method comprising: identifying (1110), from a database of images, a set of plural images (341-345) that relate to a geographical region of interest, each of the plural images having associated therewith image capture information including at least an image capture location (221-225) and an image capture orientation; applying an image recognition tool to each image in the set of plural images; determining (1120, 1130), based on the applying of the image recognition tool, which of the images include the object of interest and which of the images do not include the object of interest; for each of multiple candidate locations in the geographical region of interest, each candidate location corresponding to a sub-division (455) of the geographical region of interest and having a prior likelihood that the object of interest is located at the candidate location, calculating (1140) a likelihood value representing a posterior probability of the object of interest existing at the candidate location using the image capture information for images in the set of plural images determined to include the object of interest and using the image capture information for images in the set of plural images determined not to include the object of interest; and determining (1150) the location of the object using the likelihood values for the multiple candidate locations.', '5. The method of claim 1, wherein the multiple candidate locations include locations contained in a field of view (231, 232, 235) of each image of the set of plural images.']",False,"['760', '705', '762', '743', '705', '22', '733', '7']" 200,EP_3580690_B1 (5).png,EP3580690B1,BAYESIAN METHODOLOGY FOR GEOSPATIAL OBJECT/CHARACTERISTIC DETECTION,['FIG8'],['FIG8 is a top-view illustration of example obstructions according to aspects of the disclosure'],"[""As mentioned above, computation of the normalized confidence score may be affected by occlusion, such as when other objects impede a view of an object of interest within an image. FIG8 provides a top-view illustration of example obstructions 871-873, resulting in at least partial occlusion of object 805. The obstructions 871-873 in this example are trees, although occlusion may occur from weather conditions such as fog, or any other objects, such as people, monuments, buildings, animals, etc. When computing the confidence score for an image corresponding to field of view 833, such occlusion may be accounted for. For example, a radial falloff function may be used representing the probability that the object 805 would be visible in that image conditional on it's actually being there. As another example, a non-radial or location-dependent falloff function may account for factors like local population density or vegetation density which would increase the risk of occlusion. Accordingly, the confidence score includes a discount factor reflecting the likelihood of a false negative for reasons other than non-presence, such as occlusion.""]",16,210,view,G,"[{'element_identifier': '833', 'terms': ['view']}, {'element_identifier': '805', 'terms': ['object']}]","['1. A method (1100) of determining a location of an object of interest (205, 305), the method comprising: identifying (1110), from a database of images, a set of plural images (341-345) that relate to a geographical region of interest, each of the plural images having associated therewith image capture information including at least an image capture location (221-225) and an image capture orientation; applying an image recognition tool to each image in the set of plural images; determining (1120, 1130), based on the applying of the image recognition tool, which of the images include the object of interest and which of the images do not include the object of interest; for each of multiple candidate locations in the geographical region of interest, each candidate location corresponding to a sub-division (455) of the geographical region of interest and having a prior likelihood that the object of interest is located at the candidate location, calculating (1140) a likelihood value representing a posterior probability of the object of interest existing at the candidate location using the image capture information for images in the set of plural images determined to include the object of interest and using the image capture information for images in the set of plural images determined not to include the object of interest; and determining (1150) the location of the object using the likelihood values for the multiple candidate locations.', '5. The method of claim 1, wherein the multiple candidate locations include locations contained in a field of view (231, 232, 235) of each image of the set of plural images.']",False,"['833', '805', '873', '872', '23', '871', '8']" 201,EP_3580690_B1 (6).png,EP3580690B1,BAYESIAN METHODOLOGY FOR GEOSPATIAL OBJECT/CHARACTERISTIC DETECTION,['FIG9'],['FIG9 is a top-view illustration of an example probability of obstructions affecting observations according to aspects of the disclosure'],"['A likelihood of occlusion may increase as a distance between an image capture location and an object of interest increases. FIG9 illustrates an example probability of obstructions affecting observations. Object 905 is within a field of view 933 of an image captured from location 923. The field of view 933 is subdivided into different regions 982, 984, 986 based on the probability of occlusion. For example, for any objects within first region 982, which is closest to the image capture location 923, the probability of occlusion is lowest. For objects within second region 984, such as object 905, the probability of occlusion is higher than for the first region 982. For region 986, which is furthest from the image capture location 923, the risk of occlusion is greatest. In some examples, the probabilities may be adjusted using iterative training based on observations.']",21,160,view,G,"[{'element_identifier': '982', 'terms': ['first region']}, {'element_identifier': '986', 'terms': ['region']}, {'element_identifier': '923', 'terms': ['location']}, {'element_identifier': '905', 'terms': ['Object']}, {'element_identifier': '984', 'terms': ['objects within second region']}, {'element_identifier': '933', 'terms': ['view']}]","['1. A method (1100) of determining a location of an object of interest (205, 305), the method comprising: identifying (1110), from a database of images, a set of plural images (341-345) that relate to a geographical region of interest, each of the plural images having associated therewith image capture information including at least an image capture location (221-225) and an image capture orientation; applying an image recognition tool to each image in the set of plural images; determining (1120, 1130), based on the applying of the image recognition tool, which of the images include the object of interest and which of the images do not include the object of interest; for each of multiple candidate locations in the geographical region of interest, each candidate location corresponding to a sub-division (455) of the geographical region of interest and having a prior likelihood that the object of interest is located at the candidate location, calculating (1140) a likelihood value representing a posterior probability of the object of interest existing at the candidate location using the image capture information for images in the set of plural images determined to include the object of interest and using the image capture information for images in the set of plural images determined not to include the object of interest; and determining (1150) the location of the object using the likelihood values for the multiple candidate locations.', '5. The method of claim 1, wherein the multiple candidate locations include locations contained in a field of view (231, 232, 235) of each image of the set of plural images.']",False,"['933', '986', '984', '982', '923', '905', '24', '9']" 202,EP_3582908_B1 (3).png,EP3582908B1,APPARATUS AND METHOD TO GUIDE METAL PRODUCTS,['FIG4'],['FIG4 is a view from above of a guide apparatus according to another embodiment'],"['According to a variant embodiment (FIG4), the guide apparatus 10 comprises two guide rolls 13 located adjacent to each other and having their own axes of rotation X parallel to each another.', 'According to a variant embodiment (FIG4), the support arms 12 can be pivoted in an intermediate zone of the length of the support arms 12, and can support the guide rolls 13 in correspondence with one of their ends.', 'According to another variant embodiment, shown by way of example in FIG4, each adjustment device 24 is associated with one end of the support arm 12, opposite the support end of the respective guide roll 13.', 'According to the solution of FIG4, the adjustment screw 25 is screwed onto the corresponding support arm 12 and one of its ends abuts against the support body 11. By screwing or unscrewing the adjustment screw 25 it is possible to adjust the position of the respective support arm 12 and therefore of the guide roll 13 associated with it.', 'In accordance with a possible variant embodiment, shown by way of example only in FIG4, both the support arms 12 are connected, in correspondence with their ends, by an elastic element 28 provided to keep both support arms 12 distanced from one another.', 'According to another solution (FIG4), the detection devices 19 are installed on the support body 11 and the adjustment devices 24 have a portion 35 which selectively contacts the detection devices 19 to transmit the stresses from the metal product to the detection devices 19 through the adjustment devices 24. In particular, it can be provided that the adjustment screw 25 has the portion 35 positioned in contact with the detection devices 19.']",14,315,view,B,"[{'element_identifier': '24', 'terms': ['adjustment devices', 'adjustment device']}, {'element_identifier': '28', 'terms': ['elastic element']}, {'element_identifier': '35', 'terms': ['portion']}, {'element_identifier': '14', 'terms': ['gap']}, {'element_identifier': '12', 'terms': ['support arms', 'support arm']}, {'element_identifier': '19', 'terms': ['detection devices', 'detection device']}, {'element_identifier': '11', 'terms': ['support body']}, {'element_identifier': '18', 'terms': ['pivoting elements']}, {'element_identifier': '4', 'terms': ['diameter comprised between']}, {'element_identifier': '31', 'terms': ['pin']}, {'element_identifier': '112', 'terms': ['defined between rolling rolls']}, {'element_identifier': '27', 'terms': ['drive members', 'drive member']}, {'element_identifier': '10', 'terms': ['guide apparatus']}, {'element_identifier': '29', 'terms': ['command unit']}, {'element_identifier': '110', 'terms': ['rolling apparatus']}, {'element_identifier': '13', 'terms': ['rolls', 'roll']}]","['1. Apparatus to guide a metal product, said apparatus comprising, a support body (11), a plurality of support arms (12) associated with said support body (11), and a plurality of guide rolls (13) installed rotating in an idle manner on said support arms (12) and defining between them a roller guide gap (14) for said metal product, wherein a respective adjustment device (24) is associated with each support arm (12) and configured to adjust, independently from the other adjustment devices (24), the position of each of said guide rolls (13), and wherein said apparatus comprises detection devices (19), each associated with one of said support arms (12), configured to detect the stresses induced by said metal product on each of said guide rolls (13), characterised in that each adjustment device (24) comprises its own drive member (27) selected between an electric rotary motor and an electric linear actuator to adjust the position of each of said guide rolls (13), and in that said apparatus comprises a control and command unit (29) connected to said detection devices (19) and to said drive members (27), and configured to command the drive of the respective one of said drive members (27) as a function of data detected by said detection devices (19).', '4. Apparatus as in claim 1, 2 or 3, characterized in that an elastic element (28) is connected to each support arm (12) and is configured to exert on the support arm (12) an action of distancing the guide rolls (13) from the roller guide axis (G) defined by them, and in that said detection devices (19) are installed in the connection zone of said elastic element (28) to said support arm (12) and/or to the support body (11).', '5. Apparatus as in claim 1, characterized in that said detection devices (19) are installed on said support body (11) and said adjustment devices (24) have a portion (35) that selectively comes into contact with said detection devices (19) to transmit the stresses from said metal product to said detection devices (19) through said adjustment devices (24).', '7. Apparatus as in any claim hereinbefore, characterized in that said support arms (12) are pivoted to said support body (11) by pivoting elements (18), and in that said adjustment devices (24) are configured to make said support arms (12) rotate around said pivoting elements (18) of said support arms (12).', '8. Rolling machine comprising at least a rolling apparatus (110) and at least a guide apparatus (10) as in any claim hereinbefore and installed on said rolling apparatus (110).']",False,"['110', '110', '10', '31', '13', '27', '29', '12', '18', '11', '24', '14', '19', '19', '35', '28', '35', '15', '112', '13', '31', '12', '18', '24', '27', '4']" 203,EP_3586601_A1 (2).png,EP3586601A1,DEVICE AND METHOD FOR CHANGING CLEANING SHOE SHAKER ARM ANGLE,['FIG3'],['FIG3 is an isometric view of the detailed view of FIG2'],"[""As best shown in FIG3, the bracket 136 includes a vertical portion 140 that is fixed to the side 112 of the shoe 104, a slanted upwardly extending portion 142 that depends from the vertical portion 140, and a downwardly extending portion 144 that depends from and extends orthogonally to the slanted portion 142. The slanted upwardly extending portion 142 is oriented tangentially to the arc trajectory 'T' of the end 110 of the rocker arm 106 that is connected to the shoe 104. An acute interior angle C (FIG2) is formed between the slanted portion 142 and the vertical portion 140. The portion 142 is also slanted with respect to a horizontal plane running along the top side of the shoe 104 by an angle D. The vertical portion 140 is orthogonal to the horizontal plane."", 'A plurality of thru-holes 146a-146d (referred to either individually or collectively as hole(s) 146) are disposed through the portion 142. The holes 146 are aligned and evenly spaced apart in a row along an axis E (FIG3) running through the center of the portion 142. The holes 146 are each sized to receive a fastener 138. Using the holes 146 and the fasteners 138, the bearing 134 may be positioned at different locations on the mounting surface 143. Holes 146a and 146c are used together as shown to receive the two fasteners 138 attached to the bearing 134 in a first location of the bearing 134. Alternatively, the holes 146b and 146d may be used together to receive the two fasteners 138 attached to the bearing 134 in a second location of the bearing 134. More holes 146 may be disposed along the length of the portion 142 providing more positioning options for the bearing 134 on the portion.']",11,324,isometric view,A,"[{'element_identifier': '106', 'terms': ['arm', 'arms']}, {'element_identifier': '112', 'terms': ['side']}, {'element_identifier': '134', 'terms': ['bearing']}, {'element_identifier': '104', 'terms': ['shoe']}]","['1. A cleaning system (100) for a combine harvester having an adjustable throwing angle, the cleaning system comprising: a shoe (104) for holding a sieve of the cleaning system; a mounting surface (143) disposed on the shoe (104); and a rocker arm (106) either movably or removably connected to the mounting surface (143), characterized in that the rocker arm (106) being configured to be mounted to the mounting surface (143) at at least two different locations on the mounting surface (143), each location resulting in a different throwing angle (A) of the shoe (104) of the cleaning system (100).']",False,"['42', '104', '10', '106', '112', '134']" 204,EP_3586601_A1 (5).png,EP3586601A1,DEVICE AND METHOD FOR CHANGING CLEANING SHOE SHAKER ARM ANGLE,['FIG6'],['FIG6 depicts a side elevation view of a cleaning system of a combine according to yet another alternative embodiment'],"[""FIG6 depicts a fourth exemplary embodiment of a cleaning system. The fourth embodiment is substantially similar to the first embodiment with the exception that the bracket 136 is omitted and replaced by a series of holes 600 (e.g., six holes) that are disposed in the side 112 of the shoe 104. The holes 600 are aligned along the arc trajectory 'T' of the end 110 of the rocker arm 106. In use, the end 110 of the rocker arm 106 could be mounted to two of those six holes 600 using fasteners 138 such that the throwing angle A of the rocker arm 106 is maintained at the first predetermined angle. Alternatively, the end 110 of the rocker arm 106 could be mounted to two different holes of the six holes 600 such that the throwing angle A of the rocker arm 106 is maintained at the second predetermined angle.""]",19,162,side view,A,"[{'element_identifier': '112', 'terms': ['side']}, {'element_identifier': '110', 'terms': ['end']}, {'element_identifier': '600', 'terms': ['holes']}, {'element_identifier': '104', 'terms': ['shoe']}]","['1. A cleaning system (100) for a combine harvester having an adjustable throwing angle, the cleaning system comprising: a shoe (104) for holding a sieve of the cleaning system; a mounting surface (143) disposed on the shoe (104); and a rocker arm (106) either movably or removably connected to the mounting surface (143), characterized in that the rocker arm (106) being configured to be mounted to the mounting surface (143) at at least two different locations on the mounting surface (143), each location resulting in a different throwing angle (A) of the shoe (104) of the cleaning system (100).', '3. The cleaning system of claim 1 or 2, characterized in that the rocker arm (106) includes two opposed ends (108, 110), one opposed end (110) being releasably connected to the mounting surface (143), and the other opposed end (108) being connected to a fixed point on the combine harvester.']",False,"['104', '600', '112', '13', '110', '10']" 205,EP_3586601_A1 (6).png,EP3586601A1,DEVICE AND METHOD FOR CHANGING CLEANING SHOE SHAKER ARM ANGLE,['FIG7'],['FIG7 depicts a side elevation view of a cleaning system of a combine according to still another alternative embodiment '],"['FIG7 depicts a fifth exemplary embodiment of a cleaning system. The fifth embodiment is substantially similar to the first embodiment with the exception that the first end 110 of the rocker arm 106 is fixed to the shoe 104 at only one position, and the second end 108 of the rocker arm 106 is selectively mounted to a subset of the series of holes 702 (e.g., five holes) that are disposed on a curved surface 704 of the frame 102 using fasteners 130. The curve 704 is centered about the axis passing through the end 110 of the rocker arm 106. In use, the end 108 of the rocker arm 106 could be mounted to two of those five holes 702 such that the throwing angle A of the rocker arm 106 is maintained at the first predetermined angle. Alternatively, the end 108 of the rocker arm 106 could be mounted to two different holes of the five holes 702 such that the throwing angle A of the rocker arm 106 is maintained at the second predetermined angle.']",19,189,side view,A,"[{'element_identifier': '704', 'terms': ['curved surface']}, {'element_identifier': '104', 'terms': ['shoe']}, {'element_identifier': '702', 'terms': ['holes']}, {'element_identifier': '102', 'terms': ['frame']}, {'element_identifier': '108', 'terms': ['end']}]","['1. A cleaning system (100) for a combine harvester having an adjustable throwing angle, the cleaning system comprising: a shoe (104) for holding a sieve of the cleaning system; a mounting surface (143) disposed on the shoe (104); and a rocker arm (106) either movably or removably connected to the mounting surface (143), characterized in that the rocker arm (106) being configured to be mounted to the mounting surface (143) at at least two different locations on the mounting surface (143), each location resulting in a different throwing angle (A) of the shoe (104) of the cleaning system (100).', '3. The cleaning system of claim 1 or 2, characterized in that the rocker arm (106) includes two opposed ends (108, 110), one opposed end (110) being releasably connected to the mounting surface (143), and the other opposed end (108) being connected to a fixed point on the combine harvester.', '5. The cleaning system of claim 3 or 4 characterized in that the cleaning system further comprises a frame of the combine harvester, said other opposed end being mounted to the frame (102).']",False,"['104', '14', '704', '702', '102', '702', '702', '108']" 206,EP_3586657_A2 (2).png,EP3586657A2,E-LIQUID DELIVERY SYSTEM FOR PERSONAL VAPORIZERS,['FIG3'],['FIG3 is a block diagram representation of a vaporizer system incorporating liquid preheating according to an embodiment of the invention'],"['It has been found that the ability to controllably pump vaporizable liquids can be significantly affected by their viscosities. In some applications, it may be desirable to reduce the viscosity of a vaporizable liquid to enhance its flow properties and to achieve a precise, repeatable rate of delivery to the vaporization chamber. In many instances, this can be achieved by preheating the vaporizable liquid upstream of the micro-pump. FIG3 is a block diagram of a generalized vaporizer system 200 with a pre-heating arrangement. As shown in the block diagram, a micro-pump 250 such as a PZE pump is used to draw liquid from a reservoir 240 and into contact with a vaporization heating element 260 in a vaporization chamber 230. Prior to the liquid passing through the pump 250, however, the liquid passes through a preheat chamber 255, where the liquid undergoes temperature conditioning. Through preheating, the liquid is brought to a temperature selected to produce a desired viscosity, which, in turn, is tailored to allow precise, metered flow control of the liquid through the pump 250 and into the vaporization chamber 230. In some embodiments and for typical e-liquids, the desired temperature may be in a range of 75-95 °F. In particular embodiments, the desired temperature may be in a range of 78-82 °F and is preferably about 80 °F. The preheat chamber 255, pump 250, and primary heating element 260 are all controllable through control modules 292 of a main control unit 290 of the device. Temperature control for the preheat chamber 255 and heating element 260 may be accomplished through the use of thermostatic switches 294.']",20,311,block diagram,A,"[{'element_identifier': '230', 'terms': ['vaporization chamber']}, {'element_identifier': '280', 'terms': ['user input arrangement']}, {'element_identifier': '290', 'terms': ['control unit']}, {'element_identifier': '11', 'terms': ['°F.Clause']}, {'element_identifier': '294', 'terms': ['thermostatic switches']}, {'element_identifier': '250', 'terms': ['pump']}, {'element_identifier': '240', 'terms': ['reservoir']}, {'element_identifier': '255', 'terms': ['preheat chamber']}, {'element_identifier': '292', 'terms': ['controllable through control modules']}, {'element_identifier': '260', 'terms': ['heating element']}]","['1. A personal vaporizer comprising: an annular main body defining a main body interior; a vaporization chamber within the main body interior; a vaporization heating element disposed within the vaporization chamber, the vaporization heating element having a vaporization heating surface; an air flow passage from one or more air intake openings in the case wall to the vaporization chamber; a vaporization mixture flow passage extending from the vaporization chamber to an exit port; a liquid reservoir configured for storage of a vaporizable liquid and having a reservoir exit port; a liquid transport arrangement for transporting vaporizable liquid from the liquid reservoir to the vaporization chamber, the liquid transport arrangement comprising a first liquid flow duct extending from the reservoir exit port, and a piezoelectric pump operatively connected to the first liquid flow duct for drawing the vaporizable liquid from the reservoir, through the liquid flow duct, and into the vaporization chamber through a nozzle positioned adjacent or in contact with the vaporization heating element so that liquid exiting the nozzle is heated by the vaporization heating surface.']",False,"['290', '292', '280', '292', '294', '292', '294', '11', '230', '260', '240', '255', '250']" 207,EP_3586657_A2 (3).png,EP3586657A2,E-LIQUID DELIVERY SYSTEM FOR PERSONAL VAPORIZERS,['FIG4'],['FIG4 is a cross-sectional view of a personal vaporizer according to an embodiment of the invention'],"['There are many possible configurations of personal vaporizers that could be used to implement the preheating methodology of the invention. FIG4 illustrates an illustrative embodiment of a personal vaporizer 300 that incorporates this methodology. The vaporizer 300 comprises a cylindrical casing 320 having a distal end 321 and a proximal end 322. At its proximal end 322, the casing 320 is formed into a mouthpiece 324 having a passage 326. The casing 320 also has one or more air holes 328 to allow air to flow from the atmosphere into a vaporization chamber 330 which may be separated from the exit chamber 327 by a filter 370. The personal vaporizer 300 further comprises a fluid reservoir 340 in which is disposed a vaporizable liquid 342. The fluid reservoir 340 may be configured as a simple tank or may be or include a housed or unhoused adsorptive or absorptive material or structure that retains the vaporizable liquid 342. In either case, the reservoir 340 has a proximal reservoir exit port 344. A heating element 360 is positioned within the vaporization chamber 330. The personal vaporizer 300 also comprises a battery 380 and a control unit 390.']",18,207,cross-sectional view,A,"[{'element_identifier': '350', 'terms': ['fluid transport arrangement', 'fluid transport structure']}, {'element_identifier': '326', 'terms': ['passage']}, {'element_identifier': '324', 'terms': ['mouthpiece']}, {'element_identifier': '355', 'terms': ['chamber']}, {'element_identifier': '330', 'terms': ['vaporization chamber']}, {'element_identifier': '322', 'terms': ['proximal end']}, {'element_identifier': '12', 'terms': ['first liquid flow duct.Clause']}, {'element_identifier': '352', 'terms': ['conduit']}, {'element_identifier': '357', 'terms': ['exit port']}, {'element_identifier': '344', 'terms': ['proximal reservoir exit port']}, {'element_identifier': '354', 'terms': ['PZE pump']}, {'element_identifier': '360', 'terms': ['heating element']}, {'element_identifier': '390', 'terms': ['control unit']}, {'element_identifier': '380', 'terms': ['battery']}, {'element_identifier': '300', 'terms': ['vaporizer']}, {'element_identifier': '356', 'terms': ['entrance port']}, {'element_identifier': '392', 'terms': ['pump controller']}, {'element_identifier': '340', 'terms': ['reservoir']}, {'element_identifier': '327', 'terms': ['exit chamber']}, {'element_identifier': '351', 'terms': ['first fluid conduit']}, {'element_identifier': '328', 'terms': ['air holes']}, {'element_identifier': '342', 'terms': ['liquid']}, {'element_identifier': '353', 'terms': ['nozzle end']}, {'element_identifier': '370', 'terms': ['filter']}, {'element_identifier': '320', 'terms': ['casing']}, {'element_identifier': '359', 'terms': ['elements']}]","['1. A personal vaporizer comprising: an annular main body defining a main body interior; a vaporization chamber within the main body interior; a vaporization heating element disposed within the vaporization chamber, the vaporization heating element having a vaporization heating surface; an air flow passage from one or more air intake openings in the case wall to the vaporization chamber; a vaporization mixture flow passage extending from the vaporization chamber to an exit port; a liquid reservoir configured for storage of a vaporizable liquid and having a reservoir exit port; a liquid transport arrangement for transporting vaporizable liquid from the liquid reservoir to the vaporization chamber, the liquid transport arrangement comprising a first liquid flow duct extending from the reservoir exit port, and a piezoelectric pump operatively connected to the first liquid flow duct for drawing the vaporizable liquid from the reservoir, through the liquid flow duct, and into the vaporization chamber through a nozzle positioned adjacent or in contact with the vaporization heating element so that liquid exiting the nozzle is heated by the vaporization heating surface.', '2. A personal vaporizer according to claim 1 further comprising: a pump controller in electrical communication with the piezoelectric pump and configured for controlling the piezoelectric pump so as to maintain a desired flow rate of liquid through the nozzle.']",False,"['300', '324', '360', '370', '320', '32', '351', '352', '328', '344', '357', '380', '326', '12', '390', '340', '392', '356', '359', '322', '330', '355', '353', '354', '327', '350', '342']" 208,EP_3586657_A2 (4).png,EP3586657A2,E-LIQUID DELIVERY SYSTEM FOR PERSONAL VAPORIZERS,['FIG5'],['FIG5 is a cross-sectional view of a fluid transport arrangement according to an embodiment of the invention '],"[""FIG5 illustrates an alternative fluid transport arrangement 450 that could be used in the personal vaporizer 300. In this embodiment, the fluid transport arrangement 450 has a single fluid transport conduit 452 extending from the reservoir exit 344 and through the preheat chamber 455 to the PZE pump 454. Within the preheat chamber 455, a coiled heating element 459 is positioned so as to surround the conduit 452. The heating element 459 may be separated from, in contact with, or incorporated into the conduit 452 and is configured to heat liquid 342' passing through the conduit 452 so as to establish desired flow properties upstream of the PZE pump. The PZE pump 453 and nozzle end 453 are substantially similar to those of the previous embodiments.""]",19,136,cross-sectional view,A,"[{'element_identifier': '455', 'terms': ['preheat chamber']}, {'element_identifier': '452', 'terms': ['conduit']}, {'element_identifier': '328', 'terms': ['air holes']}, {'element_identifier': '342', 'terms': ['liquid']}, {'element_identifier': '344', 'terms': ['proximal reservoir exit port']}, {'element_identifier': '453', 'terms': ['PZE pump', 'nozzle end']}, {'element_identifier': '360', 'terms': ['heating element']}, {'element_identifier': '454', 'terms': ['PZE pump']}, {'element_identifier': '320', 'terms': ['casing']}, {'element_identifier': '459', 'terms': ['heating element']}, {'element_identifier': '330', 'terms': ['vaporization chamber']}, {'element_identifier': '450', 'terms': ['fluid transport arrangement']}, {'element_identifier': '13', 'terms': ['first liquid flow duct.Clause']}]","['1. A personal vaporizer comprising: an annular main body defining a main body interior; a vaporization chamber within the main body interior; a vaporization heating element disposed within the vaporization chamber, the vaporization heating element having a vaporization heating surface; an air flow passage from one or more air intake openings in the case wall to the vaporization chamber; a vaporization mixture flow passage extending from the vaporization chamber to an exit port; a liquid reservoir configured for storage of a vaporizable liquid and having a reservoir exit port; a liquid transport arrangement for transporting vaporizable liquid from the liquid reservoir to the vaporization chamber, the liquid transport arrangement comprising a first liquid flow duct extending from the reservoir exit port, and a piezoelectric pump operatively connected to the first liquid flow duct for drawing the vaporizable liquid from the reservoir, through the liquid flow duct, and into the vaporization chamber through a nozzle positioned adjacent or in contact with the vaporization heating element so that liquid exiting the nozzle is heated by the vaporization heating surface.']",False,"['452', '328', '360', '344', '13', '459', '330', '453', '342', '320', '454', '455', '450']" 209,EP_3586657_A2.png,EP3586657A2,E-LIQUID DELIVERY SYSTEM FOR PERSONAL VAPORIZERS,['FIG1'],['FIG1 is a cross-sectional view of a prior art personal vaporizer'],"['With reference to FIG1, a typical personal vaporizer 10 comprises a cylindrical casing 20 having a distal end 21 and a proximal end 22. At its proximal end 22, the casing 20 is formed into a mouthpiece 24 having a passage 26 providing fluid communication between the atmosphere and an exit chamber 27 inside the casing 20. The casing 20 also has one or more air holes 28 to allow air to flow from the atmosphere into a vaporization chamber 30 inside the casing 20 when a relative vacuum is applied at the mouthpiece passage 26 (e.g., by inhalation of a device user). The air drawn in through the air hole(s) 28 passes through a filter 70 which divides the vaporization chamber 30 and the exit chamber 27.', 'In all of the embodiments disclosed herein, including the prior art vaporizer 10 of FIG1, the various heating elements-particularly those that may be come in direct contact with the vaporizable liquid-may be replaced with elements formed from graphite/carbon fibers. The advantage of elements formed from such fibers is that they will not react or decompose at the high temperatures needed to vaporize the vaporizable liquids used in the vaporizers of the invention. This is particularly significant in personal vaporizers, because it presents little or no chance of contributing undesirable constituents (e.g., heavy metals) to the vaporization products of the device, either through interfacial thermal reaction or chemical leaching to the e-liquid or the vapor.']",13,271,cross-sectional view,A,"[{'element_identifier': '24', 'terms': ['mouthpiece']}, {'element_identifier': '28', 'terms': ['holes']}, {'element_identifier': '30', 'terms': ['chamber']}, {'element_identifier': '80', 'terms': ['is preferably about']}, {'element_identifier': '22', 'terms': ['proximal end']}, {'element_identifier': '1', 'terms': ['invention. Clause']}, {'element_identifier': '20', 'terms': ['casing']}, {'element_identifier': '40', 'terms': ['reservoir']}, {'element_identifier': '90', 'terms': ['control unit']}, {'element_identifier': '27', 'terms': ['exit chamber']}, {'element_identifier': '10', 'terms': ['vaporizer']}, {'element_identifier': '50', 'terms': ['fluid transport structure']}, {'element_identifier': '26', 'terms': ['passage']}, {'element_identifier': '21', 'terms': ['filed June', 'distal end']}, {'element_identifier': '70', 'terms': ['filter']}, {'element_identifier': '60', 'terms': ['heating element']}]","['1. A personal vaporizer comprising: an annular main body defining a main body interior; a vaporization chamber within the main body interior; a vaporization heating element disposed within the vaporization chamber, the vaporization heating element having a vaporization heating surface; an air flow passage from one or more air intake openings in the case wall to the vaporization chamber; a vaporization mixture flow passage extending from the vaporization chamber to an exit port; a liquid reservoir configured for storage of a vaporizable liquid and having a reservoir exit port; a liquid transport arrangement for transporting vaporizable liquid from the liquid reservoir to the vaporization chamber, the liquid transport arrangement comprising a first liquid flow duct extending from the reservoir exit port, and a piezoelectric pump operatively connected to the first liquid flow duct for drawing the vaporizable liquid from the reservoir, through the liquid flow duct, and into the vaporization chamber through a nozzle positioned adjacent or in contact with the vaporization heating element so that liquid exiting the nozzle is heated by the vaporization heating surface.']",False,"['10', '24', '60', '70', '20', '21', '80', '28', '26', '90', '40', '22', '30', '27', '50', '1']" 210,EP_3586682_A1 (2).png,EP3586682A1,FIRMNESS CONTROLLING APPARATUS FOR A BED OR SEATING ARRANGEMENT,['FIG5'],"['FIG5 shows a cross-sectional side view of the firmness control apparatus of FIG1 in a contracted state, with a retraction device arranged beneath the non-elastic flexible elongate elements']","['The non-elastic flexible elongate elements may also be retracted in other ways. One such alternative is illustrated in FIG5, where the non-elastic flexible elongate elements 12 are led downwards via two rollers 15b or sliding surfaces. The non-elastic flexible elongate elements may then be pulled downwardly by a plunger 15c or the like. The pulling may occur downwardly, but may also occur in the plane of the frame, e.g. by being led via a further roller 15d, as shown in the illustrative example. In this embodiment, the retraction device is arranged beneath the plane in which the non-elastic flexible elongate elements extend. The plunger may be operated manually or automatically, e.g. by being connected to an electrical pump.']",33,138,cross-sectional view,A,"[{'element_identifier': '5', 'terms': ['e.g. discussed in US']}, {'element_identifier': '12', 'terms': ['non-elastic flexible elongate element', 'non-elastic flexible elongate elements']}, {'element_identifier': '4', 'terms': ['US']}, {'element_identifier': '15', 'terms': ['retraction device']}, {'element_identifier': '3', 'terms': ['inlay']}, {'element_identifier': '13', 'terms': ['elastic flexible elongate element', 'elastic flexible elongate elements']}]","['1. A firmness controlling apparatus for use in a bed arrangement or a seating arrangement, the firmness controlling apparatus comprising: a rigid frame having two opposed sides; at least one non-elastic flexible elongate element extending between the two opposed sides, each non-elastic flexible elongate element being provided with two ends, wherein each end of the non-elastic flexible elongate element is directly or indirectly connected to one of the opposed sides, and wherein at least one of the ends of each non-elastic flexible elongate element is indirectly connected to one of the opposed sides via an elastic flexible elongate element; a plurality of elongate springs extending in a flat or curved plane, each elongate spring having two ends, the ends of each elongate spring being attached to one of the at least one non-elastic flexible elongate elements at two separated connections; and a retraction device arranged to tighten and slack the non-elastic flexible elongate element(s) between said two separated connections, thereby adjusting the distance between the two separated connections of each non-elastic flexible elongate element, and thereby controlling the curvature and height of the elongate springs.']",True,"['13', '13', '15', '12', '3', '13', '13', '13', '15', '12', '4', '13', '13', '12', '5']" 211,EP_3586690_A1.png,EP3586690A1,"MACHINE FOR PROCESSING COMPOSITE PRODUCTS CONSISTING OF MIXTURES, MIXING ELEMENT AND MIXING ASSEMBLY",['FIG1'],"['FIG1 shows a schematic section view of an example of the instant beverage dispensing machine object of the invention, where the main parts and elements it comprises can be seen']","['FIG1 shows a diagram of a machine 1 according to the present invention which may comprise a cooling/heating module 2 for cooling or heating the water or liquid which is used to prepare the beverage and regulating the temperature thereof; and at least one product holding and dosing module 3 with a housing for holding the powder which is added to said liquid to prepare the beverage, either in capsules or in bulk, at least one dosing device for dosing said powder, and a regulator for regulating volume, and a dosing element for dosing liquid, preferably water, as well as other additional devices that may be required for correctly meting out the products into the mixing element. Additionally, the machine comprises a dispensing module 4 comprising solenoid valves which regulate the exit of the liquid into the mixing elements which are moved to said dispensing module. It preferably further comprises a dispenser for dispensing containers 5 and a dispenser for dispensing covers 6. Both elements, i.e., container 5 and cover 6, form the mixing element which sometimes can be made up exclusively by a mixing container 5, without any cover 6. Said dispenser or dispensers deposit the mixing container 5 and the cover 6 in a mixing space 7 having different mechanisms for moving a container 5 and/or the cover 6 of said container. In a preferred embodiment, said dispensing module 4 would comprise the dispensing module for dispensing containers 5 and the dispensing module for dispensing covers 6.']",31,270,schematic section view,A,"[{'element_identifier': '8', 'terms': ['base']}, {'element_identifier': '5', 'terms': ['container', 'containers']}, {'element_identifier': '12', 'terms': ['device']}]","['1. A mixture-based composite product processing machine which processes composite products based on two or more ingredients by means of at least mixing and dispensing same, having said machine at least one upper dispenser for pouring ingredients and a lower base (8), with a mixing space determined between both for housing a mixing element (5, 6) to be located on the base (8), characterized in that it comprises at least one spinning head with a coupling element (9, 11) arranged between said head and the mixing space, said coupling element (9, 11) having an anchoring structure (10) for anchoring to the spinning head and a coupling structure (92, 112) for the mixing element arranged in the mixing space.', '8. The machine according to the preceding claims, characterized in that it comprises a dispensing module for dispensing covers (6) of the mixing elements and/or containers (5) of the mixing elements.']",False,"['5', '12', '8']" 212,EP_3586716_A1 (2).png,EP3586716A1,ENDOSCOPE DEVICE,"['FIG3', ' FIG4']","['FIG3 is a schematic diagram illustrating a configuration of an imaging unit according to the first embodiment of the present invention ', 'FIG4 is a diagram illustrating illumination timings in the endoscope apparatus according to the first embodiment of the present invention']","['FIG3 is a schematic diagram illustrating the configuration of the imaging unit 92. The imaging unit 92 has, as illustrated in FIG3, a first imaging element 921, a second imaging element 922, and a prism 923. In the imaging unit 92, observation light from the outside enters the prism 923 via the lens unit 91, and light spectrally separated by the prism 923 enters the first imaging element 921 and second imaging element 922. ', 'Illumination timings of the illumination light emitted by the light source device 6 will be described next by reference to FIG4. FIG4 is a diagram illustrating illumination timings in the endoscope apparatus according to the first embodiment of the present invention. According to the description hereinafter, under control by the control unit 55, the light source control unit 63 controls each unit and causes the illumination light to be emitted. Under control by the control unit 55, the imaging unit 92 and the light source device 6 operate in synchronization with each other. Because the first imaging element 921 and the second imaging element 922 are CMOSs, the electric charge is sequentially read per line.']",41,207,"diagram, schematic diagram",A,"[{'element_identifier': '923', 'terms': ['prism']}, {'element_identifier': '921', 'terms': ['first imaging element']}, {'element_identifier': '922', 'terms': ['second imaging element']}, {'element_identifier': '92', 'terms': ['imaging unit']}]","['1. An endoscope apparatus, comprising: a light source device configured to continuously emit first light of a first wavelength band, and sequentially emit second light of plural second wavelength bands different from the first wavelength band and different from each other; and an imaging device including: a spectroscopic unit configured to spectrally separate light from a subject, the light arising from illumination light emitted by the light source device, into light of the first wavelength band and light of the second wavelength bands; a first imaging element configured to generate a first image signal by receiving and photoelectrically converting the light of the first wavelength band spectrally separated by the spectroscopic unit; and a second imaging element configured to generate a second image signal by respectively receiving and photoelectrically converting the light of the second wavelength bands spectrally separated by the spectroscopic unit.']",True,"['92', '921', '922', '923', '16']" 213,EP_3586716_A1 (5).png,EP3586716A1,ENDOSCOPE DEVICE,"['FIG8', ' FIG9']","['FIG8 is a schematic diagram illustrating arrangement of light (spots) acquired by two imaging elements of the imaging unit according to the fourth embodiment of the present invention ', 'FIG9 is a schematic diagram illustrating a configuration of an imaging unit according to a fifth embodiment of the present invention']","['Imaging signals acquired by the first imaging element 921 and the second imaging element 922 will be described next by reference to FIG8. FIG8 is a schematic diagram illustrating arrangement of light (spots) acquired by the two imaging elements of the imaging unit 92 according to the fourth embodiment. In FIG8, light incident on each pixel is schematically illustrated as a circle (a spot). For example, light incident on the pixel P11 of the first imaging element 921 is illustrated as a spot SA11, and light incident on the pixel P11 of the second imaging element 922 is illustrated as a spot SB11.', 'Spots received by the pixels of the first imaging element 921 (for example, the spot SA11 to a spot SA44 illustrated in FIG8) are arranged in a matrix. Furthermore, spots received by the pixels of the second imaging element 922 (for example, the spot SB11 to a spot SB44 illustrated in FIG8) are arranged in a matrix.', 'If the arrangement of the spots received by the pixels of the first imaging element 921 and the arrangement of the spots received by the pixels of the second imaging element 922 are superimposed on each other with the optical axes of the observation light aligned with each other, the positions of the pixels Pxy of the first imaging element 921 and second imaging element 922 are displaced from each other by 1/2 pixel each in the row direction and column direction, and thus, as illustrated in FIG8, the spots SB11 to SB44 in the second imaging element 922 are arranged between the spots SA11 to SA44 in the first imaging element 921. In other words, when, for example, the spots SA11 to SA44 in the first imaging element 921 and the spots SB11 to SB44 in the second imaging element 922 are viewed along the row direction of the pixels Pxy, the spots SA11 to SA44 and the spots SB11 to SB44 are in a state of being arranged independently from each other. ', 'Described next is a fifth embodiment of the present invention. FIG9 is a schematic diagram illustrating a configuration of an imaging unit 92a according to the fifth embodiment of the present invention. According to the above description of the first embodiment, spectral separation is performed by use of the prism 923, but in this modified example, spectral separation is performed by use of a thin film mirror 924 that is provided with a dichroic film and is plate-shaped.']",51,452,schematic diagram,A,"[{'element_identifier': '921', 'terms': ['first imaging element']}, {'element_identifier': '922', 'terms': ['second imaging element']}, {'element_identifier': '924', 'terms': ['thin film mirror']}]","['1. An endoscope apparatus, comprising: a light source device configured to continuously emit first light of a first wavelength band, and sequentially emit second light of plural second wavelength bands different from the first wavelength band and different from each other; and an imaging device including: a spectroscopic unit configured to spectrally separate light from a subject, the light arising from illumination light emitted by the light source device, into light of the first wavelength band and light of the second wavelength bands; a first imaging element configured to generate a first image signal by receiving and photoelectrically converting the light of the first wavelength band spectrally separated by the spectroscopic unit; and a second imaging element configured to generate a second image signal by respectively receiving and photoelectrically converting the light of the second wavelength bands spectrally separated by the spectroscopic unit.']",True,"['921', '922', '924', '19']" 214,EP_3586725_A1 (1).png,EP3586725A1,BLOOD PRESSURE MEASUREMENT ANALYSIS METHOD AND SYSTEM,['FIG4'],['FIG4 schematically depicts an example analysis system according to one or more embodiments '],"['Accordingly, a further aspect of the invention provides a system for analyzing blood pressure measurements. An example is schematically shown in block diagram form in FIG4.', 'In other examples, the processor may be communicably connectable with a blood pressure sensing means 80 for obtaining the blood pressure measurements. This configuration is illustrated schematically in FIG4 for example.', 'The datasets and/or databases comprising the datasets may be stored on a local memory in examples. The memory may be part of the processor 78. In this case or in any case, the datasets may be comprised by the processor 78. Hence although they are shown schematically as separate components in FIG4, the actual distribution of these elements may differ.', 'Although in the example of FIG4, the further dataset is comprised by the system 70, in further examples, the further dataset may be external to the system, and wherein the processor 78 is configured to have access to the dataset. The dataset may be stored on a remote server or data store for example, with which the processor is communicable.']",13,199,schematic,A,"[{'element_identifier': '80', 'terms': ['means']}, {'element_identifier': '48', 'terms': ['contextual data']}, {'element_identifier': '56', 'terms': ['determination made']}, {'element_identifier': '50', 'terms': ['determination']}, {'element_identifier': '58', 'terms': ['it is labelled']}, {'element_identifier': '46', 'terms': ['determination', 'If it is determined']}, {'element_identifier': '70', 'terms': ['system']}]","['1. A blood pressure measurement analysis method (10), comprising: obtaining (12) a blood pressure measurement for a subject, the measurement being associated with a known tester who performed the measurement; comparing (14) the measurement with historical measurements for the subject stored in a database, and determining based on this whether the obtained measurement is an outlier for the subject; in the case the measurement is an outlier, accessing (16) a database of contextual data for the subject, pertaining to contextual factors which have an effect on blood pressure, and determining based on this any contextual cause of the outlier measurement; at least in the case of no contextual cause, accessing (18) historical measurement data for the tester in a database, and determining based on this whether the outlier is attributable to the tester; generating (20) output information indicative of an outlier status of the measurement, and any determined contextual and/or tester attributed cause.', '12. A computer program comprising code means for implementing the method of any one of claims 1 to 11 when said program is run on a computer.', '13. An analysis system (70), comprising: a first dataset (72) storing historical blood pressure measurements for one or more subjects; a second dataset (74) comprising historical measurement data relating to historical measurements performed by one or more testers; and a processor, having access to said datasets, and adapted to: obtain a blood pressure measurement for a subject, the measurement being associated with a known tester who performed the measurement, compare the measurement with historical measurements for the subject stored in said first dataset, and determining based on this whether the obtained measurement is an outlier for the subject, in the case the measurement is an outlier, access a further dataset (76) of contextual data for the subject, pertaining to contextual factors which have an effect on blood pressure, and determine based on this any contextual cause of the outlier measurement, at least in the case of no contextual cause, access historical measurement data for the tester from said second dataset, and determine based on this whether the outlier is attributable to the tester; and generate output information indicative of an outlier status of the measurement, and any determined contextual and/or tester attributed cause.']",True,"['58', '56', '50', '46', '48', '3', '70', '80', '15']" 215,EP_3586725_A1.png,EP3586725A1,BLOOD PRESSURE MEASUREMENT ANALYSIS METHOD AND SYSTEM,['FIG2'],['FIG2 schematically illustrates approaches for determining whether an outlier is attributable to a testing personnel'],"['The approach indicated by (a) above is illustrated in FIG2(a). This schematically illustrates an example distribution 32 of deviation scores of past measurements for a given tester for various subjects, the deviation scores being a deviation of each of the tester measurements from an expected measurement for the subject in question. The expected measurement may for example be an average measurement for the subject based on historical measurements for the subject.', ""The approach indicated by (b) above is illustrated in FIG2(b). This differs from (a) simply in that the average 'error' of the tester's measurements is assessed not by comparison to an average historical measurement for each patient being tested, but by comparison of the whole set of tester measurements on a population of subjects to the set of measurements taken on the same population of subjects by other testers."", 'FIG2(b) schematically illustrates this, illustrating an example distribution 34 of blood pressure measurements for the tester, and on the same axis an example distribution 36 of blood pressure measurements for the same population of subjects, taken by other testers. It can be seen that in this example there is a clear deviation, Δ, in the median/mean centers of the two distributions. This deviation is taken to be the average error value for the tester, as it indicates a systematic error or bias in the measured values for the tester.']",15,261,schematic,A,"[{'element_identifier': '14', 'terms': ['method comprises comparing']}, {'element_identifier': '18', 'terms': ['determining']}, {'element_identifier': '20', 'terms': ['output information']}, {'element_identifier': '34', 'terms': ['example distribution']}, {'element_identifier': '16', 'terms': ['accessing']}, {'element_identifier': '36', 'terms': ['example distribution']}, {'element_identifier': '32', 'terms': ['example distribution']}]","['1. A blood pressure measurement analysis method (10), comprising: obtaining (12) a blood pressure measurement for a subject, the measurement being associated with a known tester who performed the measurement; comparing (14) the measurement with historical measurements for the subject stored in a database, and determining based on this whether the obtained measurement is an outlier for the subject; in the case the measurement is an outlier, accessing (16) a database of contextual data for the subject, pertaining to contextual factors which have an effect on blood pressure, and determining based on this any contextual cause of the outlier measurement; at least in the case of no contextual cause, accessing (18) historical measurement data for the tester in a database, and determining based on this whether the outlier is attributable to the tester; generating (20) output information indicative of an outlier status of the measurement, and any determined contextual and/or tester attributed cause.']",True,"['10', '14', '16', '18', '20', '1', '34', '32', '36', '14']" 216,EP_3586734_A1 (1).png,EP3586734A1,BIO-SIGNAL MEASURING DEVICE,"['FIG3', ' FIG4']","['FIG4 is circuit diagrams showing two specific examples of a non-linear circuit in the second example ', 'FIG3 is a schematic diagram showing a second example of the bio-signal and feed power distribution means']","['As the non-linear circuit 321, a non-linear circuit 322 having a bridge connection of four diodes D1 to D4 shown in FIG4(a) and a capacitor C, and a non-linear circuit 323 having a bridge connection of transistors (in this example, FETs) Tr1 to Tr4 as four semiconductor switches shown in FIG4(b) and a capacitor C can be exemplified.', 'In a case where a diode D is used as shown in FIG4(a), since the rising voltage of the diode D is in a range of 0.5 to 0.7 V, the diode D is not turned on in a normal bio-signal. Therefore, there is no case where the bio-signal flows into the charging circuit 200.', 'Further, in a case where a transistor (FET) Tr is used as shown in FIG4(b), the transistor Tr can further increase an on-voltage according to a threshold value or reduce a leak current.', 'The non-linear circuits 322 and 323 shown in FIG4(a) and 4(b) may be used for the rectifying circuit 325. ', 'As a second example of the bio-signal and feed power distribution means 300, in the case of DC power feed, as shown in FIG3, a DC cut filter 311 is used for the signal transfer circuit 310. The DC cut filter 311 allows passage of the bio-signal (alternating current) and blocks the passage of DC power. The DC cut filter 311 may be a capacitor.', 'Further, in the case of the DC power feed, as shown in FIG3, a non-linear circuit 321 is preferably adopted for the power transfer circuit 320. The non-linear circuit 321 has low impedance when power feed voltage is high voltage, and has high impedance at low voltage such as biological voltage, and functions as the power transfer circuit 320.']",37,353,"diagrams, schematic diagram",A,"[{'element_identifier': '310', 'terms': ['signal transfer circuit']}, {'element_identifier': '210', 'terms': ['battery']}, {'element_identifier': '321', 'terms': ['non-linear circuit']}, {'element_identifier': '100', 'terms': ['bio-signal processing circuit']}, {'element_identifier': '323', 'terms': ['non-linear circuits', 'non-linear circuit']}, {'element_identifier': '311', 'terms': ['DC cut filter']}, {'element_identifier': '320', 'terms': ['power transfer circuit']}, {'element_identifier': '200', 'terms': ['charging circuit']}, {'element_identifier': '322', 'terms': ['non-linear circuits', 'non-linear circuit']}]","['1. A bio-signal measuring device comprising: a bio-signal measuring instrument which is used in a state of being mounted to a living body, wherein the bio-signal measuring instrument includes a battery as an internal power source and a charging circuit for the battery, a plurality of electrodes which are brought into contact with a skin surface of a human body at the time of bio-signal measurement and are connected to a predetermined power feeder at the time of charging of the battery, a bio-signal processing circuit which processes bio-signals detected at the electrodes in a predetermined manner, and bio-signal and feed power distribution means, the bio-signal processing circuit and the charging circuit are switchably connected to the electrodes through the bio-signal and feed power distribution means, at the time of the bio-signal measurement, the bio-signals detected at the electrodes are supplied to the bio-signal processing circuit through the bio-signal and feed power distribution means, and at the time of the charging of the battery, feed power which is supplied from the power feeder is supplied to the charging circuit through the bio-signal and feed power distribution means.', '3. The bio-signal measuring device according to claim 2, wherein in a case where the feed power which is supplied from the power feeder is a direct current, a DC cut filter is used for the signal transfer circuit and a non-linear circuit which includes a diode or a transistor is used for the power transfer circuit.']",True,"['310', '100', '320', '321', '311', '210', '200', '322', '323', '17']" 217,EP_3586734_A1 (2).png,EP3586734A1,BIO-SIGNAL MEASURING DEVICE,['FIG5'],['FIG5 is a schematic diagram showing a third example of the bio-signal and feed power distribution means'],"['Next, as a third example of the bio-signal and feed power distribution means 300, in the case of AC power feed, as shown in FIG5, a low-pass filter 312 is used for the signal transfer circuit 310, and a high-pass filter 324 and a rectifying circuit 325 are used for the power transfer circuit 320.']",19,67,schematic diagram,A,"[{'element_identifier': '327', 'terms': ['switching control means']}, {'element_identifier': '310', 'terms': ['signal transfer circuit']}, {'element_identifier': '210', 'terms': ['battery']}, {'element_identifier': '325', 'terms': ['rectifying circuit']}, {'element_identifier': '100', 'terms': ['bio-signal processing circuit']}, {'element_identifier': '326', 'terms': ['switching circuit']}, {'element_identifier': '324', 'terms': ['high-pass filter']}, {'element_identifier': '320', 'terms': ['power transfer circuit']}, {'element_identifier': '312', 'terms': ['low-pass filter']}, {'element_identifier': '200', 'terms': ['charging circuit']}]","['1. A bio-signal measuring device comprising: a bio-signal measuring instrument which is used in a state of being mounted to a living body, wherein the bio-signal measuring instrument includes a battery as an internal power source and a charging circuit for the battery, a plurality of electrodes which are brought into contact with a skin surface of a human body at the time of bio-signal measurement and are connected to a predetermined power feeder at the time of charging of the battery, a bio-signal processing circuit which processes bio-signals detected at the electrodes in a predetermined manner, and bio-signal and feed power distribution means, the bio-signal processing circuit and the charging circuit are switchably connected to the electrodes through the bio-signal and feed power distribution means, at the time of the bio-signal measurement, the bio-signals detected at the electrodes are supplied to the bio-signal processing circuit through the bio-signal and feed power distribution means, and at the time of the charging of the battery, feed power which is supplied from the power feeder is supplied to the charging circuit through the bio-signal and feed power distribution means.', '2. The bio-signal measuring device according to claim 1, wherein the bio-signal and feed power distribution means includes a signal transfer circuit and a power transfer circuit, the signal transfer circuit leads the bio-signal to the bio-signal processing circuit at the time of the bio-signal measurement and blocks a flow of the feed power to the bio-signal processing circuit at the time of the charging of the battery, and the power transfer circuit leads the feed power to the charging circuit at the time of the charging of the battery and blocks a flow of the bio-signal to the charging circuit at the time of the bio-signal measurement.', '4. The bio-signal measuring device according to claim 2, wherein in a case where the feed power which is supplied from the power feeder is an alternating current, a low-pass filter is used for the signal transfer circuit and a highpass filter and a rectifying circuit are used for the power transfer circuit.', '8. The bio-signal measuring device according to any one of claims 1 to 7, wherein a two-contact switching circuit having a first contact which connects the electrode to the bio-signal processing circuit and a second contact which connects the electrode to the charging circuit is used for the bio-signal and feed power distribution means, and the first contact side is closed at the time of the bio-signal measurement and the second contact side is closed at the time of the charging of the battery.']",True,"['310', '100', '312', '324', '325', '320', '200', '210', '326', '100', '200', '320', '327', '210', '18']" 218,EP_3586734_A1 (5).png,EP3586734A1,BIO-SIGNAL MEASURING DEVICE,"['FIG14', ' FIG15']","['FIG14 is a schematic diagram showing a fourth embodiment of the bio-signal measuring device according to the present invention ', 'FIG15 is a schematic diagram showing a fifth embodiment of the bio-signal measuring device according to the present invention']","['The MPU 25 performs advanced processing that cannot be performed in an MCU 121 (refer to FIG14) in the bio-signal measuring instrument 1 having a restriction in the power source. The MPU 25 performs, for example, encryption processing or anonymization processing in which an individual cannot be identified, from the viewpoint of personal information protection. The memory 26 temporarily stores the accumulation of past data, case data on the cloud, or the like.', 'Next, a fourth embodiment of the bio-signal measuring device will be described with reference to FIG14. In the fourth embodiment, the bio-signal measuring instrument 1 has a communication function with the power feeder 2. ', 'As another embodiment (a fifth embodiment of the present invention) of the communication function with the power feeder 2, as shown in FIG15, an aspect including a wakeup circuit 131 as connection detection means, a switch (SW) 132 for modulation, an ADC 133, an error correction decoding circuit 134a, an error correction coding circuit 134b, and a communication control unit 135 is also included in the present invention.']",42,210,schematic diagram,A,"[{'element_identifier': '210', 'terms': ['battery']}, {'element_identifier': '122', 'terms': ['memory']}, {'element_identifier': '121', 'terms': ['MCU']}, {'element_identifier': '135', 'terms': ['communication control unit']}, {'element_identifier': '123', 'terms': ['I/O interface']}, {'element_identifier': '100', 'terms': ['bio-signal processing circuit']}, {'element_identifier': '4', 'terms': ['about']}, {'element_identifier': '133', 'terms': ['ADC']}, {'element_identifier': '25', 'terms': ['MPU']}, {'element_identifier': '300', 'terms': ['feed power distribution means']}, {'element_identifier': '131', 'terms': ['wakeup circuit']}, {'element_identifier': '132', 'terms': ['switch']}, {'element_identifier': '200', 'terms': ['charging circuit']}, {'element_identifier': '124', 'terms': ['ADC']}]","['1. A bio-signal measuring device comprising: a bio-signal measuring instrument which is used in a state of being mounted to a living body, wherein the bio-signal measuring instrument includes a battery as an internal power source and a charging circuit for the battery, a plurality of electrodes which are brought into contact with a skin surface of a human body at the time of bio-signal measurement and are connected to a predetermined power feeder at the time of charging of the battery, a bio-signal processing circuit which processes bio-signals detected at the electrodes in a predetermined manner, and bio-signal and feed power distribution means, the bio-signal processing circuit and the charging circuit are switchably connected to the electrodes through the bio-signal and feed power distribution means, at the time of the bio-signal measurement, the bio-signals detected at the electrodes are supplied to the bio-signal processing circuit through the bio-signal and feed power distribution means, and at the time of the charging of the battery, feed power which is supplied from the power feeder is supplied to the charging circuit through the bio-signal and feed power distribution means.', '5. The bio-signal measuring device according to claim 2, wherein an on/off switch circuit is used for the power transfer circuit.', '20. A bio-signal measuring device comprising: a bio-signal measuring instrument which includes a plurality of electrodes which detect a bio-signal in contact with a skin surface of a human body, a bio-signal processing circuit which processes the bio-signals detected at the electrodes in a predetermined manner and stores the processed bio-signals in a memory, a battery as an internal power source, and a charging circuit for the battery, and is used in a state of being mounted to the human body; and a power feeder which supplies predetermined charging power to the battery through the charging circuit, wherein the power feeder includes communication means for transmitting the bio-signals stored in the memory to predetermined external equipment.']",True,"['123', '124', '300', '100', '122', '121', '200', '210', '131', '133', '132', '290', '4', '300', '135', '210', '100', '25']" 219,EP_3586734_A1.png,EP3586734A1,BIO-SIGNAL MEASURING DEVICE,['FIG1'],['FIG1 is a schematic diagram showing a first embodiment of a bio-signal measuring device according to the present invention'],"['As shown in FIG1, a bio-signal measuring device according to this embodiment (a first embodiment) includes a bio-signal measuring instrument 1 as a wearable biosensor (sensor chip) and a power feeder (a charger) 2 which feeds charging power to a secondary battery 210 built in the bio-signal measuring instrument 1.']",21,64,schematic diagram,A,"[{'element_identifier': '310', 'terms': ['signal transfer circuit']}, {'element_identifier': '210', 'terms': ['battery']}, {'element_identifier': '100', 'terms': ['bio-signal processing circuit']}, {'element_identifier': '300', 'terms': ['feed power distribution means']}, {'element_identifier': '16', 'terms': ['information is']}, {'element_identifier': '320', 'terms': ['power transfer circuit']}, {'element_identifier': '200', 'terms': ['charging circuit']}]","['1. A bio-signal measuring device comprising: a bio-signal measuring instrument which is used in a state of being mounted to a living body, wherein the bio-signal measuring instrument includes a battery as an internal power source and a charging circuit for the battery, a plurality of electrodes which are brought into contact with a skin surface of a human body at the time of bio-signal measurement and are connected to a predetermined power feeder at the time of charging of the battery, a bio-signal processing circuit which processes bio-signals detected at the electrodes in a predetermined manner, and bio-signal and feed power distribution means, the bio-signal processing circuit and the charging circuit are switchably connected to the electrodes through the bio-signal and feed power distribution means, at the time of the bio-signal measurement, the bio-signals detected at the electrodes are supplied to the bio-signal processing circuit through the bio-signal and feed power distribution means, and at the time of the charging of the battery, feed power which is supplied from the power feeder is supplied to the charging circuit through the bio-signal and feed power distribution means.', '2. The bio-signal measuring device according to claim 1, wherein the bio-signal and feed power distribution means includes a signal transfer circuit and a power transfer circuit, the signal transfer circuit leads the bio-signal to the bio-signal processing circuit at the time of the bio-signal measurement and blocks a flow of the feed power to the bio-signal processing circuit at the time of the charging of the battery, and the power transfer circuit leads the feed power to the charging circuit at the time of the charging of the battery and blocks a flow of the bio-signal to the charging circuit at the time of the bio-signal measurement.']",True,"['300', '100', '200', '310', '320', '100', '210', '200', '16']" 220,EP_3586742_A1.png,EP3586742A1,METHODS FOR COMPUTING A REAL-TIME STEP LENGTH AND SPEED OF A RUNNING OR WALKING INDIVIDUAL,"['FIG1', ' FIG2']","['FIG1 is a perspective view of an individual having a wrist-wearable device attached to the wrist ', 'FIG2 is a schematic perspective view of a path followed by an individual during a walking (or running) session']","['On FIG1 is schematically drawn an individual on foot 1. The individual 1 is supposed to be healthy and have all his/her members, including legs and arms, the arms having wrists 2. The individual 1 defines a vertical sagittal plane P1 (which is the global symmetry plane of the individual 1) and a vertical front plane P2, which is perpendicular to the sagittal plane P1. As depicted on FIG1, a wrist-wearable device or ""smartwatch"" 3 is attached to at least one of the individual\'s wrists, here to the right wrist 2. ', 'The smartwatch 3 is configured to monitor activity and infer various parameters of the individual 1 while he/she is moving on foot (i.e. either running or walking) on a path 4, the variations of altitude of which are voluntarily exaggerated on FIG2.']",39,157,"perspective view, schematic perspective view",A,"[{'element_identifier': '3', 'terms': ['smartwatch']}, {'element_identifier': '2', 'terms': ['wrist', 'wrists']}, {'element_identifier': '1', 'terms': ['individual']}]","[""1. Method for computing an estimation of the step length SL ^ n ′ of an individual (1) running along a path (4), over a time window n', n' being an integer higher than or equal to 1, said individual (1) being equipped with a wrist-wearable device (3) including: - a calculation unit (5), - a GNSS transponder (9) configured to deliver instant speeds of the device (3), - a barometer (8) configured to deliver instant atmospheric pressure measures (P), - an accelerometer (7) configured to deliver instant acceleration measures along three perpendicular axes, namely: ∘ a first acceleration S x along an X axis perpendicular to the wrist and parallel to a sagittal plane ( P 1) of the individual (1); ∘ a second acceleration S y along a Y axis parallel to the wrist and parallel to the sagittal plane ( P 1) of the individual (1); ∘ a third acceleration S z along a Z axis perpendicular to the wrist and parallel to a front plane (P2) of the individual (1); said method comprising the following steps, carried out by the calculation unit (5): - computing (208) a vector of features X [ n ] over a time window n , n being an integer higher than or equal to 1, as follows: X n = 1 F 1 n F 2 n F 3 n F 4 n F 2 2 n where: ∘ feature F 1 [ n ] is an instant cadence cad ^ n of the individual (1) over time window n , computed from the norms of the instant acceleration measures S x [ n ] ,S y [ n ] ,S z [ n ] delivered by the accelerometer (7) over time window n , ∘ feature F 2 [ n ] is an instant slope of the path computed from the instant atmospheric pressure measures ( P [ n ]) delivered by the barometer (8) over time window n , ∘ feature F 3 [ n ] is an instant energy of the second acceleration measures S y [ n ] delivered by the accelerometer (7) over time window n , ∘ feature F 4 [ n ] is an instant mean absolute jerk of the second acceleration measures S y [ n ] delivered by the accelerometer (7) over time window n , - computing (210) a coefficient vector β[ n ] over time window n as follows: β n = β n − 1 + D n X n SL n − X n T β n − 1 where: ∘ D [ n ] is the dispersion matrix of the instant vector of features X[n], ∘ SL n = V n cad ^ n , ∘ V [ n ] is a speed of the wrist-wearable device (3), measured by the GNSS transponder (9) over time window n , ∘ β [0] is an initial parameter, - computing (302) a vector of features X [ n' ] over time window n', as follows: X n ′ = 1 F 1 n ′ F 2 n ′ F 3 n ′ F 4 n ′ F 2 2 n ′ - computing (304) the step length SL[n'] as follows: SL ^ n ′ = X n ′ β n .""]",True,"['1', '2', '14', '3', '2']" 221,EP_3586754_B1 (1).png,EP3586754B1,"IMAGE PROCESSING APPARATUS, IMAGE PROCESSING METHOD, AND IMAGE PROCESSING PROGRAM",['FIG2'],['FIG2 is a block diagram illustrating an example of the configuration of a console and a mammography apparatus according to the embodiment'],"['For example, the console 6 according to this embodiment is a server computer. As illustrated in FIG2, the console 6 includes a control unit 40, a storage unit 42, an interface (I/F) unit 44, a display unit 46, and an operation unit 48. The control unit 40, the storage unit 42, the I/F unit 44, the display unit 46, and the operation unit 48 are connected to each other through a bus 49, such as a system bus or a control bus, such that they can transmit and receive various kinds of information.', 'As illustrated in FIG2, the mammography apparatus 10 according to this embodiment comprises the radiation detector 11, the imaging unit rotating unit 19, a radiation emitting unit 28 including the radiation source 29, a control unit 30, a storage unit 32, an I/F unit 34, and an operation panel 36. The radiation detector 11, the imaging unit rotating unit 19, the radiation emitting unit 28, the control unit 30, the storage unit 32, the I/F unit 34, and the operation panel 36 are connected to each other through a bus 39, such as a system bus or a control bus, such that they can transmit and receive various kinds of information.']",22,247,block diagram,A,"[{'element_identifier': '28', 'terms': ['radiation emitting unit']}, {'element_identifier': '30', 'terms': ['control unit']}, {'element_identifier': '19', 'terms': ['imaging unit rotating unit']}, {'element_identifier': '39', 'terms': ['bus']}, {'element_identifier': '11', 'terms': ['radiation detector']}, {'element_identifier': '48', 'terms': ['operation unit']}, {'element_identifier': '36', 'terms': ['operation panel']}, {'element_identifier': '34', 'terms': ['I/F unit']}, {'element_identifier': '16', 'terms': ['imaging table']}, {'element_identifier': '10', 'terms': ['mammography apparatus']}, {'element_identifier': '49', 'terms': ['bus']}, {'element_identifier': '29', 'terms': ['radiation source']}, {'element_identifier': '46', 'terms': ['display unit']}, {'element_identifier': '32', 'terms': ['storage unit']}]",['10. A non-transitory recording medium recording an image processing program that causes a computer to perform: acquiring ; from a mammography apparatus or from a storage unit a radiographic image of a breast and information indicating a thickness of the breast in capture of the radiographic image; and deriving a percentage of mammary glands of a breast image in the radiographic image using different methods in a case in which the thickness of the breast is equal to or greater than a predetermined thickness and a case in which the thickness of the breast is less than the predetermined thickness.'],False,"['29', '28', '19', '32', '39', '34', '36', '30', '10', '46', '48', '11', '49', '16']" 222,EP_3586754_B1 (6).png,EP3586754B1,"IMAGE PROCESSING APPARATUS, IMAGE PROCESSING METHOD, AND IMAGE PROCESSING PROGRAM",['FIG8'],"['FIG8 is a diagram illustrating an example of the display of, for example, a radiographic image on a display unit by the console according to the embodiment']","['In addition, the control unit 40 may determine which of predetermined categories classified on the basis of the percentage of the mammary glands derived in Steps S204 to S206 the breast belongs to and may display the category in addition to the percentage of the mammary glands. In this case, the ""category"" may be the same as or different from the type of breast. The criteria for determining the category are not particularly limited. For example, in a case in which the percentage of the mammary glands in the entire breast and the percentage of the mammary glands in a portion of the breast are derived, the category classified according to a combination thereof may be used. FIG8 illustrates an example of the display of the radiographic image, information indicating the percentage of the mammary glands, and information indicating the category on the display unit 46 by the control unit 40 in this case. FIG8 illustrates an example in which a radiographic image 50 includes a breast image 54 and a direct region (an image of the direct region) 56 and information 60 indicating the percentage of the mammary glands and information 62 indicating the category are displayed in the direct region 56 of the radiographic image 50 so as to be superimposed on the direct region 56.']",29,234,diagram,A,"[{'element_identifier': '62', 'terms': ['information']}, {'element_identifier': '56', 'terms': ['direct region']}, {'element_identifier': '50', 'terms': ['radiographic image']}, {'element_identifier': '46', 'terms': ['display unit']}, {'element_identifier': '54', 'terms': ['breast image']}, {'element_identifier': '60', 'terms': ['information']}]",['1. An image processing apparatus (6) comprising: an acquisition unit (40) that is adapted to acquire a radiographic image of a breast and information indicating a thickness of the breast in capture of the radiographic image; and a derivation unit (40) that is adapted to derive a percentage of mammary glands of a breast image in the radiographic image acquired by the acquisition unit characterized in that the derivation unit is adapted to use different methods in a case in which the thickness of the breast is equal to or greater than a predetermined thickness and a case in which the thickness of the breast is less than the predetermined thickness.'],False,"['8', '50', '46', '62', '54', '60', '56', '22']" 223,EP_3586777_A1.png,EP3586777A1,TOUCH FREE OPERATION OF ABLATOR WORKSTATION BY USE OF DEPTH SENSORS,['FIG1'],['FIG1 is a block diagram of an embodiment of the inventive system'],"['As shown in FIG1, the system in one embodiment comprises various components including a depth sensor 10, a computer or CPU 12, a communication medium 14 and a client computer 16 which is part of the ablator workstation. A Motion Detection Software Module 18 can reside in the CPU 12. The client computer 16 can control a Target Software Module 20. A Communication Client Module 22 can reside in the client computer 16. In one embodiment, the system can also include voice recognition, such as a microphone or a microphone array 28.']",12,102,block diagram,A,"[{'element_identifier': '24', 'terms': ['Voice Recognition']}, {'element_identifier': '14', 'terms': ['communication medium']}, {'element_identifier': '12', 'terms': ['CPU']}, {'element_identifier': '22', 'terms': ['Communication Client Module']}, {'element_identifier': '18', 'terms': []}, {'element_identifier': '20', 'terms': ['Module']}, {'element_identifier': '16', 'terms': ['client computer']}, {'element_identifier': '10', 'terms': ['depth sensor']}]","['1. A system for touch free operation of an ablator workstation comprising: a depth sensor for detecting a movement; a motion software module operable to receive the detected movement from the depth sensor, deduce a gesture based on the detected movement, and filter the gesture to accept an applicable gesture; and a client software module operable to receive the applicable gesture at a client computer in the ablator workstation for performing a task in accordance with client logic based on the applicable gesture.', '5. The system according to claim 1, further comprising voice recognition providing voice input for enabling the client to perform the task based on the voice input in conjunction with the applicable gesture.', '13. A computer readable storage device storing a program of instructions executable by a machine to perform a method for touch free operation of an ablator workstation as claimed in any of claims 6, 7 or 11 wherein the step of deducing is performed using a CPU.']",False,"['10', '12', '24', '16', '20', '22', '18', '14', '1']" 224,EP_3586781_A1.png,EP3586781A1,MAGNETIC PICKUP CANCELLATION BY COMPENSATION LEADS,['FIG1'],"['FIG1 is a schematic, pictorial illustration of a catheter-based magnetic position-tracking and ablation system, in accordance with an embodiment of the present invention']","['FIG1 is a schematic, pictorial illustration of a catheter-based magnetic position-tracking and ablation system 20, in accordance with an embodiment of the present invention. System 20 comprises a catheter 21, having a shaft distal end 22 that is navigated by a physician 30 into a heart 26 of a patient 28 via the vascular system. In the pictured example, physician 30 inserts shaft distal end 22 through a sheath 23, while manipulating the distal end of shaft distal end 22 using a manipulator 32 near the proximal end of the catheter. As shown in an inset 25, shaft distal end 22 comprises a magnetic sensor 51 contained within the shaft distal end 22 and an ablation catheter 50.']",29,132,schematic,A,"[{'element_identifier': '28', 'terms': ['patient']}, {'element_identifier': '51', 'terms': ['sensor']}, {'element_identifier': '30', 'terms': ['physician']}, {'element_identifier': '39', 'terms': ['processor']}, {'element_identifier': '38', 'terms': ['interface circuits']}, {'element_identifier': '22', 'terms': ['distal end']}, {'element_identifier': '29', 'terms': ['patient table']}, {'element_identifier': '20', 'terms': ['system']}, {'element_identifier': '25', 'terms': ['inset']}, {'element_identifier': '34', 'terms': ['driver circuit']}, {'element_identifier': '27', 'terms': ['display']}, {'element_identifier': '50', 'terms': ['ablation catheter']}, {'element_identifier': '26', 'terms': ['heart']}, {'element_identifier': '21', 'terms': ['catheter']}, {'element_identifier': '36', 'terms': ['generators']}, {'element_identifier': '23', 'terms': ['sheath']}, {'element_identifier': '32', 'terms': ['manipulator']}]","['1. A wiring assembly, comprising: a differential input port, configured to receive a differential signal from a sensor at a first end of the wiring assembly; a differential output port, configured to output the differential signal at a second end of the wiring assembly; and first and second pairs of electrical leads, which convey the differential signal from the first end to the second end, and which are connected to one another at the first end and at the second end in a configuration that cancels pickup of an ambient magnetic field by the wiring assembly.']",False,"['50', '51', '22', '25', '1', '20', '30', '26', '21', '23', '32', '27', '22', '38', '34', '39', '36', '28', '29', '36']" 225,EP_3586805_A1 (1).png,EP3586805A1,CONFORMABLE MEDICAL DRESSING WITH SELF SUPPORTING SUBSTRATE,['FIG4B'],['FIG4B is a top plan view of another exemplary embodiment of a medical dressing prior to the addition of a self supporting substrate'],"['The linear cut 31 can provide a tab 33 that creates a beginning point at which the carrier 27 may be easily lifted from backing 14 and peeled. Although cut 31 may also be a nonlinear cut which is known in the art, the preferred embodiment includes a linear cut. Linear cuts form a more distinct tab 33 to facilitate removal of the carrier 27. Tab 33 can also be formed away from the linear cut 31 as a shape in carrier 27, as shown in FIG4B.']",23,92,plan view,A,"[{'element_identifier': '24', 'terms': ['liner']}, {'element_identifier': '17', 'terms': ['adhesive']}, {'element_identifier': '14', 'terms': ['backing']}, {'element_identifier': '1', 'terms': ['than']}, {'element_identifier': '37', 'terms': ['liner']}, {'element_identifier': '33', 'terms': ['tab', 'tabs']}, {'element_identifier': '27', 'terms': ['carrier']}, {'element_identifier': '26', 'terms': ['window']}, {'element_identifier': '21', 'terms': ['adhesive layer']}, {'element_identifier': '31', 'terms': ['cut']}]","['1. An adhesive medical article (10) comprising: (a) a conformable backing (14) having a first major surface and a second major surface, and an opening (26) that forms a window through the backing (14); (b) a pressure sensitive adhesive (17) coated on at least a portion of the first major surface of the backing (14); (c) a self-supporting substrate (12) comprising a first planar surface (11), and at least one side wall (22) formed at an angle between zero to one hundred eighty degrees to the first planar surface (11), and a second planar surface connected to the at least one side wall (11) in the form of a flange (44), wherein the self-supporting substrate (12) is attached to the backing (14) to enclose the opening (26) through the backing (14); and wherein the self-supporting substrate (12) comprises a valve.', '2. The adhesive medical article of claim 1, further comprising a carrier (27) releasably attached to at least a portion of the second major surface of the backing.', '3. The adhesive medical article of claim 2, wherein the carrier (27) comprises at least one cut line (31).', '9. The adhesive medical article of any of claims 1-8, further comprising a liner (24) releasably adhered to the pressure sensitive adhesive (17) opposite the backing (14).']",True,"['14', '27', '33', '31', '37', '14', '27', '26', '33', '27', '31', '37', '27', '37', '21', '17', '26', '27', '27', '14', '17', '24', '1', '21']" 226,EP_3586805_A1.png,EP3586805A1,CONFORMABLE MEDICAL DRESSING WITH SELF SUPPORTING SUBSTRATE,['FIG3'],['FIG3 is a schematic cross section of the medical dressing of FIG1 applied to a wound'],"['Another embodiment of a medical dressing according to the present invention is depicted in FIG3 (where FIG3 is a cross-sectional view taken along line 2-2 in FIG1). The medical dressing 10 includes a backing 14 (which may preferably be conformable as described herein). The backing 14 includes two opposed major surfaces: an interior surface 41 and an external surface 42. In use, the interior surface 41 faces a wound (or other body site) over which the dressing is placed while the external surface 42 faces away from the wound (or other body site).', 'Referring again to FIG3, the dressing 10 is located over a wound W while the backing layer 14 and adhesive layer 17 is attached to the tissue (e.g., skin) surrounding the wound W. The dressing 10 and self supporting substrate 12, along with the wound W and the tissue surrounding the wound, preferably define a sealed environment in which the wound W is isolated from the surrounding environment. The interior surface 41 of the backing 14 faces the sealed environment in which the wound is located while the external surface 42 of the backing 14 faces away from the wound W.', 'Referring again to FIG3, maintenance of the negative pressure within the sealed environment may, in some embodiments, be enhanced by the addition of a ballast component 29 within the sealed cavity 25 created by the self supporting substrate 12. A ballast component 29 may be a resiliently compressible material that, e.g., compresses or shrinks as a vacuum (negative pressure) is provided within the sealed cavity 25 and that attempts to return to at least a portion of its pre-compression size because of its resilient nature. For example, the ballast component 29 may be a resilient foam (open or closed cell, although preferably open cell), nonwoven material, spring, or other structure that can be compressed, but that also is resilient such that it will attempt to return to at least a portion of its pre-compressed size (e.g., the resilient material has a spring constant).']",16,389,schematic cross-sectional view,A,"[{'element_identifier': '1', 'terms': ['than']}, {'element_identifier': '20', 'terms': ['backing layer']}, {'element_identifier': '29', 'terms': ['ballast component']}, {'element_identifier': '31', 'terms': ['cut']}, {'element_identifier': '12', 'terms': ['substrate']}, {'element_identifier': '11', 'terms': ['planar surface']}, {'element_identifier': '25', 'terms': ['cavity']}, {'element_identifier': '24', 'terms': ['liner']}, {'element_identifier': '17', 'terms': ['adhesive']}, {'element_identifier': '22', 'terms': ['side wall']}, {'element_identifier': '16', 'terms': ['corrugated portion']}, {'element_identifier': '27', 'terms': ['carrier']}, {'element_identifier': '21', 'terms': ['adhesive layer']}, {'element_identifier': '15', 'terms': ['perimeter']}, {'element_identifier': '7', 'terms': ['in U.S. Patent No.']}, {'element_identifier': '14', 'terms': ['backing']}, {'element_identifier': '2', 'terms': ['than']}, {'element_identifier': '33', 'terms': ['tab', 'tabs']}, {'element_identifier': '3', 'terms': ['U.S. Patent Nos.']}]","['1. An adhesive medical article (10) comprising: (a) a conformable backing (14) having a first major surface and a second major surface, and an opening (26) that forms a window through the backing (14); (b) a pressure sensitive adhesive (17) coated on at least a portion of the first major surface of the backing (14); (c) a self-supporting substrate (12) comprising a first planar surface (11), and at least one side wall (22) formed at an angle between zero to one hundred eighty degrees to the first planar surface (11), and a second planar surface connected to the at least one side wall (11) in the form of a flange (44), wherein the self-supporting substrate (12) is attached to the backing (14) to enclose the opening (26) through the backing (14); and wherein the self-supporting substrate (12) comprises a valve.', '2. The adhesive medical article of claim 1, further comprising a carrier (27) releasably attached to at least a portion of the second major surface of the backing.', '3. The adhesive medical article of claim 2, wherein the carrier (27) comprises at least one cut line (31).', '9. The adhesive medical article of any of claims 1-8, further comprising a liner (24) releasably adhered to the pressure sensitive adhesive (17) opposite the backing (14).', '15. The adhesive medical article of any of the preceding claims, wherein the self-supporting substrate (12) comprises a corrugated portion (16) on at least a portion of the first planar surface (11) and the corrugated portion (16) comprises alternating ridges and grooves.']",True,"['27', '33', '12', '15', '14', '33', '16', '31', '1', '25', '11', '12', '27', '14', '17', '24', '22', '27', '21', '14', '17', '24', '2', '29', '11', '12', '25', '21', '14', '17', '7', '3', '20']" 227,EP_3586821_A1 (1).png,EP3586821A1,STEM CELL STIMULATING COMPOSITIONS AND METHODS,['FIG2'],['FIG2 shows side-by-side photographs that show a reduction in the appearance of brown spots '],['FIG2 shows before (A) and after (B) images acquired by a 3D LifeViz™ system with the brown-spot filter for participant 8-IK (female) of Clinical Study 1. Participant 3-PC was given the test formulation. Images show a reduction in brown spots on the face as a result of treatment. Photos have not been retouched.'],18,70,side view,A,"[{'element_identifier': '28', 'terms': ['Aspect', 'Aspects']}, {'element_identifier': '2', 'terms': ['neutrophil defensin', 'beta-defensin']}]","['2. The use of claim 1, wherein the first defensin is selected from the group consisting of alpha-defensin 1, alpha-defensin 5, alpha-defensin 6, neutrophil defensin 1, neutrophil defensin 2, neutrophil defensin 3, neutrophil defensin 4, theta-defensin, beta-defensin 1, beta-defensin 2, beta-defensin 3, and beta-defensin']",False,"['2', '28']" 228,EP_3586821_A1.png,EP3586821A1,STEM CELL STIMULATING COMPOSITIONS AND METHODS,['FIG1'],['FIG1 shows side-by-side photographs that show reduction in wrinkles'],['FIG1 shows the before (A) and after (B) images acquired by a 3D LifeViz™ system for participant 3-PC (63 year old female) of Clinical Study 1. Participant 3-PC was given the test formulation. Measurements by the 3D LifeViz™ system showed that participant 3-PC saw a reducing in visible skin age estimation (based on the skin evenness value calculated by the 3D LifeViz™ system) from 64 years to 37 years. Photos have not been retouched.'],13,95,side view,A,"[{'element_identifier': '6', 'terms': ['alpha-defensin']}, {'element_identifier': '1', 'terms': ['between']}]","['2. The use of claim 1, wherein the first defensin is selected from the group consisting of alpha-defensin 1, alpha-defensin 5, alpha-defensin 6, neutrophil defensin 1, neutrophil defensin 2, neutrophil defensin 3, neutrophil defensin 4, theta-defensin, beta-defensin 1, beta-defensin 2, beta-defensin 3, and beta-defensin']",False,"['6', '1', '27']" 229,EP_3586893_A1.png,EP3586893A1,OPTIMIZED INTRATHECAL DRUG DELIVERY,['FIG1'],['FIG1 is a schematic view depicting an intrathecal drug delivery system in accordance with an embodiment of the disclosure'],"['Referring to FIG1, a schematic view of an intrathecal drug delivery system 100 is depicted in accordance with an embodiment of the disclosure. The intrathecal drug delivery system 100 can include an implantable medical pump 102, one or more physiological sensors 104 (such as sensors 104A and 104B), and optional server 105, and an optional external programmer 106.']",19,66,schematic view,A,"[{'element_identifier': '100', 'terms': ['intrathecal drug delivery system']}, {'element_identifier': '106', 'terms': ['external programmer']}, {'element_identifier': '102', 'terms': ['implantable medical pump', 'implantable medical pumps']}]","['1. An intrathecal drug delivery system (100) configured to monitor one or more physiological conditions of a patient to look for opportunities to time medicament delivery to coincide with a desired posture of the patient or patient activity inferring heightened cerebrospinal fluid oscillations, thereby improving dispersion of the medicament within an intrathecal space of the patient, the intrathecal drug delivery system comprising: an implantable medical pump (102) configured to deliver medicament within the intrathecal space of a patient; one or more physiological sensors (104) configured to monitor one or more physiological conditions of the patient; and an external programmer (106) configured to program the implantable medical pump (102) with a treatment protocol specifying at least one period of time during which a specified quantity of medicament is to be administered, wherein during the at least one period of time, the implantable medical pump (102) utilizes data from the one or more physiological sensors (104) to time delivery of the medicament.']",False,"['100', '102', '106', '1', '8']" 230,EP_3586927_A2 (3).png,EP3586927A2,INERTING SYSTEM,['FIG4'],['FIG4 is a schematic illustration of an example embodiment of an PEM electrochemical cell inerting system'],"[""Turning to FIG4, an example embodiment of an inerting system 50' with a PEM electrochemical cell 52' onboard an aircraft is shown. As shown in FIG4, air from a compressed air source 54 such as a compressor section of a turbine fan engine is directed along a cathode supply fluid flow path 22 to a PEM electrochemical cell 52'. In some embodiments, some of the compressed air can be diverted to an additional pneumatic load such as an aircraft environmental control system 70. The hot compressed air is then passed through a heat exchanger that receives cooling air 74 from ram air duct 76 to cool the compressed air to a temperature suitable for the PEM electrochemical cell 52' (e.g., 50-120°C). A proton source 78 is directed to the anode side fluid flow path 25 (e.g., hydrogen gas for operation of the cell in fuel cell (power production) mode, or water for operation of the cell in electrolyzer (power consumption) mode). Condenser 58 receives wet inerting gas from the cathode side fluid flow path 22 and cools it with ram cooling air 74 to condense and remove water 80 from the inerting gas. The inerting gas is optionally then directed to a membrane separator 62 with a water-permeable tubular membrane 64 for removal of additional water 66 and subsequently through pressure control device 68 to protected space 56.""]",16,259,schematic,A,"[{'element_identifier': '76', 'terms': ['oxygen sensor', 'such as check valve']}, {'element_identifier': '78', 'terms': ['ram air discharge']}, {'element_identifier': '14', 'terms': ['cathode']}, {'element_identifier': '82', 'terms': ['membrane']}]","['1. A system for providing inerting gas to a protected space (54), comprising an electrochemical cell (10) comprising a cathode (14) and an anode (16) separated by a separator (12) comprising an ion transfer medium; a cathode fluid flow path (23) in operative fluid communication with a catalyst (14) at the cathode between a cathode fluid flow path inlet and a cathode fluid flow path outlet; a cathode supply fluid flow path (22) between the protected space and the cathode fluid flow path inlet; an anode fluid flow path (25) in operative fluid communication with a catalyst (16) at the anode, including an anode fluid flow path outlet; an electrical connection to a power source or power sink; an inerting gas flow path (24) in operative fluid communication with the cathode flow path outlet and the protected space.', '3. The system of claim 2, wherein the gas treatment module includes any one or combination of: a filter, an adsorbent, a membrane separator, a catalytic combustor, electrostatic precipitator, a scrubber, a condensing separator, and a gas-liquid separator.']",False,"['78', '78', '67', '76', '14', '82']" 231,EP_3586937_A1.png,EP3586937A1,ANTIFOAMING AGENT AND LUBRICANT COMPOSITION,['FIG1'],['FIG1 is an explanatory view of the structure of a homogenizer test machine that is used for the evaluation of defoaming performance '],"['Defoaming performance of each of the prepared lubricating oil compositions was evaluated by a homogenizer test machine shown in FIG1. The homogenizer test machine shown in FIG1 includes a homogenizer 1, a cylindrical heater for heating 2, a temperature adjuster 3, a thermocouple for oil temperature measurement 4, an electric power source for the heater 5, a glass cylinder corresponding to an oil tank 6 (graduated cylindrical glass vessel, 40 mm in inner diameter, 300 mm in depth, 2 mL grading divisions from 0 to 250 mL), and an air blow tube (air blow rate: 30 mL/min) 7.']",22,116,explanatory view,B,"[{'element_identifier': '5', 'terms': ['than']}, {'element_identifier': '2', 'terms': ['general formula']}, {'element_identifier': '1', 'terms': ['general formula']}]","['1. A defoaming agent comprising a polymer, the polymer comprising: at least one first polymer chain comprising a polysiloxane structure, the polysiloxane structure being represented by the following general formula (1) and having a polymerization degree of 5 to 2000; and at least one second polymer chain comprising a repeating unit, the repeating unit being represented by the following general formula (2), the second polymer chain being bonded to the first polymer chain: wherein in the general formula (1), polysiloxane repeating units may be in any order; each of R 1 and R 2 is independently a C 1-18 organic group comprising no fluorine atom; each of R 3 and R 4 is independently a C 1-18 organic group comprising no less than 3 fluorine atoms or a C 1-18 organic group comprising no fluorine atom, wherein at least one of R 3 and R 4 is the organic group comprising no less than 3 fluorine atoms; n is an integer of no less than 0; m is an integer of no less than 1; and n+m is 5 to 2000, wherein in the general formula (2), X 1 is a repeating unit obtainable by polymerization of an ethylenic unsaturated group; Y 1 is a side chain consisting of a substituted or unsubstituted C 1-40 hydrocarbyl group; and Z 1 is a linking group linking the repeating unit X 1 and the side chain Y 1 .']",False,"['1', '5', '2', '38']" 232,EP_3586966_A1 (4).png,EP3586966A1,VESSEL CLOSURES AND METHODS FOR USING AND MANUFACTURING SAME,['FIG22'],['FIG22 is an exploded view of the fluid transfer hub'],"['To help create a seal between the two tri-clamp vessel closures 6010, 6015, a gasket 6020 is provided. Gaskets 6020 are available in standard sizes that corresponding with the standard dimensions of tri-clamps and their corresponding fittings. Gaskets 6020 are available in several materials, including copolymers of acrylonitrile and butadiene (BUNA-N), VITON®, fluoroelastomers as defined by ASTM D1418 (FKM), ethylene propylene diene monomer (EPDM), polytetrafluoroethylene (PTFE), silicone, and others. An open gasket 6020 is illustrated in FIG22, but other types of gaskets are available that may be used within the fluid transfer hub 6000. Alternative gaskets 6020 include orifice gaskets, screen gaskets, and perforated plate gaskets that may control flow of a fluid through the fluid transfer hub 6000, or provide a filtering function. Each of these alternative gaskets are available in several sizes, or can be customized, based upon the dimensions of the fittings, the orifice diameter through the gasket, or the pore size of the perforated plate or screen gaskets. Suitable gaskets 6020 are available from Flow Smart Inc. and others.']",10,212,exploded view,B,"[{'element_identifier': '22', 'terms': ['filed June']}, {'element_identifier': '6005', 'terms': ['tri-clamp']}, {'element_identifier': '6000', 'terms': ['fluid transfer hub']}, {'element_identifier': '6025', 'terms': ['body', 'bodies']}, {'element_identifier': '6030', 'terms': ['cast seal']}, {'element_identifier': '6035', 'terms': ['insert', 'inserts']}, {'element_identifier': '6020', 'terms': ['gasket']}, {'element_identifier': '6015', 'terms': ['second tri-clamp vessel closure']}, {'element_identifier': '6010', 'terms': ['vessel closure', 'vessel closures']}, {'element_identifier': '6055', 'terms': ['anchor', 'anchors']}]","['1. A fluid transfer hub, comprising: a first vessel closure; a second vessel closure; a gasket arranged between the first vessel closure and the second vessel closure; and a clamp at least partially surrounding the first vessel closure, the second vessel closure and the gasket, wherein the first vessel closure comprises: a first body, one or more apertures extending axially through the first body, one or more first inserts extending axially through the one or more apertures, and a cast seal disposed within the first body and surrounding each first insert, wherein the second vessel closure comprises: a second body, one or more apertures extending axially through the second body, one or more second inserts extending axially through the one or more apertures, and a cast seal disposed within the second body and surrounding each second insert.', '10. The fluid transfer hub of claim 9, wherein the silicone tubes are adhesively attached to one or more anchors, preferably wherein the one or more anchors are constructed from material selected from the group consisting of metal, plastic, glass-filled plastic, ceramics, and composites.']",False,"['6000', '6035', '6055', '6015', '6020', '6025', '6030', '6010', '6005', '6035', '22', '16']" 233,EP_3587024_A1 (1).png,EP3587024A1,LASER WELDING METHOD,['FIG2'],"['FIG2 are process explanatory views of the laser welding method ', 'FIG2 are process explanatory views of the laser welding method ', 'FIG2 are process explanatory views of the laser welding method']","['More specifically, first, the pair of separators 11 and 12 are stacked on each other, and then the separators 11 and 12 are irradiated with a laser beam (first irradiation) to form the welded portion L1, i.e., the welded seal 14, of the separators 11 and 12 as illustrated in FIG2(A).', 'Subsequently, as illustrated in FIG2(B) and 2(C), the accessory component 20 is stacked on the pair of welded separators 11 and 12, and then the separators 11 and 12 and the accessory component 20 are irradiated with a laser beam (second irradiation) to form the welded portion L2 of the accessory component 20. When the separators 11 and 12 and the accessory component 20 are welded, the welded portion L2 of the accessory component 20 is reciprocatingly irradiated with laser along a fixed welding line. Herein, the description ""the welded portion L2 of the accessory component 20 is reciprocatingly irradiated with laser along a fixed welding line"" means that the irradiation is performed twice (one reciprocation) along the fixed welding line. However, when the start end and the termination end of the irradiation are set at the same position while overlapping each other on the plane, a state where the density of the energy to be emitted becomes excessively high is caused, so that a defect, such as a hole, occurs in some cases as described above.', 'First scanning of second irradiation (forward scanning, FIG2(B))', 'Second scanning of second irradiation (return scanning, FIG2(C)) ', 'More specifically, first, the pair of separators 11 and 12 are stacked on each other, and then the separators 11 and 12 are irradiated with a laser beam (first irradiation) to form the welded portion L1, i.e., the welded seal 14, of the separators 11 and 12 as illustrated in FIG2(A).', 'Subsequently, as illustrated in FIG2(B) and 2(C), the accessory component 20 is stacked on the pair of welded separators 11 and 12, and then the separators 11 and 12 and the accessory component 20 are irradiated with a laser beam (second irradiation) to form the welded portion L2 of the accessory component 20. When the separators 11 and 12 and the accessory component 20 are welded, the welded portion L2 of the accessory component 20 is reciprocatingly irradiated with laser along a fixed welding line. Herein, the description ""the welded portion L2 of the accessory component 20 is reciprocatingly irradiated with laser along a fixed welding line"" means that the irradiation is performed twice (one reciprocation) along the fixed welding line. However, when the start end and the termination end of the irradiation are set at the same position while overlapping each other on the plane, a state where the density of the energy to be emitted becomes excessively high is caused, so that a defect, such as a hole, occurs in some cases as described above.', 'First scanning of second irradiation (forward scanning, FIG2(B))', 'Second scanning of second irradiation (return scanning, FIG2(C)) ', 'More specifically, first, the pair of separators 11 and 12 are stacked on each other, and then the separators 11 and 12 are irradiated with a laser beam (first irradiation) to form the welded portion L1, i.e., the welded seal 14, of the separators 11 and 12 as illustrated in FIG2(A).', 'Subsequently, as illustrated in FIG2(B) and 2(C), the accessory component 20 is stacked on the pair of welded separators 11 and 12, and then the separators 11 and 12 and the accessory component 20 are irradiated with a laser beam (second irradiation) to form the welded portion L2 of the accessory component 20. When the separators 11 and 12 and the accessory component 20 are welded, the welded portion L2 of the accessory component 20 is reciprocatingly irradiated with laser along a fixed welding line. Herein, the description ""the welded portion L2 of the accessory component 20 is reciprocatingly irradiated with laser along a fixed welding line"" means that the irradiation is performed twice (one reciprocation) along the fixed welding line. However, when the start end and the termination end of the irradiation are set at the same position while overlapping each other on the plane, a state where the density of the energy to be emitted becomes excessively high is caused, so that a defect, such as a hole, occurs in some cases as described above.', 'First scanning of second irradiation (forward scanning, FIG2(B))', 'Second scanning of second irradiation (return scanning, FIG2(C))']",30,861,process views,B,"[{'element_identifier': '2', 'terms': ['same welding line.']}, {'element_identifier': '20', 'terms': ['accessory component']}, {'element_identifier': '12', 'terms': ['separators']}, {'element_identifier': '11', 'terms': ['separators']}]","['6. The laser welding method according to Claim 3 or 5, wherein the first and second workpieces are fuel cell separators, and the third workpiece is an accessory component attached to the fuel cell separator.']",True,"['20', '12', '20', '12', '20', '2', '11', '12', '10']" 234,EP_3587066_A1.png,EP3587066A1,PLASTIC INJECTION MOLD TOOLING AND A METHOD OF MANUFACTURE THEREOF,['FIG1'],"['FIG1 is a flowchart of a series of steps that may be involved in manufacturing plastic injection mold tooling, in accordance with a method of the present disclosure ']","['A series of steps that may be involved in manufacturing plastic injection molding tooling having high hardenability in sections of 20 inches and larger is shown in FIG1. At a first block 102, a steel melt may be formed in a heating unit, such as an electric arc furnace. The melt may contain a majority but less than all of the requisite alloys, aluminum for example being deferred until near the end of the process. It will be understood that the heating unit used for forming the steel melt may be other types of heating units apparent to those skill in the art such as, but not limited to, a vacuum induction furnace or a laser melting device. Thus, the steel melt may be formed by various processes such as, but not limited to, electric arc melting, vacuum induction melting, laser melting, and other suitable heating methods apparent to those with ordinary skill in the art. For instance, it some embodiments, the alloy elements may be provided as a powder and melted with a laser to form the steel melt.']",29,199,flowchart,B,"[{'element_identifier': '1', 'terms': ['-']}, {'element_identifier': '116', 'terms': ['next block']}, {'element_identifier': '102', 'terms': ['first block']}, {'element_identifier': '108', 'terms': ['block']}, {'element_identifier': '110', 'terms': ['block']}, {'element_identifier': '114', 'terms': ['next block']}]","['7. The method of manufacturing the plastic injection mold and die block tooling of claim 1, further characterized in that the molds and die blocks have the following composition by weight percent: C 0.25 - 0.33, Mn 0.80 - 1.10, Si 0.20 - 0.45, Cr 1.20 - 2.00, Ni 0.30 - 0.80, Mo 0.35 - 0.55, V 0.10 - 0.20, Al 0.020 max, P 0.015 max, and S 0.005 max.']",False,"['102', '110', '20', '04', '112', '106', '114', '11', '108', '116', '1']" 235,EP_3587091_A1 (4).png,EP3587091A1,PLY LOCATION TEMPLATES FOR DOUBLE DIAPHRAGM VACUUM BAGGING SYSTEM,['FIG9'],['FIG9 is a zoomed in section cut side view of PLT mounted to a mandrel in an illustrative embodiment'],"['FIG9 is a zoomed in section cut side view of PLT 122 mounted to a mandrel 110 in an illustrative embodiment. FIG9 illustrates further features, such as portion 910 of securement element 716, which protrudes beneath socket 724. FIG9 also illustrates prongs 920 of socket 724. Prongs 920 reduce a diameter of socket 724 in order to prevent securement element 716 from falling downwards out of socket 724. Specifically, while a portion of socket 724 and securement element 716 generally have a diameter D1, prongs 920 reduce the diameter of another portion of socket 724 to D2, which is less than D1. This aspect physically prevents securement element 716 from exiting its socket 724. Socket 752 has a diameter D3 which is smaller than D1, and smaller than or equal to D2.']",19,145,zoomed-in sectional view,B,"[{'element_identifier': '8', 'terms': ['corresponds with view arrows']}, {'element_identifier': '724', 'terms': ['socket', 'sockets']}, {'element_identifier': '712', 'terms': ['caps', 'cap']}, {'element_identifier': '122', 'terms': ['PLT']}, {'element_identifier': '810', 'terms': []}, {'element_identifier': '752', 'terms': ['receptacle', 'receptacles']}, {'element_identifier': '120', 'terms': ['first vacuum bag']}, {'element_identifier': '920', 'terms': ['prongs']}, {'element_identifier': '716', 'terms': ['securement element', 'securement elements']}, {'element_identifier': '732', 'terms': []}, {'element_identifier': '110', 'terms': ['mandrel']}, {'element_identifier': '200', 'terms': ['preform']}, {'element_identifier': '714', 'terms': ['biasing devices']}]","['1. A method for facilitating layup of preforms, comprising: selecting a mandrel that includes at least one receptacle (1002); disposing a first vacuum bag atop the mandrel that covers the receptacle (1004); selecting a Ply Location Template (PLT) that includes a securement element (1006); aligning a portion of the securement element with the receptacle (1008); pressing the portion of the securement element downward into the first vacuum bag and driving the portion of the securement element into the receptacle (1010); and abutting a preform against the PLT (1012).', '4. The method of claim 1, further comprising: securing the securement element into the receptacle by placing a cap atop a socket of the PLT.', '13. The apparatus of claim 12, wherein: the prongs prevent the securement element from falling downward out of the socket.']",True,"['8', '810', '714', '716', '712', '732', '9', '120', '122', '724', '200', '110', '52', '9', '714', '810', '17', '712', '122', '716', '920', '752']" 236,EP_3587103_A1.png,EP3587103A1,DISPLAY DEVICE INCLUDING PROTRUDING PLATE,['FIG1B'],['FIG1B is a sectional view that is taken along line A-A of FIG1A of the display device including the resin component in Exemplary embodiment 1'],"['A state where reinforcing layer 9 illustrated in FIG1B is made of resin by insert molding is illustrated. However, as long as members have both light transmittance and strength such as a resin plate or a glass plate, they may be used. Resin that can be used as the resin material of reinforcing layer 9 is a general-purpose molding resin such as polymethylmethacrylate resin (PMMA resin), acrylonitrile ·butadiene ·styrene resin (ABS resin), polystyrene resin (PS resin), or polycarbonate resin (PC resin). In addition thereto, as the resin material of reinforcing layer 9, it is also possible to deal with resin requiring molding at a high temperature, such as resin for optical applications, super engineering resin, or the like. Therefore, display device 80 using the protruding plate can also be used for a lamp cover or the like. Even if the general purpose molding resin such as the PMMA resin, the ABS resin, the PS resin, or the PC resin, resin for the optical use, or the super engineering resin is used for the resin base material of reinforcing layer 9, similar to the above case, when light source 10 is turned off, only the reflected light of protruding plate 1 can be viewed by the external light. When light source 10 is turned on, it is possible to visually recognize shape 13 of an arbitrary character, mark, or pattern which uniformly emits the light to an arbitrary color on the surface of protruding plate 1.']",27,286,sectional view,B,"[{'element_identifier': '80', 'terms': ['display device']}, {'element_identifier': '2', 'terms': ['thin film layer']}, {'element_identifier': '10', 'terms': ['light source']}, {'element_identifier': '31', 'terms': ['resin component']}, {'element_identifier': '13', 'terms': ['shape']}]","['1. A display device including a protruding plate, comprising: the protruding plate that has a first surface and a second surface on a side opposite to the first surface, and is made of natural wood; a thin film layer that is disposed on the first surface of the protruding plate; a transparent base material; a first concealing layer; a light diffusion layer; a light color toning layer; and a second concealing layer, the transparent base material, the first concealing layer, the light diffusion layer, the light color toning layer, and the second concealing layer being disposed on a side of the second surface of the protruding plate, wherein the first concealing layer has a dispositional relationship in which the first concealing layer is disposed closer to the protruding plate than the second concealing layer and the light color toning layer to the protruding plate, wherein the transparent base material, the first concealing layer, the light diffusion layer, the light color toning layer, and the second concealing layer are disposed in an arbitrary order except for the dispositional relationship, wherein the protruding plate, the transparent base material, the thin film layer, and the second concealing layer include a greater thickness in this order, wherein the second concealing layer, the first concealing layer, and the light diffusion layer have a same thickness, wherein the light diffusion layer is thicker than the light color toning layer, and wherein in light transmittance measured when light from a light source is radiated from the side of the second surface to a side of the first surface of the protruding plate, the transparent base material and the thin film layer have a same light transmittance, and the thin film layer, the protruding plate, the light diffusion layer, the light color toning layer, the first concealing layer, and the second concealing layer have a higher light transmittance in this order.', '2. The display device including the protruding plate of Claim 1, further comprising: the light source that radiates the light from the side of the second surface to the side of the first surface of the protruding plate, wherein the first concealing layer has a first light transmitting portion in a shape of a character, a mark, or a pattern, wherein the second concealing layer has a second light transmitting portion in a shape of a character, a mark, or a pattern, wherein the first light transmitting portion is located at a same position as the second light transmitting portion as viewed from the side of the first surface of the protruding plate, wherein when the light of the light source is radiated from the side of the second surface to the side of the first surface of the protruding plate, the light is transmitted through only the first light transmitting portion of the first concealing layer and the second light transmitting portion of the second concealing layer, and wherein an outer periphery of the first light transmitting portion is larger than an outer periphery of the second light transmitting portion.']",True,"['13', '2', '80', '13', '13', '13', '2', '31', '80', '10', '12']" 237,EP_3587141_B1 (1).png,EP3587141B1,PNEUMATIC TIRE AND METHOD FOR PRODUCING PNEUMATIC TIRE,['FIG3'],['FIG3 is a schematic view illustrating the positional relationship of the nozzle to a tire'],"['FIG3 is a schematic view illustrating the positional relationship of the nozzle to the tire.', 'As shown in FIG3, the sealant may be applied while maintaining the distance between the inner periphery 11 of the tire 10 and the tip 31 of the nozzle 30 at a predetermined distance (d0) during the movement of the nozzle 30 to positions (a) to (d) relative to the tire 10.']",15,77,schematic view,B,"[{'element_identifier': '31', 'terms': ['tip']}, {'element_identifier': '30', 'terms': ['nozzle']}, {'element_identifier': '10', 'terms': ['tire']}]","['1. A pneumatic tire (10), comprising an innerliner (19) and a sealant layer (22) located radially inside the innerliner, the sealant layer (22) comprising a first sealant layer (22a) and a second sealant layer (22b) stacked in that order from the innerliner, the first sealant layer (22a) comprising a generally string-shaped sealant provided continuously and spirally along an inner periphery (11) of the tire, the second sealant layer (22b) comprising a generally string-shaped sealant provided continuously and spirally along the first sealant layer (22a), the tire (10) is characterized in that the sealant (20a) of the first sealant layer (22a) and the sealant (20b) of the second sealant layer (22b) extending in directions crossing each other.']",True,"['30', '10', '31', '31']" 238,EP_3587147_A1.png,EP3587147A1,AUTOMATIC CONTRACTING AND LOCKING RATCHET WHEEL LOCK,['FIG2'],['FIG2 is another structural diagram of the automatic retracting and locking ratchet wheel lock catch according to the implementation embodiment of this invention'],"['The first button 600 is coupled with the first end of the locking buckle 500 (as in the example of FIG2, the right end of the locking buckle 500).', 'The second button 700 is coupled with the second end of the locking buckle 500 (as in the example of FIG2, the left end of the locking buckle 500).', 'Take FIG2 as an example. When the first button 600 is pressed, the second button 700 bounces under the driving of the locking buckle; the locking protrusion 510 is combined with any one of the locking ratchets 201, and the non-return protrusions 520 are disengaged from any one of the non-return grooves 202; the rotating wheel 200 is allowed to rotate in the counterclockwise direction and prohibited from rotating in the clockwise direction; the steel cable 400 is tightened.', 'FIG2 shows the initial state of the automatic retracting and locking ratchet wheel lock catch according to the embodiment of this invention. At this time, the locking protrusion 510 is coupled with any one of the locking ratchets 210, while the non-return protrusion 520 is disengaged from any one of the non-return grooves 202; the rotation wheel 200 is allowed to rotate in the counterclockwise direction and prohibited from rotating in the clockwise direction; the steel cable 400 is tightened.']",23,249,structural diagram,B,"[{'element_identifier': '800', 'terms': ['limit-position buckle']}, {'element_identifier': '900', 'terms': ['spring']}, {'element_identifier': '1100', 'terms': ['steel cable sleeve']}, {'element_identifier': '710', 'terms': ['second return spring']}, {'element_identifier': '100', 'terms': ['housing']}, {'element_identifier': '400', 'terms': ['steel cable']}, {'element_identifier': '600', 'terms': ['first button']}, {'element_identifier': '500', 'terms': ['locking buckle']}, {'element_identifier': '101', 'terms': ['first connecting hole']}, {'element_identifier': '102', 'terms': ['second connecting hole']}, {'element_identifier': '1000', 'terms': ['buckle']}, {'element_identifier': '610', 'terms': ['first return spring']}, {'element_identifier': '510', 'terms': ['locking protrusion']}, {'element_identifier': '200', 'terms': ['wheel']}, {'element_identifier': '520', 'terms': ['protrusion', 'protrusions']}, {'element_identifier': '700', 'terms': ['second button']}]","['1. A ratchet wheel lock catch that automatically shrinks and locks, characterized in comprising: a housing; a rotating wheel: the rotating wheel is rotatably mounted on the housing; multiple locking ratchets as well as multiple non-return grooves under multiple locking ratchets are evenly arranged on the outer peripheral wall of the rotating wheel along the circumferential direction of the rotating wheel; an energy storage spring: the energy storage spring is coaxially sleeved in the rotating wheel; the first end of the energy storage spring is fixed to the housing, and the second end of the energy storage spring is fixed to the rotating wheel; the energy storage spring is used to normally drive the rotating wheel to rotate in the first direction; a steel cable: the steel cable is wound around the outer peripheral wall of the rotating wheel; the first end of the steel cable is fixed to the rotating wheel and the second end of the steel cable extends out of the housing; a locking buckle: the locking buckle is pivotally mounted on the housing; the first end of the locking buckle has locking protrusions adapted to any of the locking ratchets, while the second end has non-return protrusions adapted to any of the non-return grooves; the locking protrusions and the non-return protrusions are respectively disposed on both sides of the pivot point of the locking buckle; a first button: the first button is coupled with the first end of the locking buckle; a second button: the second button is coupled with the second end of the locking buckle; when the first button is pressed, the second button bounces under the driving of the locking buckle; the locking protrusion is combined with any one of the locking ratchets, and the non-return protrusions are disengaged from any one of the non-return grooves; the rotating wheel is allowed to rotate in the first direction and prohibited from rotating in the second direction; the steel cable is tightened; when the second button is pressed, the first button bounces under the driving of the locking buckle; the locking protrusion is disengaged from any one of the locking ratchets, and the non-return protrusion is combined with any one of the non-return grooves; the rotating wheel is allowed to rotate in the second direction and prohibited from rotating in the first direction; the steel cable is pulled out.', '2. The automatic shrinking and locking ratchet wheel lock catch as claimed in claim 1, characterised in that it also comprises a limit-position buckle and a spring, the first end of the spring abuts on the housing, while the second end of the spring abuts on the limit-position buckle to push the limit-position buckle to be coupled with the first end of the locking buckle, so that the locking buckle is positioned at a position where the ratchet is coupled with the rotating wheel or where the ratchet is disengaged from the rotating wheel.', '3. The automatic shrinking and locking ratchet wheel lock catch as claimed in claim 2, characterised in that it also comprises a first return spring and a second return spring; the first end of the first return spring abuts on the first end of the locking buckle, while the second end of the first return spring abuts on the first button; the first end of the second return spring abuts on the housing, while the second end of the second return spring abuts on the second button.', '5. The automatic shrinking and locking ratchet wheel lock catch as claimed in claim 4, characterised in that it also comprises a steel cable sleeve; the steel cable sleeve is coupled with the housing; the second end of the steel cable passes through the steel cable sleeve and coupled with the buckle.', '6. The automatic shrinking and locking ratchet wheel lock catch as claimed in claim 4, characterised in that the housing has a first connecting hole and a second connecting hole.']",False,"['101', '1100', '1000', '100', '600', '102', '700', '400', '1100', '1000', '200', '900', '800', '009', '610', '510', '500', '520', '710', '700', '2']" 239,EP_3587154_A1 (1).png,EP3587154A1,VEHICLE SIDE DOOR,['FIG3'],['FIG3 is a schematic plan view of the side door illustrated without some members'],"['Further, as illustrated in FIG3, a virtual plane IP perpendicular to the horizontal direction is assumed. When the virtual plane IP approaches the door main body 21 from the outer side in the vehicle right-left direction, the virtual plane IP makes contact with only the side plate portion 45 of the mirror stay 40 and the outwardly projecting portion 22a of the outer panel 22. In other words, when the virtual plane IP makes contact with the side plate portion 45, the virtual plane IP does not make contact with other parts of the outer panel 22 except the outwardly projecting portion 22a.']",14,113,schematic plan view,B,"[{'element_identifier': '51', 'terms': ['support']}, {'element_identifier': '44', 'terms': ['bottom plate portion']}, {'element_identifier': '22', 'terms': ['outer panel']}, {'element_identifier': '45', 'terms': ['side plate portion']}, {'element_identifier': '20', 'terms': ['side door', 'side doors']}, {'element_identifier': '40', 'terms': ['stay']}, {'element_identifier': '57', 'terms': ['spacer']}, {'element_identifier': '25', 'terms': ['inner panel']}, {'element_identifier': '41', 'terms': ['front plate portion']}, {'element_identifier': '42', 'terms': []}, {'element_identifier': '52', 'terms': ['support cover']}, {'element_identifier': '50', 'terms': ['mirror unit']}, {'element_identifier': '10', 'terms': ['vehicle']}, {'element_identifier': '26', 'terms': ['reinforcing member']}, {'element_identifier': '21', 'terms': ['door main body']}, {'element_identifier': '43', 'terms': []}, {'element_identifier': '46', 'terms': ['fixed portions']}, {'element_identifier': '23', 'terms': ['opening']}]","['1. A vehicle side door (20) comprising: a door main body (21) configured to open and close a side face opening (12) of a vehicle (10); a mirror stay (40) fixed to the door main body (21) so as to be at least partially placed outwardly from the door main body (21) in a vehicle right-left direction, the mirror stay (40) including a support portion (43a) placed outwardly from the door main body (21) in the vehicle right-left direction; and a mirror unit (50) including a mirror holder (53) supported by the support portion (43a), and a mirror (54) supported by the mirror holder (53), wherein: the door main body (21) includes an outer panel (22) constituting an outer face of the door main body (21) in the vehicle right-left direction, an inner panel (25) placed inwardly from the outer panel (22) in the vehicle right-left direction and fixed to the outer panel (22), and a reinforcing member (26) fixed to the inner panel (25) or the outer panel (22) and extending in a front-rear direction; and the mirror stay (40) is fixed to the reinforcing member (26).', '4. The vehicle side door (20) according to any one of claims 1 to 3, further comprising a spacer (57; 65) disposed in a gap between the inner panel (25) and the outer panel (22), the spacer (57; 65) being placed behind the mirror stay (40) so as to be fixed to the inner panel (25) or a member fixed to the inner panel (25).']",True,"['3', '20', '21', '57', '22', '45', '4', '43246', '43', '40', '45', '46', '41', '46', '46', '44', '51', '52', '50', '43', '46', '25', '40', '42', '44', '23', '20', '22', '46', '21', '26', '10']" 240,EP_3587160_A1 (1).png,EP3587160A1,POWER TRANSMISSION DEVICE,['FIG2'],['FIG2 is a skeleton diagram of a power transmission device according to a second embodiment'],"['A second embodiment will be described with reference to FIG2. In the first embodiment, the power transmission device 10 including the first clutch 24 including the one-way clutch has been described. On the contrary, in the second embodiment, a power transmission device 40 including a first clutch 41 including an engaging clutch will be described. It should be noted that the same portions as the portions described in the first embodiment are indicated by the same reference numerals, and the description thereafter is omitted. FIG2 is a skeleton diagram of the power transmission device 40 according to the second embodiment.', 'As illustrated in FIG2, in the power transmission device 40, the first clutch 41 is disposed to the intermediate shaft 13. In this embodiment, the first clutch 41 is the engaging clutch that can switch the coupling of the second gear 23 to the intermediate shaft 13 and the releasing of the second gear 23 from the intermediate shaft 13. As the engaging clutch, a gear clutch, a tooth clutch, a dog clutch, and the like are given. The first clutch 41 operates the actuator (not illustrated) to switch the disconnection and the connection.']",15,219,diagram,B,"[{'element_identifier': '17', 'terms': ['differential gear']}, {'element_identifier': '14', 'terms': ['output shaft']}, {'element_identifier': '35', 'terms': ['sixth gear']}, {'element_identifier': '11', 'terms': ['first input shaft']}, {'element_identifier': '18', 'terms': ['wheels']}, {'element_identifier': '34', 'terms': ['fifth gear']}, {'element_identifier': '31', 'terms': []}, {'element_identifier': '16', 'terms': ['second motor']}, {'element_identifier': '33', 'terms': ['fourth gear']}, {'element_identifier': '15', 'terms': ['first motor']}, {'element_identifier': '23', 'terms': ['second gear']}, {'element_identifier': '32', 'terms': ['third gear']}, {'element_identifier': '13', 'terms': ['intermediate shaft', 'intermediate shafts']}]","['1. A power transmission device comprising: a first input shaft and a second input shaft coupled to a first motor and a second motor, respectively, and disposed on the same axis; a first speed reduction mechanism transmitting the rotation of the first input shaft to an output shaft via an intermediate shaft; a second speed reduction mechanism transmitting the rotation of the second input shaft to the output shaft via the intermediate shaft at a speed reduction ratio different from the speed reduction ratio of the first speed reduction mechanism; and a first clutch disconnecting or connecting the transmission of the power of the first speed reduction mechanism.']",False,"['31', '2', '11', '32', '25', '23', '34', '15', '16', '13', '18', '33', '14', '17', '35', '2']" 241,EP_3587160_A1 (2).png,EP3587160A1,POWER TRANSMISSION DEVICE,['FIG3'],['FIG3 is a skeleton diagram of a power transmission device according to a third embodiment '],"['A third embodiment will be described with reference to FIG3. In the first embodiment, the case where the first input shaft 11 and the second input shaft 12 are relatively rotatably coupled to each other via the pilot bearing (not illustrated) has been described. On the contrary, in the third embodiment, the case where a second clutch 51 disconnecting or connecting the first input shaft 11 and the second input shaft 12 will be described. It should be noted that the same portions as the portions described in the first embodiment are indicated by the same reference numerals, and the description thereafter is omitted. FIG3 is a skeleton diagram of a power transmission device 50 according to the third embodiment.', 'As illustrated in FIG3, in the power transmission device 50, the second clutch 51 is disposed between the first input shaft 11 and the second input shaft 12 disposed on the same axis. The second clutch 51 disconnects or connects the first input shaft 11 and the second input shaft 12. The second clutch 51 adopts any clutch, such as the engaging clutch and a friction clutch. Of course, synchromesh can be incorporated into the second clutch 51.']",15,218,diagram,B,"[{'element_identifier': '17', 'terms': ['differential gear']}, {'element_identifier': '14', 'terms': ['output shaft']}, {'element_identifier': '12', 'terms': ['second input shaft']}, {'element_identifier': '23', 'terms': ['second gear']}, {'element_identifier': '35', 'terms': ['sixth gear']}, {'element_identifier': '22', 'terms': ['first gear']}, {'element_identifier': '18', 'terms': ['wheels']}, {'element_identifier': '21', 'terms': ['first speed reduction mechanism']}, {'element_identifier': '31', 'terms': []}, {'element_identifier': '16', 'terms': ['second motor']}, {'element_identifier': '33', 'terms': ['fourth gear']}, {'element_identifier': '34', 'terms': ['fifth gear']}, {'element_identifier': '50', 'terms': ['power transmission device']}, {'element_identifier': '15', 'terms': ['first motor']}, {'element_identifier': '3', 'terms': ['andFig.']}, {'element_identifier': '32', 'terms': ['third gear']}]","['1. A power transmission device comprising: a first input shaft and a second input shaft coupled to a first motor and a second motor, respectively, and disposed on the same axis; a first speed reduction mechanism transmitting the rotation of the first input shaft to an output shaft via an intermediate shaft; a second speed reduction mechanism transmitting the rotation of the second input shaft to the output shaft via the intermediate shaft at a speed reduction ratio different from the speed reduction ratio of the first speed reduction mechanism; and a first clutch disconnecting or connecting the transmission of the power of the first speed reduction mechanism.']",False,"['50', '31', '15', '21', '16', '32', '12', '22', '23', '34', '3', '18', '33', '14', '17', '35', '3', '8']" 242,EP_3587206_A1 (6).png,EP3587206A1,VEHICLE CONTROL METHOD AND SYSTEM,['FIG9'],"['FIG9 is a graph representing a relationship between a pedal return speed coefficient and an accelerator pedal return speed, in this embodiment']","['Next, with reference to FIG9, the pedal return speed coefficient K4 will be described. The pedal return speed coefficient K4 is a coefficient to be set during return of the accelerator pedal (during decrease of the depression amount). Thus, when the depression speed is zero, or the accelerator pedal is being depressed (the depression amount is increasing), the pedal return speed coefficient K4 is set to 1. As depicted in FIG9, the pedal return speed coefficient K4 is set such that the value thereof increases along with an increase in a manipulation speed during return of the accelerator pedal (pedal return speed [mm/sec]). Specifically, generally, when the accelerator pedal depression speed is relatively large, the vehicle 1 is quickly decelerated, and the deceleration of the vehicle 1 becomes relatively large. In a state in which the deceleration of the vehicle 1 is relatively large, the load on the front road wheels is relatively large due to an inertial force acting on the vehicle 1. As a result, when the accelerator pedal return speed is relatively large, the suspension 3 of the front road wheels is relatively compressed. Therefore, when the accelerator pedal return speed is relatively large, the effect of improving the responsiveness and linear feeling of the behavior of the vehicle 1 under the same incremental torque is deteriorated. In order to correct such a deterioration in in the responsiveness and linear feeling improvement effect, the pedal return speed coefficient K4 is set such that the value thereof increases along with an increase in the pedal return speed.', 'In the vehicle control system and method according to the above embodiment, the incremental torque is set to a larger value when the manipulation speed during return of the accelerator pedal is relatively large than when the manipulation speed during return of the accelerator pedal is relatively small (FIG9), so that it becomes possible to sufficiently improve the responsiveness and linear feeling of the vehicle behavior even when the manipulation speed during return of the accelerator pedal is relatively large.']",23,380,graph,B,"[{'element_identifier': '0', 'terms': ['is']}]","['1. A method of controlling a vehicle in which rear road wheels are driven by a prime mover, comprising: a mode selection step of selecting a first pedal mode in which an acceleration of the vehicle is set based on a depression amount of an accelerator pedal of the vehicle, or a second pedal mode in which the acceleration and a deceleration of the vehicle are set based on the depression amount of the accelerator pedal of the vehicle; a basic torque setting step of setting, based on a driving state of the vehicle, a basic torque to be generated by the prime mover; an incremental torque setting step of setting an incremental torque to allow the basic torque to be increased in accordance with an increase in steering angle of a steering device equipped in the vehicle; and a torque generation step of controlling the prime mover to generate a torque which is determined by adding the incremental torque to the basic torque, wherein the incremental torque setting step includes setting the incremental torque to different values between when the first pedal mode is selected in the mode selection step and when the second pedal mode is selected in the mode selection step.']",True,"['0', '23']" 243,EP_3587260_A2 (1).png,EP3587260A2,EXTENDED DURATION REGENERATIVE POWERED UNMANNED AERIAL VEHICLE (UAV) PLATFORM,['FIG2'],['FIG2 is a perspective view of a UAV cluster configured according to the present aspects in-flight and delivering one or more payloads to corresponding delivery locations'],"['FIG2 illustrates a UAV cluster 10 configured to perform a mission according to the present disclosure. Particularly, UAV cluster 10 is created to comprise a plurality of individual mission UAVs 12 and a plurality of core UAVs. The core UAVs include fuel storage UAVs 14 and propulsion UAVs 16. In one aspect, the creation of a given UAV cluster 10 occurs ""on the ground"" at one of the distribution points DP. In these aspects, the individual UAVs 12, 14, 16, for use in creating the UAV cluster 10 are selected and interconnected physically and communicatively while at the distribution location. The UAV cluster 10 is then launched to fly its mission, with the individual mission UAVs 12 detaching from the UAV cluster 10 to deliver their respective payloads to their respective destination locations DL. In other aspects, individual UAVs 12, 14, 16 may be launched from one or more of the distribution points DP and join an already existing UAV cluster 10 in-flight. In these aspects, the individual UAVs 12, 14, 16 are configured to autonomously dock with each other while in-flight and form the physical and communication connections.']",28,216,perspective view,B,"[{'element_identifier': '10', 'terms': ['UAV cluster', 'UAV clusters']}, {'element_identifier': '20', 'terms': ['frame']}]","['1. An unmanned aerial vehicle (UAV) cluster (10) comprising: a plurality of mission UAVs arranged in a cluster, with a set of one or more mission UAVs being configured for controlled independent flight; and a plurality of core UAVs (14, 16, 30, 40) distributed throughout the cluster according to a selected distribution pattern that distributes the core UAVs according to a predefined mission characteristic of the UAV cluster.']",False,"['10', '20']" 244,EP_3587260_A2 (3).png,EP3587260A2,EXTENDED DURATION REGENERATIVE POWERED UNMANNED AERIAL VEHICLE (UAV) PLATFORM,['FIG10'],['FIG10 is a functional block diagram illustrating component parts of a UAV in a UAV cluster according to one aspect of the present disclosure'],"['FIG10 is a functional block diagram illustrating some component parts of a computing device 80 configured to implement method 60 according to one aspect of the present disclosure. As seen in FIG10, the computing device 80 comprises processing circuitry 82, memory 84, a user interface 86, and communications circuitry 88.', 'Memory 84 comprises any non-transitory machine-readable storage media known in the art or that may be developed, whether volatile or non-volatile, including (but not limited to) solid state media (e.g., SRAM, DRAM, DDRAM, ROM, PROM, EPROM, flash memory, solid state drive, etc.), removable storage devices (e.g., Secure Digital (SD) card, miniSD card, microSD card, memory stick, thumb-drive, USB flash drive, ROM cartridge, Universal Media Disc), fixed drive (e.g., magnetic hard disk drive), or the like, individually or in any combination. As seen in FIG10, memory 84 is configured to store a computer program product (e.g., control program 90) comprising the instructions executed by processing circuitry 82 to perform the previously described aspects of the present disclosure. Additionally, memory 84 is configured to store various information and data, such as the rules for selecting the number and types of individual UAVs to be used to build UAV cluster 10, as well as the respective distribution patterns for the core UAVs.']",24,269,block diagram,B,"[{'element_identifier': '28', 'terms': ['fuel reservoir']}, {'element_identifier': '80', 'terms': ['computing device']}, {'element_identifier': '86', 'terms': ['user interface']}, {'element_identifier': '84', 'terms': ['memory']}, {'element_identifier': '90', 'terms': ['control program']}, {'element_identifier': '10', 'terms': ['UAV cluster', 'UAV clusters']}, {'element_identifier': '88', 'terms': ['communications circuitry']}, {'element_identifier': '82', 'terms': ['processing circuitry']}]","['5. The UAV cluster of claim 3, wherein one of the plurality of core UAVs to be distributed throughout the cluster comprises one of: a propulsion UAV (16) configured to augment a propulsion provided by each individual mission UAV in the cluster; a fuel storage UAV (14) comprising a fuel reservoir (28) storing a fuel, and configured to augment the fuel consumed by each individual mission UAV in the cluster; a power UAV (30) configured to augment electrical power consumed by each individual mission UAV in the cluster; and a sensor UAV (40) comprising a sensor (46).', '15. The self-aligning docking mechanism of any one of claims 12-14, wherein the docking jaw is configured to move between an open state to undock from the corresponding docking jaw, and a closed state to dock with the corresponding docking jaw, and wherein the docking jaw (130a) comprises opposing first and second grippers (132, 134) constructed from a shape memory alloy, and wherein the docking control circuit is further configured to: apply a first voltage to each of the first and second grippers to move the docking jaw to the open state, wherein the first voltage meets or exceeds a threshold value; and reduce the first voltage being applied to the first and second grippers to a second voltage to move the docking jaw to the closed state, wherein the second voltage is less than the threshold value.']",False,"['80', '84', '90', '88', '82', '86', '10', '28']" 245,EP_3587279_A1 (2).png,EP3587279A1,METHOD AND APPARATUS FOR PRODUCING SHIMS FOR USE IN AN AIRCRAFT AIRFRAME,['FIG5'],['FIG5 is a schematic illustration (not to scale) showing machining apparatus for machining a component of the airframe'],"['FIG5 is a schematic illustration (not to scale) illustrating an example conventional process of producing a frame 202 that may be performed at step s8.', 'In this embodiment, a workpiece (which is to be machined to form the frame 202 and is therefore indicated in FIG5 by the reference numeral 202) is fixed to a frame machining fixture 500. The frame machining fixture 500 comprises a substantially rigid base portion 502 and a plurality of locator pins 504.']",20,87,schematic,B,"[{'element_identifier': '202', 'terms': ['parts', 'part']}, {'element_identifier': '502', 'terms': ['base portion']}, {'element_identifier': '400', 'terms': ['portion']}, {'element_identifier': '506', 'terms': ['CNC milling machine']}, {'element_identifier': '204', 'terms': ['shear webs', 'shear web']}, {'element_identifier': '508', 'terms': ['controller']}, {'element_identifier': '402', 'terms': ['gaps']}, {'element_identifier': '500', 'terms': ['machining fixture']}, {'element_identifier': '504', 'terms': ['locator pins', 'locator pin']}, {'element_identifier': '510', 'terms': ['fixture attachment feature', 'fixture attachment features']}]","['1. A method of producing a shim for use in an aircraft airframe, the method comprising: providing a plurality of component parts of the aircraft airframe; measuring a surface of each of the component parts; for each component part, creating a digital model of that component part using the measurements of the surface of that component part; digitally assembling together the digital models of the component parts thereby to produce a digital model of at least part of the aircraft airframe; using the digital model of at least part of the aircraft airframe, creating a digital model of a shim, the digital model of the shim filling a gap between at least two digital models of component parts in the digital model of at least part of the aircraft airframe; and producing a physical shim using the digital model of the shim.']",False,"['4', '400', '202', '402', '204', '5', '506', '510', '504', '500', '504', '504', '510', '202', '508', '510', '502', '504', '510', '16']" 246,EP_3587281_A1 (6).png,EP3587281A1,ENHANCED RIG CHECK AND LEAK DETECTION OF AIRCRAFT DOORS,['FIG6'],['FIG6 is a side view of the leak testing device in an illustrative embodiment'],"['FIG6 is a side view of a leak testing device 600 in an illustrative embodiment. As shown in this example, components of the leak testing device 600, including the structural frame 310 and the crossbars 320, may be shaped or oriented to correspond with or match the curvature of the external surface of the aircraft 100. Each of the suction cups 340 may be attached to a bottom side 602 of the structural frame 310 via a t-bar 610 and a pivot joint 620. The bottom side 602 is generally the aircraft-facing side of the structural frame 310 and the crossbars 320 that is opposite to the top side 604. The t-bar 610 extends perpendicularly from the crossbar 320 and mechanically couples the suction cup 340 with the crossbar 320 and structural frame 310. The pivot joint 620 enables rotation of the suction cup 340 about the t-bar 610 to orient a suctioning surface 622 of the suction cup 340 according to the surface curvature of the aircraft door 150, thereby facilitating secure engagement for pulling the aircraft door 150.']",14,198,side view,B,"[{'element_identifier': '150', 'terms': ['aircraft door', 'aircraft doors']}, {'element_identifier': '620', 'terms': ['pivot joint']}, {'element_identifier': '634', 'terms': ['engagement surface']}, {'element_identifier': '600', 'terms': ['leak testing device']}, {'element_identifier': '610', 'terms': ['t-bar']}, {'element_identifier': '632', 'terms': ['spring']}, {'element_identifier': '604', 'terms': ['top side']}, {'element_identifier': '602', 'terms': ['bottom side']}, {'element_identifier': '630', 'terms': ['floating mount', 'floating mounts']}, {'element_identifier': '340', 'terms': ['suction cups', 'suction cup']}, {'element_identifier': '410', 'terms': ['gasket channel', 'gasket channels']}, {'element_identifier': '622', 'terms': ['suctioning surface']}]","['1. An apparatus (300, 400, 500, 600) for leak testing a seal (270) between an aircraft door (150) and a fuselage (130) of an aircraft (100), the apparatus comprising: a structural frame (310) including: a suction cup (340) configured to suction an outer surface (202) of an aircraft door (150); and legs (330) configured to contact an outside of a fuselage and to extend in length to push the structural frame (310) away from the fuselage (130) and cause the suction cup (340) to pull the aircraft door (150) toward an outside of the aircraft (100) to tighten the seal (270) between the aircraft door (150) and the fuselage (130) of the aircraft (100).', '2. The apparatus of claim 1 wherein: the structural frame (310) further including: a crossbar (320) sized to straddle the aircraft door (150) outside the aircraft (100), wherein the crossbar couples with the legs (330) at either end of the crossbar, and wherein the crossbar couples with the suction cup (340) at a location between the legs; and a gasket channel (410) on a bottom side of the structural frame (310), the gasket channel being sized to correspond with an outer periphery of the aircraft door (150) and configured to fluidly couple with the seal (270) between the aircraft door and the fuselage (130).', '9. The apparatus of claim 1 wherein: the structural frame (310) including: one or more floating mount supports (630) attached to a bottom side (602) of the structural frame, the one or more floating mount supports having springs (632) to provide a spring contact force between the aircraft door (150) and the structural frame to facilitate alignment of the structural frame with respect to the aircraft door while the suction cup pulls the aircraft door.']",False,"['6', '632', '630', '600', '634', '340', '604', '602', '340', '610', '150', '622', '340', '620', '410', '16']" 247,EP_3587315_A1 (5).png,EP3587315A1,"IMAGE FORMING APPARATUS, PROGRAM, AND LIFE DETERMINATION METHOD",['FIG10'],['FIG10 is a flowchart showing the operation of an image forming apparatus in a modification example 2'],"['FIG10 is a flowchart showing the operation of the image forming apparatus 1 in the embodiment.', 'The processing in FIG10 is achieved by a cooperation between the controller 10 and the program stored in the storage 17.']",17,40,flowchart,B,"[{'element_identifier': '166', 'terms': ['second sensor']}, {'element_identifier': '164', 'terms': ['separating roller']}, {'element_identifier': '162', 'terms': ['pickup roller']}, {'element_identifier': '163', 'terms': ['sheet feeding roller']}, {'element_identifier': '165', 'terms': ['first sensor']}, {'element_identifier': '161', 'terms': ['tray']}]","['1. An image forming apparatus (1) comprising: a sheet feeding roller (163) which feeds a sheet (P) accumulated on a tray (161); a speed detector (10) which detects a movement speed of the sheet that is currently fed by the sheet feeding roller; and a life determiner (10) which calculates a difference amount between the movement speed and a first reference speed, and determines a life of the sheet feeding roller based on the difference amount, wherein the life determiner determines whether or not to use the movement speed of a first sheet (PO) for life determination based on a relationship between the movement speed of the first sheet and the movement speed of a sheet which is fed before the first sheet, and if the life determiner determines not to use the movement speed of the first sheet for the life determination, the life determiner calculates the difference amount by excluding the movement speed of the first sheet.', '7. The image forming apparatus according to any one of claims 2 to 4, comprising a second sensor (166) which is arranged downstream of the first sensor in the conveyance direction of the sheet and detects arrival of the front end of the sheet which is fed, wherein the first sensor is arranged at a position which is downstream of the sheet feeding roller in the conveyance direction of the sheet and at which a distance from the sheet feeding roller is shorter than a length of the sheet in the conveyance direction, the speed detector detects, as a first movement speed, the movement speed from start of sheet feeding of the sheet by the sheet feeding roller to detection of the front end of the sheet by the first sensor, and the speed detector detects, as a second movement speed, the movement speed from the detection of the front end of the sheet by the first sensor to detection of the front end of the sheet by the second sensor.']",True,"['163', '162', '165', '166', '164', '161', '20']" 248,EP_3587315_A1.png,EP3587315A1,"IMAGE FORMING APPARATUS, PROGRAM, AND LIFE DETERMINATION METHOD",['FIG2'],['FIG2 is a block diagram showing a functional configuration of the image forming apparatus according to the present invention'],"['As shown in FIG2, the controller 10 is configured by including a CPU (Central Processing Unit) 101, a ROM (Read Only Memory) 102, a RAM (Random Access Memory) 103, and the like. The CPU 101 reads out a program corresponding to the processing contents from the ROM 102, loads the program onto the RAM 103, and integrally controls the operations of the components of the image forming apparatus 100 in cooperation with the loaded program. At this time, various types of data stored in the storage 17 are referred to.']",19,106,block diagram,B,"[{'element_identifier': '103', 'terms': ['RAM']}, {'element_identifier': '17', 'terms': ['storage']}, {'element_identifier': '14', 'terms': ['image former']}, {'element_identifier': '12', 'terms': ['display']}, {'element_identifier': '16', 'terms': ['sheet feeder', 'sheet feeders']}, {'element_identifier': '102', 'terms': ['ROM']}, {'element_identifier': '10', 'terms': ['controller']}, {'element_identifier': '15', 'terms': ['conveyer']}, {'element_identifier': '13', 'terms': ['image reader']}]","['13. The image forming apparatus according to claim 12, wherein the life determiner calculates an average value of the movement speed of a predetermined number of sheet which is detected by the speed detector and stores the average value in a storage (17), and if the tray is detected being opened during the sheet feeding of the second sheet which is fed by the sheet feeding roller immediately after the first sheet, the life determiner deletes the average value which is stored in the storage.']",True,"['13', '12', '16', '16', '16', '10', '102', '103', '15', '12', '13', '16', '17', '14']" 249,EP_3587361_A1 (2).png,EP3587361A1,WASTE SUSPENSION TREATMENT APPARATUS,"['FIG3a', ' FIG3b']","['FIG3a is a cross-sectional elevation of the waste suspension treatment apparatus shown in FIG2, taken along line A-A ', 'FIG3b is a cross-sectional elevation of the waste suspension treatment apparatus shown in FIG2, taken along line B-B']","['FIG3a', 'FIG3a is intended to assist in illustrating the design and imparted functionality of the elongate narrow apertures 27 of the first filter 4 comprised within the primary waste treatment chamber 3 of the apparatus 1. The structure of said elongate narrow apertures 27 is clearly depicted in FIG3a, again, evidencing the corresponding dimensions and shape for optimised filtration of macroscopic waste products from the waste solution, whilst allowing free flow of said waste solution through said first filter 4 towards the waste treatment chamber 8. ', 'The waste treatment chamber 8 further comprises a treatment medium (referenced in FIG3b & 4). Preferentially, the waste treatment chamber 8 comprises treatment media, occupying a given volume of said waste treatment chamber 8. More particularly, in the present embodiment, the treatment chamber 8 comprises hundreds to thousands of individual pieces of treatment media. Said treatment media occupies the majority of the volume of the waste treatment chamber 8, whilst preserving sufficient chamber volume for circulation of said media. The circulation of said media within the treatment chamber 8 helps to burst oxygen bubbles projected by the diffusers 10 so as to incorporate maximum levels of oxygen within the filtered waste suspension.', 'FIG3b', 'FIG3b provides additional clarity to the structure comprised within the waste treatment chamber 8 of the apparatus 1. As previously discussed, there are a plurality of diffusers 10 within said waste treatment chamber 8. More particularly, said plurality of diffusers 10 are generally equally transversely spaced along a bottom surface of said waste treatment chamber, so as to give an even and through distribution of air from said diffusers 10 to the filtered waste suspension therein, from the bottom upwards.']",46,306,cross-sectional view,C,"[{'element_identifier': '8', 'terms': ['chamber']}, {'element_identifier': '28', 'terms': ['waste treatment media']}, {'element_identifier': '11', 'terms': ['pipe']}, {'element_identifier': '27', 'terms': ['apertures']}, {'element_identifier': '10', 'terms': ['diffusers', 'diffuser']}]","['1. A waste suspension treatment apparatus (1), comprising; a primary waste chamber (3), provided with at least one waste suspension inlet means (2); a first filter means (4), located within the primary waste chamber (3); a waste treatment chamber (8), having first and second ends and containing at least one treatment medium (28); a second filter means (15), located within the waste treatment chamber (8); and at least one final waste suspension outlet means (17); characterised in that said first filter means (4) is adapted for separation of macroscopic waste products from a waste suspension and said second filter means (15) is adapted for removal filtration of finer suspended solids.', '7. The waste suspension treatment apparatus of claim 6, wherein the air incorporation means (10) comprises a diffuser connected to an air compressor.']",True,"['8', '28', '11', '27', '10']" 250,EP_3587476_A1 (5).png,EP3587476A1,METHOD FOR PRODUCING A COMPOSITION WITH SOLUBLE NANOPARTICLES FOR COMPOSITE PERFORMANCE ENHANCEMENT,['FIG10A'],['FIG10A is a schematic illustration of the cured resin mixture of FIG10 after dissolution of the sheaths such that the shaped particles remains in the resin'],"['FIG10A is a schematic illustration of the cured resin mixture 114 of FIG10 after dissolution of the sheaths 242 during the cure cycle such that only the shaped particles 246 remain after the resin mixture 114 cures. Advantageously, the dissolved sheath 242 may adhesively bond the core 244 (FIG10) to the cured resin 112 without the use of reactive species that may undesirably generate heat. Dissolution of the sheath 242 within the resin 112 may result in a significant increase in the toughness of the resin mixture 114 similar to the above-described toughness increase provided by the at least partial dissolution of polymer nanoparticles 200. Advantageously, by using a spherically-shaped sheath, the shaped particles 246 may be uniformly distributed within the resin 112 (FIG10) without agglomeration during resin flow, and without significantly increasing resin viscosity. The shaped particles 246 may be formed of any one of a variety of materials including, but not limited to, metallic material, polymeric material, and inorganic material including ceramics and glasses. In some examples, the shaped particles 246 may be formed of the same material as the resin 112 and may be at least partially cured prior to curing of the resin mixture 114.']",26,222,schematic,C,"[{'element_identifier': '242', 'terms': ['sheath', 'sheaths']}, {'element_identifier': '112', 'terms': ['resin', 'resins']}, {'element_identifier': '246', 'terms': ['particles', 'particle']}, {'element_identifier': '10', 'terms': ['constitute no less than']}, {'element_identifier': '240', 'terms': ['core-sheath nanoparticles', 'core-sheath nanoparticle']}, {'element_identifier': '244', 'terms': ['core', 'cores']}, {'element_identifier': '110', 'terms': ['composition']}, {'element_identifier': '200', 'terms': ['polymer nanoparticles', 'polymer nanoparticle']}, {'element_identifier': '114', 'terms': ['resin mixture']}]","['1. A method of manufacturing a composition, comprising: mixing soluble and/or semi-soluble polymer nanoparticles (204) into a resin (112) to form a resin mixture (114); curing the resin mixture; and at least partially dissolving the polymer nanoparticles in the resin prior to or during the curing of the resin.', '2. The method of Claim 1, wherein the polymer nanoparticles (204) are semi-soluble in the resin (112), the method further including: forming a gradient of mechanical properties between a particle center of the polymer nanoparticles and the resin in response to curing the resin.', '4. The method of Claim 3, wherein the polymer nanoparticles (204) include core-sheath nanoparticles (240) having a sheath (242) encapsulating a core (244), the method further including, the core being formed of insoluble material, the method further including: at least partially dissolving the sheath in the resin (112) prior to or during the curing of the resin such that the sheath bonds the core to the resin.', '9. The method of any preceding claim, wherein the nanoparticles constitute no less than 5 percent by volume of the resin mixture.']",True,"['110', '244', '114', '240', '242', '112', '110', '114', '246', '246', '246', '200', '27', '10']" 251,EP_3587515_A1.png,EP3587515A1,"INK-JET RECORDING LIQUID SET, PREPARATION METHOD OF PRETREATMENT LIQUID FOR INK-JET RECORDING, PRINTED MATTER, AND INK-JET RECORDING METHOD","['FIG1', ' FIG2', ' FIG3']","['FIG2 is a cross-sectional drawing which illustrates a schematic structure of the printed matter of the present invention ', 'FIG3 is a cross-sectional drawing of a PET/CPP laminate body for measuring peeling strength ', 'FIG1 is a schematic view illustrating an example of a pretreatment and an ink-jet recording apparatus preferably used for the present invention']","['As illustrated in FIG2, a printed matter (P) is obtained by discharging the pretreatment liquid according to the present invention from an ink-jet head on a substrate (F) to form a pretreatment layer (C), the ink is discharged from an ink-jet head at a position where the pretreatment layer (C) is fixed, and the ink is fixed to form a printing layer (R). ', 'As illustrated in FIG3, a dry laminate adhesive (TAKELAC A626, made by Mitsui Chemicals, Inc.) and a two-part curing type isocyanate cross-linking agent (TAKENATE A50, made by Mitsui Chemicals, Inc.) were applied in a coating amount of 3.0 g/m2 to obtain a coated layer (54) on a printed matter (a pretreatment layer (52) and an ink layer (53)) formed on a PET film (51),and the coated layer (54) was bonded with a CPP film (55) (P1128 60 µm, made by Toyobo Co., Ltd.) to obtain a PET/CPP laminate body (the numbers in parentheses refer to the numbers indicated in FIG3.). The obtained laminate body was cut into a length of 70 mm and a width of 15 mm, and the peeling strength in the 90 degree direction was measured at a peeling speed of 300 mm/min using a TENSILON tensile tester. ', 'FIG1 is a schematic view of a pretreatment/ink-jet recording apparatus preferred for the present invention. However, the present invention is not limited to this. For example, in the pretreatment/ink-jet recording apparatus 1 illustrated in FIG1, the first drying unit 14 may be omitted.']",62,321,"cross-sectional view, schematic view",B,"[{'element_identifier': '5', 'terms': ['preferably', 'but it is usually', 'C.I. Pigment Red', 'polyethylene glycol having', 'pigment solid content became', 'x', 'less than']}, {'element_identifier': '30', 'terms': ['about']}, {'element_identifier': '14', 'terms': ['first drying unit']}, {'element_identifier': '20', 'terms': ['IJ printing unit']}, {'element_identifier': '52', 'terms': ['pretreatment layer']}, {'element_identifier': '53', 'terms': ['ink layer']}, {'element_identifier': '10', 'terms': ['is', 'precoat application unit']}, {'element_identifier': '50', 'terms': ['at']}, {'element_identifier': '21', 'terms': ['ink-jet head']}, {'element_identifier': '23', 'terms': ['second drying unit']}]","['1. An ink-jet recording liquid set comprising a pretreatment liquid and an ink, wherein the pretreatment liquid contains a coagulant, water, and water-insoluble resin particles containing at least one of a polyester skeleton, a polyolefin skeleton and polyurethane skeleton; and the ink contains at least a pigment, a compound having an oxazoline group, and water.', '2. The ink-jet recording liquid set described in claim 1, wherein the coagulant is a polyvalent metal salt or an organic acid.']",True,"['10', '20', '21', '14', '23', '30', '50', '5', '53', '52', '5', '27']" 252,EP_3587550_A1 (2).png,EP3587550A1,CELL PROCESSING SYSTEM AND CELL PROCESSING DEVICE,['FIG3'],['FIG3 is a schematic cross-sectional perspective view of a cell processing system according to an embodiment'],"['As shown in FIG3, the gas discharger 613 comprises an exhaust system 605 that exhausts gas inside the enclosure 601 to the exterior of the enclosure 601, and an exhaust purification filter 603 that purifies gas that has been drawn in by the exhaust system 605. The exhaust system 605 comprises a fan, for example. The exhaust purification filter 603 may be situated facing the interior of the enclosure 601, upstream from the exhaust system 605. It is often difficult to accomplish sterilization of the exhaust system 605, which is an electrical device. Therefore, the exhaust purification filter 603 may be arranged upstream from the exhaust system 605, making it possible to inhibit contamination of the exhaust system 605. The gas discharger 613 may also comprise a second exhaust purification filter 606 disposed downstream from the exhaust system 605.', 'As shown in FIG3, the outer enclosure 701 may be provided with a pressure adjustment hole 702 for adjustment of the pressure inside the outer enclosure 701. An occluding member 703 capable of occluding the pressure adjustment hole 702 is also preferably attached to the outer enclosure 701. A filter is disposed in the pressure adjustment hole 702. The material of the filter disposed in the pressure adjustment hole 702 is the same as for the intake air purification filter 602, for example.']",18,242,schematic cross-sectional view,C,"[{'element_identifier': '613', 'terms': ['gas discharger']}, {'element_identifier': '601', 'terms': ['enclosure']}, {'element_identifier': '606', 'terms': ['second exhaust purification filter']}, {'element_identifier': '605', 'terms': ['exhaust system']}, {'element_identifier': '701', 'terms': ['outer enclosure']}, {'element_identifier': '702', 'terms': ['pressure adjustment hole']}, {'element_identifier': '604', 'terms': ['partitions']}, {'element_identifier': '602', 'terms': ['intake air purification filter']}, {'element_identifier': '703', 'terms': ['occluding member']}, {'element_identifier': '603', 'terms': ['exhaust purification filter']}]","['1. A cell processing system comprising an enclosure, an outer enclosure that envelops the enclosure, an intake air purification filter provided in the enclosure, that purifies gas that has been drawn in from outside the enclosure, a circulating apparatus, inside the outer enclosure, that circulates gas inside and outside the enclosure in such a manner that gas in the outer enclosure is drawn into the enclosure through the intake air purification filter and gas inside the enclosure is discharged into the outer enclosure, and a cell processing apparatus for processing of cells, disposed inside the enclosure.', '2. The cell processing system according to claim 1, wherein a pressure adjustment hole is provided in the outer enclosure.', '4. The cell processing system according to claim 3, wherein the gas discharger comprises an exhaust system that exhausts gas inside the enclosure to the exterior of the enclosure, and an exhaust purification filter that purifies gas that has been drawn in by the exhaust system.', '9. The cell processing system according to claim 5, which further comprises a second exhaust purification filter disposed downstream from the exhaust system.']",False,"['703', '702', '605', '701', '601', '606', '603', '613', '604', '602', '47']" 253,EP_3587576_A9 (1).png,EP3587576A9,ANTISENSE OLIGONUCLEIC ACID,['FIG2'],['FIG2 is a graph showing the results of hepatotoxicity of antisense oligonucleic acid evaluated in the Example described later'],"['In the same manner as in the above-mentioned Example 1 except that #12, #98, #14 or derivatives thereof which induce strong hepatotoxicity by contribution of the above-mentioned hepatotoxicity induction mechanism (iii) were used instead of antisense oligonucleic acid #101, the hepatotoxicity was evaluated. The theoretical value of the molecular weight of #12 was 4614.73 and the measured value was 4614.27, the theoretical value of the molecular weight of #12-C2-10 was 4630.73 and the measured value was 4627.86, the theoretical value of the molecular weight of #98 was 4613.75 and the measured value was 4612.79, the theoretical value of the molecular weight of #98-C2-7 was 4629.75 and the measured value was 4631.10, the theoretical value of the molecular weight of #14 was 4606.71 and the measured value was 4605.66, and the theoretical value of the molecular weight of #14-C2-6 was 4622.71 and the measured value was 4619.72. The sequence of each antisense oligonucleic acid used in this Example is shown in Table 2, and the measurement results of the hepatotoxicity are shown in FIG2. In FIG2, ""*"" indicates presence of a significant difference at p<0.05.[Table 2]#12G T mC c g c a t g c c T A A#12-C2-10G T mC c g c a t g ζ c T A A#98G A T a t g c c c t a mC T A#98-C2-7G A T a t g ζ c c t a mC T A#14G T A t g c c t c c g T T A#14-C2-6G T A t g ζ c t c c g T T A', ""As shown in the results of FIG2, the serum concentrations of AST and ALT could be reduced significantly only by changing cytosine, which is in one of the 2',4'-non-bridged nucleic acid residues in the middle part, to 5-hydroxycytosine also in other antisense oligonucleic acids #12, #98 and #14 having high hepatotoxicity. The serum concentrations of AST and ALT were reduced to several percents by the above-mentioned mutation, though not as much as that in #101 having particularly high hepatotoxicity.""]",19,421,graph,A,"[{'element_identifier': '100', 'terms': ['than']}, {'element_identifier': '2', 'terms': ['than']}, {'element_identifier': '10', 'terms': ['than']}]","[""1. An antisense oligonucleic acid having a base length of not less than 7nt and not more than 30nt, wherein nucleic acid residues of not less than 1nt and not more than 5nt respectively from the both terminals are 2',4'-bridged nucleic acids, 2',4'-non-bridged nucleic acid residue(s) is(are) present between the both terminals, and one or more bases in the nucleic acid residue(s) of the 2',4'-non-bridged nucleic acid residue(s) is/are modified.""]",False,"['2', '10000', '10000', '68', '1000', '1000', '100', '100', '296', '10', '10']" 254,EP_3587576_A9 (2).png,EP3587576A9,ANTISENSE OLIGONUCLEIC ACID,['FIG3'],['FIG3 is a graph showing the results of hepatotoxicity of antisense oligonucleic acid and GR gene expression-suppressing activity evaluated in the Example described later'],"['With regard to each of the obtained antisense oligonucleic acids, the ALT concentration in mouse serum was measured in the same manner as in the above-mentioned Example 1 (2). The results are shown in FIG3 (1).', 'In addition, the GR gene expression-suppressing activity of each antisense oligonucleic acid was measured. To be specific, after blood was collected in the above-mentioned hepatotoxicity test, the mouse was euthanized by freezing, and the liver was removed and the weight was measured. About 100 mg was collected as a sample from a site where no abnormality was found macroscopically in the excised liver. The weight of the collected sample was measured, the sample was frozen in liquid nitrogen and stored in an ultra low temperature freezer. The cryopreserved liver sample was homogenized as much as possible using a homogenizer (Shake Master auto, Bio Medical Science Inc.) and TRIzol reagent (Thermo Fisher Scientific) under ice-cooling and total RNA was extracted. The UV absorption spectrum of the extracted total RNA was measured using Nano Vue or Nano Vue Plus (GE Healthcare), and the purity was calculated from the RNA concentration and O.D.260/O.D.280 ratio. Quantitative PCR was performed on total RNA using One Step SYBR PrimeScript RT-PCR Kit (Takara) and Applied Biosystems 7500 (Life Technologies Japan Ltd),the expression ratio of the target gene in the antisense oligonucleic acid administration group relative to the saline administration group was calculated, and the activity was evaluated. The results are shown in FIG3 (2).', ""As shown in the results of FIG3 (1), the hepatotoxicity by Posi12 was reduced to 40% by only changing cytosine, which is in one of the 2',4'-non-bridged nucleic acid residues in the middle part, to 5-hydroxycytosine. On the other hand, as shown in the results of FIG3 (2), GR gene expression-suppressing activity did not change even when cytosine, which is in one of the 2',4'-non-bridged nucleic acid residues in the middle part of Posi12, was changed to 5-hydroxycytosine. Thus, according to the present invention, hepatotoxicity can be reduced without reducing the activity of antisense oligonucleic acid.""]",26,414,graph,A,"[{'element_identifier': '100', 'terms': ['than']}, {'element_identifier': '3', 'terms': ['Example']}, {'element_identifier': '10', 'terms': ['than']}]","[""1. An antisense oligonucleic acid having a base length of not less than 7nt and not more than 30nt, wherein nucleic acid residues of not less than 1nt and not more than 5nt respectively from the both terminals are 2',4'-bridged nucleic acids, 2',4'-non-bridged nucleic acid residue(s) is(are) present between the both terminals, and one or more bases in the nucleic acid residue(s) of the 2',4'-non-bridged nucleic acid residue(s) is/are modified.""]",False,"['3', '100000', '10000', '1000', '100', '10', '69']" 255,EP_3587576_A9 (3).png,EP3587576A9,ANTISENSE OLIGONUCLEIC ACID,['FIG15'],['FIG15 is a graph showing the results of hepatotoxicity of antisense oligonucleic acid evaluated in the Example described later'],"['In the same manner as in the above-mentioned Example 1 except that #101 or a derivative thereof #101-G4-6 was used, hepatotoxicity was evaluated. The theoretical value of the molecular weight of #101-G4-6 was 4668.61 and the measured value was 4670.31. The sequence of each antisense oligonucleic acid used in this Example is shown in Table 15, and the measurement results of the hepatotoxicity are shown in FIG15. In FIG15, ""*"" indicates presence of a significant difference at p<0.05.[Table 15]#101G T T a t g c c a c c mC T A#101-G4-6G T T a t µ c c a c c mC T A', ""As shown in the results of FIG15, the serum concentrations of AST and ALT could be reduced by only converting guanine, which is in one of the 2',4'-non-bridged nucleic acid residues in the middle part of antisense oligonucleic acid #101 having very high hepatotoxicity, to 8-bromoguanine.""]",19,188,graph,A,"[{'element_identifier': '15', 'terms': ['solution']}, {'element_identifier': '100', 'terms': ['than']}, {'element_identifier': '10', 'terms': ['than']}]","[""1. An antisense oligonucleic acid having a base length of not less than 7nt and not more than 30nt, wherein nucleic acid residues of not less than 1nt and not more than 5nt respectively from the both terminals are 2',4'-bridged nucleic acids, 2',4'-non-bridged nucleic acid residue(s) is(are) present between the both terminals, and one or more bases in the nucleic acid residue(s) of the 2',4'-non-bridged nucleic acid residue(s) is/are modified.""]",False,"['15', '10000', '100000', '10000', '1000', '100', '10', '81', '1000', '100', '10']" 256,EP_3587576_A9 (4).png,EP3587576A9,ANTISENSE OLIGONUCLEIC ACID,['FIG16'],['FIG16 is a graph showing the results of hepatotoxicity of antisense oligonucleic acid evaluated in the Example described later'],"['In the same manner as in the above-mentioned Example 1 except that #12, #98, #14 or derivatives thereof were used instead of antisense oligonucleic acid #101, hepatotoxicity was evaluated. The theoretical value of the molecular weight of #12-G4-9 was 4693.62 and the measured value was 4692.50, the theoretical value of the molecular weight of #98-G4-6 was 4692.64 and the measured value was 4693.45, the theoretical value of the molecular weight of #14-G4-5 was 4685.60 and the measured value was 4683.86. The sequence of each antisense oligonucleic acid used in this Example is shown in Table 16, and the measurement results of the hepatotoxicity are shown in FIG16. In FIG16, ""*"" indicates presence of a significant difference at p<0.05.[Table 16]#12G T mC c g c a t g c c T A A#12-G4-9G T mC c g c a t µ c c T A A#98G A T a t g c c c t a mC T A#98-G4-6G A T a t µ c c c t a mC T A#14G T A t g c c t c c g T T A#14-G4-5G T A t µ c c t c c g T T A', ""As shown in the results of FIG16, the serum concentratio ns of AST and ALT could be reduced significantly only by changin g guanine, which is in one of the 2',4'-non-bridged nucleic acid residues in the middle part, to 8-bromoguanine also in other an tisense oligonucleic acids #12, #98 and #14 having high hepatoto xicity.""]",19,316,graph,A,"[{'element_identifier': '100', 'terms': ['than']}, {'element_identifier': '16', 'terms': []}, {'element_identifier': '10', 'terms': ['than']}]","[""1. An antisense oligonucleic acid having a base length of not less than 7nt and not more than 30nt, wherein nucleic acid residues of not less than 1nt and not more than 5nt respectively from the both terminals are 2',4'-bridged nucleic acids, 2',4'-non-bridged nucleic acid residue(s) is(are) present between the both terminals, and one or more bases in the nucleic acid residue(s) of the 2',4'-non-bridged nucleic acid residue(s) is/are modified.""]",False,"['16', '10000', '10000', '82', '1000', '1000', '100', '100', '10', '10']" 257,EP_3587576_A9 (5).png,EP3587576A9,ANTISENSE OLIGONUCLEIC ACID,['FIG17'],['FIG17 is a graph showing the results of hepatotoxicity of antisense oligonucleic acid and GR gene expression-suppressing activity evaluated in the Example described later'],"['With regard to each of the obtained antisense oligonucleic acids, the ALT concentration in mouse serum and GR gene expression-suppressing activity were measured in the same manner as in the above-mentioned Example 3. The results are shown in FIG17. In FIG17, ""*"" indicates presence of a significant difference at p<0.05.', ""As shown in the results of FIG17 (1), the hepatotoxicity by Posi14 was reduced to 30% by only changing guanine, which is in one of the 2',4'-non-bridged nucleic acid residues in the middle part, to 8-bromoguanine. On the other hand, as shown in the results of FIG17 (2), GR gene expression-suppressing activity almost did not change even when guanine, which is in one of the 2',4'-non-bridged nucleic acid residues in the middle part of Posi14, was changed to 8-bromoguanine. Thus, according to the present invention, hepatotoxicity can be reduced without reducing the activity of antisense oligonucleic acid.""]",26,186,graph,A,"[{'element_identifier': '100', 'terms': ['than']}, {'element_identifier': '17', 'terms': ['sequence shown in Table']}, {'element_identifier': '10', 'terms': ['than']}]","[""1. An antisense oligonucleic acid having a base length of not less than 7nt and not more than 30nt, wherein nucleic acid residues of not less than 1nt and not more than 5nt respectively from the both terminals are 2',4'-bridged nucleic acids, 2',4'-non-bridged nucleic acid residue(s) is(are) present between the both terminals, and one or more bases in the nucleic acid residue(s) of the 2',4'-non-bridged nucleic acid residue(s) is/are modified.""]",False,"['17', '10000', '83', '1000', '100', '10']" 258,EP_3587576_A9 (6).png,EP3587576A9,ANTISENSE OLIGONUCLEIC ACID,['FIG18'],['FIG18 is a graph showing the results of hepatotoxicity of antisense oligonucleic acid and PCSK9 gene expression-suppressing activity evaluated in the Example described later'],"['With regard to each of the obtained antisense oligonucleic acids, the ALT concentration in mouse serum and PCSK9 gene expression-suppressing activity were measured in the same manner as in the above-mentioned Example 3. The results are shown in FIG18. In FIG18, ""*"" indicates presence of a significant difference at p<0.05.', ""As shown in the results of FIG18 (2), PCSK9 gene expression-suppressing activity somewhat decreased when guanine, which is in one of the 2',4'-non-bridged nucleic acid residues in the middle part of Posi15, was changed to 8-bromoguanine. As shown in the results of FIG18 (1), hepatotoxicity due to Posi15 was significantly reduced to 1%. Thus, according to the present invention, hepatotoxicity can be reduced without reducing the activity of antisense oligonucleic acid too much.""]",26,155,graph,A,"[{'element_identifier': '18', 'terms': ['sequence shown in Table']}, {'element_identifier': '100', 'terms': ['than']}, {'element_identifier': '10', 'terms': ['than']}]","[""1. An antisense oligonucleic acid having a base length of not less than 7nt and not more than 30nt, wherein nucleic acid residues of not less than 1nt and not more than 5nt respectively from the both terminals are 2',4'-bridged nucleic acids, 2',4'-non-bridged nucleic acid residue(s) is(are) present between the both terminals, and one or more bases in the nucleic acid residue(s) of the 2',4'-non-bridged nucleic acid residue(s) is/are modified.""]",False,"['18', '10000', '84', '1000', '100', '10']" 259,EP_3587576_A9.png,EP3587576A9,ANTISENSE OLIGONUCLEIC ACID,['FIG1'],['FIG1 is a graph showing the results of hepatotoxicity of antisense oligonucleic acid evaluated in the Example described later'],"['Five-week-old male C57BL/6NCrl mice (Nihon Charles River Co., Ltd.) were quarantined and acclimated for 1 week and used for experiments. The mice were optionally divided into 3 groups (4 mice per group), and physiological saline (manufactured by Otsuka Pharmaceutical Co., Ltd.) or each antisense oligonucleic acid solution was administered once at a dose of 10 mL/kg body weight (20 mg/kg body weight as dose of antisense oligonucleic acid) from the tail vein. On the fourth day (96 hours later), the mice were anesthetized by inhalation of 2.0 to 4.0% isoflurane (manufactured by DS Pharma Animal Health), and blood was collected from the abdominal portion of posterior vena cava as much as possible. The obtained blood was allowed to stand at room temperature for 20 to 60 min and centrifuged at 1700xg for 5 min to give serum. At the time of blood collection, when the blood volume did not reach the amount necessary for analysis, it was diluted with water for injection and used for the analysis. The concentrations of aspartate transaminase (AST) and alanine transaminase (ALT) in the obtained serum were measured using an automatic biochemical analyzer (""JCA-BM6070"" manufactured by JEOL Ltd.). The breeding and experiment of the above-mentioned animal experiment were conducted in the animal experiment facility of Safety Laboratory, SHIN NIPPON BIOMEDICAL LABORATORIES, LTD. in accordance with the animal experiment regulations of SHIN NIPPON BIOMEDICAL LABORATORIES, LTD. The results are shown in FIG1. In FIG1, ""*"" indicates presence of a significant difference at p<0.05.', ""As shown in the results of FIG1, AST and ALT are enzymes to be the indices of liver dysfunction, and the serum concentrations of these enzymes due to particularly high hepatotoxicity of #101 could be reduced significantly only by changing cytosine, which is in one of the 2',4'-non-bridged nucleic acid residues in the middle part, to 5-hydroxycytosine.""]",19,371,graph,A,"[{'element_identifier': '100', 'terms': ['than']}, {'element_identifier': '10', 'terms': ['than']}, {'element_identifier': '1', 'terms': ['Example']}]","[""1. An antisense oligonucleic acid having a base length of not less than 7nt and not more than 30nt, wherein nucleic acid residues of not less than 1nt and not more than 5nt respectively from the both terminals are 2',4'-bridged nucleic acids, 2',4'-non-bridged nucleic acid residue(s) is(are) present between the both terminals, and one or more bases in the nucleic acid residue(s) of the 2',4'-non-bridged nucleic acid residue(s) is/are modified.""]",False,"['1', '100000', '10000', '1000', '100', '10', '100000', '10000', '1000', '100', '10', '67']" 260,EP_3587634_A1 (3).png,EP3587634A1,"CAN CARRIER, FIBER PROCESSING SYSTEM, AIR-JET SPINNING FRAME, CAN TRANSPORTATION METHOD, CAN TRANSPORTATION PROGRAM, AND SELF-PROPELLED CAN",['FIG5'],['FIG5 is a block diagram of the carrier controlling device'],"['The carrier controlling device 70 will be described below in detail by using FIG5. The carrier controlling device 70 controls the transport of the can K by the first can carrier D1 to the sixth can carrier D6. In the following explanation, a configuration by which the carrier controlling device 70 controls the first can carrier D1 and the second can carrier D2 will be mainly described. The carrier controlling device 70 includes, as functional sections, a transport instructing section 71 and a mode selecting section 72. Upon receiving the transport request signal from the request controlling section 62 of the unit controller 56A, the transport instructing section 71 transmits to the first can carrier D1 or the second can carrier D2 a transport instruction signal that instructs the transport of the can K. More specifically, upon receiving the transport request signal from the request controlling section 62 of the unit controller 56A, the carrier controlling device 70 transmits to the first can carrier D1 or the second can carrier D2 the transport instruction signal that contains the processing unit specification information that specifies the spinning unit 51A in the first air-jet spinning frame 50A.']",10,207,block diagram,B,"[{'element_identifier': '72', 'terms': ['mode selecting section']}, {'element_identifier': '5', 'terms': ['be fully consumed after']}, {'element_identifier': '62', 'terms': ['request controlling section']}, {'element_identifier': '61', 'terms': ['remaining amount managing section']}, {'element_identifier': '26', 'terms': ['travelling section']}, {'element_identifier': '70', 'terms': ['carrier controlling device']}, {'element_identifier': '71', 'terms': ['transport instructing section']}]","['5. A fiber processing system (1) comprising: a pre-processing machine (30) that performs a pre-processing on a fiber bundle; a post-processing machine (50) that performs a post-processing on the fiber bundle on which the pre-processing has been performed; a can carrier (D) that transports, by travelling in a factory in which the pre-processing machine (30) and the post-processing machine (50) are installed, a can (K) containing the fiber bundle subjected to the pre-processing from a receiving destination position in the pre-processing machine (30) to a transport destination position in the post-processing machine (50); and a carrier controlling device (70) that controls the transport of the can (K) by the can carrier (D), wherein the post-processing machine (50) transmits, to the carrier controlling device (70), a transport request signal requesting transport of the can (K) containing the fiber bundle subjected to the pre-processing, the carrier controlling device (70) transmits, upon receiving the transport request signal, a transport instruction signal instructing the transport of the can (K) to the can carrier (D), and the can carrier (D) includes a travelling section (26) that transports the can (K) by travelling in the factory; a map storage section (24) that stores therein a factory map indicating an installation position of equipment in the factory including installation positions of the pre-processing machine (30) and the post-processing machine (50); a travelling route determining section (23) that determines, upon receiving the transport instruction signal transmitted from the carrier controlling device (70), based on the factory map, a travelling route for travelling from the receiving destination position in the pre-processing machine (30) to the transport destination position in the post-processing machine (50); and a travelling control section (25) that causes the travelling section (26) to travel autonomously, when the travelling route has been determined by the travelling route determining section (23), based on the determined travelling route from the receiving destination position in the pre-processing machine (30) to the transport destination position in the post-processing machine (50) thereby transporting the can (K), wherein the pre-processing machine (30) is preferably provided in plurality, the post-processing machine (50) is preferably provided in plurality, the carrier controlling device (70), upon receiving the transport request signal from the post-processing machine (50), preferably includes post-processing machine specification information that specifies the post-processing machine (50) that requested the transport of the can (K) and pre-processing machine specification information that specifies the pre-processing machine (30) to be a receiving destination of the can (K) among the plurality of pre-processing machines (30) in the transport instruction signal, and preferably transmits the transport instruction signal to the can carrier (D), the can carrier (D) preferably includes a receiving destination specifying section (21) that determines, upon receiving the transport instruction signal, the pre-processing machine (30) specified based on the pre-processing machine specification information as the pre-processing machine (30) to be the receiving destination of the can (K); and a transport destination specifying section (22) that determines, upon receiving the transport instruction signal, the post-processing machine (50) specified based on the post-processing machine specification information as the post-processing machine (50) to be a transport destination of the can (K), and the travelling route determining section (23) preferably determines the travelling route that goes from the receiving destination position in the pre-processing machine (30) determined as the receiving destination by the receiving destination specifying section (21) to the transport destination position in the post-processing machine (50) determined as the transport destination by the transport destination specifying section (22), or wherein the post-processing machine (50) preferably includes a first post-processing machine (50B) and a second post-processing machine (50A), the carrier controlling device (70) preferably includes a mode selecting section (72) that selects one of a first mode and a second mode based on a status of the transport request of the can (K) from the first post-processing machine (50B); and a transport instructing section (71) that transmits to the can carrier (D) a transport instruction signal for the first mode when the first mode is selected by the mode selecting section (72) and transmits to the can carrier (D) a transport instruction signal for the second mode when the second mode is selected by the mode selecting section (72), and the transport instruction signal for the first mode is preferably the transport instruction signal that causes the can carrier (D) to transport the can (K) to the transport destination position in the first post-processing machine (50B), and the transport instruction signal for the second mode is preferably the transport instruction signal that causes the can carrier (D) to transport the can (K) to the transport destination position in the second post-processing machine (50A).', '6. The fiber processing system (1) as claimed in Claim 5, wherein the post-processing machine (50) includes a plurality of processing units (51) that perform the post-processing on each of the fiber bundles in the plurality of cans (K) containing the fiber bundle subjected to the pre-processing; a remaining amount managing section (61) that manages a remaining amount of the fiber bundle in each can (K) that is subjected to the post-processing by each processing unit (51); and a request controlling section (62) that, when it is detected by the remaining amount managing section (61) that the remaining amount of the fiber bundle in a specific can (K) has become equal to or less than a predetermined reference remaining amount, specifies a specific processing unit (51) that processes the fiber bundle in the specific can (K) and includes processing unit specification information that specifies the specific processing unit (51) in the transport request signal and transmits the transport request signal to the carrier controlling device (70), wherein the carrier controlling device (70) includes, upon receiving the transport request signal, the processing unit specification information in the transport instruction signal and transmits the transport instruction signal to the can carrier (D), the can carrier (D) further includes a transport destination specifying section (22) that, upon receiving the transport instruction signal including the processing unit specification information, determines the specific processing unit (51) specified based on the processing unit specification information as the transport destination position in the post-processing machine (50), and the travelling route determining section (23) determines the travelling route going to the specific processing unit (51) specified as the transport destination position by the transport destination specifying section (22).']",True,"['4', '61', '62', '5', '70', '71', '72', '26']" 261,EP_3587647_A1.png,EP3587647A1,METHOD FOR DETECTING DEFECTS IN A NONWOVEN SUBSTRATE,['FIG1'],['FIG1 is a schematic drawing showing an embodiment of the present invention comprising two rollers'],"['FIG1 shows a system wherein the web 30 is transported between two opposing surfaces, preferably the two opposing surfaces are opposing surfaces of adjacent rotating rolls 11, 12. In this embodiment pressure is applied to the nonwoven substrate by transporting the nonwoven substrate through a nip 13 between the rotating rolls 11, 12. Alternatively the nonwoven substrate may be transported over slide bars, i.e. bars which do not rotate or which rotate at a slower speed relative to the speed of the web.']",15,90,schematic,A,"[{'element_identifier': '14', 'terms': ['roller']}, {'element_identifier': '5', 'terms': ['US']}, {'element_identifier': '30', 'terms': ['web']}, {'element_identifier': '20', 'terms': ['tactile sensor']}, {'element_identifier': '40', 'terms': ['mean ""about']}, {'element_identifier': '13', 'terms': ['nip']}]","['2. The method according to Claim 1 wherein the detection zone (40) is situated at a nip (13) between a pair of rotating rolls (11, 12) and wherein the nonwoven web (30) is advanced through the nip (13) formed between the pair of rolls (11, 12).', '6. The method according to any of the previous Claims wherein the sensor (20) is a tactile sensor which is configured to measure pressure up to about 3500 kPa,']",True,"['30', '20', '13', '40', '30', '1', '30', '14', '20', '30', '2', '40', '5']" 262,EP_3587710_A1 (2).png,EP3587710A1,LOCK CYLINDER AND LOCKSET,['FIG4'],['FIG4 is a structural diagram when the lock set is damaged by force'],"['According to another aspect of the invention, there is provided a lockset, including front lock shell 40, rear lock shell 50, as well as the new lock cylinder in the above embodiment. The said front lock shell and rear lock shell are adaptively installed on the new lock cylinder. In the initial state, the lock shells are positioned on the front and back ends of the connection member, and normally, when the key is inserted into the lock shell, the key profile correctly aligns the pins and then the lock will be unlocked. But when it is unlocked by force outside the door, as shown in FIG4, the lock shell on the outside of the door is unconstrained and will detach, so that there is no obstacle in the front of the connection shaft, and the top bolt at the back of the connection shaft forwardly pushes out the connection shaft due to the action of internal compression spring. The limit through-hole of the connection shaft moves away from the position of the stop collar, and there is space both in upper and lower space, and at this time, the elastic part disposed in the limit through-hole pushes out the balls, so that the connection shaft cannot be connected to the transmission block. Because the lock-out cavity is occupied by the balls, the connection shaft cannot to be pushed into the inside, so that the lock cylinder mechanism provided by the lock set can perform the anti-force and anti-theft role.']",13,286,structural diagram,E,"[{'element_identifier': '24', 'terms': ['limit through-hole']}, {'element_identifier': '28', 'terms': ['flange part']}, {'element_identifier': '272', 'terms': ['pin roller']}, {'element_identifier': '30', 'terms': ['transmission block']}, {'element_identifier': '11', 'terms': ['fixing sleeve']}, {'element_identifier': '29', 'terms': ['lock-out cavity', 'flange part']}, {'element_identifier': '271', 'terms': ['circular grooves']}, {'element_identifier': '20', 'terms': ['lock cylinder mechanism']}, {'element_identifier': '25', 'terms': ['elastic part']}, {'element_identifier': '31', 'terms': ['cavity']}, {'element_identifier': '33', 'terms': ['top bolt']}, {'element_identifier': '27', 'terms': ['stop collar']}, {'element_identifier': '10', 'terms': ['connection member']}, {'element_identifier': '21', 'terms': ['unlocking cam']}, {'element_identifier': '23', 'terms': ['connection shaft']}, {'element_identifier': '32', 'terms': ['compression spring']}]","['1. A lock cylinder, characterised in that it includes: a connection member having a fixing sleeve extending from it; a lock cylinder mechanism, the said lock cylinder mechanism including an unlocking cam set behind the fixing sleeve, the unlocking cam being slidably connected with the fixing sleeve, an axle sleeve disposed in the said unlocking cam, and a connection shaft in the said unlocking cam the front end of the said connection shaft extends through the fixing sleeve, and the rear end of the connection shaft features limit through-holes, the limit through-holes including an elastic part within, there being balls on both end of the elastic part, and a stop collar in the limit through-hole corresponding to the said connection shaft.', '2. A lock cylinder according to claim 1, characterized in that there is provided a flange part in the middle of the said connection shaft, the said connection shaft forming a lock-out cavity with the flange part and axle sleeve, the said connection shaft being set in the middle of unlocking cam, the stop collar, axle sleeve and flange part limiting the movement of the unlocking cam.', '3. A lock cylinder according to claim 1, characterized in that there is a transmission block in the end of the connection shaft, and there is a cavity formed in the said transmission block, there being a compression spring in the said cavity, and top bolts on the said compression spring, the said top bolts abutting with the connection shaft.']",True,"['20', '11', '25', '21', '30', '31', '32', '33', '29', '23', '28', '24', '10', '4', '27', '271', '272', '5']" 263,EP_3587740_A1 (1).png,EP3587740A1,GAS TURBINE ENGINE COMPONENT,['FIG2'],['FIG2 is an enlarged schematic view of a portion of a turbine section'],"['FIG2 illustrates an enlarged schematic view of the high pressure turbine 54, however, other sections of the gas turbine engine 20 could benefit from this disclosure, such as the compressor section 24 or low pressure turbine 46. In the illustrated example, the high pressure turbine 54 includes a one-stage turbine section including a first rotor assembly 60. In another example, the high pressure turbine 54 could include a two-stage high pressure turbine section with multiple rotor assemblies.', 'The forward wall 102, the aft wall 104, the outer wall 106, and the base portion 108 of the BOAS 82 define a passage 110 for accepting a wear liner 112, such as a metallic wear liner. A radially inner side of the base portion 108 at least partially defines the core flow path C and is located adjacent a tip of the airfoil 80 (See FIG2).']",13,165,enlarged schematic view,F,"[{'element_identifier': '80', 'terms': ['airfoil', 'airfoils']}, {'element_identifier': '92', 'terms': ['one airfoil', 'two airfoils']}, {'element_identifier': '96', 'terms': ['vane outer platform']}, {'element_identifier': '64', 'terms': ['first disk']}, {'element_identifier': '66', 'terms': ['respective first rim']}, {'element_identifier': '108', 'terms': ['base portion']}, {'element_identifier': '36', 'terms': ['engine static structure']}, {'element_identifier': '62', 'terms': ['first rotor blades']}]","['1. A blade outer air seal (82) comprising: a base portion (108) extending between a leading edge (98) and a trailing edge (100); and a forward wall (102) and an aft wall (104) extending radially outward from the base portion (108) to a radially outer portion (106), wherein the radially outer portion (106) is spaced from the base portion (108).']",False,"['36', '108', '96', '62', '92', '80', '09', '36', '66', '64']" 264,EP_3587859_A1 (1).png,EP3587859A1,TRANSMISSION BELT,"['FIG3', ' FIG4']","['FIG3 is a schematic view for explaining a measurement method of bending stress of power transmission belts obtained in Examples ', 'FIG4 is a schematic view for explaining a durability running test of power transmission belts obtained in Examples']","['Each rubber composition shown in Table 1 was press vulcanized at a temperature of 170°C for 20 minutes to prepare a vulcanized rubber body (60 mm × 25 mm × 6.5 mm thick). Short fibers were oriented in parallel to a longitudinal direction of the vulcanized rubber body. As shown in FIG3, the vulcanized rubber body 21 was placed on a pair of rotatable rolls (diameter 6 mm) having a distance of 20 mm and supported thereon. Metal pressing member 23 was put on a central portion of the upper surface of the vulcanized rubber body 21 in a width direction (direction orthogonal to the orientation direction of the short fibers). The tip of the pressing member 23 has a semicircular shape having a diameter of 10 mm, and the tip can smoothly press the vulcanized rubber body 21. When pressing, frictional force acts between the lower surface of the vulcanized rubber body 21 and rolls 22a, 22b with compressive deformation of the vulcanized rubber body 21. However, the influence by friction is reduced by making rolls 22a, 22b rotatable. The state that the tip of the pressing member 23 is brought into contact with the upper surface of the vulcanized rubber body 21 and does not press is an initial position, and the pressing member 23 presses downward the upper surface of the vulcanized rubber body 21 from this state in a speed of 100 mm/min. Stress when bending strain reached 8% was measured as bending stress. By measuring bending stress in the direction orthogonal to the orientation direction of the short fibers, it can be judged that resistance force to buckling deformation called dishing during belt running is high when bending stress is increased, and the bending stress can be used as indexes of high load transmission and high durability. Assuming the belt temperature during running, the measurement temperature was 120°C. ', 'Durability running test was conducted using a biaxial running tester containing a driving (Dr.) pulley 32 having a diameter of 110 mm and a driven (Dn.) pulley 33 having a diameter of 240 mm as shown in FIG4. Raw edge cogged V-belt 31 was bridged over each pulley, load of number of revolutions: 6000 rpm of the driving pulley and 25 kW was applied to the belt and the belt was run at an ambient temperature of 80°C for 70 hours. The side surface (surface contacting pulley) of the belt after running was visually measured. Presence or absence of peeling between the compression rubber layer and the cord and the presence or absence of cracks in valley parts of the lower cogs were examined. Those were evaluated by the following criteria.']",38,496,schematic view,C,"[{'element_identifier': '2', 'terms': ['preferably']}, {'element_identifier': '33', 'terms': ['pulley']}, {'element_identifier': '31', 'terms': ['Raw edge cogged V-belt']}, {'element_identifier': '21', 'terms': ['vulcanized rubber body']}, {'element_identifier': '3', 'terms': ['Example']}, {'element_identifier': '32', 'terms': ['pulley']}]","['14. The power transmission belt according to any one of claims 1 to 13, which is a raw edge cogged V-belt used for CVT driving.']",True,"['3', '2', '2', '2', '2', '2', '2', '2', '31', '33', '32', '21']" 265,EP_3587933_A2 (3).png,EP3587933A2,REFRIGERANT TRANSFER CONTROL IN MULTI MODE AIR CONDITIONER WITH HOT WATER GENERATOR,['FIG4'],['FIG4 is a schematic diagram of a system for heating water and conditioning an interior space in hot water heating mode accordance with an embodiment'],"['FIG4 depicts a configuration for the multi-purpose system 10 for heating water and conditioning an interior space in a water heating only mode. In this embodiment, the system 10 operates as a conventional vapor compression cycle to provide water heating via the water heating module 12, particularly when cooling or heating for the building interior space is not provided. In an embodiment, refrigerant is compressed in the compressor 20, exiting the compressor 20 as high pressure, high temperature refrigerant vapor and passes through the heat exchanger 60 of the water heating module 12. Notably, heat is dissipated in the water heater module 12 at this point because based on a call for heated water as described herein, the controller 50 has commanded flow control valve 62, to open. In addition, in this mode, flow control valve 40 denoted SVd is opened in this mode as needed to pass refrigerant as will be discussed later herein. The cooled refrigerant leaving the heat exchanger 60 of the water heating module 12 is directed to the third port 33 of the four-way valve 30, which is in its inactive position. The refrigerant exits the four-way valve 30 at the second port 32 and then passes through the thermal expansion valve 26. Flow control valves 27 and 28 are commanded by controller 50 to an inactive state in this operating mode for the system 10 in order to direct the flow of refrigerant through the thermal expansion valve 26. The thermal expansion valve 26 meters the flow of refrigerant, which is then expanded and directed to the heat exchanger 18 of the outdoor unit 14 to evaporate the refrigerant. Controller 50 provides commands to the fan 25 to operate and provide ambient heat (typically from atmosphere (or the ground for heat pump applications)) to evaporate the refrigerant. The refrigerant evaporated refrigerant is then transmitted to via flow control valve 36, which is now commanded to the open state by the controller 50, to the suction side of the compressor 20 to repeat the refrigerant thermal cycle. It is noteworthy that flow control valve 82 and flow control valve 38 are closed in this mode, so that branch in the circuit passes no refrigerant.']",25,406,schematic diagram,F,"[{'element_identifier': '19', 'terms': ['temperature sensor']}, {'element_identifier': '40', 'terms': ['flow control valve']}, {'element_identifier': '76', 'terms': ['heat exchanger']}, {'element_identifier': '16', 'terms': ['indoor unit assembly']}, {'element_identifier': '21', 'terms': ['suction pressure sensor', 'temperature sensors']}, {'element_identifier': '82', 'terms': ['flow control valve']}, {'element_identifier': '70', 'terms': ['water return connector']}]","['1. A method (100) for controlling an operating discharge pressure in a multi-purpose HVAC system (10) including an outdoor unit assembly (14), and an indoor unit assembly (16), the HVAC system including a plurality of flow control valves configured to isolate the indoor unit assembly from the multi-purpose HVAC system, a compressor (20), and a controller (50) operably coupled to a water heater module (12), the water heater module including at least one valve (62), the controller executing a method comprising: operating (110) the multi-purpose HVAC system in a water heating mode; operating (120) the controller to monitor at least an operating discharge pressure from the compressor; and operating (130) the controller to produce a signal commanding at least one of the plurality of flow control valves to isolate the indoor unit assembly from the outdoor unit assembly and water heater module and direct high pressure refrigerant to the indoor unit assembly when the operating discharge pressure is greater than or equal to a predetermined pressure value.', '5. The method (100) of any preceding claim, wherein the at least one of the plurality of flow control valves comprises: a first valve (62) coupled to an inlet of a heat exchanger (60) configured to transfer heat to water; a second valve having a first side coupled to a heat exchanger (18) of the outdoor unit assembly (14), and a second side coupled to the indoor unit assembly (16) in fluid communication with an outlet of a heat exchanger (76) of the indoor unit assembly; a third valve having a first side coupled to an inlet to the heat exchanger of the indoor unit assembly and a second side coupled to a fourth port of a four way valve; a fourth valve having an inlet coupled to a discharge port on the compressor (20) and an outlet coupled to the inlet to the heat exchanger of the indoor unit assembly; and wherein the operating the controller to produce a signal comprises opening the first and fourth valves and closing the second and third and fourth valves.', '8. The method (100) of any preceding claim, further including controlling a superheat value of the HVAC system with an electronic expansion valve (78), the electronic expansion valve in fluid communication with a heat exchanger (76) of the indoor unit assembly (16); and/or the method further including maintaining a desired refrigerant level in the HVAC system with a flow restriction in fluid communication with a suction port of the compressor (20) and a fifth flow control valve, in fluid communication with an inlet to the heat exchanger of the indoor unit assembly (16).']",False,"['70', '19', '21', '40', '16', '82', '76', '4']" 266,EP_3587944_A1 (1).png,EP3587944A1,AIR CONDITIONING DEVICE,['FIG4'],"['FIG4 is a view for showing a cooling unit, the humidification unit and a discharged-water storage unit of the air conditioner']","['Next, the discharged-water storage unit 40 is described. The discharged-water storage unit 40 is disposed for storing water discharged from the cooling unit 14 and the water discharged from the humidification unit 20. In the example shown in FIG4, the discharged-water storage unit 40 is structured as the drain pan 41 disposed below the cooling unit 14. The exhaust pipe (first exhaust pipe) 46 for discharging water stored in the discharged-water storage unit 40 is connected to the discharged-water storage unit 40 (drain pan 41). In the illustrated example, the air conditioner 10 has a pump P for discharging water stored in the discharged-water storage unit 40. The exhaust pipe 46 is connected to the pump P at an end opposed to the end connected to the discharged-water storage unit 40. In the illustrated example, the exhaust pipe (second exhaust pipe) 34 for discharging water in the storage tank 22 of the humidification unit 20 is connected to the exhaust pipe 46 at a connection 48 positioned at an intermediate portion of the exhaust pipe 46. Thus, the exhaust pipe 46 has the first part 461 that extends from the discharged-water storage unit 40 to the connection 48, and a second part 462 that extends from the connection 48 to the pump P. As described above, water droplets adhering to the cooling unit 14 fall down into the discharged-water storage unit 40 disposed below the cooling unit 14 so as to be stored in the discharged-water storage unit 40. In addition, water discharged from the storage tank 22 of the humidification unit 20 flows into the discharged-water storage unit 40 so as to be stored therein through the exhaust pipe 34 and the exhaust pipe 46 (first part 461) or through the overflow pipe 38, the exhaust pipe 34 and the exhaust pipe 46 (first part 461).', 'In the example shown in FIG4, liquid level detectors 44, 45 that detect water levels in the discharged-water storage unit 40 are disposed in the discharged-water storage unit 40. Particularly in the illustrated example, in the discharged-water storage unit 40, there are a lower water level detector 44 disposed relatively below, and a higher water level detector 45 disposed relatively above. Float switches may be used as the water level detectors 44, 45, for example.']",24,449,view,F,"[{'element_identifier': '24', 'terms': ['heater']}, {'element_identifier': '35', 'terms': ['exhaust valve']}, {'element_identifier': '5', 'terms': ['downstairs exhaust pipe']}, {'element_identifier': '12', 'terms': ['air flow path']}, {'element_identifier': '14', 'terms': ['unit']}, {'element_identifier': '38', 'terms': ['overflow pipe']}, {'element_identifier': '22', 'terms': ['storage tank']}, {'element_identifier': '48', 'terms': ['connection']}, {'element_identifier': '45', 'terms': ['higher water level detector']}, {'element_identifier': '20', 'terms': ['unit']}, {'element_identifier': '34', 'terms': ['exhaust pipe']}, {'element_identifier': '26', 'terms': ['water level detector']}, {'element_identifier': '33', 'terms': ['supply valve']}, {'element_identifier': '44', 'terms': ['level detectors', 'level detector']}, {'element_identifier': '32', 'terms': ['supply pipe']}]","['1. An air conditioner comprising: an air flow path; a cooling unit disposed in the air flow path, the cooling unit being configured to cool air introduced into the air flow path so as to condense vapor contained in the air; a humidification unit that humidifies the air, the humidification unit including a storage tank for storing water and a heater for heating water in the storage tank; a discharged-water storage unit capable of storing water discharged from the cooling unit and water discharged from the humidification unit; and an exhaust pipe connected to the storage tank, the exhaust pipe being configured to discharge water in the storage tank to the discharged-water storage unit; and an exhaust valve disposed midway on the exhaust pipe; wherein the air conditioner further comprises an overflow pipe that connects the storage tank and a part of the exhaust pipe on the downstream side of the exhaust valve.', '4. The air conditioner according to any of claims 1 to 3, further comprising a water level detector that detects a water level in the discharged-water storage unit.']",True,"['20', '26', '38', '35', '24', '22', '34', '33', '32', '12', '20', '38', '33', '35', '34', '32', '5', '14', '45', '44', '48', '34', '11']" 267,EP_3587944_A1 (3).png,EP3587944A1,AIR CONDITIONING DEVICE,['FIG7'],"['FIG7 is a view showing a cooling unit, a humidification unit and a discharged-water storage unit of an air conditioner according to a modification example of the present invention ']","['A modification example of the air conditioner 10 is described with reference to FIG7. FIG7 is a view showing a cooling unit 14, a humidification unit 20 and a discharged-water storage unit 40 of an air conditioner 10 according to this modification example.']",32,48,view,F,"[{'element_identifier': '35', 'terms': ['exhaust valve']}, {'element_identifier': '5', 'terms': ['downstairs exhaust pipe']}, {'element_identifier': '12', 'terms': ['air flow path']}, {'element_identifier': '14', 'terms': ['unit']}, {'element_identifier': '38', 'terms': ['overflow pipe']}, {'element_identifier': '45', 'terms': ['higher water level detector']}, {'element_identifier': '20', 'terms': ['unit']}, {'element_identifier': '34', 'terms': ['exhaust pipe']}, {'element_identifier': '42', 'terms': ['bottom wall']}, {'element_identifier': '52', 'terms': ['exhaust pipe']}, {'element_identifier': '43', 'terms': ['sidewall']}, {'element_identifier': '41', 'terms': ['pan']}, {'element_identifier': '33', 'terms': ['supply valve']}, {'element_identifier': '44', 'terms': ['level detectors', 'level detector']}, {'element_identifier': '49', 'terms': ['connection']}, {'element_identifier': '32', 'terms': ['supply pipe']}, {'element_identifier': '13', 'terms': ['side wall']}]","['1. An air conditioner comprising: an air flow path; a cooling unit disposed in the air flow path, the cooling unit being configured to cool air introduced into the air flow path so as to condense vapor contained in the air; a humidification unit that humidifies the air, the humidification unit including a storage tank for storing water and a heater for heating water in the storage tank; a discharged-water storage unit capable of storing water discharged from the cooling unit and water discharged from the humidification unit; and an exhaust pipe connected to the storage tank, the exhaust pipe being configured to discharge water in the storage tank to the discharged-water storage unit; and an exhaust valve disposed midway on the exhaust pipe; wherein the air conditioner further comprises an overflow pipe that connects the storage tank and a part of the exhaust pipe on the downstream side of the exhaust valve.', '2. The air conditioner according to claim 1, wherein the discharged-water storage unit is a drain pan disposed below the cooling unit.', '3. The air conditioner according to claim 1 or 2, wherein a bottom wall of the discharged-water storage unit is inclined with respect to a horizontal plane.', '4. The air conditioner according to any of claims 1 to 3, further comprising a water level detector that detects a water level in the discharged-water storage unit.']",True,"['14', '13', '13', '12', '45', '43', '44', '43', '42', '12', '20', '38', '33', '35', '32', '34', '5', '14', '41', '45', '49', '52', '34', '13']" 268,EP_3587945_A1 (3).png,EP3587945A1,AIR CONDITIONING DEVICE,['FIG6'],['FIG6 is a schematic diagram for explaining an example of a relationship between an air flow from the air conditioning device according to an Embodiment 1 of the present invention and a person'],"['The air blowing control unit 185 is control means for controlling the air blowing mechanism in accordance with the detection result of the human body detection unit 183 and the determination result of the work state determination unit 184. In particular, the air blowing control unit 185 controls the air blowing mechanism to blow air toward the upper part of the person at a first wind speed (arrow A in FIG6) when a person is working. At the same time, the air is blown toward the lower part of the person at a second wind speed (arrow B in FIG6). The second wind speed is different from the first wind speed.', 'That is, as indicated by the arrow A in FIG6, a relatively slow wind which is diffused in a wide range is sent to the upper part of the person. Further, as indicated by the arrow B in FIG6, a relatively fast which is wind narrowly throttled is sent to the lower part of the person. In the relatively slow wind which is diffused in a wide range, the wind blown out from the inlet port 111 easily mixes with the surrounding air and tends to approach the temperature of the surrounding air before reaching the person. Meanwhile, in the relatively fast wind which is narrowly throttled, the wind blown out from the inlet port 111 hardly mixes with the surrounding air and tends to reach the person while maintaining the temperature at the time of blowing out from the inlet port 111.', 'In the case of one air conditioning device as shown in FIG6 or the like, it is necessary to control the distribution of blown air with a plurality of wind direction plates, whereas by using a plurality of air conditioning devices 100, it is possible to form a cold-head and warm-feet temperature distribution by sending winds with different speeds toward the upper part and lower part of the person with a simpler configuration. Further, even in an environment where there is a plurality of persons, for example, such as an office, the wind speed can be made different between the upper part and the lower part for each of a plurality of persons, and it is possible to form a cold-head and warm-feet temperature distribution for each person. Which outlet ports of which air conditioning devices 100, among the plurality of outlet ports of the plurality of air conditioning devices 100, to use for blowing air to the upper part side or lower part side of the person may be appropriately set depending on the position of the person in the room and the like.']",33,483,schematic diagram,F,"[{'element_identifier': '100', 'terms': ['air conditioning device', 'air conditioning devices']}]","['1. An air conditioning device comprising: a housing in which an inlet port and an outlet port are formed; a heat exchanger provided in the housing, the heat exchanger generating conditioned air by exchanging heat with air taken in from the inlet port; an air blowing mechanism provided in the housing, the air blowing mechanism generating an air flow by taking in air from the inlet port and blowing the conditioned air from the outlet port, the air blowing mechanism being capable of changing the direction of conditioned air blown from the outlet port; person detection means configured to detect a person in a preset detection area; work state detection means configured to detect a work state of the person; and control means configured to control the air blowing mechanism in accordance with a detection result of the person detection means and a detection result of the work state detection means, wherein the air conditioning device is configured to, while the person is working, blow air at a first wind speed toward an upper part of the person and blow at a second wind speed different from the first wind speed toward a lower part of the person.']",False,"['100', '16']" 269,EP_3587982_A1 (2).png,EP3587982A1,HEAT EXCHANGER WITH INTEGRAL FEATURES,['FIG3'],['FIG3 is a partial cross-sectional view of an embodiment of a core section of a heat exchanger'],"['A cross-sectional view of a portion of the core section 28 of the heat exchanger 10 is illustrated in FIG3. The core section 28 includes a plurality of first passages 30 to convey the first fluid flow 12 therethrough, and a plurality of second passages 32 to convey the second fluid flow 14 therethrough. The first fluid passages 30 are circular in cross-section. This allows the first fluid passages 30 to convey the high pressure first fluid flow 12, and to allow for the use of lower strength polymeric materials in place of the traditional metal materials in forming the first fluid passages 30, the second fluid passages 32 and the core section 28. For some materials the first fluid passages may be any polygonal shape that maximizes primary heat transfer area between the first and the second fluid. The second fluid passages 32 are located between adjacent first fluid passages 30 and are separated from the first fluid passages 30 by web sections 34, which at least partially form walls of the first fluid passages 30. While in some embodiments, the second fluid passages 32 may have circular cross sections, the second fluid passages 32 may have other cross-sectional shapes due to the lower pressure of the second fluid flow 14.']",19,231,partial cross-sectional view,B,"[{'element_identifier': '28', 'terms': ['core section']}, {'element_identifier': '30', 'terms': ['passages']}, {'element_identifier': '32', 'terms': ['passages']}, {'element_identifier': '34', 'terms': ['web sections']}]","['1. A counterflow heat exchanger configured to exchange thermal energy between a first fluid flow (12) at a first pressure and a second fluid flow (14) at a second pressure less than the first pressure, comprising: a first fluid inlet (18); a first fluid outlet (20) fluidly coupled to the first fluid inlet via a core section; a second fluid inlet (24); a second fluid outlet (26) fluidly coupled to the second fluid inlet via the core section; the core section including: a plurality of first fluid passages (30) configured to convey the first fluid flow from the first fluid inlet toward the first fluid outlet; and a plurality of second fluid passages (32) configured to convey the second fluid flow from the second fluid inlet toward the second fluid outlet such that the first fluid flow exchanges thermal energy with the second fluid flow at the core section; wherein each first fluid passage of the plurality of first fluid passages has a circular cross-section.']",False,"['28', '30', '32', '32', '34', '3']" 270,EP_3587989_A1 (3).png,EP3587989A1,ADDITIVELY MANUFACTURED HEAT TRANSFER DEVICE,['FIG7'],"['FIG7 is a cross sectional view of the cold plate of FIG3, along line 7-7FIG8 is a cutaway isometric view of another illustrative cold plate as described herein']","['FIG7 is a cross-sectional view of cold plate 100 along line 7-7, through a cross passage 144 and facing toward input wall 124. It should be noted that the rest of the plurality of cross passages 144 match the one depicted. Further, the plurality of cross passages 150 are vertically mirrored relative to the depicted cross passage 144, but otherwise matching the depicted cross passage.']",31,75,cross-sectional view,F,"[{'element_identifier': '142', 'terms': ['side-passage', 'side-passages']}, {'element_identifier': '242', 'terms': ['left side-passage']}, {'element_identifier': '208', 'terms': ['outer walls']}, {'element_identifier': '228', 'terms': ['channel']}, {'element_identifier': '20', 'terms': ['than']}, {'element_identifier': '252', 'terms': ['side-passage']}, {'element_identifier': '112', 'terms': ['top conductive wall']}, {'element_identifier': '152', 'terms': ['left side-passage']}, {'element_identifier': '144', 'terms': ['cross passages', 'cross passage']}, {'element_identifier': '120', 'terms': ['right wall']}, {'element_identifier': '214', 'terms': ['bottom conductive wall']}, {'element_identifier': '12', 'terms': ['housing']}, {'element_identifier': '156', 'terms': ['bottom corners']}, {'element_identifier': '200', 'terms': ['cold plate', 'cold plates']}, {'element_identifier': '236', 'terms': ['intake port']}, {'element_identifier': '22', 'terms': ['conductive wall', 'conductive walls']}, {'element_identifier': '250', 'terms': ['cross passages', 'cross passage']}, {'element_identifier': '146', 'terms': ['right side-passage']}, {'element_identifier': '210', 'terms': ['housing']}, {'element_identifier': '230', 'terms': ['channel']}, {'element_identifier': '218', 'terms': ['external transfer surfaces', 'external transfer surface']}, {'element_identifier': '100', 'terms': ['cold plate', 'cold plates']}, {'element_identifier': '148', 'terms': ['side-passage']}, {'element_identifier': '240', 'terms': ['outtake port']}, {'element_identifier': '244', 'terms': ['cross passage', 'cross passages']}, {'element_identifier': '212', 'terms': ['top conductive wall']}]","['1. An additively manufactured heat transfer device (10,100, 200, 312), comprising: an enclosure portion (12, 110, 210, 318) including outer walls (18, 108, 208, 324), the outer walls containing a first inner channel (14, 128, 228, 334) configured to direct flow of a coolant fluid, a first fluid intake port (32, 136, 234, 321) connected to the first inner channel, the first fluid intake port configured to direct flow of a coolant fluid through an outer wall (20A, 124, 224, 324) of the enclosure portion into the first inner channel, and a first fluid outtake port (34, 138, 238, 323) connected to the first inner channel, the first fluid outtake port configured to direct flow of a coolant fluid through an outer wall (20B, 126, 218, 324) of the enclosure portion out of the first inner channel, wherein the first inner channel is defined by internal walls (40, 132, 232, 338), the enclosure portion and the internal walls forming a single additively manufactured unit.', '5. The heat transfer device (10, 312) of any of claims 2-4, wherein the enclosure portion (12, 318) has first and second opposing heat transfer sides (26, 326, 328), the first inner channel (14, 334) being closer to the first heat transfer side than the second heat transfer side, the second inner channel (16, 336) being closer to the second heat transfer side than the first heat transfer side.', '10. A method (600) of manufacturing a heat transfer device (10,100, 200, 312), comprising: printing (602, 604) a first housing (12, 110, 210, 318) having an external heat transfer face (26, 118, 218, 330), and an internal wall structure (40, 132, 232, 338, 342, 350) defining a first inner channel (14, 128, 228, 334) configured to channel fluid for cooling the heat transfer face.']",True,"['100', '112', '144', '146', '142', '12', '152', '120', '148', '156', '200', '236', '240', '210', '208', '212', '22', '242', '218', '20', '230', '228', '214', '250', '244', '252', '218', '22']" 271,EP_3587989_A1 (4).png,EP3587989A1,ADDITIVELY MANUFACTURED HEAT TRANSFER DEVICE,['FIG9'],"['FIG9 is a cutaway isometric view of the cold plate of FIG8, cut along line 9-9']","['As shown in FIG9, first channel 228 includes a right side-passage 246 connected to intake port 234. A plurality of cross-passages 244 branch off at regular intervals from side-passage 246 and extend across cold plate 200 to a left side-passage 242. Left side-passage 242 extends across cold plate 200 to outtake port 238, proximate output wall 226, as shown in FIG8.', 'FIG9 is a cutaway view of cold plate 200 along line 9-9, cut through a cross passage 244 and facing toward input wall 224. It should be noted that the rest of the plurality of cross passages 244 match the one depicted. Cross passages 244 of first channel 228 alternate with cross passages 250 of second channel 230. Each cross passage has a matching diamond cross-sectional shape, which may also be referred to as a rhombus or lozenge. Further, the plurality of cross passages 250 are vertically mirrored relative to the depicted cross passage 244, but otherwise matching the depicted cross passage.', 'As shown in FIG9, left side-passage 242 and right side-passage 246 each have a diamond cross-sectional shape with four perpendicular sides of equal length. The diamond cross-sectional shapes of side-passages 242, 246 and cross passages 244, 250 may allow cold plate 200 to be additively manufactured without secondary supports in the inner channels. Each interior surface of first channel 228 and second channel 230 may form an angle of 45 degrees or less with a vertical line parallel to the manufacturing axis of the cold plate.']",19,296,cutaway isometric view,F,"[{'element_identifier': '242', 'terms': ['left side-passage']}, {'element_identifier': '323', 'terms': ['outtake port']}, {'element_identifier': '252', 'terms': ['side-passage']}, {'element_identifier': '214', 'terms': ['bottom conductive wall']}, {'element_identifier': '314', 'terms': ['back cold plate']}, {'element_identifier': '234', 'terms': ['intake port']}, {'element_identifier': '10', 'terms': ['cold plate']}, {'element_identifier': '312', 'terms': ['plate', 'plates']}, {'element_identifier': '200', 'terms': ['cold plate', 'cold plates']}, {'element_identifier': '236', 'terms': ['intake port']}, {'element_identifier': '310', 'terms': ['heat source']}, {'element_identifier': '300', 'terms': ['system']}, {'element_identifier': '0', 'terms': ['than', 'tolerance may be 1mil', 'may be 10mil']}, {'element_identifier': '218', 'terms': ['external transfer surfaces', 'external transfer surface']}, {'element_identifier': '321', 'terms': ['intake port']}, {'element_identifier': '222', 'terms': ['left wall']}, {'element_identifier': '232', 'terms': ['internal walls']}, {'element_identifier': '320', 'terms': ['apertures', 'aperture']}, {'element_identifier': '244', 'terms': ['cross passage', 'cross passages']}, {'element_identifier': '212', 'terms': ['top conductive wall']}]","['1. An additively manufactured heat transfer device (10,100, 200, 312), comprising: an enclosure portion (12, 110, 210, 318) including outer walls (18, 108, 208, 324), the outer walls containing a first inner channel (14, 128, 228, 334) configured to direct flow of a coolant fluid, a first fluid intake port (32, 136, 234, 321) connected to the first inner channel, the first fluid intake port configured to direct flow of a coolant fluid through an outer wall (20A, 124, 224, 324) of the enclosure portion into the first inner channel, and a first fluid outtake port (34, 138, 238, 323) connected to the first inner channel, the first fluid outtake port configured to direct flow of a coolant fluid through an outer wall (20B, 126, 218, 324) of the enclosure portion out of the first inner channel, wherein the first inner channel is defined by internal walls (40, 132, 232, 338), the enclosure portion and the internal walls forming a single additively manufactured unit.', '5. The heat transfer device (10, 312) of any of claims 2-4, wherein the enclosure portion (12, 318) has first and second opposing heat transfer sides (26, 326, 328), the first inner channel (14, 334) being closer to the first heat transfer side than the second heat transfer side, the second inner channel (16, 336) being closer to the second heat transfer side than the first heat transfer side.']",True,"['234', '200', '212', '236', '218', '222', '242', '232', '244', '214', '252', '218', '300', '320', '0', '6', '0', '6', '6', '00', '6', '0', '312', '310', '314', '321', '323', '10', '23']" 272,EP_3587989_A1 (5).png,EP3587989A1,ADDITIVELY MANUFACTURED HEAT TRANSFER DEVICE,['FIG12'],['FIG12 is a cutaway isometric view of the cold plate quadrant of FIG11'],"['Outer walls 324 contain a first layer 334 and a second layer 336, divided by an internal wall 338. As shown in FIG12, a cutaway view of the quadrant, each layer is divided into plurality of channels 340 by ribs 342. Each layer is configured to direct multiple flows of coolant fluid parallel to external heat transfer surface 330 of back wall 328. In some examples, channels 340 may branch or interconnect, outer walls 324 may include a third layer, and/or quadrant 318 may include any appropriate number and configuration of layers and channels.', 'As shown in FIG12, each channel 340 follows a curved, bent, or cornered path from an input 344 to an output 346. In the present example, the input and output are open ends of cold plate quadrant 318, configured for connection to a bridging component. When assembled to form the front cold plate, input 344 of one quadrant is connected to an output 346 of another quadrant such that together the four quadrants operate in series with a single effective input and output. Each bridging component may include a perpendicular channel connected to the input or output such that channels 340 function similarly to the cross passages described in cold plate 100. Any effective structures or fluid connections may be used to assemble quadrant 318 into front cold plate 312. The front cold plate may be configured for any effective coolant fluid flow pattern.']",13,261,cutaway isometric view,F,"[{'element_identifier': '24', 'terms': ['conductive wall']}, {'element_identifier': '338', 'terms': ['internal wall']}, {'element_identifier': '346', 'terms': ['output']}, {'element_identifier': '328', 'terms': ['back wall']}, {'element_identifier': '332', 'terms': ['attachment features']}, {'element_identifier': '342', 'terms': ['ribs', 'rib']}, {'element_identifier': '326', 'terms': ['front wall']}, {'element_identifier': '344', 'terms': ['input']}, {'element_identifier': '324', 'terms': ['outer walls', 'outer wall']}, {'element_identifier': '318', 'terms': ['quadrant']}, {'element_identifier': '320', 'terms': ['apertures', 'aperture']}, {'element_identifier': '340', 'terms': ['channels', 'channel']}, {'element_identifier': '336', 'terms': ['second layer']}, {'element_identifier': '330', 'terms': ['external heat transfer surface']}]","['1. An additively manufactured heat transfer device (10,100, 200, 312), comprising: an enclosure portion (12, 110, 210, 318) including outer walls (18, 108, 208, 324), the outer walls containing a first inner channel (14, 128, 228, 334) configured to direct flow of a coolant fluid, a first fluid intake port (32, 136, 234, 321) connected to the first inner channel, the first fluid intake port configured to direct flow of a coolant fluid through an outer wall (20A, 124, 224, 324) of the enclosure portion into the first inner channel, and a first fluid outtake port (34, 138, 238, 323) connected to the first inner channel, the first fluid outtake port configured to direct flow of a coolant fluid through an outer wall (20B, 126, 218, 324) of the enclosure portion out of the first inner channel, wherein the first inner channel is defined by internal walls (40, 132, 232, 338), the enclosure portion and the internal walls forming a single additively manufactured unit.', '9. The heat transfer device (312) of any of claims 1-8, wherein the enclosure portion (318) has first and second opposing planar sides (326, 328) parallel to a direction of fluid flow through the first inner channel (334), and a first passage (320) from the first planar side to the second planar side configured to guide microwave transmission through the heat transfer device, wherein the first passage has an internal wall structure (350) separating the first passage from the first inner channel.']",True,"['48', '344', '318', '320', '000000', '00000', '0000', '000008', '000008', '000006', '300000', '332', '324', '326', '338', '336', '330', '328', '11', '342', '344', '318', '320', '35', '324', '332', '340', '342', '346', '24']" 273,EP_3587989_A1 (6).png,EP3587989A1,ADDITIVELY MANUFACTURED HEAT TRANSFER DEVICE,['FIG14'],['FIG14 is a schematic diagram of an illustrative additive manufacturing apparatus as described herein'],"['At step 410, digital information describing an ordered plurality of layers is received. The digital information may be received by a computer controller 512 of an additive manufacturing device 510 as depicted in FIG14. The additive manufacturing device may also be referred to as a printer, or a fabricator. Computer controller 512 may include any data processing system configured to receive digital design information and control functions of printer 510. The illustrative computer controller shown in FIG14 includes a processor 514 for controlling printer functions and memory 516 for storing received data.']",14,99,schematic diagram,F,"[{'element_identifier': '518', 'terms': ['build platform']}, {'element_identifier': '400', 'terms': ['method']}, {'element_identifier': '25', 'terms': ['inch']}, {'element_identifier': '514', 'terms': ['processor']}, {'element_identifier': '516', 'terms': ['memory']}, {'element_identifier': '528', 'terms': ['workpiece']}, {'element_identifier': '510', 'terms': ['printer']}, {'element_identifier': '512', 'terms': ['computer controller']}, {'element_identifier': '520', 'terms': ['building environment']}, {'element_identifier': '524', 'terms': ['raw material source']}]","['10. A method (600) of manufacturing a heat transfer device (10,100, 200, 312), comprising: printing (602, 604) a first housing (12, 110, 210, 318) having an external heat transfer face (26, 118, 218, 330), and an internal wall structure (40, 132, 232, 338, 342, 350) defining a first inner channel (14, 128, 228, 334) configured to channel fluid for cooling the heat transfer face.']",True,"['400', '510', '512', '514', '516', '520', '524', '528', '518', '25']" 274,EP_3587989_A1.png,EP3587989A1,ADDITIVELY MANUFACTURED HEAT TRANSFER DEVICE,['FIG2'],['FIG2 is another schematic diagram of the cold plate of FIG1'],"['As shown in FIG2, second inner channel 16 is connected to a second fluid intake port 36 and a second fluid outtake port 38. FIG2 is a schematic plan view of cold plate 10, showing the first and second inner channels as dashed to indicate their disposition behind conductive wall 22. First inner channel 14 is separated from second inner channel 16 by an internal wall structure 40 of housing 12. In the present example, inner wall structure 40 is a single wall, spanning between side wall 20A and side wall 20B to define rectangular inner channels 14, 16. Inner wall structure 40 may include multiple walls, to define any desired shape and/or path of one or more inner channels.']",11,131,schematic diagram,F,"[{'element_identifier': '24', 'terms': ['conductive wall']}, {'element_identifier': '28', 'terms': ['transfer surface']}, {'element_identifier': '14', 'terms': ['channel', 'channels']}, {'element_identifier': '30', 'terms': ['coolant fluid']}, {'element_identifier': '38', 'terms': ['second fluid outtake port', 'inches']}, {'element_identifier': '208', 'terms': ['outer walls']}, {'element_identifier': '34', 'terms': ['outtake port']}, {'element_identifier': '40', 'terms': ['wall structure']}, {'element_identifier': '16', 'terms': ['channel']}, {'element_identifier': '26', 'terms': ['transfer surface', 'transfer surfaces']}]","['1. An additively manufactured heat transfer device (10,100, 200, 312), comprising: an enclosure portion (12, 110, 210, 318) including outer walls (18, 108, 208, 324), the outer walls containing a first inner channel (14, 128, 228, 334) configured to direct flow of a coolant fluid, a first fluid intake port (32, 136, 234, 321) connected to the first inner channel, the first fluid intake port configured to direct flow of a coolant fluid through an outer wall (20A, 124, 224, 324) of the enclosure portion into the first inner channel, and a first fluid outtake port (34, 138, 238, 323) connected to the first inner channel, the first fluid outtake port configured to direct flow of a coolant fluid through an outer wall (20B, 126, 218, 324) of the enclosure portion out of the first inner channel, wherein the first inner channel is defined by internal walls (40, 132, 232, 338), the enclosure portion and the internal walls forming a single additively manufactured unit.', '2. The heat transfer device (10,100, 200) of claim 1, wherein the enclosure portion (12, 110, 210) contains a second inner channel (16, 130, 230) configured to direct flow of a coolant fluid, the second inner channel being connected to a second fluid intake port (36, 134, 236) and a second fluid outtake port (38, 140, 240), the first and second inner channels being isolated from each other.', '9. The heat transfer device (312) of any of claims 1-8, wherein the enclosure portion (318) has first and second opposing planar sides (326, 328) parallel to a direction of fluid flow through the first inner channel (334), and a first passage (320) from the first planar side to the second planar side configured to guide microwave transmission through the heat transfer device, wherein the first passage has an internal wall structure (350) separating the first passage from the first inner channel.']",True,"['26', '28', '14', '28', '30', '24', '26', '34', '208', '38', '16', '40', '19']" 275,EP_3588064_A1 (1).png,EP3588064A1,"OH RADICAL DETECTION PROBE, OH RADICAL MEASUREMENT DEVICE, AND OH RADICAL MEASUREMENT METHOD",['FIG3'],['FIG3 is a flowchart for illustrating a flow of processing of an OH radical measurement method'],"['Subsequently, an OH radical measurement method using the OH radical measurement device 100 is described. FIG3 is a flowchart for illustrating a flow of processing of the OH radical measurement method. The OH radical measurement method includes a contact step S110, an irradiation and measurement step S120, and a derivation step S130.']",16,58,flowchart,G,"[{'element_identifier': '100', 'terms': ['OH radical measurement device']}, {'element_identifier': '5', 'terms': ['Example']}, {'element_identifier': '150', 'terms': ['irradiation unit']}, {'element_identifier': '25', 'terms': ['days']}]","['5. An OH radical measurement device, comprising: an accommodation unit configured to accommodate an OH radical detection probe including an aromatic carboxylic acid, a polar aprotic organic solvent, and a polar protic organic solvent; a gas supply unit configured to supply a gas to be measured into the accommodation unit; and a concentration conversion unit configured to convert a concentration of an OH radical in the gas to be measured based on a concentration of a reaction product of the aromatic carboxylic acid and the OH radical in the OH radical detection probe after being brought into contact with the gas to be measured.', '6. The OH radical measurement device according to claim 5, wherein the concentration conversion unit comprises: an irradiation unit configured to irradiate the OH radical detection probe after being brought into contact with the gas to be measured with UV light; a measurement unit configured to measure an intensity of fluorescence generated from the OH radical detection probe; and a concentration derivation unit configured to derive a concentration of the OH radical in the gas to be measured based on the intensity of the fluorescence measured by the measurement unit.']",True,"['250', '200', '150', '100', '50', '5', '10', '15', '20', '25', '50', '100', '50', '10', '15', '20', '25', '5', '13']" 276,EP_3588064_A1.png,EP3588064A1,"OH RADICAL DETECTION PROBE, OH RADICAL MEASUREMENT DEVICE, AND OH RADICAL MEASUREMENT METHOD","['FIG1', ' FIG2']","['FIG2 is a view for illustrating a specific configuration of an accommodation unit, a heating unit, and a gas supply unit ', 'FIG1 is a view for illustrating an OH radical measurement device']","['FIG2 is a view for illustrating a specific configuration of the accommodation unit 110, the heating unit 120, and the gas supply unit 130. In FIG2, a flow of the gas to be measured is represented by the solid line arrow, and a flow of the gas after contact is represented by the broken line arrow. As illustrated in FIG2, the accommodation unit 110 is a sealed container. The OH radical detection probe 102 is accommodated in an inner space 110a of the accommodation unit 110. ', 'FIG1 is a view for illustrating an OH radical measurement device 100. In FIG1, a flow of a gas or a liquid is represented by the solid line arrow, a flow of light is represented by the broken line arrow, and a flow of a signal is represented by the #dashed-dotted line arrow.', 'As illustrated in FIG1, the OH radical measurement device 100 includes an accommodation unit 110, a heating unit 120, a gas supply unit 130, and a concentration conversion unit 140.', 'Returning to FIG1, the concentration conversion unit 140 is configured to convert the concentration of an OH radical in the gas to be measured based on the concentration of a reaction product (HTA) of the aromatic carboxylic acid (terephthalic acid) and the OH radical in the OH radical detection probe 102 after being brought into contact with the gas to be measured. In this embodiment, the concentration conversion unit 140 includes an irradiation unit 150, a measurement unit 160, and a control unit 170.']",34,287,view,G,"[{'element_identifier': '172', 'terms': ['concentration derivation unit']}, {'element_identifier': '160', 'terms': ['measurement unit']}, {'element_identifier': '12', 'terms': ['No.']}, {'element_identifier': '136', 'terms': ['exhaust pipe']}, {'element_identifier': '130', 'terms': ['gas supply unit']}, {'element_identifier': '100', 'terms': ['OH radical measurement device']}, {'element_identifier': '4', 'terms': ['Example']}, {'element_identifier': '102', 'terms': ['OH radical detection probe']}, {'element_identifier': '134', 'terms': ['outer pipe']}, {'element_identifier': '132', 'terms': ['inner pipe']}, {'element_identifier': '140', 'terms': ['concentration conversion unit']}, {'element_identifier': '110', 'terms': ['accommodation unit']}, {'element_identifier': '150', 'terms': ['irradiation unit']}, {'element_identifier': '170', 'terms': ['control unit']}, {'element_identifier': '120', 'terms': ['heating unit']}]","['5. An OH radical measurement device, comprising: an accommodation unit configured to accommodate an OH radical detection probe including an aromatic carboxylic acid, a polar aprotic organic solvent, and a polar protic organic solvent; a gas supply unit configured to supply a gas to be measured into the accommodation unit; and a concentration conversion unit configured to convert a concentration of an OH radical in the gas to be measured based on a concentration of a reaction product of the aromatic carboxylic acid and the OH radical in the OH radical detection probe after being brought into contact with the gas to be measured.', '6. The OH radical measurement device according to claim 5, wherein the concentration conversion unit comprises: an irradiation unit configured to irradiate the OH radical detection probe after being brought into contact with the gas to be measured with UV light; a measurement unit configured to measure an intensity of fluorescence generated from the OH radical detection probe; and a concentration derivation unit configured to derive a concentration of the OH radical in the gas to be measured based on the intensity of the fluorescence measured by the measurement unit.', '8. The OH radical measurement device according to any one of claims 5 to 7, further comprising a heating unit configured to heat the gas to be measured in the accommodation unit.']",True,"['100', '170', '172', '160', '140', '130', '110', '120', '102', '4', '150', '136', '130', '132', '134', '110', '120', '12']" 277,EP_3588098_A1.png,EP3588098A1,"NANOFLUIDIC DEVICES WITH INTEGRATED COMPONENTS FOR THE CONTROLLED CAPTURE, TRAPPING, AND TRANSPORT OF MACROMOLECULES AND RELATED METHODS OF ANALYSIS","['FIG1', ' FIG2B']","['FIG2B is an alternate embodiment of a nanofluidic analysis device which includes integrated transverse electrodes positioned next to the transport nanochannel according to embodiments of the present invention ', 'FIG1 is a schematic illustration of a device with wide, shallow nanofluidic channels positioned proximate a transport nanochannel according to embodiments of the present invention']","['FIG2B illustrates a differently configured device 10 having similar function but with the transverse nanochannels replaced by transverse electrodes 51, 52 that abut the transport channel 20. The electrodes 51, 52 can be integrated into the substrate of the device or attached to the substrate of the device adjacent the transport channel 20. The transverse electrodes can have a length L that is about 10 µm to about 5 mm or up to about 2 cm long and/or otherwise configured to provide suitable voltages, typically between about 1-20 V. Devices 10 that use integrated electrodes 51, 52 may exhibit limited lifetimes due to electrode fouling/degradation. This may be reduced or minimized by using electrode coatings or using appropriate anti-fouling or fouling resistant electrode material. ', 'The shallow channel segments 30s (FIG1, 2A, 3 and 5) can be low ionic resistance channels that connect wide, deeper nanofluidic channels to the transport nanochannels.', ""In some particular embodiments, the fluid transport nanochannels 20 (FIG1) can be defined as conduits having lengths substantially commensurate with, or exceeding, the analyte's contour length. If the nanochannel's width and depth are smaller than the radius of gyration of the macromolecule, then confinement of the molecule in the nanochannel necessarily results in molecular extension. The molecule's extended configuration will include a string of non-penetrating blobs (e.g., agglomerations) if the nanochannel width and depth are greater than the persistence length of the polymer (∼50 nm for double-stranded DNA). Alternately, if the nanochannel critical dimensions are smaller than the persistence length, the molecule, unable to fold back on itself, can assume a reflecting rod conformation. In either case, the extension of a macromolecule along the length of a nanochannel facilitates single molecule characterizations. Specifically, the confinement of DNA in nanochannels has proven useful for sizing, mapping, separations, and epigenetic analysis."", ""By way of simple illustration, one example of a device 10 is shown in FIG1. In this embodiment, the device 10 includes transverse nanofluidic elements 30 that interface to the transport nanochannel 20 through shallow nanochannels 30s. The transport nanochannel 20 has a segment 20s1 on one side of the cross channel and another segment 20s2 on the other side. As noted above, each side of the channel 301, 302 can have these shallow segments 30s with depths that are smaller than the analyte macromolecules' hydrodynamic sizes and the depth of the transport nanochannel. This ensures that the macromolecules will not migrate through the transverse channels 30 under appropriate operating conditions but will remain in the transport nanochannel 20. The shallow segments 30s can have a length of about 50 nm to about 10 µm or longer. The shallow segments 30s for each side 301, 302, of the respective nanochannel 30 can have the same depth and/or length or a different depth and/or length.""]",54,532,"embodiment, schematic",B,"[{'element_identifier': '30', 'terms': ['channel', 'channels']}, {'element_identifier': '301', 'terms': ['nanochannels']}, {'element_identifier': '20', 'terms': ['nanochannel', 'nanochannels']}, {'element_identifier': '1', 'terms': ['about']}]","['1. A device having at least one fluid transport nanochannel and two transverse integrated electrodes abutting opposing sides of the at least one fluid transport nanochannel at an intersection with the transport nanochannel that resides a distance between opposing first and second end portions of the at least one transport channel to define a first segment and second segment of the transport nanochannel wherein, in operation, the first and second segments have significantly different field strengths.', '6. The system of any of Claims 3-5, wherein the device comprises a plurality of parallel fluid transport nanochannels that cooperate with a respective intersection.']",True,"['301', '30', '20', '1', '302', '30', '301', '09', '2480', '20', '302', '17']" 278,EP_3588138_A1 (1).png,EP3588138A1,LASER POSITIONING APPARATUS AND LASER POSITIONING METHOD,['FIG3'],['FIG3 illustrates a flowchart 300 of a laser positioning method according to the present invention'],"['Further, a second aspect of the present invention provides a laser positioning method, and FIG3 illustrates a flowchart 300 of a laser positioning method according to the present invention. As can be seen from the figure, the laser positioning method comprises the following steps:First, in a first step 310, adjusting a first laser generated by a laser emitter to a second laser and a third laser by using a beam splitter mirror, wherein the second laser and the third laser are perpendicular to each other; and']",15,96,flowchart,G,"[{'element_identifier': '310', 'terms': ['first step']}, {'element_identifier': '4', 'terms': ['andFIG.', 'anda first receiver']}, {'element_identifier': '300', 'terms': ['flowchart']}, {'element_identifier': '320', 'terms': ['second step']}, {'element_identifier': '3', 'terms': ['rotating mechanism', 'receiving objective lens']}]","['4. The laser positioning apparatus according to claim 1, characterized in that the distance determining module comprises: a first receiving objective lens configured to receive and process the laser reflected or diffused back by the second laser on the surface of the first object to be measured; and a first receiver configured to receive the laser processed by the first receiving objective lens.']",True,"['300', '310', '320', '3', '4', '10']" 279,EP_3588141_A1 (4).png,EP3588141A1,"DISTANCE-MEASURING APPARATUS, MOBILE OBJECT, DISTANCE-MEASURING METHOD, AND DISTANCE-MEASURING SYSTEM",['FIG14'],['FIG14 is a diagram illustrating a configuration of a distance-measuring apparatus according to an embodiment of the present disclosure'],"['FIG14 is a block diagram illustrating the functions of the distance-measuring apparatus 100 according to the present embodiment.', 'In particular, FIG14 illustrates the functions of the stereo image computation unit 250 according to the present embodiment. As illustrated in FIG14, the stereo image computation unit 250 includes a distortion corrector 13 to which the reference images and comparison images obtained by the right camera 11 and the left camera 12, which together make up a stereo camera, are input, and a distance computing unit 14 that performs principle fusion. In the present embodiment, the images captured by the right camera 11 are used as reference images, and the images captured by the left camera 12 are used as comparison images.', 'The configuration as illustrated in FIG14 is given by way of example, and no limitation is indicated thereby. For example, the laser signal processor 240 and the stereo image computation unit 250 may be combined together. Alternatively, the laser signal processor 240 may have some of the functions of the stereo image computation unit 250. Alternatively, the ECU 190 may have some of or the entirety of the functions of the stereo image computation unit 250.']",21,219,diagram,G,"[{'element_identifier': '24', 'terms': ['unit']}, {'element_identifier': '28', 'terms': ['distance calculator']}, {'element_identifier': '30', 'terms': ['distance-image generation unit']}, {'element_identifier': '12', 'terms': ['left camera']}, {'element_identifier': '14', 'terms': ['distance computing unit']}, {'element_identifier': '11', 'terms': ['right camera']}, {'element_identifier': '29', 'terms': ['fusion unit']}, {'element_identifier': '250', 'terms': ['stereo image computation unit']}, {'element_identifier': '25', 'terms': ['distance interpolator']}, {'element_identifier': '31', 'terms': ['pixel-range determination unit']}, {'element_identifier': '27', 'terms': ['determination unit']}, {'element_identifier': '240', 'terms': []}, {'element_identifier': '26', 'terms': ['reflected-signal cost converter']}, {'element_identifier': '21', 'terms': ['data acquisition unit']}, {'element_identifier': '23', 'terms': ['stereo matching unit']}, {'element_identifier': '32', 'terms': ['irradiation-direction pixel-range table']}, {'element_identifier': '13', 'terms': ['distortion corrector']}]","['1. A distance-measuring apparatus (100) comprising: a plurality of imaging devices (11, 12) configured to obtain a plurality of images; a converter (23) configured to perform matching for the plurality of images obtained by the plurality of imaging devices (11, 12) to convert the plurality of images into first distance information on a pixel-by-pixel basis; an irradiation unit (232, 233) configured to emit a laser beam where at least one of a first laser-beam resolution in a horizontal direction and a second laser-beam resolution in a vertical direction exceeds two degrees; a light receiver (234, 235) configured to obtain a reflected signal obtained when the laser beam is reflected by an object; a distance calculator (28) configured to detect a peak that corresponds to reflection from the object from the reflected signal and calculate second distance information based on a length of time (T) taken to observe the peak after the laser beam is emitted by the irradiation unit (232, 233); and an integration unit (29) configured to integrate the first distance information and the second distance information with each other.', '2. The distance-measuring apparatus (100) according to claim 1, further comprising a pixel-range determination unit (31) configured to determine a pixel range corresponding to an irradiation field (101) of one laser beam, wherein the integration unit (29) combines the first distance information in the pixel range with the second distance information in the pixel range.']",False,"['14', '240', '13', '250', '14', '27', '11', '20', '12', '21', '23', '28', '24', '29', '25', '30', '26', '31', '32', '37']" 280,EP_3588141_A1.png,EP3588141A1,"DISTANCE-MEASURING APPARATUS, MOBILE OBJECT, DISTANCE-MEASURING METHOD, AND DISTANCE-MEASURING SYSTEM",['FIG1'],"['FIG1 is a diagram illustrating the spatial resolution and the distance resolution of a stereo camera, a LiDAR device, and a principle fusion in comparison to each other']","['FIG1 is a diagram illustrating the spatial resolution and the distance resolution of a stereo camera, a LiDAR device, and a principle fusion in comparison to each other.', 'As illustrated in FIG1, the spatial resolution of a stereo camera is high, and the spatial resolution of a LiDAR device is low when an object is at a remote point. However, when a principle fusion is adopted, high spatial resolution is achieved even when an object is at a remote point. The distance resolution of a stereo camera is low when an object is at a remote point, and the distance resolution of a LiDAR device is high regardless of the distance. However, when a principle fusion is adopted, high distance resolution is achieved even when an object is at a remote point. The performance that goes beyond the principle of measurement of a stereo camera and a LiDAR device can be obtained in such a principle fusion.']",30,173,diagram,G,"[{'element_identifier': '24', 'terms': ['unit']}, {'element_identifier': '1', 'terms': ['less than', 'β becomes']}]","['1. A distance-measuring apparatus (100) comprising: a plurality of imaging devices (11, 12) configured to obtain a plurality of images; a converter (23) configured to perform matching for the plurality of images obtained by the plurality of imaging devices (11, 12) to convert the plurality of images into first distance information on a pixel-by-pixel basis; an irradiation unit (232, 233) configured to emit a laser beam where at least one of a first laser-beam resolution in a horizontal direction and a second laser-beam resolution in a vertical direction exceeds two degrees; a light receiver (234, 235) configured to obtain a reflected signal obtained when the laser beam is reflected by an object; a distance calculator (28) configured to detect a peak that corresponds to reflection from the object from the reflected signal and calculate second distance information based on a length of time (T) taken to observe the peak after the laser beam is emitted by the irradiation unit (232, 233); and an integration unit (29) configured to integrate the first distance information and the second distance information with each other.']",False,"['1', '4', '24']" 281,EP_3588147_A1 (4).png,EP3588147A1,A LENS AND A LIGHTING UNIT USING THE LENS,['FIG5'],['FIG5 shows a clearer plan view of the lens design of FIG4'],"['FIG5 shows a clearer plan view, which shows the annular array 82 of light sources 83 more clearly, which are aligned with the central portions 36 of the beam shaping portions 62a, 62b. The annular Fresnel teeth are shown as the ridges 84.']",12,48,plan view,F,"[{'element_identifier': '84', 'terms': ['ridges']}, {'element_identifier': '34', 'terms': []}, {'element_identifier': '82', 'terms': ['annular array']}, {'element_identifier': '36', 'terms': ['central portion', 'central portions', 'portions', 'portion']}, {'element_identifier': '70', 'terms': ['whole lens', 'example from about', 'angle 52b maybe']}, {'element_identifier': '83', 'terms': ['light sources']}]","['1. A lens (30) for providing wide beam illumination from a light source (40), comprising: a lens body (31) comprising a light entry side (33) and a light exit side (32), wherein in cross section the lens body comprises a beam shaping portion having an optical axis (35), wherein a light source location (40) is defined in the vicinity of the light entry side (33), wherein the beam shaping portion comprises: a central portion (36), with respect to the optical axis, on the light entry side (33) facing the light source location and adapted to direct light output from the light source location (40) as a diverging beam; and Fresnel tooth portions (42a, 42b; 44a, 44b; 46a, 46b) on the light entry side (33) and on both lateral sides of the optical axis (35), wherein the Fresnel tooth portions are adapted to direct light output from the light source location (40) as a reflected beam which converges towards the optical axis (35), wherein tooth portions on opposite sides of the central portion (36) are adapted to direct light output from the light source location (40) as converging beams which converge to a set of different convergence locations (60) on the light exit side (32).', '12. A lighting unit comprising: a lens as claimed in claim 8, 9 or 10; and an annular array (82) of light sources (83) aligned with the central portions (36) of the beam shaping portions.']",False,"['70', '82', '83', '84', '36', '34', '34', '13']" 282,EP_3588180_A1 (4).png,EP3588180A1,ELECTRONIC MODULATING DEVICE,['FIG6'],['FIG6 illustrates a cross-sectional view of the electronic modulating device in accordance with some embodiments of the present disclosure'],"[""Refer to FIG6, which illustrates a cross-sectional view of the electronic modulating device 200' in accordance with some embodiments of the present disclosure. The electronic modulating device 200 becomes the electronic modulating device 200' when its volume expands. As mentioned above, the fourth recovering force F4 may be greater than the third recovering force F3. Therefore, the recovering force pushing on the region of the second substrate 112 that corresponds to the second portion 20 is greater than that corresponds to the first portion 10. As a result, the distance between the first substrate 102 and the second substrate 112 that corresponds to the first portion 10 may be the distance Z3 plus the thickness H7, and the distance between the first substrate 102 and the second substrate 112 that corresponds to the second portion 20 may be the distance Z4 plus the thickness H7. The sum of the distance Z3 and the thickness H7 is less than that of the distance Z4 and the thickness H7. In other embodiments, the adjustment unit 204b may have the thickness H8, and the adjustment unit 206b may have the thickness H9. As shown in FIG6, the thickness H9 may be greater than the thickness H8. In this embodiment, the distance between the first substrate 102 and the second substrate 112 that corresponds to the first portion 10 is substantially equal to the thickness H8, and the distance between the first substrate 102 and the second substrate 112 that corresponds to the second portion 20 is substantially equal to the thickness H9, which is greater than the thickness H8.""]",21,290,cross-sectional view,G,"[{'element_identifier': '20', 'terms': ['second portion', 'second portions']}, {'element_identifier': '112', 'terms': ['second substrate']}, {'element_identifier': '102', 'terms': ['first substrate']}, {'element_identifier': '10', 'terms': ['first portion', 'first portions']}, {'element_identifier': '108', 'terms': ['adjustment unit', 'adjustment units']}, {'element_identifier': '110', 'terms': ['modulating material layer']}]","['1. An electronic modulating device (100), comprising: a first substrate (102) comprising a first portion (10) and a second portion (20); a second substrate (112) disposed opposite to the first substrate; at least one working device disposed between the first substrate (102) and the second substrate (112), wherein the at least one working device overlaps the first portion (10) and does not overlap the second portion (10); a first adjustment unit (104) disposed between the first portion (10) of the first substrate (102) and the second substrate (112), wherein the first adjustment unit has a first elastic coefficient; and a second adjustment unit (106) disposed between the second portion (20) of the first substrate (102) and the second substrate (112); wherein the second adjustment unit (106) has a second elastic coefficient, and the first elastic coefficient is less than the second elastic coefficient.', '7. The electronic modulating device according to one of the claims 1-6, further comprising: a modulating material layer disposed between the first substrate and the second substrate, wherein the modulating material layer fills a gap between the first adjustment unit and the second adjustment unit.']",False,"['10', '20', '112', '15', '102', '110', '108', '108', '110', '108', '108', '110']" 283,EP_3588193_A1.png,EP3588193A1,COMMUNICATION BETWEEN AN IMAGE FORMING DEVICE AND A REPLACEABLE SUPPLY ITEM,"['FIG1', ' FIG2']","['FIG2 is a block diagram depiction of the image forming device including a communication bus that permits communication between a controller of the image forming device and one or more supply chips according to one example embodiment ', 'FIG1 is a schematic view of an image forming device having one or more replaceable supply items according to one example embodiment']","['FIG2 shows a communication bus 30 of image forming device 10 that facilitates communication between controller 20 and supply chips 110 according to one example embodiment. FIG2 shows one supply item 100 and associated supply chip 110 in solid line and an additional supply item lOOn and associated supply chip 110n in broken line indicating that additional supply items 100 having supply chips 110 may be used as desired. In the example embodiment illustrated, communication bus 30 utilizes the Inter-Integrated Circuit (I2C) protocol; however, other communication protocols may be used as desired. Controller 20 is configured to serve as the master node of communication bus 30 with each supply chip 110 configured to serve as a respective slave node. In the example embodiment illustrated, a system chip 22 serves as an additional slave node of communication bus 30. In this embodiment, controller 20 and system chip 22 combine to form a control unit 24 of image forming device 10 that controls communication with supply chips 110. In one embodiment, system chip 22 facilitates encrypted communication between controller 20 and supply chips 110 where controller 20 and supply chips 110 are unable to directly interpret messages from each other for security purposes. For example, prior to sending an encrypted command to a supply chip 110, controller 20 may send the command to system chip 22 which may decrypt and re-encrypt the command according to a format that will be understood by supply chip 110 and return the re-encrypted command to controller 20 to be sent by controller 20 to supply chip 110. Similarly, upon receiving an encrypted response from a supply chip 110, controller 20 may send the response to system chip 22 which may decrypt and re-encrypt the response according to a format that will be understood by controller 20 and return the re-encrypted response to controller 20. System chip 22 may also aid controller 20 in the authentication and validation of supply chips 110. ', 'Referring now to the drawings and particularly to FIG1, there is shown a schematic depiction of an image forming device 10 according to one example embodiment. Image forming device 10 may include, for example, an electrophotographic printer (commonly referred to as a laser printer), which may include scanning, copying or faxing functionality. One or more supply items 100 are removably installed in image forming device 10 allowing a user to replace or repair supply items 100 as needed in order to continue printing. For example, FIG1 shows an access door 12 on image forming device 10 that opens to allow a user to install or remove supply items 100 from image forming device 10. In the example embodiment illustrated, each supply item 100 includes a reservoir 102 formed within a housing 104 of the supply item 100 for holding a supply of toner for use in print operations by image forming device 10. However, supply item 100 may include any component requiring periodic user replacement such as, for example, a fuser of an electrophotographic printer, a waste toner container that stores unused toner removed from a photoconductive drum or intermediate transfer member of an electrophotographic printer, etc.']",59,574,"block diagram, schematic view",G,"[{'element_identifier': '24', 'terms': ['control unit']}, {'element_identifier': '30', 'terms': ['communication bus']}, {'element_identifier': '12', 'terms': ['access door']}, {'element_identifier': '22', 'terms': ['system chip']}, {'element_identifier': '100', 'terms': ['supply item', 'supply items']}, {'element_identifier': '20', 'terms': ['controller']}, {'element_identifier': '34', 'terms': ['clock line']}, {'element_identifier': '102', 'terms': ['reservoir']}, {'element_identifier': '10', 'terms': ['image forming device']}, {'element_identifier': '110', 'terms': ['supply chip', 'supply chips']}, {'element_identifier': '32', 'terms': ['data line']}]","['1. A method of electrical communication between a slave node of an I2C communication bus positioned on a replaceable supply item installed in an image forming device and a controller of the image forming device as a master node of the I2C communication bus, comprising: receiving a first write command by the slave node on the replaceable supply item from the controller of the image forming device; comparing by the slave node on the replaceable supply item a value of a transmission cycle bit contained in a header of the first write command with a value of a transmission cycle bit contained in a header of a second write command received by the slave node on the replaceable supply item from the controller of the image forming device previous to the first write command; and if the value of the transmission cycle bit contained in the header of the first write command is equal to the value of the transmission cycle bit contained in the header of the second write command, sending by the slave node on the replaceable supply item to the controller of the image forming device a response to the second write command without executing the first write command.']",True,"['110', '100', '102', '100', '100', '100', '12', '1', '24', '34', '32', '30', '20', '110', '100', '22', '2', '10']" 284,EP_3588198_A1 (1).png,EP3588198A1,IMAGE FORMING APPARATUS,['FIG2'],['FIG2 is a block diagram illustrating a control configuration of the image forming apparatus of the first embodiment'],"['A control configuration for controlling functions of the image forming apparatus 1 will be described below with reference to a block diagram in FIG2. In the image forming apparatus 1, a controller 200 of the present embodiment is mounted. The controller 200 is provided with functioning portions including a central processing unit (CPU) 201, a memory 202, an operating portion 203, an image formation control portion 205, a sheet conveyance control portion 206 and others. The CPU 201 realizes various processing to be executed by the image forming apparatus 1 by reading a control program stored in the memory 202. The memory 202 includes a random access memory (RAM) and a read-only memory (ROM) for example and stores programs and data in predetermined storage areas. The operating portion 203 includes devices such as a liquid crystal panel and buttons and accepts operations performed by a user, such as input of information to be used in printing (e.g., size, grammage, surface nature and others of a sheet), and instructions such as execution of printing and of its interruption.']",18,203,block diagram,B,"[{'element_identifier': '150', 'terms': ['fixing motor']}, {'element_identifier': '201', 'terms': ['CPU']}, {'element_identifier': '202', 'terms': ['memory']}, {'element_identifier': '203', 'terms': ['operating portion']}, {'element_identifier': '160', 'terms': ['discharge motor']}, {'element_identifier': '120', 'terms': ['pre-registration motor']}, {'element_identifier': '130', 'terms': ['registration motor']}, {'element_identifier': '206', 'terms': ['sheet conveyance control portion']}, {'element_identifier': '204', 'terms': ['computer']}, {'element_identifier': '110', 'terms': ['feed motor']}, {'element_identifier': '76', 'terms': ['duplex sensor']}, {'element_identifier': '180', 'terms': ['duplex motor']}, {'element_identifier': '205', 'terms': ['image formation control portion']}, {'element_identifier': '200', 'terms': ['controller']}, {'element_identifier': '70', 'terms': ['reverse conveyance portion']}, {'element_identifier': '207', 'terms': ['sensor control portion', 'sensor control unit']}]","['1. An image forming apparatus comprising: a first conveyance path (59); an image forming means (10) configured to form an image on a sheet passing through the first conveyance path (59); a first conveyance member (71) configured to receive the sheet from the first conveyance path (59) and convey the sheet to reverse the sheet; a second conveyance path (79) through which the sheet reversed by the first conveyance member (71) is guided to the first conveyance path (59); a first driving source (170) configured to drive the first conveyance member (71); and a controller (200) configured to control the first driving source (170) such that in a case where images are to be formed on a first surface of a preceding sheet, on a first surface of a succeeding sheet fed to the first conveyance path (59) succeeding to the preceding sheet and on a second surface of the preceding sheet, the controller (200) causes the first conveyance member (71) to stop without reversing the preceding sheet (2B in FIG. 10A) in a direction of heading to the second conveyance path (79) in a case where the image has been formed on the first surface of the preceding sheet and permission of preparing the image to be formed on the first surface of the succeeding sheet is not issued yet, and the controller (200) causes the first conveyance member (71) to restart conveyance of the preceding sheet (2B in FIG. 10C) to the second conveyance path (79) based on timing when the image forming means (10) starts preparing the image to be formed on the first surface of the succeeding sheet.']",False,"['200', '201', '204', '202', '203', '205', '206', '130', '110', '120', '150', '160', '70', '180', '207', '76', '20']" 285,EP_3588198_A1 (2).png,EP3588198A1,IMAGE FORMING APPARATUS,['FIG3'],['FIG3 is a diagram illustrating a driving configuration of a sheet conveyance system of the first embodiment'],"['Next, the sheet conveyance system and the driving structure controlled by the sheet conveyance control portion 206 of the present embodiment will be described with reference to FIG3. The sheet conveyance system provided in the image forming apparatus 1 includes a feed path 49, an image forming path 59 and the duplex conveyance path 79. Sheet conveyance spaces of these paths are defined by guide members supported by the apparatus body 100. A ""sheet conveyance direction"" in the following description refers to a major conveyance direction in a sheet conveyance path where a member that is related to the conveyance direction is disposed.']",17,111,diagram,B,"[{'element_identifier': '150', 'terms': ['fixing motor']}, {'element_identifier': '51', 'terms': ['fixing roller pair']}, {'element_identifier': '160', 'terms': ['discharge motor']}, {'element_identifier': '40', 'terms': ['feed unit']}, {'element_identifier': '42', 'terms': ['registration roller pair']}, {'element_identifier': '76', 'terms': ['duplex sensor']}, {'element_identifier': '61', 'terms': ['post-fixing roller pair', 'conveyance roller pairs']}, {'element_identifier': '180', 'terms': ['duplex motor']}, {'element_identifier': '120', 'terms': ['pre-registration motor']}, {'element_identifier': '170', 'terms': ['motor']}, {'element_identifier': '72', 'terms': ['first duplex roller pair']}, {'element_identifier': '73', 'terms': ['second duplex roller pair']}, {'element_identifier': '49', 'terms': ['feed path']}, {'element_identifier': '21', 'terms': ['intermediate transfer belt']}, {'element_identifier': '44', 'terms': ['registration sensor']}, {'element_identifier': '140', 'terms': ['motor']}, {'element_identifier': '62', 'terms': ['discharge roller pair']}, {'element_identifier': '75', 'terms': ['one-way clutch']}, {'element_identifier': '71', 'terms': ['roller pair']}, {'element_identifier': '130', 'terms': ['registration motor']}, {'element_identifier': '79', 'terms': ['path']}, {'element_identifier': '74', 'terms': ['third duplex roller pair', 'third duplex roller pairs']}]","['1. An image forming apparatus comprising: a first conveyance path (59); an image forming means (10) configured to form an image on a sheet passing through the first conveyance path (59); a first conveyance member (71) configured to receive the sheet from the first conveyance path (59) and convey the sheet to reverse the sheet; a second conveyance path (79) through which the sheet reversed by the first conveyance member (71) is guided to the first conveyance path (59); a first driving source (170) configured to drive the first conveyance member (71); and a controller (200) configured to control the first driving source (170) such that in a case where images are to be formed on a first surface of a preceding sheet, on a first surface of a succeeding sheet fed to the first conveyance path (59) succeeding to the preceding sheet and on a second surface of the preceding sheet, the controller (200) causes the first conveyance member (71) to stop without reversing the preceding sheet (2B in FIG. 10A) in a direction of heading to the second conveyance path (79) in a case where the image has been formed on the first surface of the preceding sheet and permission of preparing the image to be formed on the first surface of the succeeding sheet is not issued yet, and the controller (200) causes the first conveyance member (71) to restart conveyance of the preceding sheet (2B in FIG. 10C) to the second conveyance path (79) based on timing when the image forming means (10) starts preparing the image to be formed on the first surface of the succeeding sheet.', '4. The image forming apparatus according to claim 3, wherein the restriction portion (75) is a one-way clutch.']",False,"['71', '72', '62', '170', '75', '61', '76', '79', '73', '51', '21', '42', '44', '160', '150', '140', '130', '120', '180', '74', '4', '49', '40', '21']" 286,EP_3588198_A1.png,EP3588198A1,IMAGE FORMING APPARATUS,['FIG1'],['FIG1 is a schematic diagram illustrating a configuration of an image forming apparatus of a first embodiment'],"['The intermediate transfer belt 21 is wrapped around a secondary transfer inner roller 22, a stretch roller 23, a tension roller 24 and the primary transfer rollers 25 and is driven to rotate in counterclockwise (see arrow R1) in FIG1. The image forming operations described above are executed in parallel in the respective image forming units PY through PK, and the four color toner images are superimposed so as to overlap with each other to form a full-color toner image on the intermediate transfer belt 21. This toner image is borne on the intermediate transfer belt 21 and is conveyed to a transfer portion, i.e., a secondary transfer portion, provided as a nip portion between the secondary transfer inner roller 22 and a secondary transfer roller 43. The secondary transfer roller 43 serving as a transfer member is applied with a bias voltage having an inverse polarity from the charging polarity of the toner to secondarily transfer the toner image borne on the intermediate transfer belt 21 onto the sheet P. Residual toner left on the intermediate transfer belt 21 after the transfer is removed by a belt cleaner 26.']",17,204,schematic diagram,B,"[{'element_identifier': '40', 'terms': ['feed unit']}, {'element_identifier': '76', 'terms': ['duplex sensor']}, {'element_identifier': '43', 'terms': ['secondary transfer roller']}, {'element_identifier': '31', 'terms': ['sheet feed cassette']}, {'element_identifier': '12', 'terms': ['charging roller']}, {'element_identifier': '10', 'terms': ['image forming engine']}, {'element_identifier': '70', 'terms': ['reverse conveyance portion']}, {'element_identifier': '24', 'terms': ['tension roller']}, {'element_identifier': '72', 'terms': ['first duplex roller pair']}, {'element_identifier': '80', 'terms': ['discharge tray']}, {'element_identifier': '73', 'terms': ['second duplex roller pair']}, {'element_identifier': '44', 'terms': ['registration sensor']}, {'element_identifier': '62', 'terms': ['discharge roller pair']}, {'element_identifier': '23', 'terms': ['stretch roller']}, {'element_identifier': '71', 'terms': ['roller pair']}, {'element_identifier': '100', 'terms': ['apparatus body']}, {'element_identifier': '79', 'terms': ['path']}, {'element_identifier': '50', 'terms': ['fixing unit']}, {'element_identifier': '26', 'terms': ['belt cleaner']}, {'element_identifier': '33', 'terms': ['manual feed tray']}, {'element_identifier': '60', 'terms': []}]","['1. An image forming apparatus comprising: a first conveyance path (59); an image forming means (10) configured to form an image on a sheet passing through the first conveyance path (59); a first conveyance member (71) configured to receive the sheet from the first conveyance path (59) and convey the sheet to reverse the sheet; a second conveyance path (79) through which the sheet reversed by the first conveyance member (71) is guided to the first conveyance path (59); a first driving source (170) configured to drive the first conveyance member (71); and a controller (200) configured to control the first driving source (170) such that in a case where images are to be formed on a first surface of a preceding sheet, on a first surface of a succeeding sheet fed to the first conveyance path (59) succeeding to the preceding sheet and on a second surface of the preceding sheet, the controller (200) causes the first conveyance member (71) to stop without reversing the preceding sheet (2B in FIG. 10A) in a direction of heading to the second conveyance path (79) in a case where the image has been formed on the first surface of the preceding sheet and permission of preparing the image to be formed on the first surface of the succeeding sheet is not issued yet, and the controller (200) causes the first conveyance member (71) to restart conveyance of the preceding sheet (2B in FIG. 10C) to the second conveyance path (79) based on timing when the image forming means (10) starts preparing the image to be formed on the first surface of the succeeding sheet.']",False,"['71', '100', '60', '72', '62', '79', '76', '6', '70', '50', '73', '80', '23', '26', '24', '10', '43', '12', '31', '32', '44', '33', '40', '4', '19']" 287,EP_3588229_A2 (1).png,EP3588229A2,WORK VEHICLE AND BASE STATION,"['FIG4', ' FIG5']","['FIG5 is a diagram showing an example of a determination made by the determination unit ', 'FIG4 is a diagram showing an example of a determination made by a determination unit']","['The first determination unit 23 can also determine that work cannot continue to be performed on the work target in the case where the distance to an object included in a captured image acquired by the first captured image acquisition unit 22 is less than or equal to a preset value. The object included in the captured images may be a moving object or a still object, and firstly, the first determination unit 23 uses known image recognition processing to determine whether or not such an object is included in a captured image acquired by the first captured image acquisition unit 22. A configuration is possible in which in the case where it is determined that an object is included in a captured image, the distance between the object and the work vehicle 1 is then calculated. Accordingly, in the case where a rock 89 or the like is located ahead in the traveling direction of the work vehicle 1 as shown in FIG5, it is possible to stop the work vehicle 1 at a position that is a predetermined distance ahead of the object. ', 'It is preferable that the first determination unit 23 determines that work cannot continue to be performed on the work target in the case where the inclination of the vehicle body detected by the inclination sensor 21 is greater than or equal to a preset value. The ""preset value"" may be set based on the value at which traveling of the work vehicle 1 becomes difficult due to inclination of the vehicle body relative to the horizontal plane. Specifically, as shown in FIG4 for example, the first determination unit 23 may determine that the traveling of the work vehicle 1 becomes difficult in the case where the inclination of the vehicle body relative to the horizontal plane has reached a predetermined angle θ. This therefore prevents the risk of overturning of the work vehicle 1.']",30,339,diagram,A,"[{'element_identifier': '22', 'terms': ['captured image acquisition unit']}, {'element_identifier': '1', 'terms': ['work vehicle']}, {'element_identifier': '4', 'terms': ['motors']}, {'element_identifier': '89', 'terms': ['rock']}, {'element_identifier': '10', 'terms': ['travel control apparatus']}, {'element_identifier': '23', 'terms': ['first determination unit']}]","['1. A work vehicle configured to perform work while traveling autonomously, comprising: a drive wheel unit (2A) that is provided in a vehicle body (3) and is configured to be driven by a travel drive mechanism (10); a work unit (25) that is provided in the vehicle body (3) and is configured to perform work on a work target; a battery (5) provided in the vehicle body (3); and a motor (4) that is configured to receive electric power from the battery (5) and to drive the work unit (25), characterized by : an inclination sensor (21) configured to detect an inclination of the vehicle body (3) relative to a horizontal plane; a first captured image acquisition unit (22) configured to acquire a captured image that shows surroundings of the vehicle body (3) when the work is being performed; a first determination unit (23) configured to determine whether or not the work can be continued while traveling autonomously, based on at least one of a detection result from the inclination sensor (21) and the captured image; and a stop unit (24) configured to stop driving of the drive wheel unit in a case where the first determination unit (23) determined that the work cannot be continued.']",True,"['23', '22', '10', '1', '4', '89', '17']" 288,EP_3588229_A2 (3).png,EP3588229A2,WORK VEHICLE AND BASE STATION,['FIG9'],['FIG9 is a diagram showing a configuration of a base station'],"['FIG9 shows a plan view of a grounding surface 101 to which the wheels 2 of the work vehicle 1 are grounded at the base station 100, and also shows a schematic view of the base station 100. As shown in FIG9, the base station 100 includes a shower unit 31, an air blower unit 32, a return detection unit 33, a control unit 34, a second captured image acquisition unit 35, a diagnosis unit 36, and an announcement unit 37.', 'Here, the mowing blade 26 has a circular shape when viewed from above. In view of this, as shown in FIG9, a configuration is possible in which a plurality of shower units 31 and a plurality of air blower units 32 are alternatingly arranged coaxially with the mowing blade 26 so as to together form a single circular shape. This therefore prevents cases where some portions are not washed or are not dried. Of course, a configuration is possible in which the shower unit 31 forms a circular shape on its own, and the air blower unit 32 forms a circular shape on its own inward or outward of the shower unit 31 in the diameter direction.']",11,218,diagram,A,"[{'element_identifier': '35', 'terms': ['captured image acquisition unit']}, {'element_identifier': '100', 'terms': ['base station']}, {'element_identifier': '37', 'terms': ['announcement unit']}, {'element_identifier': '34', 'terms': ['control unit']}, {'element_identifier': '101', 'terms': ['grounding surface']}, {'element_identifier': '26', 'terms': ['mowing blade', 'mowing blades']}, {'element_identifier': '33', 'terms': ['return detection unit']}, {'element_identifier': '36', 'terms': ['diagnosis unit']}, {'element_identifier': '31', 'terms': ['shower unit', 'shower units']}, {'element_identifier': '32', 'terms': ['air blower unit', 'air blower units']}]","['1. A work vehicle configured to perform work while traveling autonomously, comprising: a drive wheel unit (2A) that is provided in a vehicle body (3) and is configured to be driven by a travel drive mechanism (10); a work unit (25) that is provided in the vehicle body (3) and is configured to perform work on a work target; a battery (5) provided in the vehicle body (3); and a motor (4) that is configured to receive electric power from the battery (5) and to drive the work unit (25), characterized by : an inclination sensor (21) configured to detect an inclination of the vehicle body (3) relative to a horizontal plane; a first captured image acquisition unit (22) configured to acquire a captured image that shows surroundings of the vehicle body (3) when the work is being performed; a first determination unit (23) configured to determine whether or not the work can be continued while traveling autonomously, based on at least one of a detection result from the inclination sensor (21) and the captured image; and a stop unit (24) configured to stop driving of the drive wheel unit in a case where the first determination unit (23) determined that the work cannot be continued.', '5. The work vehicle according to any one of claims 1 to 4, characterized by : a battery identification information acquisition unit (202) configured to acquire preset identification information from a charging device (201A) configured to charge only the battery (5) that has the preset identification information; an identification information determination unit (203) configured to determine whether or not the preset identification information acquired by the battery identification information acquisition unit (202) matches identification information of the battery (5) provided in the vehicle body (3); and a permission unit (204) configured to permit charging of the battery (5) in a case where the identification information determination unit (203) determined that the preset identification information matches the identification information of the battery (5) provided in the vehicle body (3), wherein the charging device (201A) is configured to be provided in a base station (100) to which the vehicle body (3) is to return while traveling autonomously.', '11. A base station to which a work vehicle is to return after the work vehicle performs work while traveling autonomously, the base station being characterized by : at least one shower unit (31) configured to spray water onto a work unit (25) that is provided in the work vehicle (1) and to perform work on a work target; at least one air blower unit (32) configured to blow air onto the work unit (25) after the shower unit (31) sprays water; a return detection unit (33) configured to detect a return of the work vehicle (1); and a control unit (34) configured to perform control such that the work unit (25) is immediately cleaned by operation of the shower unit (31) and the air blower unit (32) when the return detection unit (33) detects the return of the work vehicle (1).', '12. The base station according to claim 11, characterized by : a second captured image acquisition unit (35) configured to acquire a captured image that shows the work unit (25) of the work vehicle (1) after returning; a diagnosis unit (36) configured to determine a constituent component of the work unit (25) that requires replacement, based on the captured image acquired by the second captured image acquisition unit (35); and an announcement unit (37) configured to announce a determination result from the diagnosis unit (36) to a user.']",True,"['100', '101', '26', '31', '26', '32', '32', '31', '32', '33', '34', '35', '36', '31', '32', '31', '37', '19']" 289,EP_3588229_A2 (6).png,EP3588229A2,WORK VEHICLE AND BASE STATION,"['FIG12', ' FIG13']","['FIG13 is a schematic diagram showing the application of an electric shock by an electric shock application unit ', 'FIG12 is a schematic diagram illustrating an indication given by an indication unit']","['According to this configuration, as shown in FIG13, if the object (person 80) ignores the above-described warning (indication) given by the indication unit 54 and touches the vehicle body, it is possible to apply an electric shock equivalent to a static shock so as to stop the object from touching the work vehicle 1, thus preventing theft. ', 'According to this configuration, as shown in FIG12, if a person 80 (unauthorized person 80) different from the user of the work vehicle 1 has approached the work vehicle 1 (has moved within a preset range), it is possible to give a warning by operating a warning buzzer or the like so as to inform the person who is not the user that the work vehicle 1 is located nearby, or so as to warn the person 80 and prevent theft.']",31,158,schematic diagram,A,"[{'element_identifier': '80', 'terms': ['person']}, {'element_identifier': '22', 'terms': ['captured image acquisition unit']}]","['1. A work vehicle configured to perform work while traveling autonomously, comprising: a drive wheel unit (2A) that is provided in a vehicle body (3) and is configured to be driven by a travel drive mechanism (10); a work unit (25) that is provided in the vehicle body (3) and is configured to perform work on a work target; a battery (5) provided in the vehicle body (3); and a motor (4) that is configured to receive electric power from the battery (5) and to drive the work unit (25), characterized by : an inclination sensor (21) configured to detect an inclination of the vehicle body (3) relative to a horizontal plane; a first captured image acquisition unit (22) configured to acquire a captured image that shows surroundings of the vehicle body (3) when the work is being performed; a first determination unit (23) configured to determine whether or not the work can be continued while traveling autonomously, based on at least one of a detection result from the inclination sensor (21) and the captured image; and a stop unit (24) configured to stop driving of the drive wheel unit in a case where the first determination unit (23) determined that the work cannot be continued.']",True,"['80', '80', '22']" 290,EP_3588231_A1 (4).png,EP3588231A1,SYSTEM AND METHOD FOR DETERMINING A VELOCITY OF A ROTORCRAFT,['FIG6'],['FIG6 is a flow diagram illustrating a method of determining a velocity of a rotorcraft'],"['FIG6 is a flow diagram illustrating a method 600 of determining a velocity of a rotorcraft according to some embodiments. Initially, a GPS signal may be received by a GPS of the rotorcraft in block 602. The GPS signal may, for example, be a GPS carrier signal received from a GPS satellite. In block 604, the GPS signal is processed to determine groundspeed data. The GPS signal may be processed to determine a measured frequency of the GPS signal, and that measured frequency may be compared with a reference frequency. Groundspeed data indicating a groundspeed of the rotorcraft may be determined from a difference between the measured frequency and the reference frequency. The GPS signal may be processed by the GPS.']",15,133,flow diagram,B,"[{'element_identifier': '7', 'terms': ['andFigure']}, {'element_identifier': '606', 'terms': ['GPS. In block']}, {'element_identifier': '705', 'terms': ['analysis engine']}, {'element_identifier': '4', 'terms': ['value between about']}, {'element_identifier': '600', 'terms': ['method']}, {'element_identifier': '616', 'terms': ['rotorcraft. In block']}, {'element_identifier': '701', 'terms': ['computer system']}, {'element_identifier': '614', 'terms': ['acceleration data. In block']}, {'element_identifier': '604', 'terms': ['GPS satellite. In block']}, {'element_identifier': '602', 'terms': ['rotorcraft in block']}, {'element_identifier': '608', 'terms': ['block']}, {'element_identifier': '612', 'terms': []}, {'element_identifier': '703', 'terms': ['interface']}, {'element_identifier': '610', 'terms': ['block']}, {'element_identifier': '707', 'terms': ['database']}]","['1. A method of operating a rotorcraft, the method comprising: receiving a GPS carrier signal by a GPS sensor; determining a groundspeed of the rotorcraft based on a received frequency of the GPS carrier signal; receiving acceleration data from an inertial sensor; determining a velocity based on the groundspeed and the acceleration data; determining an actuator command based on the velocity; and controlling a flight control device according to the actuator command.']",True,"['600', '602', '604', '606', '608', '610', '612', '614', '4', '616', '6', '703', '705', '707', '7', '701', '16']" 291,EP_3588233_A1 (2).png,EP3588233A1,"METHOD, APPARATUS AND STORAGE MEDIUM FOR CONTROLLING DRAINAGE OF EQUIPMENT",['FIG6'],['FIG6 is a block diagram of an apparatus for controlling drainage of equipment according to an exemplary embodiment'],"['FIG6 is a block diagram of an apparatus for controlling drainage of equipment according to an exemplary embodiment, wherein, the equipment is provided with a drain pipe. As shown in FIG6, the apparatus 60 includes:']",18,40,block diagram,E,"[{'element_identifier': '501', 'terms': ['step']}, {'element_identifier': '61', 'terms': ['determination module']}, {'element_identifier': '63', 'terms': ['anda first control module']}, {'element_identifier': '60', 'terms': ['apparatus']}]","['7. An apparatus for controlling drainage of equipment, wherein the equipment is provided with a drain pipe, and the apparatus comprises: a determination module (61), configured to determine that the equipment is in a drain state; a detection module (62), configured to detect whether a floor drain connected to the drain pipe of the equipment is at risk of drainage overflow or the drainage overflow occurs; and a first control module (63), configured to reduce the amount of water discharged from the drain pipe per unit time if it is detected that the floor drain is at risk of drainage overflow or the drainage overflow occurs.']",True,"['102', '103', '501', '60', '61', '63', '12']" 292,EP_3588233_A1 (3).png,EP3588233A1,"METHOD, APPARATUS AND STORAGE MEDIUM FOR CONTROLLING DRAINAGE OF EQUIPMENT",['FIG7'],['FIG7 is a block diagram of a detection module according to an exemplary embodiment'],"['In a practical manner, the image of the drain pipe includes at least two images of the drain pipe collected at different times. FIG7 is a block diagram of a detection module according to an exemplary embodiment. As shown in FIG7, the detection module 62 may include:']",14,52,block diagram,E,"[{'element_identifier': '80', 'terms': ['apparatus']}, {'element_identifier': '623', 'terms': ['anda third detection submodule']}, {'element_identifier': '63', 'terms': ['anda first control module']}, {'element_identifier': '61', 'terms': ['determination module']}, {'element_identifier': '81', 'terms': ['second control module']}, {'element_identifier': '62', 'terms': ['detection module']}, {'element_identifier': '622', 'terms': []}]","['7. An apparatus for controlling drainage of equipment, wherein the equipment is provided with a drain pipe, and the apparatus comprises: a determination module (61), configured to determine that the equipment is in a drain state; a detection module (62), configured to detect whether a floor drain connected to the drain pipe of the equipment is at risk of drainage overflow or the drainage overflow occurs; and a first control module (63), configured to reduce the amount of water discharged from the drain pipe per unit time if it is detected that the floor drain is at risk of drainage overflow or the drainage overflow occurs.', '12. The apparatus according to any one of claims 7 to 11, wherein the apparatus further comprises: a second control module (81), configured to, after the amount of water discharged from the drain pipe per unit time is reduced, increase the amount of water discharged from the drain pipe per unit time if it is determined that the drainage overflow does not occur for the floor drain and there is no risk of drainage overflow.']",True,"['622', '623', '80', '61', '62', '63', '81', '13']" 293,EP_3588242_A1 (1).png,EP3588242A1,ELECTRONIC DEVICE,['FIG2B'],"[""FIG2B is a schematic diagram illustrating a section along BB' of the electronic device shown in FIG2A""]","['In some embodiments, as shown in FIG2B, the projection of the laser sensor 2 in the direction parallel to the display panel 1 is not allowed to fall on the display panel 1 by sliding down the display panel 1 or sliding up the back plate 6. In this case, the first signal emitted by the laser sensor 2 and the second signal received by the laser sensor 2 both not pass through the through hole 3 in the frame 12 of the display panel 1 nor pass through the top layer glass 10, thereby reducing consumption. Thus, the signal may be emitted with a smaller first power. Further, a larger current value may be obtained only by processing the received signal with a smaller first gain and a smaller first integral time.']",18,143,schematic diagram,G,"[{'element_identifier': '11', 'terms': ['display region']}, {'element_identifier': '4', 'terms': ['bottom layer glass']}, {'element_identifier': '2', 'terms': ['laser sensor']}, {'element_identifier': '10', 'terms': ['glass']}, {'element_identifier': '3', 'terms': ['through hole']}]","['1. An electronic device, comprising: a display panel (1) comprising a display region (11) and a frame (12), wherein the frame (12) comprises a through hole (3); and a laser sensor (2) arranged to be aligned with the through hole (3) in a preset state; wherein in the preset state, the laser sensor (2) emits a first signal to a light-out side of the display panel (1) and receives a second signal through the through hole (3).', '2. The electronic device according to claim 1, further comprising: a bottom layer glass (4) arranged at a side that is above the laser sensor (2) and close to the display panel (1).']",True,"['2', '10', '11', '3', '4', '11']" 294,EP_3588262_A1 (1).png,EP3588262A1,"INFORMATION PROCESSING APPARATUS, METHOD, AND CARRIER MEANS","['FIG2', ' FIG3']","['FIG2 is a block diagram illustrating a hardware configuration of an information processing apparatus according to embodiments of the present disclosure ', 'FIG3 is a block diagram illustrating a hardware configuration of an image forming apparatus according to embodiments of the present disclosure']","['FIG2 is a block diagram illustrating a hardware configuration of an information processing apparatus according to the present embodiment. The information processing apparatus 101 includes, for example, a central processing unit (CPU) 201, a random access memory (RAM) 202, a read only memory (ROM) 203, a storage device 204, a network interface (I/F) 205, an input device 206, a display device 207, an external device I/F 208, a bus 209, and the like.', 'In the information processing apparatus 101, for example, programs such as an application 410, an OS 420, and a printer driver 430 are executed by the CPU 201 illustrated in FIG2.', 'The printer driver 430 is a program for controlling printing by the image forming apparatus 102. The information processing apparatus 101 implements a UI unit 431, a drawing unit 432, and the like by, for example, the CPU 201 in FIG2 executing the printer driver 430. ', 'FIG3 is a block diagram illustrating a hardware configuration of an image forming apparatus according to embodiments of the present disclosure. The image forming apparatus 102 includes, for example, a controller 310, an operation panel 320, a communication I/F 330, a plotter 340, a scanner 350, and a facsimile control unit (FCU) 360.']",42,254,block diagram,G,"[{'element_identifier': '201', 'terms': ['CPU']}, {'element_identifier': '202', 'terms': ['RAM']}, {'element_identifier': '350', 'terms': ['scanner']}, {'element_identifier': '208', 'terms': ['external device I/F']}, {'element_identifier': '315', 'terms': ['HDD']}, {'element_identifier': '205', 'terms': ['network I/F']}, {'element_identifier': '330', 'terms': ['communication I/F']}, {'element_identifier': '313', 'terms': ['ROM']}, {'element_identifier': '203', 'terms': ['ROM']}, {'element_identifier': '209', 'terms': ['bus']}, {'element_identifier': '204', 'terms': ['storage device']}, {'element_identifier': '314', 'terms': ['NVRAM']}, {'element_identifier': '360', 'terms': ['FCU']}, {'element_identifier': '312', 'terms': ['RAM']}, {'element_identifier': '310', 'terms': ['controller']}, {'element_identifier': '340', 'terms': ['plotter']}, {'element_identifier': '207', 'terms': ['display device']}, {'element_identifier': '206', 'terms': ['input device']}, {'element_identifier': '311', 'terms': ['CPU']}, {'element_identifier': '320', 'terms': ['operation panel']}, {'element_identifier': '102', 'terms': ['image forming apparatus']}, {'element_identifier': '3', 'terms': ['Version']}]","['1. An information processing apparatus (101) comprising: a setting information acquisition unit (402) configured to acquire setting information on a language displayed on a display device (207) by the information processing apparatus (101); a correspondence acquisition unit (403) configured to acquire correspondence information stored in a conversion table (408) indicating correspondence between the language and a code page; a character code identification unit (404) configured to identify a target character code based on the setting information acquired and the correspondence information; and a character code conversion unit (405) configured to convert a character code of data to be output to an external device into the identified target character code.', '7. The information processing apparatus (101) of any one of claims 1 to 6, wherein the external device is an image forming apparatus (102) that stores font data for a plurality of character codes and outputs characters using the font data.']",True,"['2', '202', '0', '204', '201', '203', '209', '208', '205', '206', '207', '3', '312', '313', '320', '330', '102', '310', '315', '350', '311', '314', '340', '360', '14']" 295,EP_3588314_A1 (6).png,EP3588314A1,PROCESSOR INSTRUCTION SUPPORT TO DEFEAT SIDE-CHANNEL ATTACKS,['FIG12B'],['FIG12B is an expanded view of part of the processor core in FIG12A according to embodiments of the invention'],"['FIG12B is an expanded view of part of the processor core in FIG12A according to embodiments of the invention. FIG12B includes an L1 data cache 1206A part of the L1 cache 1204, as well as more detail regarding the vector unit 1210 and the vector registers 1214. Specifically, the vector unit 1210 is a 16-wide vector processing unit (VPU) (see the 16-wide ALU 1228), which executes one or more of integer, single-precision float, and double-precision float instructions. The VPU supports swizzling the register inputs with swizzle unit 1220, numeric conversion with numeric convert units 1222A-B, and replication with replication unit 1224 on the memory input. Write mask registers 1226 allow predicating resulting vector writes.']",19,140,expanded view,G,"[{'element_identifier': '1204', 'terms': ['cache']}, {'element_identifier': '1226', 'terms': ['input. Write mask registers']}, {'element_identifier': '1228', 'terms': ['ALU']}, {'element_identifier': '1210', 'terms': ['vector unit']}, {'element_identifier': '1214', 'terms': ['vector registers']}, {'element_identifier': '1224', 'terms': []}, {'element_identifier': '1220', 'terms': ['inputs with swizzle unit']}, {'element_identifier': '1208', 'terms': ['scalar unit']}, {'element_identifier': '1202', 'terms': ['interconnect network']}, {'element_identifier': '1212', 'terms': ['scalar registers']}, {'element_identifier': '1206', 'terms': ['cache']}, {'element_identifier': '1200', 'terms': ['instruction decoder']}]","['3. The apparatus of any one of claims 1-2, further comprising: a cache, an entry in the cache including a second flag that, when set, identifies an entry that, upon eviction, causes the first flag in the first register to be cleared and the second flag in the entry to be cleared.']",True,"['1200', '1226', '1208', '1210', '1228', '1224', '1220', '1214', '1212', '1214', '1206', '31', '1204', '1202']" 296,EP_3588321_A1.png,EP3588321A1,EMBEDDED NETWORK ON CHIP ACCESSIBLE TO PROGRAMMABLE LOGIC FABRIC OF PROGRAMMABLE LOGIC DEVICE IN MULTI-DIMENSIONAL DIE SYSTEMS,['FIG2'],"['FIG2 is a block diagram of a package including the programmable logic device where a fabric die is vertically stacked with a base die, in accordance with an embodiment']","['One example of the programmable logic device 12 is shown in FIG2, but any suitable programmable logic device may be used. In the example of FIG2, the programmable logic device 12 includes a fabric die 22 and a base die 24 that are connected to one another via microbumps 26. Although the fabric die 22 and base die 24 appear in a one-to-one relationship in FIG2, other relationships may be used. For example, a single base die 24 may attach to several fabric die 22, or several base die 24 may attach to a single fabric die 22, or several base die 24 may attach to several fabric die 22 (e.g., in an interleaved pattern along the x- and/or y-direction). Peripheral circuitry 28 may be attached to, embedded within, and/or disposed on top of the base die 24, and heat spreaders 30 may be used to reduce an accumulation of heat on the programmable logic device 12. The heat spreaders 30 may appear above, as pictured, and/or below the package (e.g., as a double-sided heat sink). The base die 24 may attach to a package substrate 32 via C4 bumps 34. In the example of FIG2, two pairs of fabric die 22 and base die 24 are shown communicatively connected to one another via a silicon bridge 36 (e.g., an embedded multi-die interconnect bridge (EMIB)) and microbumps 38 at a silicon bridge interface 39.']",30,275,block diagram,G,"[{'element_identifier': '24', 'terms': ['base die']}, {'element_identifier': '28', 'terms': ['peripheral circuitry']}, {'element_identifier': '14', 'terms': ['design software']}, {'element_identifier': '12', 'terms': ['programmable logic device']}, {'element_identifier': '30', 'terms': ['heat spreaders']}, {'element_identifier': '38', 'terms': ['microbumps']}, {'element_identifier': '22', 'terms': ['fabric die']}, {'element_identifier': '18', 'terms': ['bitstream']}, {'element_identifier': '39', 'terms': ['silicon bridge interface']}, {'element_identifier': '2', 'terms': ['sector', 'integrated circuit die. CLAUSE']}, {'element_identifier': '20', 'terms': ['configuration program']}, {'element_identifier': '34', 'terms': ['via C4 bumps']}, {'element_identifier': '26', 'terms': ['microbumps']}, {'element_identifier': '21', 'terms': ['CLAUSE']}, {'element_identifier': '36', 'terms': ['silicon bridge']}, {'element_identifier': '32', 'terms': ['package substrate']}]","['7. A programmable logic device comprising: a plurality of regions of programmable logic fabric disposed in a first integrated circuit die, wherein the plurality of regions comprises a first set of programmable logic elements controlled by a respective set of configuration memory cells; network on chip (NOC) circuitry disposed in a second integrated circuit die, wherein the NOC circuitry is connected to at least one of the plurality of regions of programmable logic fabric via a physical connection, wherein the NOC circuitry is configured to communicate data between the first integrated circuit die and the second integrated circuit die via the physical connection.']",False,"['14', '18', '39', '26', '39', '20', '12', '21', '22', '30', '28', '000', '34', '32', '24', '30', '28', '0000000000000000', '38', '36', '24', '2']" 297,EP_3588327_A1.png,EP3588327A1,SYSTEM AND METHOD FOR EVALUATING AND DEPLOYING UNSUPERVISED OR SEMI-SUPERVISED MACHINE LEARNING MODELS,['FIG1'],['FIG1 is a schematic diagram illustrating an exemplary networked system embodying the invention'],"['FIG1 is a block diagram illustrating an exemplary networked system 100 including an evaluation system 102, which is configured to implement a method of evaluating and deploying one or more unsupervised or semi-supervised machine learning models, in accordance with an embodiment of the invention. The evaluation system 102 may comprise a computer system having a conventional architecture. In particular, the evaluation system 102, as illustrated, comprises a processor 104. The processor 104 is operably associated with a non-volatile memory/storage device 106, e.g. via one or more data/address busses 108 as shown. The non-volatile storage 106 may be a hard disk drive, and/or may include a solid-state non-volatile memory, such as ROM, flash memory, solid-state drive (SSD), or the like. The processor 104 is also interfaced to volatile storage 110, such as RAM, which contains program instructions and transient data relating to the operation of the evaluation system 102.', ""Continuing the discussion of FIG1, the networked system 100 also includes a monitored system 118. The monitored system 118 may be, for example, a database system, a transaction processing system, an information system, a web service provider system, an industrial system, a security system, a robotics system, or any other system for which it is desirable to perform monitoring to detect unusual, novel, outlying, or anomalous behaviours. The monitored system 118 may take any one of a number of forms, included centralised and distributed architectures. While a variety of terms are used for the type of monitoring to which embodiments of the present invention are directed (e.g. outlier detection, change detection, or novelty detection), in the present specification the term 'anomaly detection' is consistently employed, with the understanding that other terminology is commonplace in the art.""]",13,348,schematic diagram,G,"[{'element_identifier': '122', 'terms': ['processor']}, {'element_identifier': '128', 'terms': ['device']}, {'element_identifier': '124', 'terms': ['data/address busses']}, {'element_identifier': '116', 'terms': ['Internet']}, {'element_identifier': '130', 'terms': ['communications interface']}, {'element_identifier': '100', 'terms': ['networked system']}, {'element_identifier': '1', 'terms': ['about', 'AP is thus']}, {'element_identifier': '126', 'terms': ['volatile storage']}, {'element_identifier': '132', 'terms': ['executable image']}, {'element_identifier': '104', 'terms': ['processor']}, {'element_identifier': '112', 'terms': ['communications interface']}, {'element_identifier': '102', 'terms': ['evaluation system']}, {'element_identifier': '108', 'terms': ['data/address busses']}, {'element_identifier': '106', 'terms': ['device']}, {'element_identifier': '110', 'terms': ['volatile storage']}, {'element_identifier': '114', 'terms': ['instructions']}, {'element_identifier': '120', 'terms': ['monitoring system']}]","['1. A method of evaluating and deploying machine learning models for anomaly detection of a monitored system (118), comprising: providing a plurality of candidate machine learning algorithms (204) configured for anomaly detection of the monitored system; providing training data (206) including a pool of negative data samples (302) representing normal activity of the monitored system and one or more smaller pools of positive data samples (304), wherein each pool of positive data samples represents one type of anomalous activity of the monitored system; for each type of anomalous activity, generating (412) a benchmarking dataset (306) which comprises a first number of samples drawn from the pool of negative samples, and a second number of samples drawn from the pool of positive samples corresponding with the type of anomalous activity, wherein the first number of samples is substantially larger than the second number of samples; for each combination of a candidate machine learning algorithm selected from the plurality of candidate machine learning algorithms with a type of anomalous activity: drawing (414) a plurality of training and cross-validation sets (314, 316) from the benchmarking dataset corresponding with the type of anomalous activity, wherein each training set comprises only negative data samples, and each cross-validation set comprises a mix of negative and positive data samples; for each one of the plurality of training and cross-validation sets, training (416) a machine-learning model based on the candidate algorithm using the training set, and validating (418) the machine-learning model using the cross-validation set with average precision as a performance metric; computing a mean average precision value for the candidate machine learning algorithm across the average precision performance metrics obtained using the plurality of training and cross-validation sets, for each candidate machine learning algorithm, computing (608) a ranking value based upon at least the mean average precision values computed for the candidate machine learning algorithm for each type of anomalous activity; selecting (610) a machine learning algorithm from the candidate machine learning algorithms based upon the computed ranking values; and deploying (612) a machine learning model based on the selected algorithm to a monitoring system (120), whereby the monitoring system executes the deployed machine learning model to detect anomalies of the monitored system.', '7. A computing system for evaluating machine learning models for anomaly detection of a monitored system (118), comprising: a processor (104); at least one memory device (110) accessible by the processor; and at least one data store (106) accessible by the processor and containing a plurality of candidate machine learning algorithms (204) configured for anomaly detection of the monitored system and training data (206) including a pool of negative data samples (302) representing normal activity of the monitored system and one or more smaller pools of positive data samples (304), wherein each pool of positive data samples represents one type of anomalous activity of the monitored system, wherein the memory device contains a body of program instructions (114) which, when executed by the processor, cause the computing system to implement a method comprising steps of: for each type of anomalous activity, generating (412) a benchmarking dataset (306) which comprises a first number of samples drawn from the pool of negative samples, and a second number of samples drawn from the pool of positive samples corresponding with the type of anomalous activity, wherein the first number of samples is substantially larger than the second number of samples; for each combination of a candidate machine learning algorithm selected from the plurality of candidate machine learning algorithms with a type of anomalous activity: drawing (414) a plurality of training and cross-validation sets (314, 316) from the benchmarking dataset corresponding with the type of anomalous activity, wherein each training set comprises only negative data samples, and each cross-validation set comprises a mix of negative and positive data samples; for each one of the plurality of training and cross-validation sets, training (416) a machine-learning model based on the candidate algorithm using the training set, and validating (418) the machine-learning model using the cross-validation set with average precision as a performance metric; computing a mean average precision value for the candidate machine learning algorithm across the average precision performance metrics obtained using the plurality of training and cross-validation sets, and for each candidate machine learning algorithm, computing (608) a ranking value based upon at least the mean average precision values computed for the candidate machine learning algorithm for each type of anomalous activity.']",False,"['108', '100', '104', '110', '114', '106', '112', '102', '116', '11', '124', '122', '126', '132', '130', '128', '120', '1', '15']" 298,EP_3588346_A1 (1).png,EP3588346A1,METHOD OF DETECTING MALICIOUS FILES RESISTING ANALYSIS IN AN ISOLATED ENVIRONMENT,['FIG2'],"['FIG2 shows a block diagram of the activity monitoring module, in accordance with exemplary aspects of the present disclosure']","['In one example, the security module 110 and the hypervisor 115 of virtual machine 120 are implemented on the computing device of the user. In some examples, the hypervisor 115 controls the operation of the virtual machine 120. In the given case, the security module 110 is a security application, such as an antivirus application. An example of the security module 110 is the security module 210 (or second security module), discussed further with respect to FIG2. In another case, the security module 110 and the hypervisor 115 are implemented on a remote server (or on different servers), or as a cloud service. The security module 110 in this case obtains the file 100 from third party sources (for example, from the security module 210 running on the computing devices of a user), and transfers the file 100 to the virtual machine 120, where the file 100 may be opened. In yet another case, the security module 110 obtains the file from other security modules carrying out the monitoring and intercepting of network traffic data.', 'FIG2 shows an example of the proposed method of recognizing a file as malicious. In the context of the present disclosure, for each file 100 being analyzed with the use of the virtual machine 120 and for which no verdict has been given with regard to its maliciousness, the security module 110 forms a unique behavior template 220 from the log 150, which includes, as mentioned above, all or at least some of the security-related events saved by the intercept module 130 in the log 150. This behavior template is then used by the security module 210 which provides protection to the computer system 200.']",20,315,block diagram,G,"[{'element_identifier': '210', 'terms': ['security module']}, {'element_identifier': '230', 'terms': ['activity monitoring module']}, {'element_identifier': '220', 'terms': ['behavior template']}, {'element_identifier': '100', 'terms': ['file']}, {'element_identifier': '200', 'terms': ['computer system']}]","['1. A method for recognizing a file as malicious, comprising: intercepting a file for analysis received at a computing device of a user; opening the file for analysis in an environment for safe execution; generating a log that stores a portion of information occurring during opening of the file for analysis in the environment for safe execution; analyzing the log to recognize a first set of security related events from the portion of information; tracking a second set of security related events when the file for analysis is opened on the computing device; comparing the second set of security related events and the first set of security related events to identify a discrepancy; and in response to identifying the discrepancy, recognizing the file under analysis as malicious.', '2. The method according to claim 1, further comprising: forming a behavior template based on the first set of security related events; calculating a coefficient of danger of the file under analysis based on events from the behavior template; increasing the coefficient of danger for each event found in the second set of security related events that is not found in the first set of security related events; and recognizing the file under analysis is malicious when the coefficient of danger exceeds a threshold value.']",False,"['200', '230', '210', '12', '100', '220', '2']" 299,EP_3588366_A1 (2).png,EP3588366A1,"LIVING BODY DETECTION METHOD, APPARATUS, SYSTEM AND NON-TRANSITORY COMPUTER-READABLE RECORDING MEDIUM","['FIG4', ' FIG5']","['FIG5 shows a schematic block diagram of a system used for living body detection according to one embodiment of the present disclosure ', 'FIG4 shows a schematic block diagram of an apparatus used for living body detection according to an embodiment of the present disclosure']","['According to another embodiment of the present disclosure, there is further provided an apparatus for living body detection. FIG5 shows a schematic block diagram of an apparatus for living body detection according to an embodiment of the present disclosure.', 'FIG5 shows a schematic block diagram of a system 500 used for living body detection according to an embodiment of the present disclosure. As shown in FIG5, the system 500 comprises an input device 510, a storage device 520, a processor 530 and an output device 540. ', 'As shown in FIG4, the apparatus 400 comprises an acquiring module 410, a risk module 420 and a determining module 430. The respective modules can perform respective functions/functions of the method for living body detection as described above. Only major functions of respective components of the apparatus 400 are described below, while detailed content having been described above are omitted.']",44,163,schematic block diagram,G,"[{'element_identifier': '430', 'terms': ['determining module']}, {'element_identifier': '420', 'terms': ['risk module']}, {'element_identifier': '540', 'terms': ['output device']}, {'element_identifier': '500', 'terms': ['system']}, {'element_identifier': '530', 'terms': ['processor']}, {'element_identifier': '510', 'terms': ['input device']}, {'element_identifier': '410', 'terms': ['acquiring module']}, {'element_identifier': '520', 'terms': ['storage device']}]","['9. An apparatus for living body detection, comprising: an acquiring module, configured to acquire device information of a terminal; a risk module, configured to determine a device risk level of the terminal by utilizing the device information of the terminal; a determining module, configured to determine a living body detection strategy based on the device risk level of the terminal.', '14. A system for living body detection, comprising a processer and a storage, wherein a computer program instruction is stored in the storage, and the computer program instruction is used to perform the living body detection method according to any one of claims 1 to 8 when being ran by the processor.']",True,"['410', '420', '430', '4', '500', '510', '530', '540', '520', '5', '16']" 300,EP_3588367_A1 (3).png,EP3588367A1,"DISPLAY SCREEN, DISPLAY APPARATUS, AND MOBILE TERMINAL","['FIG7', ' FIG8']","['FIG8 is a schematic structural diagram illustrating a display screen according to a fourth embodiment of the present disclosure ', 'FIG7 is a schematic structural diagram illustrating a display screen according to a third embodiment of the present disclosure']","['Referring to FIG8, the interval at which the first data lines 117 are spaced apart is greater than the interval at which the second data lines 118 are spaced apart. The interval at which first scan lines 115 are spaced apart is greater than interval at which the second scan lines 116 are spaced apart. The interval at which the first data lines 117 are spaced apart is greater than the interval at which the second data lines 118 are spaced apart. Compared with the first embodiment, with such structural design, a light-shielding area corresponding to the fingerprint recognition area 111 can be further reduced by increasing the interval at which the first thin-film transistors 113 are arranged, the interval at which the first data lines 117 are spaced apart, and the interval at which the first scan lines 115 are spaced apart, as such, light transmittance of the fingerprint recognition area 111 can be further increased, and more light signals can pass through the display screen 100. Accordingly, more light signals can be received by the fingerprint module, and efficiency of fingerprint collection and recognition of the fingerprint module can be improved. ', 'Referring to FIG7, the first scan lines 115 are arranged in a manner same as the second scan lines 116. The first scan line 115 is electrically coupled with the second scan line 116. The first scan line 115 is parallel to the second scan line 116. An interval at which the first data lines 117 are spaced apart is greater than an interval at which the second data lines 118 are spaced apart. The interval at which the first thin-film transistors 113 are arranged is greater than the interval at which the second thin-film transistors 114 are arranged. Compared with the first embodiment, with such structural design, a light-shielding area corresponding to the fingerprint recognition area 111 can be further reduced by increasing the interval at which the first thin-film transistors 113 are arranged and the interval at which the first data lines 117 are spaced apart, as such, light transmittance of the fingerprint recognition area 111 can be further increased, and more light signals can pass through the display screen 100. Accordingly, more light signals can be received by the fingerprint module, and efficiency of the fingerprint collection and recognition of the fingerprint module can be improved.']",38,434,schematic structural diagram,G,"[{'element_identifier': '110', 'terms': ['display layer']}, {'element_identifier': '115', 'terms': ['first scan lines', 'first scan line']}, {'element_identifier': '116', 'terms': ['second scan lines', 'second scan line']}]","['1. A display screen, comprising a display layer, the display layer having a fingerprint recognition area and a peripheral area adjacent to the fingerprint recognition area, the fingerprint recognition area being provided with a plurality of first driving components, the peripheral area being provided with a plurality of second driving components, an interval at which the plurality of first driving components are arranged being greater than an interval at which the plurality of second driving components are arranged.', '5. The display screen of claim 4, wherein the fingerprint recognition area is further provided with first scan lines electrically coupled with the first thin-film transistors, the peripheral area is further provided with second scan lines electrically coupled with the second thin-film transistors, and an interval at which the first scan lines are spaced apart is greater than an interval at which the second scan lines are spaced apart.']",True,"['110', '110', '116', '115', '8', '12']" 301,EP_3588367_A1 (5).png,EP3588367A1,"DISPLAY SCREEN, DISPLAY APPARATUS, AND MOBILE TERMINAL","['FIG11', ' FIG12']","['FIG11 is another schematic structural diagram illustrating a display screen according to a sixth embodiment of the present disclosure ', 'FIG12 is a schematic structural diagram illustrating a display screen according to an embodiment of the present disclosure']","['FIG11 is a schematic structural diagram illustrating a display screen 100 according to a seventh embodiment of the present disclosure. Referring to FIG11, the fingerprint recognition area 111 corresponds to the whole display layer 110. With such structural design, light transmittance of the fingerprint recognition area 111 can be increased. In addition, an area for fingerprint recognition becomes larger and therefore, inaccuracy and/or failure of fingerprint recognition due to poor finger placement can be avoided or reduced. Furthermore, inaccuracy and/or failure of fingerprint recognition due to existence of a foreign material in the fingerprint recognition area 111 of the display screen 100 can be avoided or reduced. Moreover, fingerprint recognition can be implemented in any area of the display layer 110, thereby improving user experience. ', 'The number of the fingerprint recognition area 111 is not limited in the present disclosure. Referring to FIG12, the fingerprint recognition area 111 may be embodied as multiple fingerprint recognition areas. The multiple fingerprint recognition areas 111 are distributed in an area corresponding to the whole display layer 110. With such structural design, inaccuracy and/or failure of fingerprint recognition due to existence of a foreign material in one or more of the fingerprint recognition areas 111 of the display screen 100 can be avoided or reduced. Moreover, fingerprint recognition can be implemented in any area of the display layer 110, which can improve user experience.']",37,252,schematic structural diagram,G,"[{'element_identifier': '100', 'terms': ['display screen']}, {'element_identifier': '111', 'terms': ['fingerprint recognition area', 'fingerprint recognition areas']}, {'element_identifier': '110', 'terms': ['display layer']}, {'element_identifier': '112', 'terms': ['peripheral area']}]","['1. A display screen, comprising a display layer, the display layer having a fingerprint recognition area and a peripheral area adjacent to the fingerprint recognition area, the fingerprint recognition area being provided with a plurality of first driving components, the peripheral area being provided with a plurality of second driving components, an interval at which the plurality of first driving components are arranged being greater than an interval at which the plurality of second driving components are arranged.']",True,"['110', '11', '100', '10', '112', '111', '14']" 302,EP_3588367_A1 (6).png,EP3588367A1,"DISPLAY SCREEN, DISPLAY APPARATUS, AND MOBILE TERMINAL","['FIG13', ' FIG14']","['FIG14 is a schematic structural diagram illustrating a display device according to an embodiment of the present disclosure ', 'FIG13 is a schematic structural diagram illustrating a display screen according to an embodiment of the present disclosure']","['FIG14 illustrates a display device 200 according to an embodiment of the present disclosure. The display device 200 includes the display screen 100 according to any of the above embodiments, an optical fingerprint module 202, and a frame 201. The display screen 100 and the optical fingerprint module 202 are fixed on the frame 201. The optical fingerprint module 202 is located on one side of the display screen 100 intended to away from a user. The optical fingerprint module 202 is located in a position corresponding to the fingerprint recognition area 111, whereby light signals transmitted or received can pass through the fingerprint recognition area 111. The optical fingerprint module 202 includes a light emitter 203 and a light inductor 204. The light emitter 203 is configured to emit light signals b and the light inductor 204 is configured to receive light signals c. When a finger is in contact with a surface of the display screen 100, lights transmitted from the light emitter 203 form incident lights b, and incident lights b sequentially pass through the through hole 121 and the fingerprint recognition area 111 of the display layer 110 to be projected onto patterns of a finger 205. Since the display layer 110 corresponding to the fingerprint recognition area 111 is provided with first thin-film transistors 113, first scan lines 115, and first data lines 117 arranged at large intervals, transmittance in the display layer of light signals b can be improved, and the intensity of incident lights b projected onto the patterns of the finger 205 can be increased. Accordingly, the intensity of reflected lights c formed from incident lights b reflected by the patterns of the finger 205 can also be increased. When reflected lights c, which is formed from reflection of the patterns of the finger 205, sequentially pass through the fingerprint recognition area 111 and the through hole 121 to be projected to the light inductor 204, transmittance of light signals c in the fingerprint recognition area 111 of the display layer 110 can also be increased, and intensity of light signals c received by the light inductor 204 can be increased, thereby increasing the accuracy of fingerprint recognition of the optical fingerprint module 202. ', 'Referring to FIG13, the display screen 100 may further include a light-shielding layer 120. The light-shielding layer 120 is disposed on one side of the display layer 110 intended to away from a user. The light-shielding layer 120 defines a through hole 121. The through hole 121 is located in a position corresponding to the fingerprint recognition area 111, whereby the optical fingerprint module can transmit and receive light signals through the fingerprint recognition area 111 and the through hole 121. In an embodiment, the shape and size of the through hole 121 is the same as that of the fingerprint recognition area 111. An orthographic projection area of the through hole 121 on the display layer 110 coincides with the fingerprint recognition area 111.']",36,539,schematic structural diagram,G,"[{'element_identifier': '201', 'terms': ['frame']}, {'element_identifier': '121', 'terms': ['through hole']}, {'element_identifier': '202', 'terms': ['optical fingerprint module']}, {'element_identifier': '203', 'terms': ['light emitter']}, {'element_identifier': '204', 'terms': ['light inductor']}, {'element_identifier': '112', 'terms': ['peripheral area']}, {'element_identifier': '205', 'terms': ['finger']}, {'element_identifier': '110', 'terms': ['display layer']}, {'element_identifier': '200', 'terms': ['display device']}, {'element_identifier': '120', 'terms': ['light-shielding layer']}]","['1. A display screen, comprising a display layer, the display layer having a fingerprint recognition area and a peripheral area adjacent to the fingerprint recognition area, the fingerprint recognition area being provided with a plurality of first driving components, the peripheral area being provided with a plurality of second driving components, an interval at which the plurality of first driving components are arranged being greater than an interval at which the plurality of second driving components are arranged.', '15. The display screen of any of claims 1 to 14, further comprising a light-shielding layer, wherein the light-shielding layer is disposed on one side of the display layer intended to away from a user and defines a through hole, wherein the through hole is located in a position corresponding to the fingerprint recognition area, and the optical fingerprint module is configured to transmit and receive light signals through the through hole.', '18. A display device, comprising the display screen according to any of claims 1 to 17, an optical fingerprint module, and a frame, wherein the display screen and the optical fingerprint module are fixed on the frame, the optical fingerprint module is located on one side of the display screen intended to away from a user, the optical fingerprint module is located in a position corresponding to the fingerprint recognition area, wherein the fingerprint recognition area is configured to allow light signals transmitted or received by the optical fingerprint module to pass through.', '19. The display device of claim 18, wherein the optical fingerprint module comprises a light emitter and a light inductor, the light emitter is configured to emit light signals and the light inductor is configured to receive light signals, wherein lights emitted by the light emitter pass through the fingerprint recognition area to be projected onto patterns of a finger when the finger is in contact with a surface of the display screen.']",True,"['112', '110', '120', '121', '13', '200', '120', '205', '112', '203', '204', '201', '202', '14', '15']" 303,EP_3588367_A1.png,EP3588367A1,"DISPLAY SCREEN, DISPLAY APPARATUS, AND MOBILE TERMINAL",['FIG2'],['FIG2 is a schematic structural diagram illustrating a display screen according to another embodiment of the present disclosure'],"['As illustrated in FIG2, in one embodiment, the size of the overlapped area may be smaller than the size of the display area A0 and greater than or equal to half of the size of the display area A0. The overlapped area may be located in any position of the display area A0, and the size of the overlapped area may be greater than or equal to half of the size of the display area A0.', 'By way of example, as illustrated in FIG2, the overlapped area may be located in a center area of the display area A0. As an example, the overlapped area may be located in an area close to the end of the display area A0. The size of the overlapped area may be greater than or equal to half of the size of the display area A0.']",18,154,schematic structural diagram,G,"[{'element_identifier': '400', 'terms': ['display screen']}, {'element_identifier': '111', 'terms': ['fingerprint recognition area', 'fingerprint recognition areas']}, {'element_identifier': '110', 'terms': ['display layer']}, {'element_identifier': '405', 'terms': ['cathode strips']}]","['1. A display screen, comprising a display layer, the display layer having a fingerprint recognition area and a peripheral area adjacent to the fingerprint recognition area, the fingerprint recognition area being provided with a plurality of first driving components, the peripheral area being provided with a plurality of second driving components, an interval at which the plurality of first driving components are arranged being greater than an interval at which the plurality of second driving components are arranged.']",True,"['110', '111', '14', '30', '140', '400', '405', '106']" 304,EP_3588442_A1 (1).png,EP3588442A1,CONSERVATIVE RASTERIZATION,['FIG2B'],['FIG2B is a schematic diagram showing the edge vectors for various primitives'],"['As described above and shown in FIG2B, each primitive 21, 22, 23 has a plurality of edges (e.g. three edges for a triangular primitive 21). Each edge is defined by an edge equation which is a vector of the form: fxy=Ax+By+C where A, B and C are constant coefficients specific to the polygon edge (and hence may be precalculated) and C has been pre-adjusted such that the scene origin is translated to the tile origin. The conservative rasterization hardware 212 determines for each edge of a primitive and for each pixel corner 120, 122 in a microtile 104, whether the pixel corner (having coordinates x,y) lies to the left or right or on the edge by calculating the value, or the sign, of f(x,y) for the edge. The calculation is a sum-of-products (SOP).']",12,167,schematic diagram,G,"[{'element_identifier': '210', 'terms': ['tiling unit']}, {'element_identifier': '214', 'terms': ['coefficient generation hardware block']}, {'element_identifier': '202', 'terms': ['geometry processing phase']}, {'element_identifier': '208', 'terms': ['tessellation unit']}, {'element_identifier': '206', 'terms': ['vertex shader']}, {'element_identifier': '204', 'terms': ['rasterization phase']}, {'element_identifier': '205', 'terms': ['parameter memory']}, {'element_identifier': '200', 'terms': ['pipeline']}]","['1. A graphics processing pipeline (200) arranged to render in a rendering space (100), wherein the rendering space (100) is sub-divided into a plurality of tiles (102), each tile is sub-divided into a plurality of microtiles (104), each microtile comprising an identical arrangement of pixels (106), the graphics processing pipeline comprising conservative rasterization hardware (212) and wherein the conservative rasterization hardware comprises: a plurality of first hardware sub-units (300) each arranged to calculate, for a different edge of a primitive, an outer coverage result for the edge and an inner coverage result for the edge for each pixel in a microtile; and a plurality of second hardware sub-units (320) each arranged to calculate, for a different pixel in a microtile, an outer coverage result for the primitive and an inner coverage result for the primitive, wherein each first hardware sub-unit (300) comprises: edge test calculation hardware (302) arranged to calculate, for each corner of the pixels in the microtile a value indicating whether the pixel corner is to the left of the edge; a plurality of OR logic blocks each configured to perform an OR operation (304), one for each pixel in the microtile, and each arranged to receive as inputs four values from the edge test calculation hardware, one for each corner of the pixel, and wherein an output of the OR logic block is the outer coverage result for the pixel and the edge; and a first plurality of AND logic blocks each configured to perform an AND operation (306), one for each pixel in the microtile, and each arranged to receive as inputs four values from the edge test calculation hardware, one for each corner of the pixel and wherein an output of the AND logic block is the inner coverage result for the pixel and the edge; and wherein each second hardware sub-unit (320) comprises: a second plurality of AND logic blocks (308), one for each pixel in the microtile, and each arranged to receive as inputs an outer coverage result for the pixel and each of the edges, one from each of the first hardware sub-units and wherein an output of the AND logic block is the outer coverage result for the pixel and the primitive; and a third plurality of AND logic blocks (308), one for each pixel in the microtile, and each arranged to receive as inputs an inner coverage result for the pixel and each of the edges, one from each of the first hardware sub-units and wherein an output of the AND logic block is the inner coverage result for the pixel and the primitive.']",True,"['200', '206', '208', '210', '202', '205', '214', '204', '22', '23', '18']" 305,EP_3588442_A1 (2).png,EP3588442A1,CONSERVATIVE RASTERIZATION,['FIG3B'],['FIG3B is a schematic diagram showing a second part of the conservative rasterization hardware from the pipeline of FIG2A in more detail'],"['Having calculated outer coverage results, On,i, for a pixel i and each edge n, the results for the different edges are combined using an AND gate 308 (block 408) as shown in FIG3B. This generates a single outer coverage result Oi for the pixel i and if it is zero it indicates that the primitive does not intersect any part of the square pixel area. Conservative rasterization does not permit false negatives for outer coverage results, although a small number of false positives for outer coverage results are permitted. The false positives that are obtained may be removed using a bounding box, as described below.', 'Having calculated inner coverage results, In,i, for a pixel i and each edge n, the results for the different edges are combined using an AND gate 310 (block 410) as shown in FIG3B. This generates a single inner coverage result Ii for the pixel i and if it is zero it indicates that the primitive does not fully cover the square pixel area. The inner coverage is performed precisely and there are no inherent false positives.']",22,203,schematic diagram,G,"[{'element_identifier': '310', 'terms': ['gate']}, {'element_identifier': '306', 'terms': ['gate', 'gates']}, {'element_identifier': '304', 'terms': ['gate']}, {'element_identifier': '302', 'terms': ['hardware elements', 'hardware element']}, {'element_identifier': '308', 'terms': ['gate']}]","['2. The graphics processing pipeline according to claim 1, wherein the edge test calculation hardware (302) comprises one or more hardware arrangements (500, 520) each arranged to perform an edge test using a sum-of-products, each hardware arrangement comprising: a microtile component hardware element (502) comprising hardware logic arranged to calculate a first output using the sum-of-products and coordinates of a microtile within a tile in the rendering space; a plurality of pixel component hardware elements (504, 524), each comprising hardware logic arranged to calculate one of a plurality of second outputs using the sum-of-products and coordinates for different pixel corners defined relative to an origin of the microtile; a plurality of adders arranged to generate a plurality of output results for the sum-of-products in parallel by combining, for each output result, a different combination of the first output and one of the plurality of second outputs.']",True,"['302', '300', '302', '302', '302', '302', '305', '306', '304', '320', '308', '310']" 306,EP_3588452_A1 (1).png,EP3588452A1,VIN BASED ACCELEROMETER THRESHOLD,['FIG2'],['FIG2 is diagrammatic view of an vehicular telemetry hardware system including an on-board portion and a resident vehicular portion'],"['Referring now to FIG2 of the drawings, there is illustrated a vehicular telemetry hardware system generally indicated at 30. The on-board portion generally includes: a DTE (data terminal equipment) telemetry microprocessor 31; a DCE (data communications equipment) wireless telemetry communications microprocessor 32; a GPS (global positioning system) module 33; an accelerometer 34; a non-volatile flash memory 35; and provision for an OBD (on board diagnostics) interface 36 for connection 43 and communicating with a vehicle network communications bus 37.']",21,100,diagrammatic view,G,"[{'element_identifier': '35', 'terms': ['memory']}, {'element_identifier': '30', 'terms': ['system']}, {'element_identifier': '39', 'terms': ['microcontrollers']}, {'element_identifier': '38', 'terms': ['ECM']}, {'element_identifier': '37', 'terms': ['vehicle network communications bus']}, {'element_identifier': '2', 'terms': ['As illustrated in Table']}, {'element_identifier': '40', 'terms': ['PCM']}, {'element_identifier': '42', 'terms': ['portion']}, {'element_identifier': '34', 'terms': ['accelerometer']}, {'element_identifier': '43', 'terms': ['connection']}, {'element_identifier': '41', 'terms': ['ECU']}, {'element_identifier': '33', 'terms': ['GPS module']}, {'element_identifier': '44', 'terms': ['remote site']}, {'element_identifier': '36', 'terms': ['interface']}, {'element_identifier': '31', 'terms': ['microprocessor']}, {'element_identifier': '32', 'terms': ['wireless telemetry communications microprocessor']}]","['1. A method of determining a VIN based accelerometer threshold for vehicular telemetry system comprising the steps of: receiving a VIN, decoding said VIN in to vehicle components, and determining said accelerometer threshold based upon said vehicle components.']",False,"['44', '30', '42', '32', '33', '34', '38', '40', '41', '39', '37', '31', '43', '14', '36', '35', '2']" 307,EP_3588453_A1 (1).png,EP3588453A1,SHEET PROCESSING APPARATUS AND SHEET PROCESSING METHOD,['FIG2'],['FIG2 is a diagram illustrating direct depositing processing by the sheet processing apparatus according to Embodiment 1'],['FIG2 is a diagram illustrating the direct depositing processing according to Embodiment 1. The direct depositing processing is depositing processing to directly store the banknotes recognized by the recognition unit 16 in any of the first storage unit 23 to the sixth storage unit 28.'],17,47,diagram,B,"[{'element_identifier': '5', 'terms': ['attachment section']}, {'element_identifier': '153', 'terms': []}, {'element_identifier': '20', 'terms': ['lower housing']}, {'element_identifier': '152', 'terms': ['second diversion path']}, {'element_identifier': '30', 'terms': ['second storage box']}, {'element_identifier': '18', 'terms': ['control section']}, {'element_identifier': '156', 'terms': ['sixth diversion path']}, {'element_identifier': '25', 'terms': ['third storage unit']}, {'element_identifier': '24', 'terms': ['second storage unit']}, {'element_identifier': '19', 'terms': ['temporary storage section']}, {'element_identifier': '22', 'terms': ['storage door']}, {'element_identifier': '151', 'terms': ['first diversion path']}, {'element_identifier': '16', 'terms': ['recognition unit']}, {'element_identifier': '27', 'terms': ['fifth storage unit']}, {'element_identifier': '21', 'terms': ['first storage box']}, {'element_identifier': '15', 'terms': ['transport unit']}, {'element_identifier': '23', 'terms': ['first storage unit']}, {'element_identifier': '13', 'terms': ['dispensing section']}, {'element_identifier': '28', 'terms': ['sixth storage unit']}, {'element_identifier': '2', 'terms': ['Embodiment']}, {'element_identifier': '155', 'terms': ['fifth diversion path']}, {'element_identifier': '26', 'terms': ['fourth storage unit']}, {'element_identifier': '33', 'terms': ['collection section']}, {'element_identifier': '150', 'terms': ['loop transport path']}]","['1. A sheet processing apparatus, comprising: a storage unit configured to store therein a sheet having a serial number; a recognition unit configured to perform a first reading processing to read the serial number from the stored sheet that is fed out from the storage unit; and a control section configured to retrieve, from a serial number list including listed serial number of the sheet stored in the storage unit, the listed serial number having a predetermined relationship relating to a degree of coincidence with the serial number read in the first reading processing.']",False,"['13', '152', '153', '19', '155', '22', '25', '151', '15', '18', '16', '150', '156', '5', '20', '21', '33', '30', '23', '24', '26', '27', '28', '2', '16']" 308,EP_3588453_A1 (3).png,EP3588453A1,SHEET PROCESSING APPARATUS AND SHEET PROCESSING METHOD,['FIG6'],['FIG6 is a diagram illustrating an example of reconciliation processing according to Embodiment 1'],"['Next, the reconciliation processing is described. FIG6 is a diagram illustrating the reconciliation processing according to the present embodiment. The reconciliation processing is processing to recount the number of banknotes stored in the first storage unit 23 to the sixth storage unit 28. The reconciliation processing may include processing to check whether the number of recounted banknotes is coincident with the number of banknotes that should be stored.']",14,73,diagram,B,"[{'element_identifier': '51', 'terms': ['dispensing table']}, {'element_identifier': '5', 'terms': ['attachment section']}, {'element_identifier': '153', 'terms': []}, {'element_identifier': '20', 'terms': ['lower housing']}, {'element_identifier': '30', 'terms': ['second storage box']}, {'element_identifier': '18', 'terms': ['control section']}, {'element_identifier': '25', 'terms': ['third storage unit']}, {'element_identifier': '24', 'terms': ['second storage unit']}, {'element_identifier': '19', 'terms': ['temporary storage section']}, {'element_identifier': '22', 'terms': ['storage door']}, {'element_identifier': '16', 'terms': ['recognition unit']}, {'element_identifier': '27', 'terms': ['fifth storage unit']}, {'element_identifier': '21', 'terms': ['first storage box']}, {'element_identifier': '15', 'terms': ['transport unit']}, {'element_identifier': '23', 'terms': ['first storage unit']}, {'element_identifier': '13', 'terms': ['dispensing section']}, {'element_identifier': '28', 'terms': ['sixth storage unit']}, {'element_identifier': '155', 'terms': ['fifth diversion path']}, {'element_identifier': '26', 'terms': ['fourth storage unit']}, {'element_identifier': '33', 'terms': ['collection section']}, {'element_identifier': '150', 'terms': ['loop transport path']}]","['1. A sheet processing apparatus, comprising: a storage unit configured to store therein a sheet having a serial number; a recognition unit configured to perform a first reading processing to read the serial number from the stored sheet that is fed out from the storage unit; and a control section configured to retrieve, from a serial number list including listed serial number of the sheet stored in the storage unit, the listed serial number having a predetermined relationship relating to a degree of coincidence with the serial number read in the first reading processing.']",False,"['13', '153', '19', '155', '22', '25', '51', '15', '18', '16', '150', '54', '54', '56', '5', '20', '21', '33', '30', '23', '24', '26', '27', '28', '6', '20']" 309,EP_3588453_A1 (4).png,EP3588453A1,SHEET PROCESSING APPARATUS AND SHEET PROCESSING METHOD,['FIG7'],['FIG7 is a diagram illustrating an example of collection processing according to Embodiment 1'],"['Next, the collection processing is described. FIG7 is a diagram illustrating an example of the collection processing according to the present embodiment. The collection processing is processing to store the banknotes stored in the first storage unit 23 to the sixth storage unit 28 in a collection storage unit. At least one of the detachable storage unit 4 and the collection section 33 can be used as the collection storage unit. In the present embodiment, a case where the detachable storage unit 4 is used as the collection storage unit is described.']",14,99,diagram,B,"[{'element_identifier': '51', 'terms': ['dispensing table']}, {'element_identifier': '5', 'terms': ['attachment section']}, {'element_identifier': '153', 'terms': []}, {'element_identifier': '20', 'terms': ['lower housing']}, {'element_identifier': '30', 'terms': ['second storage box']}, {'element_identifier': '154', 'terms': ['fourth diversion path']}, {'element_identifier': '18', 'terms': ['control section']}, {'element_identifier': '25', 'terms': ['third storage unit']}, {'element_identifier': '24', 'terms': ['second storage unit']}, {'element_identifier': '19', 'terms': ['temporary storage section']}, {'element_identifier': '22', 'terms': ['storage door']}, {'element_identifier': '16', 'terms': ['recognition unit']}, {'element_identifier': '27', 'terms': ['fifth storage unit']}, {'element_identifier': '21', 'terms': ['first storage box']}, {'element_identifier': '15', 'terms': ['transport unit']}, {'element_identifier': '23', 'terms': ['first storage unit']}, {'element_identifier': '13', 'terms': ['dispensing section']}, {'element_identifier': '28', 'terms': ['sixth storage unit']}, {'element_identifier': '155', 'terms': ['fifth diversion path']}, {'element_identifier': '26', 'terms': ['fourth storage unit']}, {'element_identifier': '33', 'terms': ['collection section']}, {'element_identifier': '150', 'terms': ['loop transport path']}]","['1. A sheet processing apparatus, comprising: a storage unit configured to store therein a sheet having a serial number; a recognition unit configured to perform a first reading processing to read the serial number from the stored sheet that is fed out from the storage unit; and a control section configured to retrieve, from a serial number list including listed serial number of the sheet stored in the storage unit, the listed serial number having a predetermined relationship relating to a degree of coincidence with the serial number read in the first reading processing.']",False,"['13', '153', '19', '155', '22', '25', '51', '15', '18', '16', '150', '154', '56', '5', '20', '21', '33', '30', '23', '24', '26', '27', '28', '7', '21']" 310,EP_3588453_A1.png,EP3588453A1,SHEET PROCESSING APPARATUS AND SHEET PROCESSING METHOD,['FIG1'],['FIG1 is a diagram illustrating an example of an entire configuration of a sheet processing apparatus according to Embodiment 1'],['FIG1 is a diagram illustrating an example of an entire configuration of a sheet processing apparatus according to Embodiment 1. A sheet processing apparatus 1 is a banknote depositing and dispensing machine to/from which banknotes are deposited and dispensed. The sheet processing apparatus 1 comprises a housing including an upper housing 10 and a lower housing 20.'],20,62,diagram,B,"[{'element_identifier': '1', 'terms': ['sheet processing apparatus']}, {'element_identifier': '153', 'terms': []}, {'element_identifier': '20', 'terms': ['lower housing']}, {'element_identifier': '152', 'terms': ['second diversion path']}, {'element_identifier': '30', 'terms': ['second storage box']}, {'element_identifier': '154', 'terms': ['fourth diversion path']}, {'element_identifier': '18', 'terms': ['control section']}, {'element_identifier': '156', 'terms': ['sixth diversion path']}, {'element_identifier': '25', 'terms': ['third storage unit']}, {'element_identifier': '24', 'terms': ['second storage unit']}, {'element_identifier': '19', 'terms': ['temporary storage section']}, {'element_identifier': '22', 'terms': ['storage door']}, {'element_identifier': '151', 'terms': ['first diversion path']}, {'element_identifier': '16', 'terms': ['recognition unit']}, {'element_identifier': '27', 'terms': ['fifth storage unit']}, {'element_identifier': '21', 'terms': ['first storage box']}, {'element_identifier': '15', 'terms': ['transport unit']}, {'element_identifier': '23', 'terms': ['first storage unit']}, {'element_identifier': '13', 'terms': ['dispensing section']}, {'element_identifier': '28', 'terms': ['sixth storage unit']}, {'element_identifier': '155', 'terms': ['fifth diversion path']}, {'element_identifier': '26', 'terms': ['fourth storage unit']}, {'element_identifier': '33', 'terms': ['collection section']}, {'element_identifier': '150', 'terms': ['loop transport path']}]","['1. A sheet processing apparatus, comprising: a storage unit configured to store therein a sheet having a serial number; a recognition unit configured to perform a first reading processing to read the serial number from the stored sheet that is fed out from the storage unit; and a control section configured to retrieve, from a serial number list including listed serial number of the sheet stored in the storage unit, the listed serial number having a predetermined relationship relating to a degree of coincidence with the serial number read in the first reading processing.']",False,"['13', '152', '153', '19', '155', '22', '25', '151', '15', '18', '16', '150', '54', '54', '154', '54', '154', '156', '20', '21', '33', '30', '23', '24', '26', '27', '28', '1', '15']" 311,EP_3588476_A1 (2).png,EP3588476A1,VIDEO DISPLAY DEVICE,['FIG4'],['FIG4 is a diagram illustrating an example of a drive gradation table'],"['In one or more embodiments, one frame is divided into N pieces of subframes, and on and off of the respective subframes are switched, whereby gradation display is performed. Note that the subframes are denoted by SF1, SF2... and SFN in order from a temporarily prior one. FIG4 shows an example of a drive gradation table, and longitudinal columns of the drive gradation table represent the gradations. The subframe data generator 12 generates the subframe data based on values in the drive gradation table, which correspond to the gradations of the video data.', 'In the above, as shown in FIG4, an example is shown of the drive gradation table in which the subframes which turn on are sequentially increased from the temporarily posterior subframe toward the temporarily prior subframe as the gradation rises. However, the drive gradation table is not limited to this. The drive gradation table only needs to be a table in which a temporarily prior subframe is turned off at the time of a low gradation.']",12,187,diagram,B,"[{'element_identifier': '7', 'terms': ['projection lens']}, {'element_identifier': '5', 'terms': ['PBS']}, {'element_identifier': '12', 'terms': ['subframe data generator']}, {'element_identifier': '11', 'terms': ['signal processor']}, {'element_identifier': '1', 'terms': ['visible light source']}, {'element_identifier': '9', 'terms': ['Gradation']}, {'element_identifier': '4', 'terms': ['illumination optical system']}, {'element_identifier': '2', 'terms': ['infrared light source']}, {'element_identifier': '6', 'terms': ['liquid crystal display element']}, {'element_identifier': '10', 'terms': ['signal synthesizer']}, {'element_identifier': '3', 'terms': ['dichroic mirror']}]","['1. A video display device (100) comprising: a display element (6); a visible light source (1) configured to irradiate visible illumination light; an infrared light source (2) configured to irradiate infrared illumination light; a subframe data generator (12) configured to generate subframe data based on a mixed video signal in which a frame of a video signal for a visible light image and a frame of a video signal for an infrared light image are alternately repeated, the subframe data indicating on and off of an applied voltage to the display element (6) in the frames; a pixel circuit (13) configured to drive the display element (6) based on the subframe data generated by the subframe data generator (12); and a light source controller (14) configured to control on and off of the visible light source (1), wherein, when gradation of the mixed video signal is equal to or less than a predetermined gradation, the subframe data generator (12) generates the subframe data so that an applied voltage to the display element (6) is turned off during a first predetermined period from a start of the frame of the video signal for a visible light image or the video signal for an infrared light image, and wherein the light source controller (14) turns on the visible light source (1) after a lapse of a second predetermined period from a start of the frame of the video signal for a visible light image, and turns off the visible light source (1) at a timing when the frame of the video signal for a visible light image is ended.']",False,"['4', '2', '3', '4', '5', '6', '7', '8', '9', '10', '11', '12', '8', '1', '1', '1']" 312,EP_3588476_A1 (3).png,EP3588476A1,VIDEO DISPLAY DEVICE,['FIG5'],['FIG5 is a timing chart illustrating a flow until a video signal is displayed'],"['FIG5 shows a state until the video signal is displayed based on the frame sequential signal FSS. S1 indicates the frame sequential signal FSS obtained by synthesizing the video signal for the visible light image VIS and the video signal for the infrared light image IRS with each other. In videos displayed by the simulator system that assumes the night flight, since the visible light image becomes dark, a light intensity of the visible light is low. Meanwhile, it is necessary to increase the intensity of the infrared light when the infrared light image is displayed. Therefore, it is expected that the gradation of the video signal for the visible light image VIS is low, and that the gradation of the video signal for the infrared light image IRS is high.']",14,141,flowchart,B,"[{'element_identifier': '0', 'terms': ['subframe data.']}, {'element_identifier': '5', 'terms': ['PBS']}]","['1. A video display device (100) comprising: a display element (6); a visible light source (1) configured to irradiate visible illumination light; an infrared light source (2) configured to irradiate infrared illumination light; a subframe data generator (12) configured to generate subframe data based on a mixed video signal in which a frame of a video signal for a visible light image and a frame of a video signal for an infrared light image are alternately repeated, the subframe data indicating on and off of an applied voltage to the display element (6) in the frames; a pixel circuit (13) configured to drive the display element (6) based on the subframe data generated by the subframe data generator (12); and a light source controller (14) configured to control on and off of the visible light source (1), wherein, when gradation of the mixed video signal is equal to or less than a predetermined gradation, the subframe data generator (12) generates the subframe data so that an applied voltage to the display element (6) is turned off during a first predetermined period from a start of the frame of the video signal for a visible light image or the video signal for an infrared light image, and wherein the light source controller (14) turns on the visible light source (1) after a lapse of a second predetermined period from a start of the frame of the video signal for a visible light image, and turns off the visible light source (1) at a timing when the frame of the video signal for a visible light image is ended.']",False,"['5', '0']" 313,EP_3588476_A1 (4).png,EP3588476A1,VIDEO DISPLAY DEVICE,['FIG6'],['FIG6 is a diagram illustrating another example of the drive gradation table '],"['FIG6 shows another example of the drive gradation table. In accordance with the drive gradation table in FIG6, SF4 turns on at the time of Gradation 1, and the subframes which turn on are increased in a temporarily posterior direction as the gradation rises, and SF1 is turned on at Gradation 10. That is, SF1 to SF3 are not turned on up to Gradation 9. At this time, the light source controller 14 only needs to make control so that the visible light source 1 is not turned on during an approximate period equivalent to SF1 to SF3.']",12,107,diagram,B,"[{'element_identifier': '7', 'terms': ['projection lens']}, {'element_identifier': '5', 'terms': ['PBS']}, {'element_identifier': '12', 'terms': ['subframe data generator']}, {'element_identifier': '11', 'terms': ['signal processor']}, {'element_identifier': '1', 'terms': ['visible light source']}, {'element_identifier': '9', 'terms': ['Gradation']}, {'element_identifier': '4', 'terms': ['illumination optical system']}, {'element_identifier': '2', 'terms': ['infrared light source']}, {'element_identifier': '6', 'terms': ['liquid crystal display element']}, {'element_identifier': '10', 'terms': ['signal synthesizer']}, {'element_identifier': '3', 'terms': ['dichroic mirror']}]","['1. A video display device (100) comprising: a display element (6); a visible light source (1) configured to irradiate visible illumination light; an infrared light source (2) configured to irradiate infrared illumination light; a subframe data generator (12) configured to generate subframe data based on a mixed video signal in which a frame of a video signal for a visible light image and a frame of a video signal for an infrared light image are alternately repeated, the subframe data indicating on and off of an applied voltage to the display element (6) in the frames; a pixel circuit (13) configured to drive the display element (6) based on the subframe data generated by the subframe data generator (12); and a light source controller (14) configured to control on and off of the visible light source (1), wherein, when gradation of the mixed video signal is equal to or less than a predetermined gradation, the subframe data generator (12) generates the subframe data so that an applied voltage to the display element (6) is turned off during a first predetermined period from a start of the frame of the video signal for a visible light image or the video signal for an infrared light image, and wherein the light source controller (14) turns on the visible light source (1) after a lapse of a second predetermined period from a start of the frame of the video signal for a visible light image, and turns off the visible light source (1) at a timing when the frame of the video signal for a visible light image is ended.']",False,"['6', '2', '3', '4', '5', '6', '7', '8', '9', '10', '11', '12', '1', '1', '10', '1', '1']" 314,EP_3588483_A1 (4).png,EP3588483A1,KEYBOARD INSTRUMENT,['FIG8'],['FIG8 is an enlarged planar view of the main portion showing a state where the front end of the key shown in FIG7 has been displaced in the array direction of the keys'],"['More specifically, in this keyboard instrument, in a state where a key 2 has been supported by the shaft sections 21 of the corresponding pair of key supporting pieces 17 being arranged in the shaft holes 20 of the pair of the attachment pieces 18 of the key 2, when one of the pair of attachment pieces 18 on the left side (upper side in FIG8) in the array direction of the keys 2 is shifted rearward within the range of the corresponding second spaces S2 and the other one of the pair of attachment pieces 18 on the right side (lower side in FIG8) in the array direction of the keys 2 is shifted frontward within the range of the corresponding second spaces S2, the front end of the key 2 is displaced leftward (toward the upper side in FIG8) in the array direction of the keys 2, whereby a space between the front end of the key 2 and the front end of an adjacent key 2 can be easily and favorably adjusted. As a result of this structure, spaces between the keys 2 can be aligned to be even.']",33,206,planar view,G,"[{'element_identifier': '8', 'terms': ['board supporting sections']}, {'element_identifier': '17', 'terms': ['key supporting pieces']}, {'element_identifier': '22', 'terms': ['pressing ribs', 'pressing rib']}, {'element_identifier': '18', 'terms': ['attachment pieces', 'attachment piece']}, {'element_identifier': '20', 'terms': ['shaft holes', 'shaft hole']}, {'element_identifier': '21', 'terms': ['shaft sections', 'shaft section']}, {'element_identifier': '23', 'terms': ['deformation restriction section', 'deformation restriction sections']}, {'element_identifier': '13', 'terms': ['attachment section', 'attachment sections']}]","['1. A keyboard instrument comprising: a plurality of keys (2); and a keyboard chassis (1), wherein each key (2) has a shaft (21) or a shaft hole (20) provided on one end side thereof, wherein the keyboard chassis (1) is provided with shafts (21) when the plurality of keys (2) has shaft holes (20), and is provided with shaft holes (20) when the plurality of keys (2) has shafts (21), wherein the keyboard chassis (1) supports the plurality of keys (2) by the shafts (21) being arranged in the shaft holes (20), wherein first spaces (S1) and second spaces (S2) are formed between an inner surface of the shaft hole (20) and the shaft (21), wherein the first spaces (S1) are positioned in a vertical direction of the key (2), and the second spaces (S2) are positioned in a longitudinal direction of the key (2), and wherein the second spaces (S2) are larger than the first spaces (S1).', '3. The keyboard instrument according to claim 1 or 2, wherein the keyboard chassis (1) or the plurality of keys (2) has pressing ribs (22) each of which is thinner than a corresponding shaft (21) and positioned on a straight line extending in at least one of an upper direction and a lower direction from center of the corresponding shaft (21).', '5. The keyboard instrument according to any one of claims 1 to 4, wherein each key (2) includes a U-shaped section (13) provided on the one end side, wherein the keyboard chassis (1) has pairs of key supporting pieces (17) which support U-shaped sections (13) of the plurality of keys (2), wherein shaft holes (20) are provided in both sides of each U-shaped section (13), and wherein shafts (21) are provided on opposing surfaces of each pair of key supporting pieces (17) on the keyboard chassis (1).', '8. The keyboard instrument according to claim 7, wherein each key (2) has a deformation restriction section (23) which is provided on an upper portion of the U-shaped section (13) and regulates the resilient deformation.']",False,"['8', '13', '23', '22', '17', '18', '21', '20', '21', '20', '21', '18', '22', '17']" 315,EP_3588521_A1 (6).png,EP3588521A1,TRANSFORMER,['FIG10'],['FIG10 is a comparison diagram illustrating the electric field distribution of the insulated structure in FIG6 versus the electric field distribution of the insulated structure in FIG7'],"['In order to compare the electric field distributions of the two insulated structures more intuitively, a changing curve of electric field is drafted by starting from a center of circle, along the radial direction, as illustrated in FIG10. In FIG10, the horizontal coordinate indicates the radius while the vertical coordinate indicates the electric field intensity. The solid-line curve illustrates an electric field distribution condition of the second solution in the prior art technology. It can be seen that, the insulated structure has a greater electric field value at an inner side (an external surface of the grounded aluminum pipe, at a horizontal coordinate position of 5mm), with a maximum value of 2.9 kV/mm, and the insulated structure has an extremely small electric field value at an external side ,with a value smaller than 0.5 kV/mm, and at a horizontal coordinate position greater than 17mm; that is, the electric field distribution is extremely uneven. The dash-line curve illustrates the electric field distribution condition of the embodiment of the present disclosure, in which the maximum electric field is located at an interface (at a horizontal coordinate position of 12mm) of the second solid insulating layer with the air, having a maximum value of 1.9 kV/mm, and an inner side of the second solid insulating layer has relatively smaller electric field (the maximum value is 1.2 kV/mm, and the horizontal coordinate position is smaller than 10mm). Compared with the second solution in the prior art technology, the maximum electric field value in the present disclosure is reduced: it reduced from 2.9 kV/mm to 1.9 kV/mm; meanwhile, the entire electric field distribution is more uniform. Thus, as compared with the second solution in the prior art technology, the embodiment of the present disclosure optimizes the entire insulation coordination.']",27,349,diagram,H,"[{'element_identifier': '5', 'terms': ['air']}, {'element_identifier': '9', 'terms': ['insulated wire']}, {'element_identifier': '25', 'terms': ['semi-conductive layer']}, {'element_identifier': '10', 'terms': ['cores', 'core']}, {'element_identifier': '15', 'terms': ['applied voltage is']}]","['1. A transformer, comprising: at least one magnetic core (6, 10, 13, 16), each having at least one window (A); one primary side winding (9) passing through the at least one window (A) of each of all the magnetic core (6, 10, 13, 16); and at least one secondary side winding (7, 8), each passing through the at least one window (A) of one corresponding magnetic core (6, 10, 13, 16), wherein a wire (1) forms the primary side winding (9), and the wire (1) is sequentially covered with a first solid insulating layer (2), a grounded shielding layer (3) and a second solid insulating layer (4) from inside to outside along a radial direction of the wire (1), wherein the grounded shielding layer (3) is connected to a reference ground, wherein the primary side winding (9) has a first voltage with respect to the reference ground, the secondary side winding (7, 8) has a second voltage with respect to the reference ground, and the second voltage is greater than 50 times of the first voltage.', '9. The transformer according to claim 1, wherein a space between the grounded shielding layer (3) and the second solid insulating layer (4) is further covered with a semi-conductive layer.']",False,"['9', '5', '10', '15', '20', '25', '30', '18']" 316,EP_3588552_A1 (2).png,EP3588552A1,THERMAL INTERFACE MATERIAL SHEET AND METHOD OF MANUFACTURING A THERMAL INTERFACE MATERIAL SHEET,"['FIG5', ' FIG6']","['FIG6 shows a schematic view of a TIM sheet with PVD grown thin film sensor ', 'FIG5 shows a schematic construction of a TIM sheet with PVD grown thin film sensor']","['FIG6 shows a different view of a simplified structure of the invention with the sensor and its electrical connectors visible. The structure shows a planar view of a carbon based material layer 61, a sensor 62 and the electrical conductors of the sensor. ', 'FIG5 shows another view of an embodiment of the present invention for better understanding the invention. A graphite sheet 51 is provided and an electrically insulating layer 52 is set on top of the graphite sheet 51. The electrically insulating layer is not covering the graphite sheet 51 completely as the purpose of the insulating layer is to be a base for the PVD grown sensor 53. A second electrically insulating layer 54 is placed on top of the sensor 53, and a wear resistant layer 55 is provided on top of the second insulating layer. As can be seen from FIG5, the graphite sheet or layer 51 has a surface area that is larger than the surface areas of the other layers. The other layers are provided in order to enable manufacturing of the sensor and to protect the sensor, and therefore the layers are dimensioned such that the surface area of the layers is covering the sensor. It should be noted, that base plate of the component or module may be formed of electrically insulating material, such as ceramic material. When the base plate is electrically insulating, the insulating layer on top of the graphite sheet is not required. Further, the surface of the cooling device may also be coated with an electrically insulating material, which also reduces the need of insulating layers in the thermal interface material sheet. The coating may be a ceramic coating or anodised coating when the cooling device is of aluminium.']",30,312,"schematic, schematic view",F,"[{'element_identifier': '51', 'terms': ['graphite sheet']}, {'element_identifier': '6', 'terms': ['andFigure']}, {'element_identifier': '52', 'terms': ['electrically insulating layer']}, {'element_identifier': '61', 'terms': ['carbon based material layer']}, {'element_identifier': '53', 'terms': ['sensor']}, {'element_identifier': '62', 'terms': ['sensor']}, {'element_identifier': '55', 'terms': ['wear resistant layer']}]","['1. A thermal interface material sheet to be disposed between a heat generating electrical component and a cooling device, the thermal interface material sheet comprising at least one thin film sensor and electrical conductors connected to the at least one thin film sensor for measuring a property related to the heat generating electrical component.', '4. The thermal interface material sheet according to claim 1, wherein the thermal interface material sheet comprises a thermal interface material layer, an electrically insulating layer on which the at least one thin film sensor is disposed, and a second electrically insulating layer on top of the at least one thin film sensor.']",True,"['55', '53', '52', '51', '5', '63', '62', '61', '6', '8']" 317,EP_3588566_A1 (1).png,EP3588566A1,"FLEXIBLE DISPLAY PANEL, METHOD FOR MANUFACTURING SAME, AND DISPLAY DEVICE",['FIG4'],['FIG4 is a schematic structure view of a flexible display panel provided by another embodiment of the present disclosure'],"['For example, FIG4 is a schematic structure view of a flexible display panel provided by an embodiment of the present disclosure. The flexible display panel further includes a flexible supporting layer 204, and the flexible supporting layer 204 is disposed on a side of the flexible substrate 2011 facing away from the flexible display screen 2012, and the flexible supporting layer 204 supports the flexible display screen 201, and can further prevent water, oxygen and the like from entering the flexible display panel to cause damages to the flexible display screen.', 'For example, as illustrated in FIG4, the flexible display panel 200 further includes a circular polarizer 205, and the circular polarizer 205 is disposed on the side of the flexible display screen facing away from the flexible substrate 2011.']",19,142,schematic view,G,"[{'element_identifier': '202', 'terms': ['connection layer']}, {'element_identifier': '203', 'terms': ['protection film']}, {'element_identifier': '2011', 'terms': ['flexible substrate']}, {'element_identifier': '206', 'terms': ['screen']}, {'element_identifier': '204', 'terms': ['flexible supporting layer']}, {'element_identifier': '2012', 'terms': ['flexible display screen']}, {'element_identifier': '205', 'terms': ['circular polarizer']}, {'element_identifier': '200', 'terms': ['flexible display panel']}]","['1. A flexible display panel, comprising: a flexible substrate; a flexible display screen on the flexible substrate; a protection film disposed at a side of the flexible display screen away from the flexible substrate; and a connection layer sandwiched between the flexible display screen and the protection film, wherein the connection layer comprises at least a hyperelasticity film.', '7. The flexible display panel according to any one of claims 1 to 6, further comprising a flexible supporting layer, wherein the flexible supporting layer is disposed on a side of the flexible substrate away from the flexible display screen.', '8. The flexible display panel according to any one of claims 1 to 7, further comprising a circular polarizer, wherein the circular polarizer is disposed on a side of the flexible display screen away from the flexible substrate.']",True,"['203', '202', '205', '2012', '2011', '204', '200', '4', '202', '203', '205', '2012', '2011', '204', '200', '5', '203', '202', '205', '206', '2012', '2011', '204', '200', '10']" 318,EP_3588574_A1 (1).png,EP3588574A1,DISPLAY DEVICE,['FIG2'],"[""FIG2 is a cross-sectional view taken along line I-I' of FIG1""]","['The support frame 400 is fastened to the bottom case 600 to support the display panel 100 and the top case 500. In addition, the support frame 400 maintains an interval between the display panel 100 and the optical sheet 200 to be substantially constant. To this end, as illustrated in FIG2, the support frame 400 may have an overall quadrangular frame shape including a first support portion 411a, a second support portion 411b, and a fastening portion 411c. These portions may be disposed at all sides of the display device in the top plan view, without being limited thereto.']",16,110,cross-sectional view,H,"[{'element_identifier': '310', 'terms': ['display element']}, {'element_identifier': '210', 'terms': ['thin film transistor']}, {'element_identifier': '211', 'terms': ['active layer']}, {'element_identifier': '121', 'terms': []}, {'element_identifier': '313', 'terms': ['intermediate layer']}, {'element_identifier': '213', 'terms': ['gate electrode']}, {'element_identifier': '100', 'terms': ['substrate']}, {'element_identifier': '300', 'terms': ['display layer']}, {'element_identifier': '311', 'terms': ['first electrode']}, {'element_identifier': '315', 'terms': ['second electrode']}, {'element_identifier': '131', 'terms': []}, {'element_identifier': '140', 'terms': ['planarization layer']}, {'element_identifier': '110', 'terms': ['buffer layer']}, {'element_identifier': '150', 'terms': ['pixel defining layer']}]","['1. A display device, comprising: a substrate; a circuit layer over the substrate; a display layer over the circuit layer; at least one hole in a display area of the substrate that penetrates the substrate, the circuit layer, and the display layer; and at least two grooves that surround the at least one hole, wherein the substrate comprises a first substrate layer, a first inorganic layer, a second substrate layer, and a second inorganic layer, which are sequentially stacked, and each of the at least two grooves extends from the display layer down into the second substrate layer.', '9. The display device of any one of claims 1 to 8, wherein the circuit layer includes a thin film transistor, and the display layer includes an organic light-emitting diode that is electrically connected to the thin film transistor.']",False,"['2', '310', '315', '311', '313', '300', '150', '140', '131', '121', '110', '100', '211', '213', '210', '12']" 319,EP_3588588_A1 (1).png,EP3588588A1,DEVICE FOR ASSISTING A BUS BAR TO PASS THROUGH A HOLE AND SOLAR ASSEMBLY PRODUCTION LINE,"['FIG3', ' FIG4']","['FIG4 is a schematic structural view of a driving head according to another embodiment of the present application ', 'FIG3 is a schematic structural view of a driving head in the form of a folded plate according to an embodiment of the present application']","['As shown in FIG4, in another embodiment of the present application, the device for assisting a bus bar to pass through a hole is substantially the same as that of the above embodiment, except that the driving head in this embodiment includes a clamping member that can be opened and closed, and a receiving hole 9 for the bus bar 2 to pass through is formed in the middle of the clamping member. ', 'As shown in FIG3, the hooking member can be a folded plate 7 arranged at an acute angle with respect to the piston rod of the lifting cylinder 4, and the folded plate 7 is smoothly connected to the piston rod of the lifting cylinder 4. Alternatively, the folded plate 7 is smoothly connected with the piston rod of the lifting cylinder 4 through the flexible elongated handle 5.']",43,152,schematic structural view,H,"[{'element_identifier': '7', 'terms': ['folded plate']}, {'element_identifier': '5', 'terms': ['flexible elongated handle']}, {'element_identifier': '4', 'terms': ['lifting cylinder']}, {'element_identifier': '10', 'terms': ['clamping cylinder']}]","['3. The device for assisting a bus bar to pass through a hole according to claim 1, wherein the driving head comprises a folded plate (7) arranged at an acute angle with respect to the output end of the driving assembly.', '6. The device for assisting a bus bar to pass through a hole according to claim 5, wherein the clamping member comprises two clamping jaws (8), each clamping jaw (8) is provided with a through slot, and the two through slots cooperate to form the receiving hole (9); the driving head further comprises a clamping cylinder (10) connected with the two clamping jaws (8) and arranged to drive the two clamping jaws (8) to be tightly closed or released.', '8. The device for assisting a bus bar to pass through a hole according to claim 1, wherein the driving assembly comprises a lifting cylinder (4), and a piston rod of the lifting cylinder (4) is connected with the driving head.', '12. The device for assisting a bus bar to pass through a hole according to claim 1, wherein the device for assisting a bus bar to pass through a hole further comprises a flexible elongated handle (5), and the output end of the driving assembly is connected with the driving head through the flexible elongated handle (5).']",True,"['7', '5', '10', '4']" 320,EP_3588593_A1 (2).png,EP3588593A1,MAGNETIC MEMORY DEVICES AND METHODS OF FABRICATION,['FIG2'],['FIG2 illustrates a flow diagram of a method to fabricate a memory device'],"['FIG2 illustrates a flow diagram of a method to fabricate a memory device. The method 200 begins at operation 210 by forming a first electrode in a dielectric layer above a substrate. The method 200 continues at operation 220 with the formation of a pMTJ material layer stack on the bottom electrode. In exemplary embodiments, all layers in the pMTJ material layer stack are blanket deposited in-situ without breaking vacuum. In a simplest embodiment, forming the pMTJ material layer stack includes deposition of a SAF layer on the bottom electrode, deposition of a fixed magnetic layer on the SAF layer, deposition of a tunnel barrier on the fixed magnetic layer, deposition of a first free magnetic layer on the tunnel barrier, deposition of a coupling layer on the second free magnetic layer, deposition of a second free magnetic layer on the coupling layer and deposition of a capping layer on the second free magnetic layer. The method 200 is continued at operation 240 with patterning of the pMTJ material layer stack to form a memory device. The method 200 is then resumed at operation 240 with the deposition of dielectric spacer and patterning to form a dielectric spacer adjacent to sidewalls of the memory device.']",13,221,flow diagram,G,"[{'element_identifier': '220', 'terms': ['continues at operation']}, {'element_identifier': '210', 'terms': ['begins at operation']}, {'element_identifier': '200', 'terms': ['method']}, {'element_identifier': '240', 'terms': ['at operation']}]","['9. A method of fabricating a memory device, comprising: forming a bottom electrode layer; forming a material layer stack on the bottom electrode layer, the forming comprising: forming a fixed magnetic layer above the bottom electrode layer; forming a tunnel barrier layer on fixed magnetic layer; forming a first free magnetic layer on the tunnel barrier layer; forming a coupling layer on the first free magnetic layer, wherein the coupling layer comprises a transition metal and has a thickness no more 0.1nm; and forming a second free magnetic layer on the coupling layer; forming a top electrode on the material layer stack; and etching the material layer stack to form a memory device.']",False,"['200', '210', '220', '230', '240', '17']" 321,EP_3588593_A1 (4).png,EP3588593A1,MAGNETIC MEMORY DEVICES AND METHODS OF FABRICATION,['FIG5B'],['FIG5B illustrates a cross-sectional view of the structure in FIG4A following the patterning of the conductive layer and the pMTJ material layer stack to form a pMTJ device'],"['FIG5B illustrates a cross-sectional view of the structure in FIG4A following the patterning of the conductive layer 321 and the pMTJ material layer stack 340. In an embodiment, the patterning process includes etching the conductive layer 321 by a plasma etch process to form a top electrode 120. In an embodiment, plasma etch process possesses sufficient ion energy and chemical reactivity to render vertical etched sidewalls of the top electrode 120.']",30,78,cross-sectional view,G,"[{'element_identifier': '325', 'terms': ['dashed lines']}, {'element_identifier': '304', 'terms': ['conductive interconnect', 'conductive interconnects']}, {'element_identifier': '302', 'terms': ['dielectric layer']}, {'element_identifier': '112', 'terms': ['fixed magnet']}, {'element_identifier': '300', 'terms': ['device', 'devices']}, {'element_identifier': '101', 'terms': ['bottom electrode']}, {'element_identifier': '340', 'terms': ['pMTJ material layer stack']}, {'element_identifier': '110', 'terms': ['tunnel barrier']}, {'element_identifier': '109', 'terms': ['coupling layer']}]","['1. A memory device, comprising: a bottom electrode; a top electrode; and a magnetic tunnel junction (MTJ) between the bottom electrode and the top electrode, the MTJ comprising: a fixed magnet; a free magnet structure comprising; a first free magnet; and a second free magnet adjacent the first free magnet, wherein at least a portion of the first free magnet proximal to an interface with the second free magnet comprises a transition metal; and a tunnel barrier between the fixed magnet and the free magnet structure.', '3. The memory device of claim 1, further comprising a coupling layer between the first free magnet and the second free magnet, wherein the coupling layer is discontinuous, has a thickness no more than 0.1nm and comprises the transition metal.']",False,"['300', '109', '325', '340', '325', '110', '112', '101', '302', '304', '21']" 322,EP_3588593_A1 (5).png,EP3588593A1,MAGNETIC MEMORY DEVICES AND METHODS OF FABRICATION,['FIG5C'],['FIG5C illustrates a cross-sectional view of the structure in FIG5B following the formation of a dielectric spacer adjacent to the pMTJ'],"['FIG5C illustrates a cross-sectional view of the structure in FIG5B following the formation of a dielectric spacer 326 adjacent to the memory device 300. In an embodiment, a dielectric spacer layer is deposited on the memory device 300 and on the uppermost surface of the dielectric layer 102. In an embodiment, the dielectric spacer layer is deposited without a vacuum break following the plasma etch process to prevent oxidation of magnetic layers in the pMTJ 104. In an embodiment, the dielectric spacer layer includes a material such as, but not limited to, silicon nitride, carbon doped silicon nitride or silicon carbide. In an embodiment, the dielectric spacer layer includes an insulator layer that does not have oxygen to minimize oxidation of the magnetic layers 112,107 and 108. In an embodiment, the dielectric spacer layer is etched by a plasma etch process forming dielectric spacer 326 on sidewalls of the memory device 300.']",23,168,cross-sectional view,G,"[{'element_identifier': '304', 'terms': ['conductive interconnect', 'conductive interconnects']}, {'element_identifier': '302', 'terms': ['dielectric layer']}, {'element_identifier': '326', 'terms': ['dielectric spacer']}, {'element_identifier': '300', 'terms': ['device', 'devices']}, {'element_identifier': '101', 'terms': ['bottom electrode']}, {'element_identifier': '340', 'terms': ['pMTJ material layer stack']}, {'element_identifier': '110', 'terms': ['tunnel barrier']}, {'element_identifier': '109', 'terms': ['coupling layer']}]","['1. A memory device, comprising: a bottom electrode; a top electrode; and a magnetic tunnel junction (MTJ) between the bottom electrode and the top electrode, the MTJ comprising: a fixed magnet; a free magnet structure comprising; a first free magnet; and a second free magnet adjacent the first free magnet, wherein at least a portion of the first free magnet proximal to an interface with the second free magnet comprises a transition metal; and a tunnel barrier between the fixed magnet and the free magnet structure.', '3. The memory device of claim 1, further comprising a coupling layer between the first free magnet and the second free magnet, wherein the coupling layer is discontinuous, has a thickness no more than 0.1nm and comprises the transition metal.']",False,"['300', '109', '340', '110', '326', '101', '302', '304', '22']" 323,EP_3588670_A1 (5).png,EP3588670A1,BASE STATION ANTENNAS INCLUDING WIPER PHASE SHIFTERS,['FIG2C'],['FIG2C is a schematic cross-sectional view of a phase shifter assembly for a base station antenna according to embodiments of the present inventive concepts'],"['FIG2C is a schematic cross-sectional view of a phase shifter assembly 100 for a base station antenna according to embodiments of the present inventive concepts. In particular, FIG2C illustrates a vertical stack that includes the wiper PCB 223-1 on the main PCB 230-1, and the wiper support 140-1 on the wiper PCB 223-1, on the first level 110-1L of the housing 110. Similarly, the wiper PCBs 223-2, 223-3, and 223-4 are on the main PCBs 230-2, 230-3, and 230-4, respectively, and the wiper supports 140-2, 140-3, 140-4 are on the wiper PCBs 223-2, 223-3, and 223-4, respectively. FIG2C also illustrates that the linkages 170-1 and 170-2, which are coupled to the linkage 160, are on the wiper supports 140-1 and 140-4, respectively.', 'As illustrated in FIG2C, the two inner/middle main PCBs 230-2 and 230-3 are closer to each other than to the outer main PCBs 230-1 and 230-4. Similarly, the two inner/middle main PCBs 230-6 and 230-7 are closer to each other than to the outer main PCBs 230-5 and 230-8. For example, in some embodiments, the main PCBs 230-2 and 230-3 may contact each other, and the main PCBs 230-6 and 230-7 may contact each other. The main PCBs 230-2 and 230-3 are horizontally spaced apart, however, from the main PCBs 230-1 and 230-4, respectively, and the main PCBs 230-6 and 230-7 are horizontally spaced apart from the main PCBs 230-5 and 230-8, respectively.']",26,360,schematic cross-sectional view,H,"[{'element_identifier': '160', 'terms': ['linkage', 'linkages']}, {'element_identifier': '100', 'terms': ['phase shifter assembly']}, {'element_identifier': '2', 'terms': ['frequencies lower than', 'using frequencies such as', 'using other frequencies between', 'in particular Aspect']}, {'element_identifier': '180', 'terms': ['linkage', 'linkages']}, {'element_identifier': '110', 'terms': ['housing']}]","['4. The base station antenna of either of Claim 2 or Claim 3, wherein the first and second pluralities of gear teeth (340-GT) extend less than 360 degrees around the first and second wiper supports (140-1, 140-2), respectively, and wherein the first wiper support (140-1) comprises a built-in lever linkage portion (370-BI) that protrudes beyond the first plurality of gear teeth (340-GT).', '14. A method of operating a base station antenna, the method comprising: driving (Block 540) rotational movement of a first plurality of phase shifter wiper supports (140-2, 140-3) of a plurality of inboard phase shifters (120-2, 120-3), respectively, of a phase shifter assembly (100) by driving (Block 530) rotational movement of a second plurality of phase shifter wiper supports (140-1, 140-4) of a plurality of outboard phase shifters (120-1, 120-4), respectively, of the phase shifter assembly (100).']",False,"['160', '180', '100', '110', '110', '2']" 324,EP_3588683_A1 (5).png,EP3588683A1,FIXATION STRUCTURE,['FIG6'],['FIG6 is a cross-sectional view illustrating the exemplary configuration of the fixation structure according to the second embodiment'],"['The opening 41c of the housing 40 is blocked by the lid unit 42 while the board 20 housed in the housing space 41d is fixed to the second bottom surface 41i by a screw 23 (refer to FIG6). Then, the screws 32b are screwed into cylindrical parts 32a of the fixation parts 32 through the through-holes 41f of the second bottom surface 41i so that the stapler 30A is fixed to the board 20 in the housing 40. In this case, the contact part 31a of the stapler 30A integrated with the lid unit 42 contacts the core-wire exposed part 11 and the core-wire covered part 12 of the electrical wire 10 connected with the board 20. Heads of the screws 32b are positioned at the stepped part 41g between the first bottom surface 41h and the second bottom surface 41i, and do not protrude from the first bottom surface 41h as the lowermost surface of the housing 40. In the fixation structure 1A, since the stapler 30A is fixed to the board 20 by the screws 32b, constant fixation force can be achieved. In addition, in the fixation structure 1A, resin used for the stapler 30A are not limited unlike a case in which end parts of the resin fixation parts 32 are melted to achieve fixation.']",20,241,cross-sectional view,H,"[{'element_identifier': '11', 'terms': ['core-wire exposed part']}, {'element_identifier': '20', 'terms': ['board']}, {'element_identifier': '42', 'terms': ['lid unit']}, {'element_identifier': '41', 'terms': ['housing unit']}, {'element_identifier': '23', 'terms': ['screw']}]","['1. A fixation structure (1, 1A, 1B) comprising: an electrical wire (10) including a core wire (10a) that is conductive and a cover member (10b) that covers the core wire (10a), the electrical wire (10) including a core-wire covered part (12) covered by the cover member (10b) and a core-wire exposed part (11) exposed from the core-wire covered part (12); a board (20) including a junction part (22) electrically connected with the core-wire exposed part (11); and a stapler (30, 30A) including a contact part (31a) that has a plate shape and is positioned at a boundary (13) between the core-wire exposed part (11) and the core-wire covered part (12) while contacting the core-wire exposed part (11) and the core-wire covered part (12) from a side opposite to the board (20) when the core-wire exposed part (11) is connected with the junction part (22), and a pair of fixation parts (32) that are provided on both sides of the contact part (31a) and fix the contact part (31a) and the board (20).', '5. The fixation structure (1A, 1B) according to any one of claims 1 to 4, further comprising: a housing (40, 40B) to which the board (20) is assembled, wherein the housing (40, 40B) includes a housing unit (41, 41B) that has a box shape with an opening (41c) and that houses the board (20), and a lid unit (42) that is integrated with the stapler (30, 30A) and blocks the opening (41c), and the contact part (31a) of the stapler (30, 30A) integrated with the lid unit (42) contacts the core-wire exposed part (11) and the core-wire covered part (12) of the electrical wire (10) connected with the board (20) when the board (20) is housed in the housing unit (41, 41B) and the opening (41c) is blocked by the lid unit (42).']",False,"['23', '20', '42', '11', '14', '419', '41']" 325,EP_3588697_A1 (3).png,EP3588697A1,WATERPROOF PLUG INSERTION DEVICE AND CONNECTOR HOUSING MANUFACTURING METHOD WITH WATERPROOF PLUG,['FIG5'],['FIG5 is a plan view showing a relationship between the terminal receiving chamber and a fitted portion of the waterproof plug insertion device '],"['In the example shown in FIG5, in the template 7, pin holes 71 are formed at positions overlapping the virtual receiving chambers 202B and 203E, respectively. That is, among the plurality of terminal receiving chambers 102A to 102G, 103A to 103F, the terminal receiving chambers 102B and 103E become target receiving chambers, and the waterproof plugs are inserted. Incidentally, the positions and the number of the pin holes formed in the template 7 may be appropriately set according to which terminal receiving chamber becomes the target receiving chamber.']",23,100,plan view,H,"[{'element_identifier': '100', 'terms': ['housing', 'housings']}, {'element_identifier': '10', 'terms': ['two support posts']}]","['1. A waterproof plug insertion device for inserting a waterproof plug into a target receiving chamber of a plurality of terminal receiving chambers in a connector housing, the waterproof plug insertion device comprising: an emitting device for emitting the waterproof plug from an exit aperture; a supply device for supplying the waterproof plug to the emitting device; a fitting portion interlocking with the exit aperture in an intersecting plane intersecting an emitting direction of the waterproof plug; an operation unit for moving the emitting device and the fitting portion; a holding base for holding the connector housing; and a positioning unit provided on the holding base, wherein the positioning unit has a fitted portion that can be fitted with the fitting portion at a position corresponding to the target housing chamber.']",True,"['202', '100', '202', '100', '10']" 326,EP_3588704_A1 (1).png,EP3588704A1,SURFACE-EMITTING LASER AND METHOD FOR MANUFACTURING SURFACE-EMITTING LASER,['FIG2'],['FIG2 is a cross-sectional view schematically illustrating a structure of a photonic crystal surface emitting laser according to a first embodiment'],"['FIG2 is a schematic cross-sectional view of a structure of a surface emitting laser (hereinafter sometimes simply referred to as photonic crystal surface emitting laser) 10 including a photonic crystal layer according to a first embodiment. As shown in FIG2, a semiconductor structure layer 11 is formed on a substrate 12. More specifically, an n-cladding layer 13, an n-optical guide layer 14, an active layer 15, a optical guide layer 16, an electron blocking layer 17, and a p-cladding layer 18 are sequentially formed in this order on the substrate 12. In other words, the semiconductor structure layer 11 is constituted of the semiconductor layers 13, 14, 15, 16, 17, and 18. The n-optical guide layer 14 contains a photonic crystal layer 14P.']",23,152,cross-sectional view,C,"[{'element_identifier': '17', 'terms': ['electron blocking layer']}, {'element_identifier': '14', 'terms': ['layer']}, {'element_identifier': '12', 'terms': ['substrate']}, {'element_identifier': '11', 'terms': ['semiconductor structure layer']}, {'element_identifier': '18', 'terms': ['p-cladding layer']}, {'element_identifier': '16', 'terms': ['optical guide layer']}, {'element_identifier': '10', 'terms': ['surface emitting laser']}, {'element_identifier': '15', 'terms': ['active layer']}, {'element_identifier': '13', 'terms': ['n-cladding layer']}]","['1. A method for manufacturing a surface emitting laser made of a group-III nitride semiconductor by an MOVPE method, comprising: (a) a step of growing a first cladding layer of a first conductive type on a substrate; (b) a step of growing a first optical guide layer of said first conductive type on said first cladding layer; (c) a step of forming holes having a two-dimensional periodicity in a plane parallel to said first optical guide layer, in said first optical guide layer by etching; (d) a step of supplying a gas containing a group-III material and a nitrogen source and performing growth to form recessed portions having a facet of a predetermined plane direction top of openings of said holes, thereby closing the openings of said holes; and (e) a step of planarizing said recessed portions by mass transport, after said openings of said holes have been closed, wherein after said planarizing step has been performed, at least one of side surfaces of said hole is a {10-10} facet.']",False,"['10', '18', '17', '16', '15', '11', '14', '13', '12', '12']" 327,EP_3588704_A1 (3).png,EP3588704A1,SURFACE-EMITTING LASER AND METHOD FOR MANUFACTURING SURFACE-EMITTING LASER,['FIG5'],"['FIG5 is a cross-sectional view that schematically explains the cross section of the optical guide layer substrate corresponding to (a1), (a4) and (b) of FIG4']","['At this time, the distance D1 between the (000-1) plane, which was the top surface of the embedded hole CH, and a (0001) plane, which was an outermost surface of the n-optical guide layer 14, was approximately 140 nm (FIG5, (a4)). The opening radius R of the {10-11} facet was approximately 82 nm (FIG5, (a4)).', 'At this time, the distance D2 between a plane (top surface, (000-1) plane) of the embedded hole (cavity) 14C on the side of the active layer 15 and a front surface (i.e., (0001) plane) of the n-optical guide layer 14 was approximately 105 nm (FIG5, (b)). The height HC of the hole 14C was approximately 110 nm, and the diameter (width in cross section) WC of the hole CH was approximately 60 nm.']",34,185,cross-sectional view,C,"[{'element_identifier': '15', 'terms': ['active layer']}, {'element_identifier': '14', 'terms': ['layer']}, {'element_identifier': '5', 'terms': ['was approximately']}]","['1. A method for manufacturing a surface emitting laser made of a group-III nitride semiconductor by an MOVPE method, comprising: (a) a step of growing a first cladding layer of a first conductive type on a substrate; (b) a step of growing a first optical guide layer of said first conductive type on said first cladding layer; (c) a step of forming holes having a two-dimensional periodicity in a plane parallel to said first optical guide layer, in said first optical guide layer by etching; (d) a step of supplying a gas containing a group-III material and a nitrogen source and performing growth to form recessed portions having a facet of a predetermined plane direction top of openings of said holes, thereby closing the openings of said holes; and (e) a step of planarizing said recessed portions by mass transport, after said openings of said holes have been closed, wherein after said planarizing step has been performed, at least one of side surfaces of said hole is a {10-10} facet.']",False,"['5', '14', '15']" 328,EP_3588704_A1.png,EP3588704A1,SURFACE-EMITTING LASER AND METHOD FOR MANUFACTURING SURFACE-EMITTING LASER,['FIG1'],['FIG1 is a graph of the relationship between a filling factor (FF) and a radiation factor of a photonic crystal portion in an emission direction'],"['As to the aforementioned (2), FIG1 shows the relationship between a filling factor (FF) and a radiation constant of a photonic crystal portion in an emission direction, in a square-lattice two-dimensional photonic crystal having, for example, a period of 161 nm and a distance between an active layer and the photonic crystal portion of 80 nm.']",27,69,graph,C,"[{'element_identifier': '15', 'terms': ['active layer']}, {'element_identifier': '5', 'terms': ['was approximately']}, {'element_identifier': '10', 'terms': ['surface emitting laser']}, {'element_identifier': '11', 'terms': ['semiconductor structure layer']}]","['1. A method for manufacturing a surface emitting laser made of a group-III nitride semiconductor by an MOVPE method, comprising: (a) a step of growing a first cladding layer of a first conductive type on a substrate; (b) a step of growing a first optical guide layer of said first conductive type on said first cladding layer; (c) a step of forming holes having a two-dimensional periodicity in a plane parallel to said first optical guide layer, in said first optical guide layer by etching; (d) a step of supplying a gas containing a group-III material and a nitrogen source and performing growth to form recessed portions having a facet of a predetermined plane direction top of openings of said holes, thereby closing the openings of said holes; and (e) a step of planarizing said recessed portions by mass transport, after said openings of said holes have been closed, wherein after said planarizing step has been performed, at least one of side surfaces of said hole is a {10-10} facet.']",False,"['11', '5', '10', '15', '20']" 329,EP_3588721_A1 (5).png,EP3588721A1,UNIVERSAL PLATFORM ARCHITECTURE FOR HYBRID MORE ELECTRIC AIRCRAFT,['FIG5'],['FIG5 is a block diagram illustrating the flow of battery power between the battery chargers and the voltage converter circuits when operating in the battery power mode according to a non-limiting embodiment'],"['In response to invoking the battery power mode, the power distribution controller 132 activates a third combination of switches 130 while deactivating a third combination of switches 131. Accordingly, a different third electrical path is established between the front-end power converter 102 and the backend power converter sub-system 106. The third electrical path connects an output of the bi-directional battery charger circuit 122 to one or more voltage converter circuits 124. Further, the third electrical path is configured to share the output of one or more bi-directional battery charger circuits between the voltage converter circuits 124, e.g., one or more DC-to-DC converter circuits 124 and one or more DC-to-AC converter circuits 124. The flow of battery power between the battery chargers 124 and the voltage converter circuits 124 is illustrated in FIG5.']",34,158,block diagram,B,"[{'element_identifier': '122', 'terms': ['battery charger circuit', 'battery charger circuits']}, {'element_identifier': '128', 'terms': ['motor', 'load']}, {'element_identifier': '113', 'terms': ['rectifier circuit']}, {'element_identifier': '126', 'terms': ['battery']}, {'element_identifier': '104', 'terms': ['active power distribution system']}, {'element_identifier': '108', 'terms': ['source']}, {'element_identifier': '110', 'terms': ['DC bus']}, {'element_identifier': '124', 'terms': ['converter circuits', 'converter circuit']}]","['1. An aircraft power system (100) comprising: a front-end power converter (102) configured to generate a first direct current (DC) supply voltage or a second DC supply voltage based on a voltage level of an alternating current (AC) supply voltage output from an AC voltage source (108); a backend power converter sub-system (106) configured to convert the first DC supply voltage or the second DC supply voltage into a backend supply voltage; and an active power distribution system configured to select different electrical paths between the front-end converter and the backend converter subsystem in response to detecting output of the first DC supply voltage and the second DC supply voltage.', '2. The aircraft power system of claim 1, wherein the active power distribution system comprises: a multi-phase rectifier circuit (113) including a plurality of switches operable in an open state and a closed state; and a power distribution controller (132) configured to invoke the open and closed states of the switches, wherein different combinations of open and closed switches establish the different electrical paths between the front-end power converter (102) and the backend power converter sub-system (106).', '4. The aircraft power system of claim 3, wherein the backend power converter sub-system (106) comprises: at least one bi-directional battery charger circuit (122) including an input in signal communication with the front-end power converter (102) and an output in signal communication with a battery installed on the aircraft; and at least one voltage converter circuit including at least one of a DC-to-DC converter circuit and a DC-AC converter circuit.', '13. The aircraft power system of claim 12, wherein the DC-to-DC converter circuit is configured to convert the first DC supply voltage or the second DC supply voltage into a third DC supply voltage having a different voltage level that drives a DC load installed on the aircraft, wherein the DC-to-AC converter circuit is configured to convert the first DC supply voltage or the second DC supply voltage into a second AC supply voltage that drives a motor installed on the aircraft, and wherein the power distribution controller is configured to invoke a hybrid power exchange mode, and in response to invoking the hybrid power exchange mode, deliver at least one of the first and second AC supply voltages along with battery power output from the battery to drive the DC load.']",False,"['110', '104', '122', '124', '17', '126', '108', '17', '113', '128', '5']" 330,EP_3588830_A1 (1).png,EP3588830A1,"REFERENCE SIGNAL TRANSMITTING METHOD, RECEIVING METHOD AND DEVICE",['FIG3'],['FIG3 is a schematic diagram of an indication of group information of reference signal ports according to an embodiment of this application'],"['As shown in FIG3, an indication of the first group information includes: in the first group information, port numbers 0, 1, 4, and 5 are grouped into one group, and port numbers 2, 3, 6, and 7 are grouped into one group. After receiving the port group information, the UE determines, according to the indication of the port group information, the antenna port group number k for transmitting the reference signal at the time n. Further, according to the indication of the reference signal port group information, the UE determines the port group number k used every time the reference signal is transmitted, where each port group includes at least one antenna port. For example, in a channel measurement process, a reference signal is transmitted for four times, and the following four reference signal port groups are used for transmission at the four times respectively, where port numbers corresponding to each reference signal port group are: {0, 1, 4, 5}, {2, 3, 6, 7}, {2, 3, 6, 7}, and {0, 1, 2, 3}.']",22,220,schematic diagram,H,"[{'element_identifier': '4', 'terms': ['panel pattern']}, {'element_identifier': '2', 'terms': ['layer']}]","['5. The method according to any one of claims 1 to 4, wherein the receiving, by a second network device, first group information of reference signal port from a first network device comprises: receiving, by the second network device, signaling from the first network device, wherein the signaling indicates the first group information of the reference signal port; and the signaling comprises at least one of higher layer signaling, layer 1 signaling, and layer 2 signaling.']",True,"['4', '2', '27']" 331,EP_3588830_A1 (2).png,EP3588830A1,"REFERENCE SIGNAL TRANSMITTING METHOD, RECEIVING METHOD AND DEVICE","['FIG4', ' FIG6']","['FIG6 is a schematic structural diagram of an apparatus for transmitting a reference signal according to an embodiment of this application ', 'FIG4 is a schematic diagram of another indication of group information of reference signal ports according to an embodiment of this application']","['Another embodiment of this application further provides an apparatus for transmitting a reference signal. The apparatus is configured to implement the method for transmitting a reference signal in the foregoing embodiment. The apparatus is disposed in a second network device, and the second network device includes a terminal device. As shown in FIG6, the apparatus for transmitting a reference signal includes a receiving unit 601, a processing unit 602, and a transmission unit 603. In addition, the apparatus may further include other functional units or modules such as a storage unit.', 'In this embodiment of this application, the transceiver 1301 may be configured to receive reference signal port group information transmitted by the first network device, transmit a reference signal to the first network device, and the like in the foregoing embodiment. In FIG6 of the foregoing apparatus embodiment, functions to be implemented by the receiving unit 601 may be implemented by the transceiver 1301 of the terminal device, or implemented by the transceiver 1301 controlled by the processor 1302. Functions to be implemented by the processing unit 602 in FIG6 may also be implemented by the processor 1302 of the terminal device. ', 'As shown in FIG4, FIG4 is an implementation of another indication of the first group information. The implementation specifically includes: the UE transmits the reference signal for six times according to the received reference signal port group information, and the reference signal is transmitted every time on a port group including two ports. Further, the UE determines that port numbers used when the reference signal is transmitted every time in the six times are {0, 1}, {1, 2}, {2, 3}, {3, 4}, {4, 5}, and {5, 6} respectively, and then the UE performs switching according to the grouped antenna port numbers and transmits the reference signal sequentially.']",43,350,"schematic diagram, schematic structural diagram",H,"[{'element_identifier': '601', 'terms': ['receiving unit']}, {'element_identifier': '5', 'terms': ['Table']}, {'element_identifier': '602', 'terms': ['processing unit']}, {'element_identifier': '603', 'terms': ['transmission unit']}]","['19. An apparatus for transmitting a reference signal, wherein the apparatus is disposed in a second network device and comprises: a receiving unit, configured to receive first group information of reference signal port from a first network device, wherein the first group information comprises information about N groups of reference signal port, N is a positive integer, and N≥1; a processing unit, configured to determine a k th group of reference signal antenna port in the N groups of reference signal ports, wherein k is a positive integer, and N≥k≥1; and a transmission unit, configured to transmit a reference signal on the k th group of reference signal antenna port.']",True,"['5', '601', '602', '603', '6', '28']" 332,EP_3588830_A1 (3).png,EP3588830A1,"REFERENCE SIGNAL TRANSMITTING METHOD, RECEIVING METHOD AND DEVICE","['FIG7', ' FIG8']","['FIG8 is a schematic structural diagram of different antenna panel patterns according to an embodiment of this application ', 'FIG7 is a schematic structural diagram of an apparatus for receiving a reference signal according to an embodiment of this application']","['The antenna panel information includes at least one of a distribution structure of all antennas of the UE and a panel pattern (panel pattern), or other information. Herein the panel pattern information further includes at least one of a quantity of panels and a distribution pattern of P (P≥1) panels, or other information. The distribution pattern information of the panels may be a plurality of panel distribution patterns predefined on the base station and the user side. For example, FIG8 is a schematic structural diagram of four antenna panel patterns, where × represents a pair of reference signal antenna ports in two polarization directions, different reference signal antenna ports are distributed in different positions of the terminal device, and different antenna port panel patterns are generated.', 'As shown in FIG8, a distance between a port number 1 and a port number 2 in an antenna port panel pattern 2 (pattern 2) on a UE side is a large antenna distance (codebook configuration applicable to a large antenna distance), but a distance between a port number 1 and a port number 2 in a panel pattern 3 (pattern 3) is a small antenna distance (codebook configuration applicable to a small antenna distance). Therefore, codebook configurations corresponding to the antenna port panel pattern 2 and panel pattern 3 are different. The method provided by this embodiment is used to configure an optimal codebook for antenna ports in each panel pattern, for transmitting an uplink signal, so that uplink data transmission performance can be improved. ', 'In addition, this embodiment further provides an apparatus for receiving a reference signal. The apparatus is configured to implement the method for receiving a reference signal in the foregoing embodiment. The apparatus is disposed in a first network device, for example, a base station. As shown in FIG7, the apparatus for receiving a reference signal includes a receiving unit 701, a processing unit 702, and a transmission unit 703. In addition, the apparatus may further include other functional units or modules such as a storage unit.']",39,381,schematic structural diagram,H,"[{'element_identifier': '4', 'terms': ['panel pattern']}, {'element_identifier': '701', 'terms': ['unit']}, {'element_identifier': '702', 'terms': ['processing unit']}, {'element_identifier': '703', 'terms': ['unit']}, {'element_identifier': '3', 'terms': ['panel pattern']}]","['19. An apparatus for transmitting a reference signal, wherein the apparatus is disposed in a second network device and comprises: a receiving unit, configured to receive first group information of reference signal port from a first network device, wherein the first group information comprises information about N groups of reference signal port, N is a positive integer, and N≥1; a processing unit, configured to determine a k th group of reference signal antenna port in the N groups of reference signal ports, wherein k is a positive integer, and N≥k≥1; and a transmission unit, configured to transmit a reference signal on the k th group of reference signal antenna port.']",True,"['701', '702', '703', '7', '3', '4', '8', '29']" 333,EP_3588830_A1 (4).png,EP3588830A1,"REFERENCE SIGNAL TRANSMITTING METHOD, RECEIVING METHOD AND DEVICE",['FIG10'],['FIG10 is a schematic diagram of antenna panel patterns corresponding to different codeword structures according to an embodiment of this application'],"['As shown in FIG10, a codeword structure in the M precoding matrix sets predefined in the system is relevant to distribution of a plurality of antenna ports of the UE and antenna distances between the plurality of antenna ports. Antenna distances between four antenna ports in a same polarization direction in a panel pattern 1 (pattern 1) and a panel pattern 4 (pattern 4) are relatively large. Therefore, when the base station configures a precoding matrix set, the base station sets codewords in precoding matrix sets corresponding to the panel pattern 1 (pattern 1) and the panel pattern 4 (pattern 4) as some codewords applicable to large antenna distances. Optionally, the codewords applicable to large antenna distances may be codewords applicable to large antenna distances in a dual-codebook configuration of four antenna ports in an LTE-A system.', 'As shown in FIG10, codewords in precoding matrix sets corresponding to a panel pattern 2 (pattern 2) and a panel pattern 3 (pattern 3) are some codewords applicable to small antenna distances. For example, optionally, the codewords applicable to small antenna distances may be codewords applicable to small antenna distances in a dual-codebook configuration of four antenna ports in an LTE-A system. Further, because the antenna distances between the four antenna ports in the same polarization direction in the panel pattern 1 (pattern 1) and the panel pattern 4 (pattern 4) are different, different precoding matrix sets may be configured for the panel pattern 1 and the panel pattern 4 respectively. This is not specifically limited herein in this embodiment.']",21,299,schematic diagram,H,"[{'element_identifier': '4', 'terms': ['panel pattern']}, {'element_identifier': '3', 'terms': ['panel pattern']}, {'element_identifier': '2', 'terms': ['layer']}]","['5. The method according to any one of claims 1 to 4, wherein the receiving, by a second network device, first group information of reference signal port from a first network device comprises: receiving, by the second network device, signaling from the first network device, wherein the signaling indicates the first group information of the reference signal port; and the signaling comprises at least one of higher layer signaling, layer 1 signaling, and layer 2 signaling.']",True,"['9', '10', '2', '3', '4', '30']" 334,EP_3588830_A1 (5).png,EP3588830A1,"REFERENCE SIGNAL TRANSMITTING METHOD, RECEIVING METHOD AND DEVICE","['FIG11', ' FIG12']","['FIG11 is a schematic structural diagram of an apparatus for transmitting a signal according to an embodiment of this application ', 'FIG12 is a schematic structural diagram of an apparatus for receiving a signal according to an embodiment of this application']","['Corresponding to the method for transmitting a signal according to this embodiment of this application, this embodiment further provides an apparatus for transmitting a signal. The apparatus is disposed in a terminal device. As shown in FIG11, specifically, the apparatus includes a receiving unit 1101, a processing unit 1102, and a transmission unit 1103. ', 'Corresponding to the foregoing apparatus for transmitting a signal, this embodiment further provides an apparatus for receiving a signal. As shown in FIG12, the apparatus is disposed in a base station. Further, the apparatus includes a receiving unit 1201, a processing unit 1202, and a transmission unit 1203.']",40,118,schematic structural diagram,H,"[{'element_identifier': '12', 'terms': ['RB includes']}, {'element_identifier': '1201', 'terms': ['receiving unit']}, {'element_identifier': '1203', 'terms': ['transmission unit']}, {'element_identifier': '1101', 'terms': ['receiving unit']}, {'element_identifier': '1202', 'terms': ['processing unit']}, {'element_identifier': '1102', 'terms': ['processing unit']}, {'element_identifier': '1103', 'terms': ['transmission unit']}]","['19. An apparatus for transmitting a reference signal, wherein the apparatus is disposed in a second network device and comprises: a receiving unit, configured to receive first group information of reference signal port from a first network device, wherein the first group information comprises information about N groups of reference signal port, N is a positive integer, and N≥1; a processing unit, configured to determine a k th group of reference signal antenna port in the N groups of reference signal ports, wherein k is a positive integer, and N≥k≥1; and a transmission unit, configured to transmit a reference signal on the k th group of reference signal antenna port.']",True,"['1101', '1102', '1103', '11', '1201', '1202', '1203', '12', '31']" 335,EP_3588848_A1 (1).png,EP3588848A1,NETWORK DATA PROCESSING METHOD AND APPARATUS,"['FIG2', ' FIG3']","['FIG2 is a schematic structural diagram of a network data processing apparatus according to an embodiment of this disclosure ', 'FIG3 is a schematic structural diagram of a network data processing apparatus according to an embodiment of this disclosure']","['FIG2 is a schematic structural diagram of a network data processing apparatus according to an embodiment of this disclosure. The apparatus is applied to a base station, and the apparatus includes a receiving module 201, an adding module 202, and a sending module 203. ', 'FIG3 is a schematic structural diagram of a network data processing apparatus according to an embodiment of this disclosure. The apparatus is applied to a terminal, and the apparatus includes a sending module 301, a determining module 302, and an obtaining module 303.']",38,97,schematic structural diagram,H,"[{'element_identifier': '201', 'terms': ['receiving module']}, {'element_identifier': '202', 'terms': ['adding module']}, {'element_identifier': '203', 'terms': ['sending module']}, {'element_identifier': '303', 'terms': ['obtaining module']}, {'element_identifier': '2', 'terms': ['2Multicast IP 2G-RNTI 2CPE', 'UE']}, {'element_identifier': '302', 'terms': ['determining module']}, {'element_identifier': '301', 'terms': ['sending module']}, {'element_identifier': '3', 'terms': []}]","['16. A network data processing apparatus, applied to a base station, wherein the apparatus comprises: a receiving module, configured to receive a multicast group join request sent by a terminal, wherein the multicast group join request carries a target channel identifier, and the multicast group join request is used to request to add a terminal identifier of the terminal to a multicast group corresponding to the target channel identifier; an adding module, configured to add the terminal identifier to the multicast group corresponding to the target channel identifier, wherein the multicast group comprises an identifier of a terminal that has requested network data corresponding to the target channel identifier; and a sending module, configured to deliver the network data based on the multicast group and a group scheduling identifier corresponding to the multicast group by using an air interface resource corresponding to the multicast group, wherein a terminal in the multicast group is configured to decode the air interface resource based on the group scheduling identifier, to obtain the network data.', '18. The apparatus according to claim 16, wherein the apparatus further comprises: a determining module, configured to determine a communication resource identifier corresponding to the target channel identifier, wherein the communication resource identifier is used to determine a communication resource used by a gateway to deliver the network data to the base station; and the receiving module is further configured to receive, based on the communication resource identifier, the network data delivered by the gateway.', '24. A network data processing apparatus, applied to a terminal, wherein the apparatus comprises: a sending module, configured to send a multicast group join request to a base station, wherein the multicast group join request carries a target channel identifier, the multicast group join request is used to request to add a terminal identifier of the terminal to a multicast group corresponding to the target channel identifier, and the multicast group comprises an identifier of a terminal that has requested network data corresponding to the target channel identifier; a determining module, configured to determine a group scheduling identifier corresponding to the target channel identifier, wherein the base station is configured to deliver the network data based on the multicast group and a group scheduling identifier corresponding to the multicast group by using an air interface resource corresponding to the multicast group; and an obtaining module, configured to decode the air interface resource based on the group scheduling identifier, to obtain the network data.']",True,"['2', '2', '3', '201', '202', '203', '301', '302', '303', '30']" 336,EP_3588848_A1.png,EP3588848A1,NETWORK DATA PROCESSING METHOD AND APPARATUS,"['FIG1A', ' FIG1B', ' FIG1C']","['FIG1A is a schematic structural diagram of a network data processing system according to an embodiment of this disclosure ', 'FIG1C is a schematic diagram of a network data delivery procedure according to a related technology FIG. ID is a schematic diagram of a network data delivery procedure according to an embodiment of this disclosure ', 'FIG1B is a schematic diagram of a scenario of wireless to the x according to an embodiment of this disclosure']","['FIG1A is a schematic structural diagram of a network data processing system according to an embodiment of this disclosure. The network data processing system includes a server 101, a gateway 102, a base station 103, and a terminal 104. A data connection is established between the server 101 and the gateway 102 by using a data cable or in another manner, data communication is performed between the gateway 102 and the base station 103 by using a communication resource, and data communication is performed between the base station 103 and the terminal 104 by using an air interface resource. ', 'When network data is to be processed in a related technology, as shown in FIG1C, for a plurality of terminals that need to obtain network data on a same channel, a gateway establishes a communication resource between the gateway and a base station for each terminal. The base station establishes an air interface resource between the base station and each terminal. The gateway duplicates the network data to obtain a plurality of pieces of network data based on a quantity of terminals, and separately delivers, to the base station by using different communication resources, network data required by different terminals. The base station separately receives, by using different communication resources, network data required by different terminals, and then delivers the network data to the different terminals by using different air interface resources. ', 'Referring to FIG1B, the network data system may be applied to a scenario of wireless to the x (Wireless To The x, WTTx). The terminal is at least one CPE (two CPEs are merely used as an example in FIG1B). The base station and the at least one CPE are connected over wireless broadband, and may perform data communication by using an air interface resource provided by the wireless broadband. Each CPE and at least one UE may be connected over a Wi-Fi (Wireless-Fidelity, Wireless Fidelity) connection, or may perform data communication in another manner. When receiving the network data delivered by the base station, specific CPE may deliver the network data to the at least one connected UE. The UE displays the network data to the user.']",75,402,"schematic diagram, schematic structural diagram",H,"[{'element_identifier': '103', 'terms': ['base station']}, {'element_identifier': '2', 'terms': ['2Multicast IP 2G-RNTI 2CPE', 'UE']}, {'element_identifier': '104', 'terms': ['terminal']}, {'element_identifier': '102', 'terms': ['gateway']}, {'element_identifier': '101', 'terms': ['server']}]","['11. A network data processing method, applied to a gateway, wherein the method comprises: when network data delivered by a server is received, determining a target channel identifier corresponding to the network data; determining a communication resource identifier corresponding to the target channel identifier, wherein a base station identifier corresponding to the target channel identifier is used to determine a base station that has requested the network data corresponding to the target channel identifier, and the communication resource identifier is used to determine a communication resource between the gateway and the base station; and delivering the network data by using the communication resource, wherein the base station is configured to: determine the communication resource identifier based on the target channel identifier, receive the network data based on the communication resource identifier, and deliver the network data to a terminal that requests the network data.']",True,"['102', '103', '101', '104', '2', '2', '2', '2', '29']" 337,EP_3588877_A1 (1).png,EP3588877A1,PERFORMANCE MONITORING SUPPORT FOR CFM OVER EVPN,['FIG2'],"['FIG2 is a diagram of an example environment in which systems and/or methods, described herein, may be implemented']","['FIG2 is a diagram of an example environment 200 in which systems and/or methods, described herein, may be implemented. As shown in FIG2, environment 200 may include a user device 210, a security platform 220, a network 230, and a network device 240. Devices of environment 200 may interconnect via wired connections, wireless connections, or a combination of wired and wireless connections.', 'As further shown in FIG2, computing resource 224 includes a group of cloud resources, such as one or more applications (""APPs"") 224-1, one or more virtual machines (""VMs"") 224-2, virtualized storage (""VSs"") 224-3, one or more hypervisors (""HYPs"") 224-4, and/or the like.', 'The number and arrangement of devices and networks shown in FIG2 are provided as an example. In practice, there may be additional devices and/or networks, fewer devices and/or networks, different devices and/or networks, or differently arranged devices and/or networks than those shown in FIG2. Furthermore, two or more devices shown in FIG2 may be implemented within a single device, or a single device shown in FIG2 may be implemented as multiple, distributed devices. Additionally, or alternatively, a set of devices (e.g., one or more devices) of environment 200 may perform one or more functions described as being performed by another set of devices of environment 200.']",20,270,diagram,H,"[{'element_identifier': '15', 'terms': ['clause']}, {'element_identifier': '215', 'terms': ['network', 'networks']}, {'element_identifier': '200', 'terms': ['environment']}]","['1. A method, comprising: providing, by a first provider edge (PE) device, a route advertisement, the first PE device being part of an Ethernet virtual private network (EVPN), and being multihomed to by a first customer edge (CE) device, a first attachment circuit being established between the first PE device and the first CE device, the route advertisement including a media access control (MAC) address, corresponding to the first attachment circuit, that is utilized as a connectivity fault management (CFM) MAC address for a maintenance endpoint (MEP) configured on the first attachment circuit; receiving, by a second PE device, the route advertisement, the second PE device being part of the EVPN, and being communicatively coupled to a second CE device, a second attachment circuit being established between the second PE device and the second CE device, the second PE device being configured to monitor connectivity between the second attachment circuit and the first attachment circuit; and causing, by the second PE device, traffic, relating to monitoring the connectivity, to be directed to the first PE device and/or to the first attachment circuit based on the route advertisement, the traffic not being provided to any other PE device, on the EVPN, that is multihomed to by the first CE device.']",False,"['200', '215', '15']" 338,EP_3588877_A1 (2).png,EP3588877A1,PERFORMANCE MONITORING SUPPORT FOR CFM OVER EVPN,['FIG3'],['FIG3 is a diagram of example components of one or more devices of FIG2'],"['FIG3 is a diagram of example components of a device 300. Device 300 may correspond to user device 210, security platform 220, computing resource 224, and/or network device 240. In some implementations, user device 210, security platform 220, computing resource 224, and/or network device 240 may include one or more devices 300 and/or one or more components of device 300. As shown in FIG3, device 300 may include a bus 310, a processor 320, a memory 330, a storage component 340, an input component 350, an output component 360, and a communication interface 370.', 'The number and arrangement of components shown in FIG3 are provided as an example. In practice, device 300 may include additional components, fewer components, different components, or differently arranged components than those shown in FIG3. Additionally, or alternatively, a set of components (e.g., one or more components) of device 300 may perform one or more functions described as being performed by another set of components of device 300.']",14,193,diagram,H,"[{'element_identifier': '310', 'terms': ['switching component']}, {'element_identifier': '300', 'terms': ['device', 'devices']}, {'element_identifier': '320', 'terms': ['controller']}]","['1. A method, comprising: providing, by a first provider edge (PE) device, a route advertisement, the first PE device being part of an Ethernet virtual private network (EVPN), and being multihomed to by a first customer edge (CE) device, a first attachment circuit being established between the first PE device and the first CE device, the route advertisement including a media access control (MAC) address, corresponding to the first attachment circuit, that is utilized as a connectivity fault management (CFM) MAC address for a maintenance endpoint (MEP) configured on the first attachment circuit; receiving, by a second PE device, the route advertisement, the second PE device being part of the EVPN, and being communicatively coupled to a second CE device, a second attachment circuit being established between the second PE device and the second CE device, the second PE device being configured to monitor connectivity between the second attachment circuit and the first attachment circuit; and causing, by the second PE device, traffic, relating to monitoring the connectivity, to be directed to the first PE device and/or to the first attachment circuit based on the route advertisement, the traffic not being provided to any other PE device, on the EVPN, that is multihomed to by the first CE device.']",False,"['300', '320', '16', '310']" 339,EP_3588877_A1.png,EP3588877A1,PERFORMANCE MONITORING SUPPORT FOR CFM OVER EVPN,['FIG1'],['FIG1 is a diagram of an example implementation described herein'],"['FIG1 is a diagram of an example implementation 100 described herein. As shown in FIG1, example implementation 100 may include an EVPN associated with multiple CE devices, including CE1, CE2, CE3, and CE4, and multiple PE devices, including PE1, PE2, and PE3 configured to function as MEPs (e.g., MEP 1, MEP 2, and MEP 3). As shown, an attachment circuit 1, may be established between PE1 and CE1, an attachment circuit 2, may be established between PE1 and CE2, and an attachment circuit 3, may be established between PE2 and CE2. As further shown, an attachment circuit 4, may be established between PE3 and CE3, and an attachment circuit 5, may be established between PE3 and CE4. Here, CE2 may be multihomed to PE1 and PE2 in an all-active redundancy mode.', 'As indicated above, FIG1 is provided merely as an example. Other examples are possible and may differ from what was described with regard to FIG1.']",10,192,diagram,H,"[{'element_identifier': '5', 'terms': ['attachment circuit']}, {'element_identifier': '14', 'terms': ['clause', 'clauses']}, {'element_identifier': '1', 'terms': ['attachment circuit']}, {'element_identifier': '130', 'terms': ['reference number']}, {'element_identifier': '100', 'terms': ['example implementation']}, {'element_identifier': '4', 'terms': ['attachment circuit']}, {'element_identifier': '2', 'terms': ['Type']}, {'element_identifier': '110', 'terms': ['reference number']}, {'element_identifier': '3', 'terms': ['attachment circuit']}, {'element_identifier': '120', 'terms': ['reference number']}]","['1. A method, comprising: providing, by a first provider edge (PE) device, a route advertisement, the first PE device being part of an Ethernet virtual private network (EVPN), and being multihomed to by a first customer edge (CE) device, a first attachment circuit being established between the first PE device and the first CE device, the route advertisement including a media access control (MAC) address, corresponding to the first attachment circuit, that is utilized as a connectivity fault management (CFM) MAC address for a maintenance endpoint (MEP) configured on the first attachment circuit; receiving, by a second PE device, the route advertisement, the second PE device being part of the EVPN, and being communicatively coupled to a second CE device, a second attachment circuit being established between the second PE device and the second CE device, the second PE device being configured to monitor connectivity between the second attachment circuit and the first attachment circuit; and causing, by the second PE device, traffic, relating to monitoring the connectivity, to be directed to the first PE device and/or to the first attachment circuit based on the route advertisement, the traffic not being provided to any other PE device, on the EVPN, that is multihomed to by the first CE device.', '4. The method of any preceding claim, wherein the route advertisement includes a Type 2 route advertisement, and/or does not advertise reachability of the first attachment circuit based on an Ethernet segment identifier (ESI).']",False,"['100', '1', '2', '120', '3', '5', '3', '110', '3', '4', '130', '4', '3', '14', '4', '3', '1']" 340,EP_3588891_A1 (2).png,EP3588891A1,DATA ROUTING METHOD AND APPARATUS,['FIG5'],['FIG5 is a schematic structural diagram of a processing unit according to an embodiment of this application'],"['In the foregoing apparatus, the processing unit 402 may be divided into a route unit (Route), a separation unit (DeMUX), and a packet assembly unit (MUX) based on a logical function, which are shown in FIG5.']",17,47,schematic structural diagram,H,"[{'element_identifier': '5', 'terms': ['step']}, {'element_identifier': '400', 'terms': ['routing apparatus']}, {'element_identifier': '4', 'terms': ['step']}, {'element_identifier': '403', 'terms': ['output port', 'output ports']}, {'element_identifier': '402', 'terms': ['processing unit']}, {'element_identifier': '401', 'terms': ['input port', 'input ports']}]","['10. A routing apparatus, wherein the apparatus comprises an input port, a processing unit, and an output port; wherein the input port is configured to receive data; the processing unit is configured to: determine a data bearer protocol attribute of the input port; and determine, based on the data bearer protocol attribute of the input port, an attribute of the data received by the input port, wherein when the data bearer protocol attribute of the input port is the common public radio interface CPRI protocol, the attribute of the data is an Internet Protocol IP attribute or an in-phase/quadrature IQ attribute, or when the data bearer protocol attribute of the input port is the Ethernet protocol, the attribute of the data is an IP attribute; determine, based on the attribute of the data, the data bearer protocol attribute of the output port used to output the data, wherein when the attribute of the data is the IP attribute, the data bearer protocol attribute of the output port is the CPRI protocol or the Ethernet protocol, or when the attribute of the data is the IQ attribute, the data bearer protocol attribute of the output port is the CPRI protocol; determine, based on the data bearer protocol attribute of the output port, the output port used to output the data; and send, to the determined output port, the data received from the input port; and the output port is configured to output the data sent by the processing unit.']",True,"['400', '401', '402', '403', '4', '402', '5', '22']" 341,EP_3588897_B1 (1).png,EP3588897B1,METHOD AND SYSTEM FOR DEFENDING AN INFRASTRUCTURE AGAINST A DISTRIBUTED DENIAL OF SERVICE ATTACK,['FIG2'],['FIG2 is a block diagram of an infrastructure implementing a method and a system for defending against a DDoS attack in accordance with an embodiment of the present technology'],"['Referring now to the drawings, FIG2 is a block diagram of an infrastructure implementing a method and a system for defending against a DDoS attack in accordance with an embodiment of the present technology. An infrastructure 100 may for example represent a data center, or a plurality of data centers, providing hosting services for one or more customers. In the example of FIG2, a game server 110 owned by a customer of the infrastructure operator is hosted in the infrastructure 100. It will be appreciated that the infrastructure 100 may include a large number of servers for hosting services for a large number of customers and that the infrastructure 100 may be distributed over a plurality of datacenters (not shown) for redundancy, reliability and/or load sharing purposes. The datacenters forming the infrastructure 100 may be geographically distributed, for example worldwide. The illustrated infrastructure 100 of FIG2 is heavily simplified for ease of illustration.']",29,167,block diagram,G,"[{'element_identifier': '12', 'terms': ['server']}, {'element_identifier': '22', 'terms': ['ports']}, {'element_identifier': '18', 'terms': ['devices', 'bots']}, {'element_identifier': '100', 'terms': ['infrastructure']}, {'element_identifier': '130', 'terms': ['C&C data collector']}, {'element_identifier': '2', 'terms': ['two']}, {'element_identifier': '140', 'terms': ['client']}, {'element_identifier': '110', 'terms': ['game server']}, {'element_identifier': '150', 'terms': ['cleaning component']}, {'element_identifier': '120', 'terms': ['software decoy', 'software decoys']}]","['1. A method for defending an infrastructure (100) against a distributed denial of service, DDoS, attack, comprising: receiving (420), at a software decoy (120) of the infrastructure (100), a malware intended to infect the software decoy (120); receiving the malware from the software decoy (120) at a command and control, C&C, data collector (130) of the infrastructure (100); and extracting (425) from the malware, by the C&C data collector (120), an address or a domain name of a C&C server (12); characterized in that the method further comprises: sending, from the C&C data collector (130) to a client (140) of the infrastructure (100), the address or the domain name of the C&C server (12); using (430), by the client (140), the address or the domain name of the C&C server (12) to connect the client (140) to the C&C server (12); receiving (435), at the client (140), a command intended by the C&C server (12) to cause the client (140) to participate in the DDoS attack; forwarding (440) particulars of the DDoS attack from the client (140) to a cleaning component (150) of the infrastructure (100); and discarding (450), in the cleaning component (150), incoming signals having at least one of the particulars of the DDoS attack.']",False,"['100', '110', '18', '150', '12', '22', '120', '18', '130', '140', '2']" 342,EP_3588899_A1 (2).png,EP3588899A1,NATIVE SINGLE SIGN-ON (SSO) FOR MOBILE APPLICATIONS,['FIG3'],['FIG3 is a schematic block diagram illustrating components of an exemplary system in accordance with some embodiments of the present disclosure'],"[""FIG3 is a block diagram illustrating the components for performing the systems and methods discussed herein. FIG3 includes an authorization server 300 (such as authorization server 106), network 315 (such as network 105), a shared security mechanism 320 as well as first and second mobile applications 330 and 335 (e.g., mobile applications 244 and 245). The authorization server 300 can be a special purpose machine or processor and could be hosted by a messaging server, application server, content server, social networking server, web server, search server, content provider, email service provider, ad server, user's computing device, and the like, or any combination thereof."", 'According to some embodiments, a database can be associated with the authorization server 300 (which is not shown in FIG3) and such a database can include information associated with content providers, such as, but not limited to, messaging platforms, applications, sites, or providers that enable users to send, receive, search for, upload, download, share, edit or otherwise avail users to content (e.g., Yahoo!® Search, Yahoo!® Mobile applications, Yahoo!® Mail, Flickr®, Tumblr®, Twitter®, Instagram®, SnapChat®, Facebook®, and the like). In some embodiments, such a database can comprise data and metadata associated with such information from one and/or an assortment of media hosting sites. In some embodiments, such content provider information can include, but is not limited to, versions, types and/or capabilities of applications that are resident or accessed by a user device, and/or are capable of being downloaded, executed, accessed or run on user device for purposes of rendering content.']",21,327,schematic block diagram,G,"[{'element_identifier': '335', 'terms': ['applications', 'application']}, {'element_identifier': '300', 'terms': ['server']}, {'element_identifier': '315', 'terms': ['network']}, {'element_identifier': '320', 'terms': ['shared security mechanism']}, {'element_identifier': '330', 'terms': ['applications', 'application']}]","['1. A method for enhanced single sign-on for mobile applications, the method comprising: requesting, by a first mobile application, an authorization server to return a connector code; receiving, by the first mobile application, the connector code with at least one token from a remote server; storing in a shared security mechanism, by the first mobile application, the at least one token; searching, by a second mobile application, in the shared security mechanism for the at least one token; and using, by the second mobile application, a profile to obtain a token for the second mobile application based on the at least one token and the connector code.']",False,"['330', '315', '300', '320', '335', '23']" 343,EP_3588907_A2 (2).png,EP3588907A2,"INFORMATION PROCESSING APPARATUS, CONTROL METHOD FOR INFORMATION PROCESSING APPARATUS, AND STORAGE MEDIUM",['FIG3'],['FIG3 is a block diagram illustrating software modules included in the multifunction peripheral according to the first exemplary embodiment'],"['FIG3 is a block diagram illustrating software modules included in the multifunction peripheral 100 according to the first exemplary embodiment. Furthermore, the software modules illustrated in FIG3 are implemented by the CPU 201 executing programs loaded onto the RAM 203.']",19,43,block diagram,G,"[{'element_identifier': '310', 'terms': ['device control unit']}, {'element_identifier': '307', 'terms': ['certificate management unit']}, {'element_identifier': '306', 'terms': ['encryption processing unit']}, {'element_identifier': '100', 'terms': ['multifunction peripheral', 'multifunction peripherals']}, {'element_identifier': '303', 'terms': ['communication control unit']}, {'element_identifier': '304', 'terms': ['web page control unit']}, {'element_identifier': '302', 'terms': ['network control unit']}, {'element_identifier': '301', 'terms': ['network driver']}, {'element_identifier': '309', 'terms': ['reading processing unit']}, {'element_identifier': '308', 'terms': ['control unit']}, {'element_identifier': '110', 'terms': ['network']}, {'element_identifier': '305', 'terms': ['certificate acquisition control unit']}]","['1. An information processing apparatus (100) capable of connecting to an external apparatus (102) via a network (110), the information processing apparatus comprising: setting means for enabling a function of transmitting an issuance request for a digital certificate to the external apparatus in accordance with a previously designated schedule, and for acquiring a digital certificate from the external apparatus in response to the issuance request, wherein the setting means is adapted to enable the function under a condition that information required for connection to the external apparatus is previously input.']",False,"['304', '303', '302', '301', '100', '305', '308', '309', '310', '307', '306', '110', '20']" 344,EP_3588907_A2 (6).png,EP3588907A2,"INFORMATION PROCESSING APPARATUS, CONTROL METHOD FOR INFORMATION PROCESSING APPARATUS, AND STORAGE MEDIUM",['FIG15'],"['FIG15 is a diagram illustrating an example of a web page screen of the RUI, which is displayed by the PC according to the first exemplary embodiment']","['FIG15 illustrates an example of a screen which is displayed in a case where, when the issuance and acquisition of a certificate are successful, displaying of a key pair and digital certificate list is performed again by processing in step S401, and, in the illustrated example, information 1501 about a certificate (Xyz4) issued by the certificate authority and registration authority 102 is added.']",28,71,diagram,G,"[{'element_identifier': '1501', 'terms': ['information']}]","['1. An information processing apparatus (100) capable of connecting to an external apparatus (102) via a network (110), the information processing apparatus comprising: setting means for enabling a function of transmitting an issuance request for a digital certificate to the external apparatus in accordance with a previously designated schedule, and for acquiring a digital certificate from the external apparatus in response to the issuance request, wherein the setting means is adapted to enable the function under a condition that information required for connection to the external apparatus is previously input.']",False,"['1501', '32']" 345,EP_3588907_A2.png,EP3588907A2,"INFORMATION PROCESSING APPARATUS, CONTROL METHOD FOR INFORMATION PROCESSING APPARATUS, AND STORAGE MEDIUM",['FIG1'],['FIG1 is a diagram illustrating a network configuration according to a first exemplary embodiment of the present invention'],"['FIG1 is a diagram illustrating a network configuration according to a first exemplary embodiment of the present invention. A multifunction peripheral 100, which has a printing function, is capable of connecting to another information processing apparatus via a network 110. The multifunction peripheral 100 is able to perform transmission and reception of, for example, print data, scanned image data, and management information for devices between another information processing apparatus and the multifunction peripheral 100 via the network 110. Moreover, the multifunction peripheral 100 has the function of performing enciphered communication using, for example, Transport Layer Security (TLS), Internet Protocol Security (IPsec), or IEEE 802.1X, and retains a public key pair and a digital certificate for use in cryptography processing therefor. Here, the multifunction peripheral 100 is an example of an image forming apparatus, and the image forming apparatus is not limited to this but can be an apparatus which has only one of the functions of a facsimile apparatus, a printer, and a copying machine or has a composite function including all or some of those functions. A multifunction peripheral 101 is also connected to the network 110, and the multifunction peripheral 101 has a function equivalent to that of the multifunction peripheral 100. In the following description, the multifunction peripheral 100 is mainly described, but a plurality of multifunction peripherals can be assumed to be targeted for communication of a digital certificate.']",18,263,diagram,G,"[{'element_identifier': '103', 'terms': ['PC']}, {'element_identifier': '100', 'terms': ['multifunction peripheral', 'multifunction peripherals']}, {'element_identifier': '102', 'terms': ['registration authority']}, {'element_identifier': '101', 'terms': ['multifunction peripherals', 'multifunction peripheral']}, {'element_identifier': '110', 'terms': ['network']}]","['1. An information processing apparatus (100) capable of connecting to an external apparatus (102) via a network (110), the information processing apparatus comprising: setting means for enabling a function of transmitting an issuance request for a digital certificate to the external apparatus in accordance with a previously designated schedule, and for acquiring a digital certificate from the external apparatus in response to the issuance request, wherein the setting means is adapted to enable the function under a condition that information required for connection to the external apparatus is previously input.']",False,"['102', '103', '110', '101', '100', '18']" 346,EP_3588914_A1 (2).png,EP3588914A1,"DATA STORAGE METHOD, ENCODING DEVICE AND DECODING DEVICE",['FIG3'],['FIG3 is a schematic diagram of a data dividing process according to some embodiments of the present disclosure'],"['In the disclosed embodiment, the encoding device may acquire the to-be-transmitted data from the server, and divide the to-be-transmitted data into blocks based on the content. In actual applications, the data may be divided into blocks using a Rabin fingerprint algorithm. Specifically, referring to FIG3, the data may comprise a plurality of characters, which may be 8-bit binary numbers. When dividing the data into blocks, a data sliding window may be employed to slide from the beginning to the end of the data according to a fixed step length, and the Rabin fingerprint of the data blocks in each data sliding window is calculated one by one. If the calculated fingerprint value is the same as a predefined fingerprint value, the ending position of the present data sliding window may be used as a data block dividing position. For example, in FIG3, the data sliding window may slide to the right one character at a time, where the fingerprint k for the data blocks in the k window is the same as the predefined fingerprint value. The ending position (the dashed line position in the figure) of the k window may thus be set as a dividing position for dividing data blocks. Eventually, when the data sliding window moves to the end of the data, the block dividing process may be completed. In this way, through the block dividing process, the data may be divided into a plurality of data blocks.']",18,278,schematic diagram,G,"[{'element_identifier': '2', 'terms': ['feature']}]","['4. The method according to claim 1, after storing the set of data blocks in the to-be-confirmed queue that correspond to the confirmation message in the predefined database, the method further includes: extracting a feature index of a piece of stream data where a data block corresponding to the confirmation message is located, writing the feature index into a memory, and backing up and storing the backup on a hard drive.']",False,"['2', '16']" 347,EP_3588921_A1 (2).png,EP3588921A1,SCREEN BACKLIGHT CONTROL METHOD AND MOBILE TERMINAL,['FIG3B'],['FIG3B is a schematic structural diagram illustrating a mobile terminal according to an implementation of the present disclosure'],"['When the processing unit 302 is the processor, the communication unit 303 is the communication interface, and the storage unit 301 is the memory, then the mobile terminal involved in the implementation of the present disclosure may be a mobile terminal illustrated in FIG3B.', 'Referring to FIG3B, a mobile terminal 310 includes a processor 312, a transceiver 313, and a memory 311. The mobile terminal 310 may further include a bus 314. The processor 312 is coupled with the transceiver 313 and the memory 311 via the bus 314. The bus 314 may be a peripheral component interconnect (PCI) bus, an extended industry standard architecture (EISA) bus, or the like. The bus 314 may be an address bus, a data bus, a control bus, and so on. For simple illustration, in FIG3B, the bus 314 is indicated only by a thick line, but it does not indicate that only one bus or only one type of buses are included.']",18,184,schematic structural diagram,G,"[{'element_identifier': '313', 'terms': ['transceiver']}, {'element_identifier': '303', 'terms': ['communication unit']}, {'element_identifier': '301', 'terms': ['storage unit']}, {'element_identifier': '302', 'terms': ['processing unit']}, {'element_identifier': '300', 'terms': ['mobile terminal']}, {'element_identifier': '312', 'terms': ['processor']}]","['11. A mobile terminal, the mobile terminal being in screen-off status, the mobile terminal comprising a fingerprint module and a processing unit: the processing unit being configured to: detect, based on that a system wake-up event is detected via system wake-up meta service of the mobile terminal, whether a TouchDown event exists via FingerService of the mobile terminal, the TouchDown event being generated in response to a touch operation on the fingerprint module; detect, in response to that the TouchDown event is detected via the FingerService, whether a screen backlight is lit up upon elapse of a preset period, the preset period being longer than duration of fingerprint unlocking processing performed in response to the TouchDown event by the mobile terminal; and discard the system wake-up event in response to that the screen backlight is lit up.', '20. A mobile terminal comprising: a processor; a memory; a transceiver; and a bus; the processor being coupled with the memory and the transceiver via the bus; the memory storing executable program codes; the processor being configured to invoke the executable program codes in the memory to perform the method of any of claims 1 to']",True,"['300', '301', '302', '303', '312', '313', '14', '14']" 348,EP_3588924_A1 (1).png,EP3588924A1,"AN APPARATUS, SYSTEM AND METHOD OF CALL NOTIFICATIONS TO ACTIVE COMMUNICATION DEVICES",['FIG2'],"['FIG2 depicts an apparatus for call notifications to active communication devices, according to non-limiting implementations']","['Attention is directed to FIG2, which depicts a schematic diagram of a device 103-1 according to non-limiting implementations. It should be emphasized that the structure in FIG2 is purely exemplary, and contemplates a device that can be used for both wireless voice (e.g. telephony), video and wireless data communications (e.g. email, web browsing, text, and the like). Device 103-1 comprises at least one input device 200 generally enabled to receive input data, and can comprise any suitable combination of input devices, including but not limited to a keyboard, a keypad, a pointing device, a mouse, a track wheel, a trackball, a touchpad, a touch screen and the like. Other suitable input devices are within the scope of present implementations.']",18,148,schematic,H,"[{'element_identifier': '230', 'terms': ['video camera']}, {'element_identifier': '216', 'terms': ['volatile storage']}, {'element_identifier': '218', 'terms': ['data']}, {'element_identifier': '208', 'terms': ['processor']}, {'element_identifier': '228', 'terms': ['interface']}, {'element_identifier': '226', 'terms': ['microphone']}, {'element_identifier': '224', 'terms': ['display']}, {'element_identifier': '231', 'terms': ['motion sensor']}, {'element_identifier': '200', 'terms': ['input device']}, {'element_identifier': '212', 'terms': ['non-volatile storage unit']}, {'element_identifier': '229', 'terms': ['speaker']}]","['1. A communication device (103a-1) comprising: a processor (208), a communication interface (228) and a motion sensor (231), the processor (208) enabled to: receive (501, 1101) a call via the communication interface (228); determine (503, 1103) an indication of activity of the communication device (103a-1) based on motion detected using the motion sensor (231); detect a link (1208) between the communication device (103a-1) and a second communication device (103a-2); and based on the indication of activity of the communication device (103a-1) and the link (1208) between the communication device (103a-1) and a second communication device (103a2) transmit (507, 1107) a notification (1203) of the call to the second device (103a-2) for transferring the call to the second device (103a-2) via the link (1208).']",False,"['228', '230', '226', '229', '224', '200', '231', '208', '216', '212', '218', '2', '15']" 349,EP_3588948_A1 (3).png,EP3588948A1,"METHOD OF ADAPTIVE FILTERING FOR MULTIPLE REFERENCE LINE OF INTRA PREDICTION IN VIDEO CODING, VIDEO ENCODING APPARATUS AND VIDEO DECODING APPARATUS THEREWITH",['FIG6'],['FIG6 is a flowchart illustrating a method of adaptive filtering for an MRL of intra prediction in video coding according to the disclosure'],"['Referring to FIG6, which is a flowchart illustrating a method of adaptive filtering for an MRL of intra prediction in video coding according to the disclosure, HEVC provides a mode-dependent reference sample smoothing method, and the JEM further provides a method for improving the smoothness of a reference sample, which is called an RSAF. Two low pass filters (LPFs) are used during smoothing of reference samples.', 'One implementation example of the disclosure provides an Adaptive Reference Filtering Scheme (ARFS). As shown in FIG6, with reference to a plurality of reference filters such as a filter 1 622, a filter 2 624 and a filter T 626 included in a reference smoothing module 620, the filter may be selected corresponding to a filter index 604, the filtering operation is skipped or bypass, filtering is not performed, or an input sample is directly output as a filtered sample.']",23,167,flowchart,H,"[{'element_identifier': '620', 'terms': ['reference smoothing module']}, {'element_identifier': '626', 'terms': ['filter T']}, {'element_identifier': '606', 'terms': ['input samples']}, {'element_identifier': '2', 'terms': ['P']}, {'element_identifier': '6', 'terms': ['Mode']}, {'element_identifier': '604', 'terms': ['filter index']}, {'element_identifier': '602', 'terms': ['RT index']}, {'element_identifier': '608', 'terms': ['filtered samples']}, {'element_identifier': '610', 'terms': ['filter selection process']}]","['1. A method of adaptive filtering for intra prediction, comprising: receiving an index, and performing filter selection according to the index to generate a filter index corresponding to the index; and selecting a filter corresponding to the filter index, filtering an input sample by using the filter to generate a filtered sample and outputting the filtered sample, or directly outputting the input sample as the filtered sample.']",False,"['606', '622', '624', '2', '602', '610', '604', '608', '25', '626', '620', '6']" 350,EP_3588959_A1 (3).png,EP3588959A1,TRANSCODING METHOD AND DEVICE FOR AUDIO-VIDEO STREAM,['FIG6'],['FIG6 illustrates a structural schematic of a computer terminal according to embodiments of the present invention '],"['Referring to FIG6, in the present disclosure, the technical solution in the above-mentioned embodiments may be applied to the computer terminal 10 shown in FIG6. The computer terminal 10 may include one or more (only one is shown) processors 102 (the processor 102 may include, but not limited to, a microprocessor, a microcontroller unit (MCU) or a programmable logic device FPGA (field programmable gate array)), a memory 104 used to store data, a transmission module 106 used for communication functions. Those skilled in the art may understand that the structure shown in FIG6 is merely illustrative and are not intended to limit the structure of the above electronic device. For example, the computer terminal 10 may further include more or less components than shown in FIG6 or have different configurations from shown in FIG6.']",16,156,schematic,H,"[{'element_identifier': '102', 'terms': ['processor', 'processors']}, {'element_identifier': '10', 'terms': ['computer terminal']}, {'element_identifier': '104', 'terms': ['memory']}, {'element_identifier': '6', 'terms': ['andFIG.']}]","['13. A device of transcoding audio/video streams, wherein the device includes: a memory and a processor, wherein the memory is configured to store computer programs, and when executing the computer programs, the processor is configured to perform the transcoding method according to any of claims 1 to']",False,"['10', '102', '104', '6', '12']" 351,EP_3588960_A1 (6).png,EP3588960A1,GUARANTEED DATA COMPRESSION,['FIG13B'],['FIG13B is a schematic diagram of a hardware implementation of the method of FIG13A'],"['An adjustment value is then determined (block 1204) based on the input n-bit number, N, and, as described below, this may be implemented using a number of AND and OR gates in the look-up logic unit 1224. These AND and OR logic gates (or alternative logic arrangement that is functionally equivalent) compare a plurality of pre-determined subsets of the bits of N with pre-determined values in fixed-function circuitry and based on the outcome of the comparisons, determine an adjustment value which is then added to the replicated value (from block 1302 and replication hardware unit 1322) in the increment/decrement unit 1226 (block 1306). The value of the adjustment value is either zero, one, or minus one. In some examples, i.e. for some combinations of values of n and m (where nm, the method comprising: truncating, in a truncation hardware unit (1222), the input n-bit number from n-bits to m-bits to form an intermediate m-bit number (1202); in a look-up logic hardware unit (1224): (i) comparing pre-determined subsets of the bits of the input n-bit number with pre-determined values in fixed-function circuitry, and (ii) setting an adjustment value in dependence on the results of the comparisons; and adding, in an increment/decrement hardware unit (1226), the adjustment value to the intermediate m-bit number to generate the output m-bit number (1206).', '3. A method of mapping an input n-bit number to an output m-bit number, where n and m are integers and n VC2 > VC3 > VC4). Note that, the parasitic capacitance is generated not only between the layers of the conductor 31 but also between portions adjacent to each other in the same layer of conductor 31, but since there is substantially no potential difference in parasitic capacitance between these portions, this may be neglected. ', 'Since the parasitic capacitance is generated between the layers of the conductor 31 in this manner, in the power transmitting coil 3 according to the first embodiment, as illustrated in FIG4, an insulating member 32 is provided between the layers of the conductor 31. In FIG4, the insulating member 32 is formed to have a uniform thickness. The insulating member 32 is formed of a material having a low dielectric constant, for example, a material such as acrylic, glass epoxy, carbon fiber reinforced plastic (CFRP), polyimide, or resin.']",41,241,"cross-sectional view, view",H,"[{'element_identifier': '31', 'terms': ['conductor']}, {'element_identifier': '3', 'terms': ['power transmitting coil']}, {'element_identifier': '4', 'terms': ['power receiving coil']}, {'element_identifier': '32', 'terms': ['insulating member']}]",['1. A resonance-type power transfer coil comprising: a conductor wound into a multiple-layered helical shape; and an insulating member provided between layers of the conductor.'],True,"['4', '3', '32', '200002000', '31']" 529,EP_3594981_A1.png,EP3594981A1,AN EARTHING SWITCH,['FIG1'],['FIG1 shows a schematic representation of an example of an earthing switch'],"['FIG1 shows an example of an earthing switch 10, where optional features are shown in dashed form. The earthing switch 10 comprises a housing 20, a connector 30, a movable contact 45 and an earth terminal 40. The housing 20 is configured to form an insulating shell of the earthing switch 10. The connector 30 is configured to connect to a Medium Voltage MV cable 70. The connector 30 is configured also to enable an electrical connection 50 to a core 80 of the MV cable 70 to extend at least partially through the connector 30. The electrical connection 50 can be the core 80 of the MV cable itself or a separate conductor to which the core 80 of the MV cable 70 is connected. The connector 30 is configured also to enable an outer layer 90 of the MV cable 70 to extend at least partially over the connector 30. The earth terminal 40 extends through the housing 20, and a part of the earth terminal 40 that is external to the insulating shell is configured to electrically connect to Earth potential. When the MV cable 70 is connected to the earthing switch 10, the earthing switch 10 is configured to operate in two modes. In a first mode of operation the electrical connection 50 that extends at least partially through the connector 30 is not connected to a part of the earth terminal 40 internal to the insulating shell. This means that the earthing switch 10 is open and the core 50 of the MV cable 70 is insulated from Earth potential. In a second mode of operation the electrical connection 50 that extends at least partially through the connector 30 is connected to the part of the earth terminal 40 internal to the insulating shell. This means that the earthing switch is closed and the core 50 of the MV cable 70 is electrically connected to Earth potential. The position of the movable contact 45 inside the earthing switch defines the present mode of operation.']",12,358,schematic,H,"[{'element_identifier': '150', 'terms': ['extending step']}, {'element_identifier': '30', 'terms': ['connector']}, {'element_identifier': '160', 'terms': ['extending']}, {'element_identifier': '130', 'terms': ['extending step']}, {'element_identifier': '45', 'terms': ['movable contact']}, {'element_identifier': '20', 'terms': ['housing']}, {'element_identifier': '40', 'terms': ['terminal']}, {'element_identifier': '10', 'terms': ['earthing switch']}, {'element_identifier': '50', 'terms': ['contact']}, {'element_identifier': '140', 'terms': ['extending step']}, {'element_identifier': '110', 'terms': ['forming step']}, {'element_identifier': '60', 'terms': ['outer layer']}, {'element_identifier': '170', 'terms': ['electrically connecting']}, {'element_identifier': '120', 'terms': ['connecting step']}]","['15. A method (100) of providing an earthing switch, comprising: a) forming (110) an insulating shell of a housing (20) of an earthing switch (10); c) connecting (120) a Medium Voltage MV cable (70) to a connector (30) of the earthing switch; d) extending (130) an electrical connection (50) that is connected to a core (50, 80) of the MV cable at least partially through the connector; e) extending (140) an outer layer (90) of the MV cable at least partially over the connector; g) extending (150) an earthed terminal (40) through the housing,wherein a part of the earthed terminal that is external to the insulating shell is electrically connect to Earth potential; and wherein a movable contact (45) that is inside the earthing switch is electrically connected to the earthed terminal, and wherein the method of providing an earthing switch comprises two modes of operation: • in a first mode of operation the electrical connection to the core of the MV cable that extends at least partially through the connector is not connected to the movable contact internal to the insulating shell to insulate the core of the MV cable from Earth potential; and • in a second mode of operation the electrical connection to the core of the MV cable that extends at least partially through the connector is connected to the movable contact internal to the insulating shell to electrically connect the core of the MV cable to Earth potential.']",True,"['50', '10', '30', '45', '20', '40', '60', '1', '110', '160', '120', '130', '140', '170', '150']" 530,EP_3594992_A1 (1).png,EP3594992A1,ION TRAP DEVICE,['FIG2'],"['FIG2 is a sectional view showing a schematic configuration of the heatsinks, heaters, temperature sensors and switching elements in the same embodiment']","['The main power unit 4 further includes a first heatsink 93a and a second heatsink 93b as the characteristic components of the present invention. Both heatsinks 93a and 93b are made of aluminum nitride, which is a highly heat-conductive ceramic material. The first heatsink 93a is attached to the first switching element 45, while the second heatsink 93b is attached to the second switching element 46. FIG2 shows a cross sectional structure of these heatsinks. Each of the heatsinks 93a and 93b has a rectangular parallelpiped base portion 96a or 96b with a plurality of plate-shaped fins 97a or 97b standing on its upper surface. The base portion 96a or 96b has cavities extending from its side surface inwards, with a sheet heater 94a or 94b and a temperature sensor 95a or 95b inserted into those cavities, respectively. Although the heater 94a or 94b in FIG2 is located above the temperature sensor 95a or 95b, their positional relationship is not limited to this one. For example, the temperature sensor 95a or 95b may be located at a lateral side of the heater 94a or 94b. The heater 94a or 94b may be integrally formed with the heatsink 93a or 93b by sintering the aluminum nitride after embedding the heater 94a or 94b in the base portion 96a or 96b in the production process of the heatsink 93a or 93b. The temperature sensors 95a and 95b as well as the heaters 94a and 94b are individually connected to the temperature control unit 9.']",24,272,sectional view,H,"[{'element_identifier': '46', 'terms': ['switching elements', 'switching element']}, {'element_identifier': '2', 'terms': ['ion trap']}, {'element_identifier': '45', 'terms': ['switching elements', 'switching element']}, {'element_identifier': '11', 'terms': ['laser-beam generator']}]","['1. An ion trap device, comprising: a) an ion trap including a plurality of electrodes; b) a rectangular voltage generator including a voltage source for generating a direct voltage and a switching section, the rectangular voltage generator configured to operate the switching section to generate a rectangular voltage by switching the direct voltage generated by the voltage source, and to apply the rectangular voltage to at least one of the plurality of electrodes; and c) a switching section temperature controller configured to control a temperature of the switching section so as to maintain the temperature of the switching section at a target temperature which is higher than a highest reaching temperature of the switching section during an operation of the ion trap and lower than a highest permissible temperature for an operation of the switching section.', '2. The ion trap device according to claim 1, wherein: the switching section includes a semiconductor switching element; and the switching section temperature controller includes: d) a heatsink thermally connected to the semiconductor switching element; e) a heater configured to heat the heatsink; f) a temperature sensor configured to measure a temperature of the heatsink; and g) a controller configured to control the heater so that the temperature measured with the temperature sensor becomes closer to the target temperature.']",False,"['2', '45', '46', '11']" 531,EP_3594992_A1.png,EP3594992A1,ION TRAP DEVICE,['FIG1'],['FIG1 is configuration diagram of the main components of an ion trap mass spectrometer including an ion trap device according to one embodiment of the present invention'],['One embodiment of the ion trap mass spectrometer including an ion trap device according to the present invention is hereinafter described with reference to the attached drawings. FIG1 is a configuration diagram of the main components of the ion trap mass spectrometer according to the present embodiment.'],27,49,configuration diagram,H,"[{'element_identifier': '5', 'terms': ['auxiliary power unit']}, {'element_identifier': '1', 'terms': ['ionization unit']}, {'element_identifier': '45', 'terms': ['switching elements', 'switching element']}, {'element_identifier': '42', 'terms': ['second voltage source']}, {'element_identifier': '43', 'terms': ['first switching section']}, {'element_identifier': '46', 'terms': ['switching elements', 'switching element']}, {'element_identifier': '12', 'terms': ['sample plate']}, {'element_identifier': '92', 'terms': ['current generator']}, {'element_identifier': '6', 'terms': ['timing signal generation unit']}, {'element_identifier': '25', 'terms': []}, {'element_identifier': '91', 'terms': ['current controller']}, {'element_identifier': '32', 'terms': ['secondary electron multiplier tube']}, {'element_identifier': '72', 'terms': []}, {'element_identifier': '41', 'terms': ['first voltage source']}, {'element_identifier': '21', 'terms': ['ring electrode']}, {'element_identifier': '44', 'terms': ['second switching section']}, {'element_identifier': '23', 'terms': []}, {'element_identifier': '13', 'terms': ['extraction electrode']}, {'element_identifier': '8', 'terms': ['data processing unit']}, {'element_identifier': '71', 'terms': ['frequency determiner']}, {'element_identifier': '7', 'terms': ['control unit']}, {'element_identifier': '14', 'terms': ['ion lens']}, {'element_identifier': '4', 'terms': ['main power unit']}, {'element_identifier': '2', 'terms': ['ion trap']}]","['1. An ion trap device, comprising: a) an ion trap including a plurality of electrodes; b) a rectangular voltage generator including a voltage source for generating a direct voltage and a switching section, the rectangular voltage generator configured to operate the switching section to generate a rectangular voltage by switching the direct voltage generated by the voltage source, and to apply the rectangular voltage to at least one of the plurality of electrodes; and c) a switching section temperature controller configured to control a temperature of the switching section so as to maintain the temperature of the switching section at a target temperature which is higher than a highest reaching temperature of the switching section during an operation of the ion trap and lower than a highest permissible temperature for an operation of the switching section.', '2. The ion trap device according to claim 1, wherein: the switching section includes a semiconductor switching element; and the switching section temperature controller includes: d) a heatsink thermally connected to the semiconductor switching element; e) a heater configured to heat the heatsink; f) a temperature sensor configured to measure a temperature of the heatsink; and g) a controller configured to control the heater so that the temperature measured with the temperature sensor becomes closer to the target temperature.', '3. The ion trap device according to claim 1, wherein: the rectangular voltage generator includes: h) a first voltage source configured to generate a direct voltage; i) a second voltage source configured to generate a direct voltage different from the direct voltage generated by the first voltage source; j) a first switching section configured to turn on and off an output of the direct voltage from the first voltage source; and k) a second switching section configured to turn on and off an output of the direct voltage from the second voltage source, and the rectangular voltage generator is configured to generate the rectangular voltage by alternately turning on and off the first switching section and the second switching section, where the first switching section and the second switching section are each formed by a single semiconductor switching element made of a silicon carbide semiconductor.']",False,"['1', '2', '12', '13', '14', '5', '99', '80', '23', '25', '21', '32', '8', '41', '4', '43', '45', '44', '46', '42', '91', '92', '6', '7', '71', '72', '10']" 532,EP_3594998_A1 (1).png,EP3594998A1,METHOD FOR PLASMA DICING A SEMI-CONDUCTOR WAFER,['FIG2'],['FIG2 is a cross-sectional view of a semiconductor substrate illustrating individual devices separated by streets'],"['In the present invention, as is shown in a cross sectional view in FIG2, the device structures (110) are then covered with a protective material (200) while the street areas (120) remain unprotected. This protective material (200) can be a photoresist, applied and patterned by well-known techniques. Some devices, as a final process step are coated with a protective dielectric layer such as silicon dioxide or PSG which is applied across the whole substrate. This can be selectively removed from the street areas (120) by patterning with photoresist and etching the dielectric material, as is well known in the industry. This leaves the device structures (110) protected by the dielectric material and the substrate (100) substantially unprotected in the street areas (120). Note that in some cases test features to check the wafer quality may be located in the street areas (120). Depending on the specific wafer fabrication process flow, these test features may or may not be protected during the wafer dicing process. Although the device pattern illustrated shows oblong die, this is not necessary, and the individual device structures (110) may be any other shape, such as hexagons, as best suits the optimum utilization of the substrate (100). It is important to note that while the previous example considers dielectric materials as the protective film, that the invention may be practiced with a wide range of protective films including semi-conductive and conductive protective films. Furthermore, the protective layer can consist of multiple materials. It is also important to note that some portion of the protective film may be an integral part of the final device structure, (e.g., a passivation dielectric, metal bonding pad, etc.). Furthermore, the present invention can also be beneficially used with bulk wafers without the necessity of having devices or device structures. One such example may be a semiconductor substrate (Silicon, III-V compounds, etc.), mounted on a carrier or not mounted, covered by a masking material defining the structures to be etched. The substrate may also contain at least one additional layer with different material properties, such as for example an insulating layer.']",17,418,cross-sectional view,H,"[{'element_identifier': '100', 'terms': ['substrate', 'substrates']}, {'element_identifier': '2', 'terms': ['approximately', 'than']}, {'element_identifier': '110', 'terms': ['device structures']}, {'element_identifier': '200', 'terms': ['protective material']}, {'element_identifier': '120', 'terms': ['areas']}]","['1. A method for plasma dicing a substrate (100), the method comprising: - providing a process chamber (600) having a wall; - providing a plasma source (620) adjacent to the wall of the process chamber (600); - providing a work piece support (630) within the process chamber (600) ; - providing an electrostatic chuck (670) within said work piece support (630), said electrostatic chuck (670) having a plurality of gas inlet ports (1710) ; - providing a lift mechanism (680) within the process chamber (600) ; - loading a work piece (320) onto said work piece support (630) using said lift mechanism (680), said work piece (320) having a support film (300), a frame (310) and the substrate (100), said lift mechanism (680) engaging said work piece (320) outside an outer diameter of the substrate (100) of said work piece (320) and at least one of said gas inlet ports (1710) is positioned outside of said outer diameter of the substrate (100) of said work piece (320); - electrostatically clamping said work piece (320) to said work piece support (630) using said electrostatic chuck (670); - generating a plasma (400) using the plasma source (620); and etching the work piece (320) using the generated plasma (400).']",False,"['2', '120', '200', '110', '100', '23']" 533,EP_3594998_A1 (2).png,EP3594998A1,METHOD FOR PLASMA DICING A SEMI-CONDUCTOR WAFER,['FIG3'],['FIG3 is a cross-sectional view of a semiconductor substrate mounted to tape and a frame'],"['The substrate (100) may be thinned, typically by a grinding process, which reduces the substrate thickness to a few hundred microns to as thin as approximately 30 microns or less. As is shown in FIG3, the thinned substrate (100) is then adhered to a tape (300) which in turn is mounted in a rigid frame (310) to form a work piece (320). The frame is typically metal or plastic, though other frame materials are possible. The tape (300) is typically made from a carbon-containing polymer material, and may additionally have a thin conductive layer applied to its surface. The tape (300) provides support for the thinned substrate (100) which is otherwise too fragile to handle without breakage. It should be noted that the sequence of patterning, thinning and then mounting is not critical and the steps may be adjusted to best fit the particular devices and substrate and the processing equipment used. It is important to note that while the previous example considers a work piece (320) that is comprised of mounting a substrate (100) on an adhesive tape (300) which in turn is attached to a frame (310), that the invention is not limited by the configuration of the wafer and carrier. The wafer carrier can be comprised a variety of materials. The carrier supports the substrate during the plasma dicing process. Furthermore, the wafer need not be attached to the carrier using an adhesive - any method that holds the wafer to the carrier and allows a means thermal communication of the substrate to the cathode is sufficient (e.g., an electrostatically clamped carrier, a carrier with a mechanical clamping mechanism, etc.).']",17,323,cross-sectional view,H,"[{'element_identifier': '310', 'terms': ['frame']}, {'element_identifier': '100', 'terms': ['substrate', 'substrates']}, {'element_identifier': '300', 'terms': ['tape']}, {'element_identifier': '320', 'terms': ['work piece']}, {'element_identifier': '110', 'terms': ['device structures']}, {'element_identifier': '200', 'terms': ['protective material']}, {'element_identifier': '120', 'terms': ['areas']}]","['1. A method for plasma dicing a substrate (100), the method comprising: - providing a process chamber (600) having a wall; - providing a plasma source (620) adjacent to the wall of the process chamber (600); - providing a work piece support (630) within the process chamber (600) ; - providing an electrostatic chuck (670) within said work piece support (630), said electrostatic chuck (670) having a plurality of gas inlet ports (1710) ; - providing a lift mechanism (680) within the process chamber (600) ; - loading a work piece (320) onto said work piece support (630) using said lift mechanism (680), said work piece (320) having a support film (300), a frame (310) and the substrate (100), said lift mechanism (680) engaging said work piece (320) outside an outer diameter of the substrate (100) of said work piece (320) and at least one of said gas inlet ports (1710) is positioned outside of said outer diameter of the substrate (100) of said work piece (320); - electrostatically clamping said work piece (320) to said work piece support (630) using said electrostatic chuck (670); - generating a plasma (400) using the plasma source (620); and etching the work piece (320) using the generated plasma (400).']",False,"['3', '120', '200', '310', '310', '110', '100', '320', '300', '24']" 534,EP_3594998_A1.png,EP3594998A1,METHOD FOR PLASMA DICING A SEMI-CONDUCTOR WAFER,['FIG1'],['FIG1 is a top down view of a semiconductor substrate illustrating individual devices separated by streets'],"['A typical semiconductor substrate after device fabrication is illustrated in FIG1. The substrate (100) has on its surface a number of areas containing device structures (110) separated by street areas (120) which allows for separation of the device structures into individual die. Although silicon is commonly used as a substrate material, other materials chosen for their particular characteristics are frequently employed. Such substrate materials include Gallium Arsenide and other III-V materials or non-semi-conductor substrates on which a semi-conducting layer has been deposited. Further substrate types may also include Silicon-On-Insulator (SOI) wafers and semiconductor wafers mounted on carriers. While the example above describes die separated by streets, aspects of the invention may be beneficially applied to other pattern configurations on a substrate.']",16,149,top-down view,H,"[{'element_identifier': '100', 'terms': ['substrate', 'substrates']}, {'element_identifier': '110', 'terms': ['device structures']}, {'element_identifier': '120', 'terms': ['areas']}, {'element_identifier': '1', 'terms': ['approximately']}]","['1. A method for plasma dicing a substrate (100), the method comprising: - providing a process chamber (600) having a wall; - providing a plasma source (620) adjacent to the wall of the process chamber (600); - providing a work piece support (630) within the process chamber (600) ; - providing an electrostatic chuck (670) within said work piece support (630), said electrostatic chuck (670) having a plurality of gas inlet ports (1710) ; - providing a lift mechanism (680) within the process chamber (600) ; - loading a work piece (320) onto said work piece support (630) using said lift mechanism (680), said work piece (320) having a support film (300), a frame (310) and the substrate (100), said lift mechanism (680) engaging said work piece (320) outside an outer diameter of the substrate (100) of said work piece (320) and at least one of said gas inlet ports (1710) is positioned outside of said outer diameter of the substrate (100) of said work piece (320); - electrostatically clamping said work piece (320) to said work piece support (630) using said electrostatic chuck (670); - generating a plasma (400) using the plasma source (620); and etching the work piece (320) using the generated plasma (400).']",False,"['1', '120', '110', '100', '22']" 535,EP_3595094_A1 (5).png,EP3595094A1,"CORROSION-RESISTANT TERMINAL MATERIAL, CORROSION-RESISTANT TERMINAL, AND WIRE END STRUCTURE",['FIG11'],['FIG11] It is a micrograph of a section of a terminal material of a test piece 30 '],"['FIG11 is an electron micrograph of a section at the planned core wire contact part regarding the test piece 30: it can be recognized that the ground layer (the nickel layer), the zinc-nickel alloy layer and the tin layer are formed from the substrate side though; the outermost surface part of the tin layer cannot be discriminated.']",18,66,micrograph section view,C,"[{'element_identifier': '5', 'terms': ['tin layer']}, {'element_identifier': '12', 'terms': ['electric wire']}, {'element_identifier': '11', 'terms': ['connection part']}, {'element_identifier': '20', 'terms': ['thickness', 'etching']}, {'element_identifier': '40', 'terms': ['than', 'if it exceeds']}, {'element_identifier': '200', 'terms': ['acceleration voltage']}, {'element_identifier': '15', 'terms': ['male terminal']}, {'element_identifier': '10', 'terms': ['terminal', 'terminals']}, {'element_identifier': '21', 'terms': ['carriers', 'carrier', 'test pieces']}, {'element_identifier': '800', 'terms': ['about']}]","['1. A corrosion-resistant terminal material comprising a substrate made of copper or a copper alloy and a film layered on the substrate, wherein a planned core wire contact part which is in contact with a core wire of an electric wire when a terminal is formed and a planned contact part to be a contact part are formed; the film formed in the planned core wire contact part has a tin layer made of tin or a tin alloy and a metallic zinc layer formed on the tin layer; and the film formed in the planned contact part has a tin layer made of tin or a tin alloy but does not have the metallic zinc layer.', '3. The corrosion-resistant terminal material according to claim 2, wherein the zinc-nickel alloy layer has a nickel content percentage not less than 5% by mass and not more than 35% by mass.', '5. The corrosion-resistant terminal material according to claim 1, wherein the metallic zinc layer has a zinc density not less than 5 at% and not more than 40 at%, and a thickness in terms of SiO 2 not less than 1 nm and not more than 10 nm.', '8. The corrosion-resistant terminal material according to claim 1, wherein being formed in a belt sheet shape, and to a carrier along a longitudinal direction thereof, terminal members having the planned core wire contact part and the planned contact part are coupled, with intervals along a longitudinal direction of the carrier.']",True,"['10', '50', '45', '40', '35', '20', '15', '10', '5', '12', '200', '400', '600', '800', '1000', '11', '21']" 536,EP_3595107_A1 (4).png,EP3595107A1,ELECTRICAL RACEWAY SYSTEM AND ASSOCIATED WIRE BUNDLE CLAMP SYSTEM AND METHOD,"['FIG6', ' FIG7']","['FIG7 is a cross-sectional side elevation view of the electrical raceway system of FIG3, taken along the line 7-7 of FIG3, according to one or more examples of the present disclosure ', 'FIG6 is a cross-sectional side elevation view of the electrical raceway system of FIG3, taken along the line 6-6 of FIG3, according to one or more examples of the present disclosure']","['The base 138B facilitates slidable attachment of the second clamping component 132 to the rail 116. For example, the base 138B includes arms 142B (see, e.g., FIG7) that are spaced apart from each other such that a gap is defined between the arms 142B. The gap between the arms 142B is large enough to receive a width of the rail 116 therein. The arms 142B further include rail retention features 143B (e.g., tabs, teeth, etc.) at free ends of the arms 142B. The distance between the rail retention features 143B is less than the width of the rail 116, but the length of the arms 142B, minus the length of the rail retention features 143B, is greater than a thickness of the rail 116.', 'The bundle engagement feature 136B may also have a first convex surface opposing the second concave engagement surface 137B such that the bundle engagement feature 136B has a generally C-shaped cross-section. In some examples, the bundle engagement feature 136B extends across only a portion of the width of the base 138B to promote the resilient flexibility of the arms 142B (see, e.g., FIG7). However, in other examples, the bundle engagement feature 136B may extend across the entire width of the base 138B. ', 'The base 138A facilitates fixed attachment of the first clamping component 132 to the rail 116. For example, the base 138A includes arms 142A (see, e.g., FIG6) that are spaced apart from each other such that a gap is defined between the arms 142A. The gap between the arms 142A is large enough to receive a width of the rail 116 therein. The arms 142A further include rail retention features 143A (e.g., tabs, teeth, etc.) at free ends of the arms 142A. The distance between the rail retention features 143A is less than the width of the rail 116, but the length of the arms 142A, minus the length of the rail retention features 143A, is greater than a thickness of the rail 116.', 'The bundle engagement feature 136A may also have a first convex surface opposing the first concave engagement surface 137A such that the bundle engagement feature 136A has a generally C-shaped cross-section. In some examples, the bundle engagement feature 136A extends across only a portion of the width of the base 138A to promote the resilient flexibility of the arms 142A (see, e.g., FIG6). However, in other examples, the bundle engagement feature 136A may extend across the entire width of the base 138A.']",74,474,cross-sectional view,B,"[{'element_identifier': '7', 'terms': ['example']}, {'element_identifier': '14', 'terms': ['example']}, {'element_identifier': '160', 'terms': ['second aperture']}, {'element_identifier': '113', 'terms': ['electrical raceway system']}, {'element_identifier': '25', 'terms': []}, {'element_identifier': '6', 'terms': ['example', 'clause']}, {'element_identifier': '112', 'terms': ['lateral direction']}, {'element_identifier': '152', 'terms': ['two second-clamping-component apertures']}, {'element_identifier': '132', 'terms': ['clamping component', 'clamping components']}, {'element_identifier': '140', 'terms': ['ratcheting mechanism']}, {'element_identifier': '150', 'terms': ['through-channel']}]","['7. The clamp system (130) according to claim 6, wherein: one of the first clamping component (132) or the second clamping component (134) comprises a ratcheting mechanism (140) integrated into the one of the first clamping component (132) or the second clamping component (134); and the ratcheting mechanism (140) is configured to engage the flexible retention strap (124) and allow motion of the flexible retention strap (124) through the ratcheting mechanism (140) in only one direction.', '8. The clamp system (130) according to claim 6, wherein: the first clamping component (132) comprises at least two first-clamping-component apertures (158, 160) through which the flexible retention strap (124) is extendable to couple the flexible retention strap (124) to the first clamping component (132); the second clamping component (134) comprises at least two second-clamping-component apertures (152, 154) through which the flexible retention strap (124) is extendable to couple the flexible retention strap (124) to the second clamping component (134); and, optionally, the first clamping component (132) further comprises a through-channel (150) formed in the first clamping component (132) and intercoupling the at least two first-clamping-component apertures (158, 160).', '10. An electrical raceway system (113) comprising: a plurality of clamp systems (130) including the clamp system (130) of any of claims 1 to 9, each clamp system (130) comprising: a wire bundle (114) comprising a plurality of wires (118), elongated in a longitudinal direction (110) perpendicular to the lateral direction (112); and a first clamping component (132) non-movably attached to the rail (116) and comprising a first concave engagement surface (137A); a second clamping component (134) slidably attached to the rail (116) and comprising a second concave engagement surface (137B) opposing and facing the first concave engagement surface (137A), wherein the second clamping component (134) is slidable along the rail (116) in the lateral direction (112) and one wire bundle from the plurality of wire bundles (114) is captured between the first concave engagement surface (137A) and the second concave engagement surface (137B); and a flexible retention strap (124) engaged with the first clamping component (132), the second clamping component (134), and the one wire bundle from the plurality of wire bundles (114) to at least partially affix the one wire bundle from the plurality of wire bundles (114) to the first clamping component (132) and the second clamping component (134) and to constrain movement of the second clamping component (134) away from the first clamping component (132) in the lateral direction (112).']",True,"['112', '112', '113', '113', '56', '36', '140', '132', '150', '152', '25', '160', '14', '7', '6']" 537,EP_3595128_A1 (1).png,EP3595128A1,POWER SUPPLY APPARATUS,['FIG2'],['FIG2 is a schematic circuit diagram of a power supply apparatus according to a second example embodiment'],"['FIG2 shows a schematic circuit diagram of a power supply apparatus 200 according to a second example embodiment. The power supply apparatus 200 is connected to a first power source 1, and a second power source 2. In common with the first embodiment above, the power supply apparatus 200 comprises a transformer 210 with first and secondary primary windings P1, P2 connected to the first and second power supplies 1,2 respectively, and a secondary winding S that serves to generate an output. The transformer 210 is provided with primary switching elements Q1,Q2, input rectifiers D3,D4, an output rectifier D7 and an output filter R13,C2. The operation of the primary switching elements takes place under the control of the controller. The power supply apparatus 200 comprises a voltage detection circuit 221 that includes a voltage reference circuit U3. The voltage reference circuit U3 in this embodiment is provided as a Zener shunt regulator, and is arranged to provide a reference voltage for detection of the first power source 1, a voltage shut down circuit 222 and an under voltage lock circuit 223. In addition, drive circuits D1,D2 are provided for the primary switching elements, as integrated circuits. Suitable devices are available from Texas Instruments in their UCx84x family of current-mode PWM controller devices.']",17,233,schematic circuit diagram,H,"[{'element_identifier': '210', 'terms': ['transformer']}, {'element_identifier': '221', 'terms': ['voltage detection circuit']}, {'element_identifier': '223', 'terms': ['voltage lock circuit']}, {'element_identifier': '222', 'terms': ['voltage shut down circuit']}, {'element_identifier': '2', 'terms': ['second power source']}, {'element_identifier': '3', 'terms': ['andFigure']}, {'element_identifier': '200', 'terms': ['power supply apparatus']}]","['1. A power supply apparatus, comprising: a transformer comprising a first primary winding for connection to a first power source and a second primary winding for connection to a second power source, and a secondary winding for delivering power therefrom as the output of the power supply apparatus; a controller for receiving voltage inputs from the first power source and the second power source, and in response to the received voltage inputs control supply from the first power source to the first primary winding and from the second power source to the second primary winding, such that: if the first power source and second power source are available the controller operates to allow power to be supplied to the first primary winding from the first power source and operates to shut off supply of power to the second primary winding from the second power source.', '4. The power supply apparatus of any preceding claim, wherein the controller comprises a voltage detection circuit arranged to receive power from the first power supply, to detect power from the first power source, and in response to operate to allow supply of power to the first primary winding from the first power according to a drive circuit for the first primary winding.', '5. The power supply apparatus of any preceding claim, wherein the controller comprises a the voltage shut down circuit operable to shut off the supply of power to the second primary winding from the second power source and arranged to selectively provide a shut-down signal to a drive circuit for the second primary winding.', '8. The power supply apparatus of any preceding claim, wherein the controller further comprises an under voltage lock circuit arranged to detect an under-threshold voltage, and in response to prevent the controller from allowing power to be supplied to the first primary winding from the first power source.']",False,"['2', '2', '200', '210', '221', '8', '4', '03', '3', '222', '223']" 538,EP_3595128_A1.png,EP3595128A1,POWER SUPPLY APPARATUS,['FIG1'],['FIG1 shows a schematic overview of a power supply apparatus according to a first example embodiment'],"['As shown in FIG1, a power supply apparatus 100 is connected to a first power source 1 and a second power source 2, and is arranged to provide an output voltage for electrical equipment.', 'The voltage detection circuit 221, a voltage shut down circuit 222 and an under voltage lock circuit 223 operate as described in relation to the embodiment of FIG1. It should be noted that the first and second power sources 1,2 are electrically isolated from one another by the transformer 210, and that different ground references G1,G2 are provided for the two power sources 1,2. It should also be noted that the voltage shut down circuit 222 selectively provides a shut-down signal to a drive circuit D2 for the second primary winding P1, to cause the when the first primary winding is energised by power form the first power supply. The voltage shut down circuit 222 includes an opto-isolator to maintain electrical isolation between the first and second power supplies 1,2 and their associated circuits, and operates to cause the drive circuit D2 to be in active in response to transistor switch Q3 being energised, that is, while the drive circuit D1 is operational.']",16,215,schematic,H,"[{'element_identifier': '122', 'terms': ['voltage shut down circuit']}, {'element_identifier': '121', 'terms': ['voltage detection circuit']}, {'element_identifier': '1', 'terms': ['power source', 'power sources']}, {'element_identifier': '100', 'terms': ['power supply apparatus']}, {'element_identifier': '2', 'terms': ['second power source']}, {'element_identifier': '110', 'terms': ['transformer']}, {'element_identifier': '120', 'terms': ['controller']}]","['1. A power supply apparatus, comprising: a transformer comprising a first primary winding for connection to a first power source and a second primary winding for connection to a second power source, and a secondary winding for delivering power therefrom as the output of the power supply apparatus; a controller for receiving voltage inputs from the first power source and the second power source, and in response to the received voltage inputs control supply from the first power source to the first primary winding and from the second power source to the second primary winding, such that: if the first power source and second power source are available the controller operates to allow power to be supplied to the first primary winding from the first power source and operates to shut off supply of power to the second primary winding from the second power source.', '4. The power supply apparatus of any preceding claim, wherein the controller comprises a voltage detection circuit arranged to receive power from the first power supply, to detect power from the first power source, and in response to operate to allow supply of power to the first primary winding from the first power according to a drive circuit for the first primary winding.', '5. The power supply apparatus of any preceding claim, wherein the controller comprises a the voltage shut down circuit operable to shut off the supply of power to the second primary winding from the second power source and arranged to selectively provide a shut-down signal to a drive circuit for the second primary winding.']",False,"['1', '100', '110', '1', '121', '1123', '8', '122', '2', '120']" 539,EP_3595130_A1.png,EP3595130A1,RESONANCE-TYPE POWER RECEPTION DEVICE,['FIG1'],['FIG1 is a diagram showing an exemplary configuration of a resonance-type power transfer system according to a first embodiment of the invention'],"['FIG1 is a diagram showing an exemplary configuration of a resonance-type power transfer system according to a first embodiment of the invention.', 'The resonance-type power transfer system includes, as shown in FIG1, a resonance-type transmission power supply device 1, a transmitting antenna (TX-ANT) 2, a receiving antenna (RX-ANT) 3, a receiving circuit 4, and a load 5. The resonance-type transmission power supply device 1 includes an interface power supply (VI-I/F) 6 and an inverter circuit 7. The receiving circuit 4 includes a rectifier circuit (REC) 8 and an interface power supply (Vo-I/F) 9. The resonance-type transmission power supply device 1 and the transmitting antenna 2 form a resonance-type power transmission device, and the receiving antenna 3 and the receiving circuit 4 form a resonance-type power reception device.', 'Note that the power transfer type between the transmitting antenna 2 and the receiving antenna 3 is not particularly limited, and any of a magnetic field resonance-type, an electric field resonance-type, and an electromagnetic induction-type may be used. In addition, the transmitting antenna 2 and the receiving antenna 3 are not limited to contactless antennas such as those shown in FIG1.']",24,250,diagram,H,"[{'element_identifier': '8', 'terms': ['rectifier circuit']}]","['2. The resonance-type power reception device according to claim 1, wherein the receiving circuit includes: a rectifier circuit converting the power received by the receiving antenna into direct current power; and an interface power supply controlling a ratio between a voltage and a current of the direct current power obtained by the rectifier circuit to a value proportional to a square of the mutual inductance.']",False,"['8', '71']" 540,EP_3595139_A1 (5).png,EP3595139A1,ELECTRICAL MACHINE AND MAINTENANCE METHODS THEREOF,['FIG9'],['FIG9 schematically represents a frontal view of an example of an electrical machine in a second position'],"['In FIG9, the rotor is positioned in the second position. The rotor may be rotated from the first to the second position without reconnecting the removed segment corresponding to the maintenance aperture 31 to the other parts of the electrical conductor ring for example for repairing or performing maintenance or inspecting operations in the first region 21 of the inner structure. The second region 22 of the inner structure 20 may be accessible through the maintenance aperture when the rotor is in the second position. However, the first region 21 cannot be accessible through the maintenance aperture.']",17,104,frontal view,F,"[{'element_identifier': '8', 'terms': ['through two rotor bearings', 'single rotor bearing']}, {'element_identifier': '30', 'terms': ['structure']}, {'element_identifier': '9', 'terms': ['frame']}, {'element_identifier': '2', 'terms': ['tower']}, {'element_identifier': '20', 'terms': ['structure']}, {'element_identifier': '21', 'terms': ['first region']}, {'element_identifier': '31', 'terms': ['maintenance aperture', 'maintenance apertures']}]","['1. An electrical machine (10) having a plurality of electrical phases and comprising an inner structure (20), an outer structure (30) and an air gap (40) arranged between the inner (20) and the outer structure (30); wherein the inner structure (20) is one of the rotor and of the stator and the outer structure (30) is the other of the rotor and of the stator; the rotor is configured to rotate around a rotational axis (50) extending from a first side (51) to a second side (52), and the stator comprises a plurality of electrical windings (53) and an electrical conductor ring (54) extending along the stator circumference for connecting the electrical windings (53) to an electrical converter; the outer structure (30) comprises at least one maintenance aperture (31) extending along a portion of the outer structure (30) for accessing a portion of the inner structure (20) from the first side (51); and the electrical conductor ring (54) comprises a plurality of segments (60) having a releasable segment (61) being releasable connected to the other segment or segments of the electrical conductor ring (54), wherein the releasable segment (61) is configured to connect to a selection of the electrical windings (53), the selection having the same number of windings (53) for each of the plurality of electrical phases.', '8. A method of performing maintenance operations (100) in an electrical machine (10), the electrical machine (10) having a plurality of electrical phases and comprising an inner structure (20), an outer structure (30) and an air gap (40) arranged between the inner (20) and the outer structure (30), the inner structure (20) being one of the rotor and of the stator and the outer structure (30) being the other of the rotor and of the stator; the method comprising: positioning (101) the rotor in a first position for accessing a first region (21) of the inner structure (20) through a maintenance aperture (30) in the outer structure (30); disconnecting (102) a portion of the plurality of electrical windings (53) of the stator from an electrical conductor ring (54) extending along the stator circumference for connecting the electrical windings to an electrical converter; removing (103) one or more segments of the electrical conductor ring (54) at least partially corresponding to the maintenance aperture (31) in the first position; positioning (105) the rotor in a second position for accessing a second region (22) of the inner structure (20) through the maintenance aperture (31), without connecting the removed segments of the electrical conductor ring to the remaining segment or segments of the electrical conductor ring (54).']",True,"['2', '31', '30', '20', '8', '2', '31', '30', '21', '20', '9', '16']" 541,EP_3595139_A1 (6).png,EP3595139A1,ELECTRICAL MACHINE AND MAINTENANCE METHODS THEREOF,['FIG10'],['FIG10 is a flow diagram of a method of performing maintenance operations in an electrical machine according to an example'],"['FIG10 is a flow diagram of a method of performing maintenance operations 100 in an electrical machine according to an example.', 'Box 103 represents removing one or more segments of the electrical conductor ring at least partially corresponding to the maintenance aperture. This may be according to any of the examples herein described, in particular according to examples described with respect to FIG10.', 'Box 104 and 105 represents performing maintenance operations in the first region and in the second region of the inner structure as described with respect to the FIG10. Box 105 represents positioning the rotor in a second position as described with respect to FIG10.']",20,115,flow diagram,F,"[{'element_identifier': '103', 'terms': ['Box']}, {'element_identifier': '11', 'terms': ['generator bearing']}, {'element_identifier': '100', 'terms': ['performing maintenance operations']}, {'element_identifier': '104', 'terms': ['Box']}, {'element_identifier': '105', 'terms': ['Box']}, {'element_identifier': '102', 'terms': ['Box']}, {'element_identifier': '10', 'terms': ['generator']}, {'element_identifier': '101', 'terms': ['Box']}]","['7. An electrical machine (10) according to any of claims claim 1 - 6, wherein the electrical machine is an electrical generator, specifically a generator for a direct-drive wind turbine, and more specifically a permanent magnet generator.', '8. A method of performing maintenance operations (100) in an electrical machine (10), the electrical machine (10) having a plurality of electrical phases and comprising an inner structure (20), an outer structure (30) and an air gap (40) arranged between the inner (20) and the outer structure (30), the inner structure (20) being one of the rotor and of the stator and the outer structure (30) being the other of the rotor and of the stator; the method comprising: positioning (101) the rotor in a first position for accessing a first region (21) of the inner structure (20) through a maintenance aperture (30) in the outer structure (30); disconnecting (102) a portion of the plurality of electrical windings (53) of the stator from an electrical conductor ring (54) extending along the stator circumference for connecting the electrical windings to an electrical converter; removing (103) one or more segments of the electrical conductor ring (54) at least partially corresponding to the maintenance aperture (31) in the first position; positioning (105) the rotor in a second position for accessing a second region (22) of the inner structure (20) through the maintenance aperture (31), without connecting the removed segments of the electrical conductor ring to the remaining segment or segments of the electrical conductor ring (54).']",True,"['101', '103', '104', '105', '106', '100', '10', '101', '102', '110', '103', '104', '105', '106', '11', '17']" 542,EP_3595150_A2 (1).png,EP3595150A2,"POWER CONVERTING DEVICE, COMPRESSOR INCLUDING THE SAME, AND CONTROL METHOD THEREOF",['FIG2'],['FIG2 is a graph showing a resistance value according to a temperature of a NTC thermistor'],"['FIG2 is a graph showing a resistance value according to the temperature of the NTC thermistor.', 'As shown in FIG2, the NTC thermistor 161 has a resistance value that is inversely proportional to the temperature, and thus may have a function of measuring the temperature. Further, since the voltage based on the resistance value in inverse proportion to the temperature is applied across the NTC thermistor 161, the output voltage therefrom is inversely proportional to the temperature.', 'For example, the nominal operation region in FIG2 may correspond to a temperature range below 100 °C. The overheating operation region in FIG2, or the overloading and overheating operation region in FIG2 may correspond to a temperature range exceeding 100 °C.']",16,133,graph,H,"[{'element_identifier': '100', 'terms': ['power converting device']}, {'element_identifier': '2', 'terms': ['×', 'x']}, {'element_identifier': '140', 'terms': ['driver']}, {'element_identifier': '200', 'terms': ['motor']}, {'element_identifier': '120', 'terms': ['ripple remover']}]","['1. A power converting device for driving a compressor motor, the device comprising: an inverter for generating an alternate current for driving the motor using power supplied from a power supply, the inverter including a plurality of switching elements; a driver for driving the plurality of switching elements; a variable resistance unit disposed between and electrically coupled to the driver and a gate of each of the switching elements, wherein the variable resistance unit has a resistance value varying based on a temperature of the inverter; and a controller configured for transferring a drive signal to the driver.']",False,"['2', '1000', '800', '600', '400', '200', '20', '80', '100', '120', '140', '10']" 543,EP_3595163_A1 (3).png,EP3595163A1,DIELECTRIC ELASTOMER POWER GENERATION SYSTEM,['FIG4'],['FIG4 is a system configuration diagram schematically showing the dielectric elastomer power generation system of FIG1'],"['Subsequently, according to a command of the control unit 2, the switch unit 6, as shown in FIG4, disconnects the power generation unit 1 and the intermediate power storage unit 3, and connects the intermediate power storage unit 3 and the power storage unit 5. In the present invention, this mode is defined as an output mode, in which power is output from the intermediate power storage unit 3 to the power storage unit 5. Note that switching between the input mode and the output mode can be performed at any timing, and is judged by the control unit 2 using all sorts of judgment criteria. For example, by monitoring the voltage (input voltage Vi) of power generation by the power generation unit 1, switching from the input mode to the output mode may be performed in the case where the input voltage Vi is zero or a value approaching zero. Alternatively, switching from the input mode to the output mode may be performed in the case where the dielectric elastomer power generation element 11 is not significantly elongating and contracting, using a sensor (not shown) that detects the elongation and contraction state of the dielectric elastomer power generation element 11.']",16,222,diagram,H,"[{'element_identifier': '621', 'terms': ['output path']}, {'element_identifier': '63', 'terms': ['intermediate switch unit']}, {'element_identifier': '632', 'terms': ['intermediate path']}, {'element_identifier': '1', 'terms': ['power generation unit']}]","['1. A dielectric elastomer power generation system comprising: a power generation unit including a dielectric elastomer power generation element having a dielectric elastomer layer and a pair of electrode layers that sandwich the dielectric elastomer layer; an intermediate power storage unit including a plurality of capacitors of a specific number and configured to receive input of output power from the power generation unit; a power storage unit configured to receive input of output power from the intermediate power storage unit; and a control unit configured to perform setting control by switching a mode between an input mode and an output mode, wherein in the input mode, some number of the plurality of capacitors of the intermediate power storage unit are connected to the power generation unit such that a series number is an input series number of less than or equal to the specific number, and in the output mode, some number of the plurality of capacitors are connected to the power storage unit such that the series number is an output series number which is smaller than the input series number.']",True,"['621', '63', '632', '1', '12']" 544,EP_3595163_A1 (6).png,EP3595163A1,DIELECTRIC ELASTOMER POWER GENERATION SYSTEM,['FIG9'],['FIG9 is a graph showing states of power generation by the dielectric elastomer power generation system of FIG6 '],"['FIG9 is a graph showing the input mode, the intermediate mode and the output mode in the dielectric elastomer power generation system A2. From times T11 to T12, the input mode is executed at the input voltage Vi. Subsequently, the intermediate mode is executed from times T12 to T13. The output voltage Vo from the capacitors 311 to 315 in the intermediate mode is one quarter of the input voltage Vi. Subsequently, the output mode is executed from times T13 to T21. The output voltage Vo from the capacitors 315 to 318 in the output mode is a further one quarter of the output voltage Vo in the intermediate mode, and is 1/16 of the input voltage Vi in the input mode.', 'Similarly, with such an embodiment, power generated by the power generation unit 1 can be more efficiently stored in the power storage unit 5. Also, in the present embodiment, by executing the intermediate mode between the input mode and the output mode, the output voltage Vo in the output mode can be reduced to 1/16 of the input voltage Vi in the input mode in the example shown in FIG9. This is due to the fact that the ratio of the input voltage Vi in the input mode and the output voltage Vo in the output mode will be a ratio obtained by the ratio of the input series number and the intermediate output series number being multiplied by the ratio of the intermediate input series number and the output series number.']",18,274,graph,H,"[{'element_identifier': '621', 'terms': ['output path']}, {'element_identifier': '112', 'terms': ['electrode layers']}, {'element_identifier': '31', 'terms': ['capacitors']}, {'element_identifier': '634', 'terms': ['intermediate path']}]","['1. A dielectric elastomer power generation system comprising: a power generation unit including a dielectric elastomer power generation element having a dielectric elastomer layer and a pair of electrode layers that sandwich the dielectric elastomer layer; an intermediate power storage unit including a plurality of capacitors of a specific number and configured to receive input of output power from the power generation unit; a power storage unit configured to receive input of output power from the intermediate power storage unit; and a control unit configured to perform setting control by switching a mode between an input mode and an output mode, wherein in the input mode, some number of the plurality of capacitors of the intermediate power storage unit are connected to the power generation unit such that a series number is an input series number of less than or equal to the specific number, and in the output mode, some number of the plurality of capacitors are connected to the power storage unit such that the series number is an output series number which is smaller than the input series number.']",True,"['621', '634', '621', '112', '31', '15']" 545,EP_3595205_A1 (1).png,EP3595205A1,WIRELESS COMMUNICATION METHOD AND DEVICE,['FIG3'],['FIG3 is a schematic flowchart of processing a PDCCH by a network device'],"['Optionally, DCI may be carried by using a physical downlink control channel (Physical Downlink Control Channel, PDCCH). As shown in FIG3, the network device first performs CRC encoding on the to-be-sent DCI to obtain a CRC, then scrambles the CRC with a radio network temporary identifier (Radio Network Temporary Identifier, RNTI) and antenna port information to obtain a scrambled sequence, concatenates the scrambled sequence with the DCI, and performs procedures of channel encoding, modulation, mapping, and sending.', ""The channel encoding in the procedure shown in FIG3 can improve reliability of data transmission to ensure communication quality. A polar code proposed by the Turkish professor, Ankan, is the first code that can be theoretically proved to achieve a Shannon's capacity and that has low encoding and decoding complexity. The polar code is a linear block code. An encoding matrix of the polar code is GN, and an encoding process of the polar code is x1N=u1NGN, where u1N=u1u2KuN is a binary row vector with a length of N (that is, a code length), GN is an N × N matrix, and GN=F2⊗log2N.F2⊗log2N is defined as a Kronecker (Kronecker) product of log2N matrices F2, and the matrix F2=1011.""]",13,239,schematic flowchart,H,"[{'element_identifier': '3', 'terms': ['scrambled sequence']}]","['1. A wireless communication method, comprising: scrambling, with each piece of configuration information of a plurality of pieces of configuration information used for configuring a terminal device, bits that are comprised in a cyclic redundancy check CRC of downlink control information DCI and that correspond to each piece of configuration information, to obtain a scrambled sequence, wherein at least one bit of bits that correspond to each piece of configuration information does not correspond to another piece of configuration information of the plurality of pieces of configuration information; and sending the DCI and the scrambled sequence to the terminal device.']",False,"['3', '24']" 546,EP_3595205_A1.png,EP3595205A1,WIRELESS COMMUNICATION METHOD AND DEVICE,['FIG2'],['FIG2 is a diagram of an application scenario according to an embodiment of this application'],"['The embodiments of this application may be applied to a wireless communications system. The wireless communications system usually includes cells. Each cell includes one network device, for example, a base station (Base Station, BS). The base station provides communication services for a plurality of terminal devices, for example, mobile stations (Mobile Station, MS). The base station is connected to a core network device, as shown in FIG2.']",15,83,diagram,H,"[{'element_identifier': '2', 'terms': ['is', 'scrambled sequence']}]","['1. A wireless communication method, comprising: scrambling, with each piece of configuration information of a plurality of pieces of configuration information used for configuring a terminal device, bits that are comprised in a cyclic redundancy check CRC of downlink control information DCI and that correspond to each piece of configuration information, to obtain a scrambled sequence, wherein at least one bit of bits that correspond to each piece of configuration information does not correspond to another piece of configuration information of the plurality of pieces of configuration information; and sending the DCI and the scrambled sequence to the terminal device.']",False,"['11', '2', '2', '23']" 547,EP_3595207_A1 (5).png,EP3595207A1,"ENCODING METHOD, DECODING METHOD, APPARATUS AND DEVICE",['FIG10'],['FIG10 is a structural diagram of a communications apparatus in an embodiment of this application '],"['FIG10 is a schematic structural diagram of a communications apparatus 1000 according to an embodiment of this application (for example, a communications apparatus such as an access point, a base station, a station, or a terminal; or a chip in the foregoing communications apparatus).', 'As shown in FIG10, the communications apparatus 1000 may be implemented by using a bus 1001 as a general bus architecture. Based on a specific application and an overall design constraint of the communications apparatus 1000, the bus 1001 may include any quantity of interconnection buses and bridges. The bus 1001 connects various circuits together, and the circuits include a processor 1002, a storage medium 1003, and a bus interface 1004. Optionally, the communications apparatus 1000 uses the bus interface 1004 to connect a network adapter 1005 and the like through the bus 1001. The network adapter 1005 may be configured to implement a signal processing function of a physical layer in a wireless communications network, and implement sending and receiving of a radio frequency signal through an antenna 1007. A user interface 1006 may be connected to a user terminal such as a keyboard, a display, a mouse, or a joystick. The bus 1001 may be further connected to various other circuits, such as a timing source, a peripheral device, a voltage regulator, or a power management circuit. The circuits are well known in the art, and therefore details are not described herein.']",15,270,structural diagram,H,"[{'element_identifier': '1002', 'terms': ['processor']}, {'element_identifier': '1000', 'terms': ['communications apparatus']}, {'element_identifier': '1004', 'terms': ['bus interface']}, {'element_identifier': '1007', 'terms': ['antenna']}, {'element_identifier': '1005', 'terms': ['network adapter']}, {'element_identifier': '1003', 'terms': ['storage medium']}, {'element_identifier': '10', 'terms': ['andFIG.', 'not greater than']}, {'element_identifier': '1001', 'terms': ['bus']}, {'element_identifier': '1006', 'terms': ['user interface']}]","['8. 8. The rate matching method according to claim 6 or 7, wherein the determining the first puncturing sequence from the third puncturing sequence based on the quantity N of the encoded bits and the quantity Q of to-be-punctured bits comprises: successively reading, starting from a first to-be-punctured bit in the third puncturing sequence, to-be-punctured bits that are not greater than N; and when a quantity of read to-be-punctured bits reaches the quantity Q of to-be-punctured bits, determining a sequence comprising the read Q to-be-punctured bits as the first puncturing sequence.', '24. A communications apparatus, comprising: a memory, configured to store a program; and a processor, configured to execute the program stored in the memory, wherein when the program is executed, the processor is configured to perform the step according to any one of claims 1 to', '26. A computer-readable storage medium, comprising an instruction, wherein when the instruction runs on a computer, the computer is enabled to perform the method according to any one of claims 1 to']",False,"['1000', '1007', '1001', '1004', '1005', '1006', '1003', '1002', '10', '29']" 548,EP_3595220_A1 (6).png,EP3595220A1,METHOD AND APPARATUS FOR SENDING AND RECEIVING FEEDBACK INFORMATION,['FIG14'],['FIG14 is a schematic diagram of yet another possible network device according to this application '],"['When the processing unit 1302 is a processor, the communications unit 1303 is a transceiver, and the storage unit 1301 is a memory, the network device in this application may be a network device shown in FIG14.', 'Referring to FIG14, the network device 1400 includes a processor 1402, a transceiver 1403, and a memory 1401. The transceiver 1403, the processor 1402, and the memory 1401 may communicate with each other through an internal connection to transfer a control signal and/or a data signal.']",15,95,schematic diagram,H,"[{'element_identifier': '14', 'terms': ['andFIG.']}, {'element_identifier': '1400', 'terms': ['network device']}, {'element_identifier': '1403', 'terms': ['transceiver']}, {'element_identifier': '1402', 'terms': ['processor']}, {'element_identifier': '1401', 'terms': ['memory']}]","['27. A computer readable storage medium, storing a computer program, wherein when the computer program is run by a processing unit or a processor of a communications apparatus, the communications apparatus is enabled to perform the method according to any one of claims 1 to']",False,"['1400', '1403', '1402', '1401', '14', '26']" 549,EP_3595220_A1.png,EP3595220A1,METHOD AND APPARATUS FOR SENDING AND RECEIVING FEEDBACK INFORMATION,['FIG2'],['FIG2 is a schematic diagram of a CBG division method according to this application'],"['FIG2 is a schematic diagram of a TB division manner according to this application. As shown in FIG2, a first TB includes 42 CBs, which are mapped to 12 time domain symbols in a sequence of a frequency domain first and a time domain next, and the first TB is divided into 12 CBGs based on dimensions of the time domain symbols. Because a frequency domain resource corresponding to a single time domain symbol is limited, some CBs cannot be mapped to a same time domain symbol. For example, a CBG 1 includes a CB 1 to a CB 4, a CBG 2 includes the CB 4 to a CB 7, and the CB 4 is a common CB for the CBG 1 and the CBG 2.']",14,139,schematic diagram,H,"[{'element_identifier': '14', 'terms': ['andFIG.']}, {'element_identifier': '5', 'terms': ['CB']}, {'element_identifier': '12', 'terms': ['TB is divided into']}, {'element_identifier': '2', 'terms': ['CB']}, {'element_identifier': '110', 'terms': ['access network device']}, {'element_identifier': '42', 'terms': ['first TB includes']}, {'element_identifier': '16', 'terms': ['June']}, {'element_identifier': '3', 'terms': ['CB']}, {'element_identifier': '120', 'terms': ['terminal device']}]","['12. The method according to claim 11, wherein when the type of the PUCCH is a short PUCCH, and a terminal device sends, in a slot in which the short PUCCH is located, uplink data information or information carried by a long uplink control channel, the second feedback information is used to feed back the receiving status of each of the N TBs.']",False,"['110', '120', '11', '18', '25', '32', '39', '22', '29', '36', '5', '12', '19', '26', '33', '40', '16', '23', '30', '37', '13', '20', '27', '34', '41', '2', '3', '10', '17', '24', '31', '38', '14', '21', '28', '35', '42', '11', '18', '25', '32', '39', '2', '20']" 550,EP_3595243_A1 (1).png,EP3595243A1,EMAIL INTEGRATION WITH SHARED FOLDER BASED INTEGRATED WORKSPACES,['FIG2'],['FIG2 is a block diagram of an example system for providing shared folder backed integrated workspaces'],"['FIG2 is a block diagram of an example system 200 for providing shared folder backed integrated workspaces. For example, system 200 can correspond to system 100 described above. A user of client device 210 (e.g., 102i) can create an account with content management system 106. The user can create shared folder 214 associated with content management system 106 on client device 210. When shared folder 214 is created on client device 210, a corresponding shared folder 234 can be created on server device 230 of content management system 106. The user of client device 210 can share shared folder 214 with a user of client device 240 (e.g., 102j). Once shared folder 214 is shared with the user of client device 240, a corresponding shared folder 244 can be created on client device 240. As described above, content management system 106 can synchronize shared folders 214, 234 and 244 so that content items added, modified, or deleted on one of the shared folders (e.g., shared folder 244) are correspondingly added, modified, or deleted in the corresponding shared folders (e.g., shared folders 214, 234) on other devices.']",16,216,block diagram,G,"[{'element_identifier': '210', 'terms': ['client device', 'client devices']}, {'element_identifier': '214', 'terms': ['shared folder', 'shared folders']}, {'element_identifier': '230', 'terms': ['server device']}, {'element_identifier': '136', 'terms': ['workspace server']}, {'element_identifier': '242', 'terms': ['GUI']}, {'element_identifier': '104', 'terms': ['network']}, {'element_identifier': '234', 'terms': ['shared folder', 'shared folders']}, {'element_identifier': '240', 'terms': ['client device', 'client devices']}, {'element_identifier': '244', 'terms': ['shared folder', 'shared folders']}, {'element_identifier': '200', 'terms': ['system']}, {'element_identifier': '212', 'terms': ['WS GUI']}]","['1. A method comprising: generating, by an online content management system, a workspace graphical user interface representing a shared folder backed workspace that provides an integrated environment for manipulating content items in the shared folder and communicating with the authorized users of the shared folder, the workspace interface including representations of content items stored in the online shared folder and a message stream that includes messages generated by the authorized users of the shared folder; assigning a workspace email address to the shared folder; obtaining, by the online content management system, an email message addressed to the workspace email address from an email service of an authorized user of the workspace; and posting at least a portion of the email message as a new workspace message in the message stream.']",False,"['200', '240', '242', '244', '230', '234', '136', '104', '25', '210', '214', '212']" 551,EP_3595243_A1.png,EP3595243A1,EMAIL INTEGRATION WITH SHARED FOLDER BASED INTEGRATED WORKSPACES,['FIG1'],['FIG1 is a block diagram of an example system configuration for implementing shared folder backed integrated workspaces'],"['FIG1 is a block diagram of an example system configuration 100 for implementing shared folder backed integrated workspaces, wherein electronic devices communicate through a network for purposes of exchanging content and other data. The system can be configured for use on a wide area network such as that illustrated in FIG1. However, the present principles are applicable to a wide variety of network configurations that facilitate the intercommunication of electronic devices. For example, each of the components of system 100 in FIG1 can be implemented in a localized or distributed fashion in a network.']",17,101,block diagram,G,"[{'element_identifier': '122', 'terms': ['user interface module']}, {'element_identifier': '136', 'terms': ['workspace server']}, {'element_identifier': '130', 'terms': ['sharing module']}, {'element_identifier': '1', 'terms': ['embodiment']}, {'element_identifier': '100', 'terms': ['system']}, {'element_identifier': '126', 'terms': ['also include authenticator module']}, {'element_identifier': '104', 'terms': ['network']}, {'element_identifier': '102', 'terms': ['client devices']}, {'element_identifier': '134', 'terms': []}, {'element_identifier': '132', 'terms': ['synchronization module']}, {'element_identifier': '150', 'terms': ['user account database']}, {'element_identifier': '124', 'terms': ['Account management module']}, {'element_identifier': '120', 'terms': ['communications interface']}]","['1. A method comprising: generating, by an online content management system, a workspace graphical user interface representing a shared folder backed workspace that provides an integrated environment for manipulating content items in the shared folder and communicating with the authorized users of the shared folder, the workspace interface including representations of content items stored in the online shared folder and a message stream that includes messages generated by the authorized users of the shared folder; assigning a workspace email address to the shared folder; obtaining, by the online content management system, an email message addressed to the workspace email address from an email service of an authorized user of the workspace; and posting at least a portion of the email message as a new workspace message in the message stream.']",False,"['102', '109', '109', '104', '100', '105', '120', '122', '124', '126', '125', '130', '132', '134', '136', '150', '1', '16', '24']" 552,EP_3595248_A1 (2).png,EP3595248A1,STATIC ROUTE ADVERTISEMENT,['FIG3'],"['FIG3 is a flowchart illustrating an example mode of operation for a provider edge network device to advertise or suppress a static route for an EVPN instance, according to techniques described herein']","['FIG3 is a flowchart illustrating an example mode of operation for a provider edge network device to advertise or suppress a static route for an EVPN instance, according to techniques described herein. PE 10A receives configuration data configuring the PE 10A to multi-home CE 8 for an EVI (101). An EVI for VRF 22A may have multiple associated IRBs, including IRB 19A. PE 10A determines that IRB 19A of the one or more IRBs for the EVI for VRF 22A has a gateway L3 (e.g., IP) address (or routing interface L3 address) that shares a bridge domain L3 subnet with the gateway IP address for IRB 9 of CE 8 (102). Put another way, PE 10A finds the IRB of the one or more IRBs (here, IRB 19A) with a logical interface gateway IP address that shares an L3 subnet with the gateway IP address for IRB 9 of CE 8. This indicates that IRB 19A is the outbound logical interface of PE 10A for IRB 9 of CE 8.']",33,192,flowchart,H,"[{'element_identifier': '110', 'terms': ['remote PE 10C']}, {'element_identifier': '105', 'terms': ['domain in some instances']}, {'element_identifier': '101', 'terms': ['EVI']}, {'element_identifier': '21', 'terms': ['customer edge device.Example']}, {'element_identifier': '3', 'terms': ['layer']}]","['1. A method comprising: receiving, by a provider edge router of an intermediate layer 3 network, configuration data configuring the provider edge router to provide multi-homed layer 2 virtual bridge connectivity to a customer edge device using an active-standby mode of operation; and sending, by the provider edge router to a remote provider edge router, in response to receiving, from the customer edge device, a reply to a request for a layer 2 address of a layer 3 address of the customer edge device, a route advertisement that includes a static route specifying a layer 3 address of the customer edge device as a next-hop for a layer 3 subnet.']",False,"['100', '101', '102', '104', '105', '106', '110', '108', '3', '21']" 553,EP_3595259_A1 (2).png,EP3595259A1,METHOD AND APPARATUS FOR SEAMLESSLY IMPLEMENTING TRANSFERRING DUAL-PARTY CALL INTO CONFERENCE,['FIG4'],['FIG4 is a structural diagram of an apparatus for seamlessly implementing transfer of a dual-party call into a conference according to another embodiment of the present invention'],"['As shown in FIG4, a structural diagram of an apparatus for seamlessly implementing transfer of a dual-party call into a conference according to the present embodiment is illustrated. The present embodiment merely defines the channel establishing module 203, and all other structures are coincident with those of the above embodiments, and will not be described herein further.']",29,64,structural diagram,H,"[{'element_identifier': '201', 'terms': ['request receiving module']}, {'element_identifier': '230', 'terms': ['first terminal']}, {'element_identifier': '202', 'terms': ['conference room creating module']}, {'element_identifier': '440', 'terms': ['first establishing unit']}, {'element_identifier': '441', 'terms': ['second establishing unit']}, {'element_identifier': '451', 'terms': ['information notification sub-unit']}, {'element_identifier': '204', 'terms': ['channel releasing module']}, {'element_identifier': '232', 'terms': ['third terminal']}, {'element_identifier': '4', 'terms': ['conference room creating request.Embodiment']}, {'element_identifier': '231', 'terms': ['second terminal']}]","['1. A method for establishing a conference, comprising: receiving, by a server, conference room creating request sent by a first terminal for creating the conference room by inviting a third terminal to participate in the conference, wherein the first terminal is conversing with a second terminal device via a dual-party voice channel; creating a conference room according to the conference room creating request; establishing a first voice channel between the first terminal and the conference room; establishing a second voice channel between the second terminal and the conference room; establishing a third voice channel between the third terminal and the conference room; after starting the first voice channel and the second voice channel, releasing the dual-party voice channel between the first terminal and the second terminal.']",False,"['232', '202', '201', '441', '440', '451', '230', '231', '204', '4', '14']" 554,EP_3595259_A1 (3).png,EP3595259A1,METHOD AND APPARATUS FOR SEAMLESSLY IMPLEMENTING TRANSFERRING DUAL-PARTY CALL INTO CONFERENCE,['FIG5'],['FIG5 is a structural diagram of an apparatus for seamlessly implementing transfer of a dual-party call into a conference according to another embodiment of the present invention '],"['As shown in FIG5, a structural diagram of an apparatus for seamlessly implementing transfer of a dual-party call into a conference according to the present embodiment is illustrated. The present embodiment merely further defines the channel establishing module 203, and all other structures are coincident with those of the above embodiments, and will not be described herein further.']",29,65,structural diagram,H,"[{'element_identifier': '201', 'terms': ['request receiving module']}, {'element_identifier': '230', 'terms': ['first terminal']}, {'element_identifier': '202', 'terms': ['conference room creating module']}, {'element_identifier': '203', 'terms': ['channel establishing module']}, {'element_identifier': '440', 'terms': ['first establishing unit']}, {'element_identifier': '441', 'terms': ['second establishing unit']}, {'element_identifier': '451', 'terms': ['information notification sub-unit']}, {'element_identifier': '452', 'terms': ['channel establishing sub-unit']}, {'element_identifier': '502', 'terms': ['channel starting unit']}, {'element_identifier': '204', 'terms': ['channel releasing module']}, {'element_identifier': '232', 'terms': ['third terminal']}, {'element_identifier': '501', 'terms': ['closing holding unit']}, {'element_identifier': '231', 'terms': ['second terminal']}, {'element_identifier': '503', 'terms': ['command transmitting module']}, {'element_identifier': '442', 'terms': ['third establishing unit']}]","['1. A method for establishing a conference, comprising: receiving, by a server, conference room creating request sent by a first terminal for creating the conference room by inviting a third terminal to participate in the conference, wherein the first terminal is conversing with a second terminal device via a dual-party voice channel; creating a conference room according to the conference room creating request; establishing a first voice channel between the first terminal and the conference room; establishing a second voice channel between the second terminal and the conference room; establishing a third voice channel between the third terminal and the conference room; after starting the first voice channel and the second voice channel, releasing the dual-party voice channel between the first terminal and the second terminal.']",False,"['232', '202', '201', '442', '203', '441', '502', '452', '440', '451', '230', '231', '501', '204', '503', '15']" 555,EP_3595268_A1.png,EP3595268A1,"STREAMING MEDIA RESOURCE DISTRIBUTION METHOD, SYSTEM, EDGE NODE AND CENTRAL DISPATCHING SYSTEM",['FIG2'],['FIG2 is a diagram of a system for distributing a streaming media resource according to some embodiments of the present disclosure'],"['The present disclosure provides a system for distributing a streaming media resource. Referring to FIG2, the system includes a push-stream edge node, a pull-stream edge node, a level 2 cache node, a source node, and a central scheduling system. In the present embodiment, the push-stream edge node and the source node have the same configuration information, and the pull-stream edge node and the level 2 cache node have the same configuration information. The same configuration information may refer to that the hardware resources and software resources of the server in the node are consistent, and the domain names in the nodes are also consistent for the same streaming media resource. In this way, the push-stream edge node and the pull-stream edge node can undertake the service of the normal edge node, and at the same time, the push-stream edge node can also undertake the service of the source node, and the pull-stream edge node can also undertake the service of the level 2 cache node. As shown in FIG2, in the embodiment, the central scheduling system may provide a push-stream uploading interface, and the push-stream uploading interface may receive the push-stream information uploaded by the push-stream edge node. In addition, the central scheduling system may further provide a pull-stream query interface, where the pull-stream query interface may receive a pull-stream query request sent by the pull-stream edge node, and feedback the corresponding query result to the pull-stream edge node.', 'Referring to FIG2, the present disclosure further provides a distribution system for streaming media resources, where the system includes a push-stream edge node, a pull-stream edge node, a level 2 cache node, a source node, and a central scheduling system, where:']",21,352,diagram,H,"[{'element_identifier': '2', 'terms': ['level']}]","['13. A system for distributing a streaming media resource, characterized in that , that the system comprises a push-stream edge node, a pull-stream edge node, a level 2 cache node, a source node, and a central scheduling system, wherein: the push-stream edge node and the source node have same configuration information, and the pull-stream edge node and the level 2 cache node have same configuration information; the push-stream edge node is configured to perform the steps of claim 6 or 7; the pull-stream edge node is configured to perform the steps of any one of claims 1 to 4; and the central scheduling system is configured to perform the steps of any of claims 9-']",False,"['2', '12']" 556,EP_3595297_A1 (2).png,EP3595297A1,"ABNORMALITY DETECTION METHOD, NETWORK VIDEO RECORDER (NVR) AND VIDEO SERVER",['FIG5'],['FIG5 is a schematic structural diagram of an NVR according to an embodiment of the present application'],"['In order to achieve the above technical object, an embodiment of the present application further provides an NVR, which is applicable to a video surveillance system comprising a video server, the NVR, and a front-end device, as shown in FIG5, the NVR comprising:']",17,52,schematic structural diagram,H,"[{'element_identifier': '620', 'terms': ['extraction module']}, {'element_identifier': '640', 'terms': ['anda judgment module']}, {'element_identifier': '630', 'terms': ['generation module']}, {'element_identifier': '610', 'terms': ['storage module']}, {'element_identifier': '510', 'terms': ['receiving module']}, {'element_identifier': '520', 'terms': ['anda sending module']}]","['13. A network video recorder (NVR), which is applicable to a video surveillance system comprising a video server, the NVR, and a front-end device, characterized in that the NVR comprises: a receiving module configured to receive first keep-alive information from the front-end device, wherein the first keep-alive information carries first verification information, and the first verification information is generated according to processes run by the front-end device when sending the first keep-alive information; and a sending module configured to send the first verification information to the video server with the first verification information carried in second keep-alive information, so that the video server determines, according to the first verification information and second verification information on the front-end device, whether an abnormality has occurred in the front-end device, wherein the second verification information is generated according to a process running on the front-end device in a normal running status.', '15. A video server, which is applicable to a video surveillance system comprising a network video recorder (NVR), the video server, and a front-end device, characterized in that a corresponding relation between an ID, device feature information, and second process feature information on the front-end device is stored in the video server, the video server comprising: an extraction module configured to extract, when second keep-alive information from the NVR is received, the ID and first verification information carried in the second keep-alive information, wherein the first verification information is generated according to processes run by the front-end device when sending the first keep-alive information; a generation module configured to generate the second verification information by using the device feature information and the second process feature information corresponding to the ID; and a judgment module configured to judge whether the first verification information matches the second verification information, and confirming that the front-end device is running normally when the judgment result is yes, and confirming that an abnormality has occurred in the front-end device when the judgment result is no.', '16. The video server according to claim 15 further comprising: a storage module configured to pre-store a corresponding relation between the ID, the device feature information, and the second process feature information on the front-end device in the video server, wherein the second process feature information is corresponding to processes running on the front-end device in a normal running status, and the device feature information is corresponding to device information on the front-end device.']",True,"['510', '520', '5', '610', '620', '630', '640', '9', '22']" 557,EP_3595330_A1 (1).png,EP3595330A1,AUDIO OUTPUT DEVICE,['FIG3'],['FIG3 is a plan view showing example outputs of the audio output device of FIG1'],"['FIG3 is a plan view, indicated generally by the reference numeral 20, showing example outputs of the audio output device 1. The plan view 20 includes the first to sixth loudspeakers directional 2 to 7 described above and the various audio outputs direction described above.', 'As shown in the plan view 20, the first loudspeaker 2 provides an audio output in a reference direction. In the example of FIG3, the audio output in the reference direction is a first song (song N, as labelled in FIG3).', 'Further, as shown in FIG3, a second song (song N+1) is provided in the 45 degree direction, a third song (song N+2) is provided in the 90 degree direction, a fourth song (song N+3) is provided in the 135 degree direction and a fifth song (song N+4) is provided in the 180 degree direction. Furthermore, a sixth song (song N-1) is provided in the 315 degree direction, a seventh song (song N-2) is provided in the 270 degree direction and an eighth song (song N-3) is provided in the 225 degree direction. Of course, the audio outputs shown in FIG3 are examples only.', 'The eight songs shown in FIG3 may form part of a playlist of songs, with different songs being output in different directions. In one example embodiment, the first song (song N) is played louder than the other songs. The other songs may all be played at a similar volume or may themselves be output at different volumes. For example, the volume at which a song is output may be dependent on the angle between the reference direction and the direction in which the song is output (such that, for example, the songs N+3 and N-3 are played more quietly than the songs N+2 and N-2, with the songs N+2 and N-2 being played more quietly than the songs N+1 and N-1).']",15,362,plan view,H,"[{'element_identifier': '30', 'terms': ['audio output device']}, {'element_identifier': '38', 'terms': ['first input means']}, {'element_identifier': '4', 'terms': ['third loudspeaker']}, {'element_identifier': '20', 'terms': ['plan view']}, {'element_identifier': '40', 'terms': ['second input means']}, {'element_identifier': '3', 'terms': ['second loudspeaker']}, {'element_identifier': '32', 'terms': ['sixth loudspeakers']}]","['1. An apparatus comprising: means for controlling a plurality of audio outputs of a multi-directional audio output device; means for receiving a first user input for indicating a first direction, wherein based, at least in part, on the first user input, a first one of the plurality of audio outputs is configured to be output in the first direction and is defined as a first audio output; and means for receiving a second user input for indicating a change in an audio setup of the multi-directional audio output device.']",True,"['20', '3', '30', '35', '34', '36', '38', '40', '33', '37', '32', '4', '11']" 558,EP_3595330_A1 (2).png,EP3595330A1,AUDIO OUTPUT DEVICE,['FIG5'],['FIG5 is a flow chart showing an algorithm in accordance with an example embodiment'],"['FIG5 is a flow chart showing an algorithm, indicated generally by the reference numeral 40, in accordance with an example embodiment. The algorithm 40 includes the operations 12 and 13 described above.', 'Viewing in conjunction with FIG5, when a user indication is received from the user 62 (operation 11), the first interactive object 64 is added to the interactive object queue (operation 12) and the first control area 82 is provided to the user 62 (operation 13). The first control area 82 is corresponding to the first interactive object 64, such that the user 62 may be capable of interacting with the first interactive object 64 by pointing towards, or being within, the first control area 82 (operation 14). As such, since the user 62 is not required to look at or point directly towards the first interactive object 64, the user is less likely to be disrupted while performing other tasks in the virtual reality environment. The first control area 82 may be provided in the general direction of the first interactive object 64. However, this is optional, such that the first control area 82 may be provided in any direction in the vicinity of the user 62.']",14,226,flowchart,H,"[{'element_identifier': '5', 'terms': ['fourth loudspeaker']}, {'element_identifier': '62', 'terms': ['audio output device']}, {'element_identifier': '56', 'terms': ['At operation']}, {'element_identifier': '52', 'terms': ['operation']}, {'element_identifier': '66', 'terms': ['second user']}, {'element_identifier': '50', 'terms': ['algorithm', 'algorithms']}, {'element_identifier': '58', 'terms': ['At operation']}, {'element_identifier': '54', 'terms': ['operation']}, {'element_identifier': '60', 'terms': ['reference numeral', 'user interaction']}, {'element_identifier': '68', 'terms': ['touching']}]","['1. An apparatus comprising: means for controlling a plurality of audio outputs of a multi-directional audio output device; means for receiving a first user input for indicating a first direction, wherein based, at least in part, on the first user input, a first one of the plurality of audio outputs is configured to be output in the first direction and is defined as a first audio output; and means for receiving a second user input for indicating a change in an audio setup of the multi-directional audio output device.']",True,"['50', '52', '54', '56', '58', '5', '60', '66', '68', '62', '9', '12']" 559,EP_3595330_A1 (6).png,EP3595330A1,AUDIO OUTPUT DEVICE,['FIG15'],['FIG15 is a table showing example outputs of the audio output device of FIG14'],"['FIG15 is a table, indicated generally by the reference numeral 150, showing example outputs of the audio output device of FIG14. Outputs in five different loudspeaker directions are provided (namely, 135 degrees, 90 degrees, 45 degrees, 0 degrees and 315 degrees). As a result of the first user input 144, the 45 direction is indicated as the reference direction.', 'The audio output (a song in the example of FIG15) that is output in each direction is dependent on the second input 145 provided by the user 142. Thus, in the event of a loudspeaker rotation of θ1 being indicated, the songs are allocated to the loudspeakers as indicated in the first column of the table 150. In the event of a loudspeaker rotation of θ2 being indicated, the songs are allocated to the loudspeakers as indicated in the second column of the table 150. Similarly, in the event of a loudspeaker rotation of θ3 being indicated, the songs are allocated to the loudspeakers as indicated in the third column of the table 150.']",14,197,table,H,"[{'element_identifier': '150', 'terms': ['table']}, {'element_identifier': '164', 'terms': ['operation', 'operations']}, {'element_identifier': '160', 'terms': ['algorithm', 'algorithms']}, {'element_identifier': '2', 'terms': ['loudspeakers', 'loudspeaker']}, {'element_identifier': '45', 'terms': ['at']}, {'element_identifier': '90', 'terms': ['reference numerals']}, {'element_identifier': '162', 'terms': ['operation', 'operations']}, {'element_identifier': '0', 'terms': ['is at']}, {'element_identifier': '315', 'terms': ['is output at']}, {'element_identifier': '135', 'terms': ['is output at']}]","['1. An apparatus comprising: means for controlling a plurality of audio outputs of a multi-directional audio output device; means for receiving a first user input for indicating a first direction, wherein based, at least in part, on the first user input, a first one of the plurality of audio outputs is configured to be output in the first direction and is defined as a first audio output; and means for receiving a second user input for indicating a change in an audio setup of the multi-directional audio output device.', '10. An apparatus as claimed in any one of the preceding claims, wherein the audio output device comprises a loudspeaker or a plurality of loudspeakers.']",True,"['150', '0', '0', '2', '0', '135', '90', '45', '0', '315', '15', '160', '162', '16', '164', '17']" 560,EP_3595330_A1.png,EP3595330A1,AUDIO OUTPUT DEVICE,['FIG2'],['FIG2 is a plan view of the multi-directional audio output device of FIG1'],"['FIG2 is a plan view, indicated generally by the reference numeral 10, of the multi-directional audio output device 1. The plan view 10 includes the first to sixth loudspeakers 2 to 7 described above. Each of the loudspeakers is orientated in a different direction such that each loudspeaker can provide an audio output in a different direction. Thus, as shown in FIG2, the first loudspeaker 2 is orientated in a first direction having an angle 0 degrees, with each of the other loudspeakers being orientated in a direction having an angle relative to the angle of the first loudspeaker. Specifically, the second loudspeaker 3 is orientated in a direction having an angle 45 degrees, the third loudspeaker 4 is orientated in a direction having an angle 135 degrees, the fourth loudspeaker 5 is orientated in a direction having an angle 180 degrees, the fifth loudspeaker 6 is orientated in a direction having an angle 225 degrees, and the sixth loudspeaker 7 is orientated in a direction having an angle 315. Of course, in any particular embodiment, the number of loudspeakers and the relative angles of those loudspeakers may be different to that shown in FIG2.', 'The loudspeakers 2 to 7 can provide audio outputs in the directions of the respective loudspeakers, but audio output can, of course, be provided in other directions. By way of example, as indicated by the dotted lines in FIG2, audio outputs may be provided in the directions 0 degrees (referred to below as the reference direction), 45 degrees, 90 degrees, 135 degrees, 180 degrees, 225 degrees, 270 degrees and 315 degrees. Of course, the directions shown in FIG2 are provided by way of example only. Any combination of directions could, in principle, be provided by the audio output device 1.']",15,336,plan view,H,"[{'element_identifier': '225', 'terms': ['is output at']}, {'element_identifier': '1', 'terms': ['device']}, {'element_identifier': '45', 'terms': ['at']}, {'element_identifier': '2', 'terms': ['loudspeakers', 'loudspeaker']}, {'element_identifier': '90', 'terms': ['reference numerals']}, {'element_identifier': '180', 'terms': ['angle']}, {'element_identifier': '315', 'terms': ['is output at']}, {'element_identifier': '10', 'terms': ['reference numeral', 'plan view', 'output']}, {'element_identifier': '3', 'terms': ['second loudspeaker']}, {'element_identifier': '135', 'terms': ['is output at']}]","['1. An apparatus comprising: means for controlling a plurality of audio outputs of a multi-directional audio output device; means for receiving a first user input for indicating a first direction, wherein based, at least in part, on the first user input, a first one of the plurality of audio outputs is configured to be output in the first direction and is defined as a first audio output; and means for receiving a second user input for indicating a change in an audio setup of the multi-directional audio output device.', '10. An apparatus as claimed in any one of the preceding claims, wherein the audio output device comprises a loudspeaker or a plurality of loudspeakers.']",True,"['3', '2', '1', '180', '225', '270', '135', '90', '45', '315', '2', '10']" 561,EP_3595335_A1 (3).png,EP3595335A1,RADIAL MAGNETIC CIRCUIT ASSEMBLY DEVICE AND ASSEMBLING METHOD,['FIG4'],['FIG4 depicts a schematic structural diagram of assembling each tile-shaped magnet with a magnetic central column in a radial magnetic circuit assembly method provided by an embodiment of the present invention'],"['As shown in FIG4, it needs be further noted that, a radial magnetizing needs to be performed on each tile-shaped magnet 30 before assembly of the tile-shaped magnet 30, the arrows indicate the directions of the magnetic fields of each tile-shaped magnet 30, when each tile-shaped magnet 30 is mounted on the limit step 43, the tile-shaped magnet 30 may also connected with the small-diameter section 42 in magnetically attractive manner.']",33,89,schematic structural diagram,H,"[{'element_identifier': '42', 'terms': ['section']}, {'element_identifier': '30', 'terms': ['tile-shaped magnet', 'tile-shaped magnets']}, {'element_identifier': '43', 'terms': ['limit step']}, {'element_identifier': '40', 'terms': ['magnetic central column']}]","['1. A radial magnetic circuit assembly device configured to mount an upper axial magnetic sheet and a lower axial magnetic sheet respectively on an upper axial side surface and a lower axial side surface of each of a plurality of tile-shaped magnets, characterized in that , the radial magnetic circuit assembly device comprises: a magnetic central column, and a lower lantern ring and an upper lantern ring sleeved on the magnetic central column, wherein the magnetic central column comprises a large-diameter section and a small-diameter section connected in sequence, a joint of the large-diameter section and the small-diameter section is provided with a limit step on which each tile-shaped magnet is annularly and uniformly arranged, the lower lantern ring is sleeved on the tile-shaped magnet in a direction from the large-diameter section towards the small-diameter section and is configured to limit a radial displacement of each tile-shaped magnet, and the upper lantern ring is sleeved on the tile-shaped magnet in a direction from the small-diameter section towards the large-diameter section to press the upper axial magnetic sheet and the lower axial magnetic sheet against the upper axial side surface and the lower axial side surface of each tile-shaped magnet respectively.']",False,"['42', '43', '40', '30', '12']" 562,EP_3595343_A1 (3).png,EP3595343A1,"COMMUNICATION METHOD, APPARATUS AND SYSTEM",['FIG8'],['FIG8 is a schematic structural diagram of a network side device according to an embodiment of the present invention'],"['As shown in FIG8, the network side device further includes:a first sending module 740, configured to send a second message to the terminal, where the second message carries the ciphertext of the context information of the terminal.']",19,43,schematic structural diagram,H,"[{'element_identifier': '740', 'terms': ['first sending module']}, {'element_identifier': '730', 'terms': ['connection module']}, {'element_identifier': '710', 'terms': ['receiving module']}, {'element_identifier': '720', 'terms': ['decryption module']}]","['14. A network side device, comprising: a receiving module, configured to receive a first message sent by a terminal, wherein the first message carries ciphertext of context information of the terminal, and the ciphertext of the context information is information obtained by encrypting the context information of the terminal; an encryption and decryption module, configured to: obtain a first key, and decrypt the ciphertext of the context information based on the first key, to obtain the context information; and a connection module, configured to establish a communication connection for the terminal based on the context information.', '15. The network side device according to claim 14, wherein the encryption and decryption module is further configured to: encrypt the context information of the terminal based on the first key, to obtain the ciphertext of the context information of the terminal; and the network side device further comprises: a first sending module, configured to send a second message to the terminal, wherein the second message carries the ciphertext of the context information of the terminal.']",True,"['710', '720', '730', '7', '710', '720', '730', '740', '8', '25']" 563,EP_3595352_A1 (1).png,EP3595352A1,"METHOD FOR TRANSMITTING INFORMATION, METHOD FOR RECEIVING INFORMATION, NETWORK DEVICE AND TERMINAL DEVICE",['FIG4'],['FIG4 is a schematic diagram of a time segment according to an embodiment of this application'],"['For example, as shown in FIG4, when N is 2, the first time segment, the second time segment, and a third time segment may belong to a same subframe.', 'For example, as shown in FIG4, the first time segment includes one symbol, and/or the kth second time segment includes one symbol, to save resource overheads used for measurement between the terminal devices.', 'For another example, as shown in FIG4, the first indication information is carried in downlink control information, and the downlink control information carrying the first indication information is transmitted on a downlink physical control channel in a subframe, that is, the first terminal device receives the first indication information on the downlink physical control channel.']",16,136,schematic diagram,H,"[{'element_identifier': '420', 'terms': ['transceiver unit']}, {'element_identifier': '400', 'terms': ['network device']}, {'element_identifier': '5', 'terms': ['May']}, {'element_identifier': '410', 'terms': ['processing unit']}]","['1. A method for sending information, comprising: determining, by a first network device, first indication information, wherein the first indication information is used to indicate a first time segment and N second time segments, the first time segment is used by a first terminal device to send a first measurement signal to at least one second terminal device in coverage of N second network devices, and a k th second time segment of the N second time segments is used by the first terminal device to receive a second measurement signal from a second terminal device in the coverage of a k th second network device of the N second network devices, wherein N is a positive integer, and k = 1, 2, ..., and N; and sending, by the first network device, the first indication information to the first terminal device.', '10. A network device, comprising: a processing unit, configured to determine first indication information, wherein the first indication information is used to indicate a first time segment and N second time segments, the first time segment is used by a first terminal device to send a first measurement signal to at least one second terminal device in coverage of N second network devices, and a k th second time segment of the N second time segments is used by the first terminal device to receive a second measurement signal from a second terminal device in the coverage of a k th second network device of the N second network devices, wherein N is a positive integer, and k = 1, 2, ..., and N; and a transceiver unit, configured to send the first indication information to the first terminal device.']",True,"['3', '4', '400', '410', '420', '5', '15']" 564,EP_3595352_A1 (2).png,EP3595352A1,"METHOD FOR TRANSMITTING INFORMATION, METHOD FOR RECEIVING INFORMATION, NETWORK DEVICE AND TERMINAL DEVICE",['FIG7'],['FIG7 is a schematic block diagram of a terminal device according to an embodiment of this application'],"['FIG7 is a schematic block diagram of a terminal device 600 according to an embodiment of this application.', 'As shown in FIG7, the terminal device includes a transceiver unit 610 and a processing unit 620, where the transceiver unit 610 is configured to:receive first indication information sent by a first network device, where the first indication information is used to indicate a first time segment and N second time segments, the first time segment is used to send a first measurement signal to at least one second terminal device in coverage of N second network devices, and a kth second time segment of the N second time segments is used to receive a second measurement signal from a second terminal device in the coverage of a kth second network device in the N second network devices, where N is a positive integer, and k = 1, 2, ..., and N; and the processing unit 620 is configured to: send, in the first time segment according to the first indication information, the first measurement signal to the second terminal devices in the coverage of the N second network devices, and receive, in the Nth second time segment according to the first indication information, the second measurement signal from the second terminal device in the coverage of each of the N second network devices.']",17,244,schematic block diagram,H,"[{'element_identifier': '620', 'terms': ['processing unit']}, {'element_identifier': '710', 'terms': ['processor']}, {'element_identifier': '1', 'terms': ['when N is']}, {'element_identifier': '730', 'terms': ['memory']}, {'element_identifier': '600', 'terms': ['terminal device']}, {'element_identifier': '500', 'terms': ['network device']}, {'element_identifier': '530', 'terms': ['memory']}, {'element_identifier': '720', 'terms': ['transceiver']}, {'element_identifier': '610', 'terms': ['transceiver unit']}, {'element_identifier': '510', 'terms': ['processor']}, {'element_identifier': '520', 'terms': ['transceiver']}, {'element_identifier': '700', 'terms': ['terminal device']}]","['1. A method for sending information, comprising: determining, by a first network device, first indication information, wherein the first indication information is used to indicate a first time segment and N second time segments, the first time segment is used by a first terminal device to send a first measurement signal to at least one second terminal device in coverage of N second network devices, and a k th second time segment of the N second time segments is used by the first terminal device to receive a second measurement signal from a second terminal device in the coverage of a k th second network device of the N second network devices, wherein N is a positive integer, and k = 1, 2, ..., and N; and sending, by the first network device, the first indication information to the first terminal device.', '10. A network device, comprising: a processing unit, configured to determine first indication information, wherein the first indication information is used to indicate a first time segment and N second time segments, the first time segment is used by a first terminal device to send a first measurement signal to at least one second terminal device in coverage of N second network devices, and a k th second time segment of the N second time segments is used by the first terminal device to receive a second measurement signal from a second terminal device in the coverage of a k th second network device of the N second network devices, wherein N is a positive integer, and k = 1, 2, ..., and N; and a transceiver unit, configured to send the first indication information to the first terminal device.']",True,"['500', '510', '520', '530', '6', '600', '610', '620', '7', '700', '710', '1', '1', '720', '730', '16']" 565,EP_3595377_A1.png,EP3595377A1,"METHOD, APPARATUS AND SYSTEM FOR CONFIGURING TRANSMISSION RESOURCE",['FIG2'],['FIG2 is a schematic hardware diagram of a base station according to an embodiment of the present invention'],"['The network device provided in the embodiments of the present invention may be a base station (for example, may be a common base station or an evolved NodeB (evolved node base station, eNB)), or may an access point (access point, AP) or another device with an access function. For example, in the embodiments of the present invention, the common base station is used as an example to describe a hardware structure of the base station. The following describes components of the base station provided in the embodiments of the present invention in detail with reference to FIG2. As shown in FIG2, the base station provided in the embodiments of the present invention may include a building baseband unit (building base band unit, BBU) 20, a radio remote unit (radio remote unit, RRU) 21, and an antenna 22. The BBU 20 and the RRU 21 may be connected via an optical fiber, and the RRU 21 is further connected to the antenna 22 via a coaxial cable and a power splitter (or a coupler). Generally, one BBU 20 may be connected to a plurality of RRUs 21.', 'The processing module 70 may be a processor or a controller (for example, may be the BBU 20 shown in FIG2), for example, may be a CPU, a general purpose processor, a DSP, an ASIC, an FPGA or another programmable logic device, a transistor logic device, a hardware component, or any combination thereof. The processing module 70 may implement or execute various example logical blocks, modules, and circuits described with reference to content disclosed in the embodiments of the present invention. Alternatively, the processor may be a combination of processors implementing a computing function, for example, a combination that includes one or more microprocessors, or a combination of a DSP and a microprocessor. The communications module 71 may be a transceiver, a transceiver circuit, a communications interface, or the like (for example, may be the RRU 21 shown in FIG2). The storage module 72 may be a memory.']",18,395,schematic diagram,H,"[{'element_identifier': '30', 'terms': ['processor']}, {'element_identifier': '12', 'terms': ['terminal']}, {'element_identifier': '11', 'terms': ['network device']}, {'element_identifier': '22', 'terms': ['antenna']}, {'element_identifier': '20', 'terms': ['BBU']}, {'element_identifier': '10', 'terms': ['terminal']}, {'element_identifier': '21', 'terms': ['RRU']}]","['1. A transmission resource configuration method, comprising: receiving, by a terminal, at least one piece of first transmission resource pool configuration information sent by a network device, wherein the first transmission resource pool configuration information comprises at least a first transmission resource pool identifier and first transmission resource pool resource configuration information; when the terminal determines that a first transmission resource pool corresponding to the first transmission resource pool identifier is in a first state, independently selecting, by the terminal, a direct link transmission resource from time-frequency transmission resources corresponding to the first transmission resource pool resource configuration information; and sending, by the terminal, direct link service data by using the direct link transmission resource.', '15. A terminal, comprising a processor and a memory coupled to the processor; and the memory is configured to store a computer instruction, and when the terminal runs, the processor executes the computer instruction stored in the memory, so that the terminal performs the transmission resource configuration method according to any one of claims 1 to']",False,"['11', '10', '12', '22', '22', '21', '20', '30']" 566,EP_3595404_A1 (1).png,EP3595404A1,MULTI POLYMER POSITIVE TEMPERATURE COEFFICIENT HEATER,"['FIG3', ' FIG4']","['FIG3 is a simplified view of an alternative PTC heating element ', 'FIG4 is a simplified view of a second alternative PTC heating element']","['FIG3 is a simplified view of alternative heating element 110, which is similar to heating element 10 in that it employs bus bars 12 and power source 18 in generally the same manner. As shown, heating element 110 includes polymer inks 114 and 116, which are similar to polymer inks 14 and 16, as discussed above, except that they are arranged as layers in a parallel relationship. In this sense, the total resistance (RT) of element 110 is calculated based on the sum of each polymer ink layer, such that 1/RT = 1/R1 + 1/R2. Due to this relationship, the total resistance RT will always be less than that of any individual resistor, and RT will decrease with each additional polymer ink layer added in this manner to element 110. Such an embodiment can be useful, for example, in certain heating applications for which one of the commercially available PTC inks has a resistance that is too high for such applications. ', 'FIG4 is a simplified view of second alternative heating element 210, which is similar to element 10, except that it includes three polymer inks-214, 216, 224-arranged as layers in series. Third polymer ink 224 can be any of the commercially available inks discussed above with respect to element 10, and has different properties than either polymer ink 214 or 216. The addition of polymer ink 224 can help further customize the operating range of element 210. Alternative embodiments can further include a parallel arrangement and/or more than three polymer inks arranged in series or parallel.']",23,291,simplified view,B,"[{'element_identifier': '210', 'terms': ['element']}, {'element_identifier': '214', 'terms': ['than either polymer ink']}, {'element_identifier': '12', 'terms': ['bus bars', 'bus bar']}, {'element_identifier': '116', 'terms': ['includes polymer inks']}, {'element_identifier': '18', 'terms': ['power source']}, {'element_identifier': '110', 'terms': ['element']}, {'element_identifier': '224', 'terms': ['polymer ink']}, {'element_identifier': '114', 'terms': ['includes polymer inks']}]","['1. A heating element comprising: a first bus bar (12) disposed to receive current from a power source; a second bus bar (12) non-adjacent to the first bus bar; and a polymer ink section extending between the first and second bus bars, the section comprising a plurality of PTC polymer inks (14,16) each different from one another; wherein the second bus bar is electrically connected to the first bus bar via the polymer ink section.']",True,"['110', '114', '12', '18', '12', '116', '3', '210', '12', '18', '12', '214', '216', '224', '4']" 567,EP_3595404_A1.png,EP3595404A1,MULTI POLYMER POSITIVE TEMPERATURE COEFFICIENT HEATER,['FIG2'],['FIG2 is a cross-sectional view of the PTC heating element showing additional layers'],"['Referring to FIG2, bus bars 12, polymer inks/layers 14 and 16 are disposed between dielectric layer 20 and adhesive layer 22. A second dielectric layer 20 is disposed on a side of adhesive layer opposite bus bars 12, polymer inks/layers 14 and 16. Each dielectric layer 20 can be formed from a polymer material, and can be arranged as a film, or one or more sheets or plies. An exemplary polymer can include a polyimide, such as Kapton®, because of its dielectric and non-flammable properties. Other suitable polymers having robust dielectric, mechanical, and thermal properties are contemplated herein. Adhesive layer 22 can help secure the other components of heating element 10, and can be formed generally from a thermally conductive, commercially available adhesive.']",15,147,cross-sectional view,B,"[{'element_identifier': '14', 'terms': ['polymer inks', 'polymer ink']}, {'element_identifier': '12', 'terms': ['bus bars', 'bus bar']}, {'element_identifier': '22', 'terms': ['adhesive layer']}, {'element_identifier': '18', 'terms': ['power source']}, {'element_identifier': '20', 'terms': ['dielectric layer', 'dielectric layers']}, {'element_identifier': '16', 'terms': ['polymer inks', 'polymer ink']}, {'element_identifier': '10', 'terms': ['element']}]","['1. A heating element comprising: a first bus bar (12) disposed to receive current from a power source; a second bus bar (12) non-adjacent to the first bus bar; and a polymer ink section extending between the first and second bus bars, the section comprising a plurality of PTC polymer inks (14,16) each different from one another; wherein the second bus bar is electrically connected to the first bus bar via the polymer ink section.']",True,"['14', '16', '12', '18', '12', '1', '10', '20', '22', '12', '20', '12', '14', '16', '2']" 568,EP_3597067_A1 (3).png,EP3597067A1,SOLE STRUCTURE WITH BLADDER FOR ARTICLE OF FOOTWEAR AND METHOD OF MANUFACTURING THE SAME,['FIG8'],['FIG8 is a section view of the plate taken along the line 8-8 of FIG7'],"['In some embodiments, the base 142 can be relatively flat and smooth. In other embodiments, the base 142 can have some curvature. For example, as shown in FIG8, the base 142 can be relatively flat over the majority of the base 142; however, the base 142 can curve upwards slightly at the peripheral edge 148 to, in effect, ""cup"" the wearer\'s foot.', 'As stated, the rib 164 can be spaced inwardly from the peripheral edge 148 of the base 142. As such, an outer area 175 of second surface 146 of base 142 can be defined, extending from the peripheral edge 148 to the rib 164. More specifically, in the embodiments of FIG8, the outer area 175 can include a medial outer area 177 that extends from the medial peripheral edge 150 to the first segment 172 of the rib 164. Also, as shown, the outer area 175 can include a lateral outer area 179 that extends from the lateral peripheral edge 152 to the third segment 176. Moreover, as shown in FIG7, the outer area 175 can include a heel outer area 185 that extends from the heel peripheral edge 154 to the second segment 174 of the rib 164.', 'Moreover, the shape, dimensions, and surface features of the rib 164 can be preselected to provide the desired stiffness and flexibility for the plate 136. For example, the rib 164 can have a substantially constant height 183 along its length in some embodiments. In other embodiments, the height 183 can vary along its length, and areas of reduced height 183 can be more flexible than areas of increased height 183. Moreover, the cross sectional profile of the rib 164 represented in FIG8 can be substantially constant along the length of the rib 164 in some embodiments. In other embodiments, the cross sectional profile of the rib 164 can vary along its length.']",17,356,section view,A,"[{'element_identifier': '166', 'terms': ['first side surface']}, {'element_identifier': '199', 'terms': ['area']}, {'element_identifier': '142', 'terms': ['base']}, {'element_identifier': '160', 'terms': ['medial heel notch']}, {'element_identifier': '158', 'terms': ['notches']}, {'element_identifier': '174', 'terms': ['second segment']}, {'element_identifier': '178', 'terms': ['breaks', 'break']}, {'element_identifier': '112', 'terms': ['midfoot region']}, {'element_identifier': '152', 'terms': ['edge']}, {'element_identifier': '180', 'terms': ['second break']}, {'element_identifier': '115', 'terms': ['lateral side']}, {'element_identifier': '175', 'terms': ['outer area']}, {'element_identifier': '144', 'terms': ['first surface']}, {'element_identifier': '171', 'terms': ['first longitudinal end']}, {'element_identifier': '164', 'terms': ['rib']}, {'element_identifier': '154', 'terms': ['edge']}, {'element_identifier': '136', 'terms': ['plate']}, {'element_identifier': '173', 'terms': ['second longitudinal end']}, {'element_identifier': '156', 'terms': ['forefoot edge']}, {'element_identifier': '176', 'terms': ['segment']}, {'element_identifier': '185', 'terms': ['heel outer area']}, {'element_identifier': '170', 'terms': ['end surface']}, {'element_identifier': '117', 'terms': ['medial side']}, {'element_identifier': '172', 'terms': ['segment', 'segments']}, {'element_identifier': '179', 'terms': ['lateral outer area']}, {'element_identifier': '177', 'terms': ['medial outer area']}, {'element_identifier': '183', 'terms': ['height']}, {'element_identifier': '162', 'terms': ['lateral heel notch']}, {'element_identifier': '181', 'terms': ['relatively large radius']}, {'element_identifier': '163', 'terms': ['through-holes']}, {'element_identifier': '107', 'terms': ['vertical axis']}, {'element_identifier': '146', 'terms': ['second surface']}, {'element_identifier': '168', 'terms': ['second side surface', 'second side surfaces']}, {'element_identifier': '148', 'terms': ['peripheral edge']}, {'element_identifier': '105', 'terms': ['longitudinal axis']}, {'element_identifier': '111', 'terms': ['forefoot region']}, {'element_identifier': '106', 'terms': ['transverse axis']}, {'element_identifier': '150', 'terms': ['edge']}, {'element_identifier': '114', 'terms': ['heel region']}]","['1. A sole structure for an article of footwear having an upper, the sole structure comprising: a plate including (i) a base having a first surface configured to face the upper and a second surface formed on an opposite side of the base than the first surface and (ii) a rib extending from the second surface in a direction away from the upper, the rib including a generally U-shape having a first portion extending along a medial side of the plate, a second portion extending along a lateral side of the plate, and a third portion extending between the first portion and the second portion.', '2. The sole structure of Claim 1, wherein the third portion extends along a heel region of the plate.', '3. The sole structure of Claim 1 or Claim 2, wherein the first portion, the second portion, and the third portion are spaced inward from a peripheral edge of the plate.', '5. The sole structure of any of Claims 1-3, wherein the first portion is separated from the third portion by a first break and the second portion is separated from the third portion by a second break.', '8. The sole structure of Claim 6 or Claim 7, wherein the first notch extends along a transverse axis extending in a direction between the medial edge and the lateral edge.', '13. The sole structure of Claim 12, wherein the rib includes a first side surface extending from the second surface of the plate, a second side surface extending from the second surface of the plate, and an end surface extending between the first side surface and the second side surface.']",True,"['107', '144', '175', '162', '180', '105', '106', '115', '166', '152', '176', '136', '158', '148', '142', '179', '170', '164', '154', '185', '114', '174', '160', '178', '173', '136', '199', '168', '172', '150', '112', '117', '156', '17', '111', '152', '148', '142', '144', '115', '175', '166', '179', '199', '146', '164', '168', '170', '136', '144', '158', '142', '148', '114', '160', '154', '163', '185', '175', '117', '150', '177', '183', '181', '172', '117', '150', '146', '171', '166', '178', '173', '168', '661', '180', '174', '164', '115', '170', '176', '19']" 569,EP_3597098_A1.png,EP3597098A1,"FLEXIBLE ENDOSCOPE, AND ENDOSCOPE SYSTEM EQUIPPED WITH SAME",['FIG1'],['FIG1 is a diagram for illustrating an example of a flexible endoscope of the present invention'],"['FIG1 is a diagram for illustrating an example of a flexible endoscope of the present invention.', 'In FIG1, the light guide extending from the proximal end of the catheter tube 103 included in the catheter portion 102 is connected to a first connection terminal 106 inside the connection plug 104. The image guide extending from the proximal end of the catheter tube 103 included in the catheter portion 102 is connected to a second connection terminal 108 inside the connection plug 104.', ""Furthermore, in the connection plug 104 shown in FIG1, the proximal end of the catheter tube 103 is accommodated together with the proximal ends of the image guide and the light guide in two covers 105 and 105' that are molded so as to have a hollow portion. The first connection terminal 106 and the second connection terminal 108 are arranged to protrude from the hollow covers 105 and 105' of the connection plug 104 and extend substantially in parallel. Here, the catheter tube 103 is passed through a flexible tube 107 attached to the hollow covers 105 and 105', and accommodated and fixed inside the hollow covers 105 and 105'. It is preferable that the flexible tube 107 is made of a material having appropriate elasticity, and specific examples of the material include silicone rubber, natural or synthetic rubber, polyimide, nylon, polyethylene terephthalate, and polyamide."", ""Furthermore, in the first connection terminal 106 and the second connection terminal 108, ferrule flange portions 117 and 121 that the first connection terminal 106 and the second connection terminal 108 are respectively provided with are locked to the terminal arrangement portions 119 and 123 of the hollow cover 105. This makes it possible to prevent the first connection terminal 106 and the second connection terminal 108 from coming loose from the hollow covers 105 and 105' of the connection plug 104 shown in FIG1."", 'In the flexible endoscope 100 of the present invention shown in FIG1, the length of the catheter portion 102 is not particularly limited, but the catheter portion 102 is designed to preferably have a length of 1000 mm to 2500 mm, and more preferably 1200 mm to 2300 mm. In contrast, the catheter portion 102 preferably has an average outer diameter of 0.3 mm to 3 mm, and more preferably 0.5 mm to 2 mm.']",16,426,diagram,A,"[{'element_identifier': '103', 'terms': ['catheter tube']}, {'element_identifier': '160', 'terms': ['end fitting']}, {'element_identifier': '100', 'terms': ['flexible endoscope']}, {'element_identifier': '104', 'terms': ['connection plug']}, {'element_identifier': '102', 'terms': ['catheter portion']}, {'element_identifier': '108', 'terms': ['second connection terminal']}, {'element_identifier': '106', 'terms': ['first connection terminal']}, {'element_identifier': '107', 'terms': ['flexible tube']}]","['1. An angioscope comprising: a catheter portion; and a connection plug, wherein the catheter portion includes an image guide, a light guide, and a catheter tube that surrounds the image guide and the light guide in a longitudinal direction, the connection plug includes a hollow cover that accommodates a proximal end of the catheter tube, a flexible tube that protrudes from the hollow cover and through which the catheter tube is passed, a first connection terminal that is connected to the light guide extending from the proximal end of the catheter tube, and a second connection terminal that is connected to the image guide extending from the proximal end of the catheter tube, the image guide and the light guide are slidable inside the catheter tube, the first connection terminal and the second connection terminal protrude from the hollow cover of the connection plug substantially in parallel, and at least one of the image guide and the light guide is arranged curved inside the hollow cover of the connection plug.']",False,"['160', '102', '103', '108', '106', '104', '107', '100', '11']" 570,EP_3597142_A1 (6).png,EP3597142A1,"DENTURE BASE MANUFACTURING METHOD, CUTTING APPARATUS, AND WORKPIECE MATERIAL",['FIG10'],['FIG10 is a plan view of a partial denture according to still another embodiment of the present invention'],"['FIG10 is a plan view of a partial denture 40 according to still another embodiment of the present invention. The partial denture 40 is used for the upper jaw of a patient with many missing teeth. The partial denture 40 has an approximately semicircular shape in the plan view. The partial denture 40 includes a denture base 42 and artificial teeth 45. The denture base 42 is fabricated by cutting the workpiece material 2. The artificial teeth 45 are secured to the denture base 42. The denture base 42 includes a first base 421, a second base 422, a third base 423, and a palate cover 42m. The first base 421 is located in the lower left portion of FIG10. The second base 422 is located in the lower right portion of FIG10. The third base 423 is located in the upper central portion of FIG10. The first, second, and third bases 421, 422, and 423 include securers (not illustrated), fitted portions 44, and protrusions 46. The artificial teeth 45 are disposed in the securers . The fitted portions 44 are each provided in the form of a clasp. The protrusions 46 are each provided in the form of a rest. When the workpiece material 2 is cut into the denture base 42, the cutting data creating step S20 preferably involves creating cutting data in accordance with three-dimensional data indicative of the shape of the denture base 42 including the palate cover 42m, the securers, the fitted portions 44, and the protrusions 46. This enables the cutting step S30 to fabricate the denture base 42 integral with the palate cover 42m, the securers, the fitted portions 44, and the protrusions 46.', 'The manufacturing method described above involves using the circular plate workpiece material 2 so as to fabricate the denture base 20. The workpiece material 2, however, is not limited to a circular plate shape. For example, suppose that the circular plate workpiece material 2 is cut into the denture base 42 for use in the partial denture 40 illustrated in FIG10. In this case, a portion of the workpiece material 2 where the palate cover 42m is to be formed needs to be cut more deeply than portions of the workpiece material 2 where the first to third bases 421 to 423 are to be formed. Shavings created by cutting the workpiece material 2 are typically discarded without being recycled. Accordingly, a workpiece material highly similar in shape to the denture base 42 is preferably used from the viewpoint of reducing the amount of waste and cost of disposal.']",18,480,plan view,A,"[{'element_identifier': '422', 'terms': ['second base']}, {'element_identifier': '45', 'terms': ['artificial teeth']}, {'element_identifier': '40', 'terms': ['partial denture']}, {'element_identifier': '42', 'terms': ['denture base']}, {'element_identifier': '423', 'terms': ['third base']}, {'element_identifier': '46', 'terms': ['protrusions']}]","['1. A denture base manufacturing method, comprising: an apparatus preparing step (S10) involving preparing a cutting apparatus (60), including: a retainer (66) to retain a workpiece material (2, 4) composed mainly of thermoplastic resin, a cutter (63, 78) to cut the workpiece material (2, 4), and a controller (110) communicably connected to the retainer (66) and the cutter (63, 78); a cutting data creating step (S20) involving creating cutting data in accordance with three-dimensional data indicative of a shape of a denture base (20, 32, 42) including a fitted portion (24, 34, 44) to be fitted to an abutment tooth (A1, A2) of a patient; and a cutting step (S30) involving cutting the workpiece material (2, 4) using the cutting apparatus (60) in accordance with the cutting data.']",True,"['423', '45', '46', '45', '40', '46', '46', '42', '422', '45', '45', '42', '40', '19']" 571,EP_3597176_A1 (6).png,EP3597176A1,IMPLANTS FOR LOCALIZED DRUG DELIVERY AND METHODS OF USE THEREOF,['FIG16'],"['FIG16, panels A and B, is a collection of graphs showing the measured activity of fulvestrant eluted into media from a fulvestrant-loaded silastic® tubing, according to embodiments of the present disclosure']","['FIG16, panels A-B: Silastic® tubing (9 cm) was loaded with 0.68 mg fulvestrant and incubated in 5 mL medium at 37°C for the indicated time (Panel A) or harvested every 24 hours and replenished with fresh and replenished with fresh medium (Panel B). The medium was then used to culture MCF7 cells for 72 h, and the cells were assayed for proliferation by MTS assay (Panel A) and harvested for protein and western blotted for ER and PR expression (Panel B). Inset in Panel B demonstrates sufficient fulvestrant release to inhibit ER and PR expression for at least 28 days. As a positive control, MCF7 cells were treated directly with 100 nM fulvestrant (last bar in Panel A), a concentration sufficient to down regulate ER expression and arrest cell growth.']",37,156,graphs,A,"[{'element_identifier': '28', 'terms': ['day']}, {'element_identifier': '5', 'terms': ['containing']}, {'element_identifier': '30', 'terms': ['including', 'totaling']}, {'element_identifier': '12', 'terms': ['beyond']}, {'element_identifier': '1', 'terms': ['implant']}, {'element_identifier': '4', 'terms': ['scaffold']}, {'element_identifier': '2', 'terms': ['silicone tubing']}, {'element_identifier': '0', 'terms': ['including']}, {'element_identifier': '10', 'terms': ['including']}, {'element_identifier': '21', 'terms': ['central switchback']}, {'element_identifier': '3', 'terms': ['U.S. Pat. Nos.']}, {'element_identifier': '32', 'terms': ['target tissue']}]","['1. An implant for delivering an active agent to a target tissue, the implant comprising: a biocompatible tubing comprising a wall; and an active agent loaded in the tubing, wherein the wall is permeable to the active agent thereby delivering the active agent to the target tissue when the implant is implanted.', '4. The implant of any one of claims 1-3, wherein the tubing is silicone tubing.']",False,"['16', '12', '10', '08', '10', '21', '30', '4', '0', '28', '1', '2', '3', '4', '5', '32']" 572,EP_3597230_A1 (1).png,EP3597230A1,SMART WEARABLE BREAST PUMP AND APPARATUS FOR NIPPLE CORRECTION AND BREAST AUGMENTATION,['FIG3'],['FIG3 is a perspective view showing a bottom portion of the smart wearable breast pumping machine according to the first embodiment of the present invention'],"['As shown in FIG3, the connector 140 has one side connected to the suction part 110 to introduce the breast milk pumped by means of the breast pumping pressure therein and the other side coupled to a breast milk container such as a feeding bottle, a breast milk storage pack, and the like.']",25,57,perspective view,A,"[{'element_identifier': '122', 'terms': ['breast pumping part']}, {'element_identifier': '121', 'terms': ['cover part']}, {'element_identifier': '151', 'terms': ['command input part']}, {'element_identifier': '100', 'terms': ['breast pumping machine']}, {'element_identifier': '180', 'terms': ['silicone head']}, {'element_identifier': '140', 'terms': ['connector']}, {'element_identifier': '110', 'terms': ['suction part']}, {'element_identifier': '150', 'terms': ['controller']}]","[""1. A smart wearable breast pumping machine comprising: a suction part attached to a user's breast; a connector connected to the suction part to introduce breast milk pumped by means of a breast pumping pressure and coupled to a breast milk container; and a breast pumping part coupled to the suction part to accommodate the connector and having a breast pump adapted to apply the breast pumping pressure to the suction part and a controller adapted to control operations of the breast pump by means of control commands."", ""6. A smart wearable breast pumping machine comprising: a suction part attached to a user's breast; a breast pump for applying a breast pumping pressure to the suction part; a connector connected to the suction part to introduce breast milk pumped by means of the breast pumping pressure; a controller for controlling operations of the breast pump by means of control commands; and a cover part coupled to the suction part to accommodate the breast pump, the connector, and the controller therein.""]",True,"['110', '100', '121', '140', '180', '3', '170', '151', '150', '122', '180', '4', '12']" 573,EP_3597243_A1 (6).png,EP3597243A1,MEDICAL DELIVERY DEVICES HAVING LOW LUBRICANT SYRINGE BARRELS,['FIG12'],['FIG12 is a schematic illustration of a lubricant free syringe barrel in accordance with some embodiments'],"['FIG12 illustrates a lubricant free syringe barrel 201 having an inner surface 202 and needle 203. The inner surface 202 has a surface energy and a water contact angle. It is to be appreciated that the needle 203 is exemplary in nature, as a needleless system such as a luer-lock system may alternatively be utilized. The barrel has a point 201a which is the approximate point where the stopper 204 has completely translated past its initial position in the barrel and a point 201b that is the approximate point before the front of the stopper 204 reaches the conical portion of the barrel. In a 1 ml long syringe, point 201a is 10 mm from the front end 205 of the stopper 204 and point 201b is 28 mm from the front end 205 of the stopper 204. It is to be appreciated that point 201b and point 201b can easily be determined for other syringe sizes such as, but not limited to, 0.5 ml, 1-3 ml standard, 5 ml, 10 ml, 20 ml, 50 ml, and 100 ml.']",16,199,schematic,A,"[{'element_identifier': '201', 'terms': ['lubricant free syringe barrel']}, {'element_identifier': '202', 'terms': ['inner surface']}, {'element_identifier': '12', 'terms': ['P2Y Purinoceptor', 'clause']}, {'element_identifier': '204', 'terms': ['stopper']}, {'element_identifier': '36', 'terms': ['clause']}, {'element_identifier': '205', 'terms': ['body']}]","['1. A medical delivery device comprising: a barrel having an inner surface; and a stopper positioned within the barrel, the stopper contacting at least a portion of the inner surface of the barrel; the stopper having a compressibility of greater than 7.9% measured against the barrel, the stopper comprising two or more ribs; and a plunger rod or actuation mechanism to displace the stopper; wherein the inner surface of the barrel has a water contact angle between 1° and 58°, wherein the stopper comprises an elastomeric body and the stopper is at least partially covered with one or more non-fluoropolymer layers, and wherein the compressibility (C) is defined by the following formula: C % = v − y / v × 100 where v is the maximum outer diameter of the rib(s) in a non-compressed state, and y is the inner diameter of the inner surface of the barrel.']",False,"['202', '201', '205', '204', '12', '36']" 574,EP_3597292_A1 (1).png,EP3597292A1,"METAL SUPPORT, SUPPORTED METAL CATALYST, PRODUCTION METHOD FOR AMMONIA, PRODUCTION METHOD FOR HYDROGEN, AND PRODUCTION METHOD FOR CYANAMIDE COMPOUND","['FIG3', ' FIG4']","['FIG3 is a graph showing the results of a stability evaluation test for the catalyst of Example 1 ', 'FIG4 is a graph showing the results of the ammonia decomposition reaction shown in Example 6, Comparative Example 5 and Comparative Example 6 ']","['The ammonia synthesis reaction was continued at a reaction temperature of 400 °C for 92.5 hours to evaluate the stability of the catalyst. FIG3 shows the results of ammonia synthesis using 2 wt% Ru/CaCN2 of Example 1 as a catalyst. The catalyst activity gradually elevated from the start of the reaction and showed a constant value in about 70 hours. No decrease in catalytic activity was confirmed during the reaction, and it was found that ammonia was stably generated even in the reaction of 90 hours or more. ', 'Using 2 wt% Ru/CaCN2 prepared in Example 1 as a supported metal catalyst, ammonia decomposition reaction to produce nitrogen and hydrogen was carried out. 0.1 g of the supported Ru material was packed in a glass tube as an ammonia decomposition catalyst, and the reaction was carried out in a fixed bed flow reactor. The gas flow rate was set to NH3: 5 mL/min, and the reaction pressure was 0.1 MPa. The gas discharged from the fixed bed flow reactor was quantified by a gas chromatograph. The conversion of ammonia decomposition at 400 °C was 76.4%. The results are shown in FIG4.', 'Using this as a catalyst, an ammonia decomposition reaction was carried out under the same conditions as in Example 10. The conversion of ammonia decomposition at 400 °C was 47.3%. The results are shown in FIG4.', 'Using this as a catalyst, an ammonia decomposition reaction was carried out under the same conditions as in Example 6. The conversion for ammonia decomposition at 400 °C was 25.9%. The results are shown in FIG4.']",42,300,graph,B,"[{'element_identifier': '80', 'terms': ['preferably']}, {'element_identifier': '100', 'terms': ['preferably']}, {'element_identifier': '400', 'terms': []}, {'element_identifier': '4', 'terms': ['example', 'Table']}, {'element_identifier': '2', 'terms': ['Document', 'was']}, {'element_identifier': '200', 'terms': ['is usually']}, {'element_identifier': '20', 'terms': ['preferably']}, {'element_identifier': '250', 'terms': ['preferably']}, {'element_identifier': '300', 'terms': ['preferably']}, {'element_identifier': '40', 'terms': ['BET specific surface area']}, {'element_identifier': '1000', 'terms': ['may be', 'Porapak Q4']}, {'element_identifier': '3', 'terms': ['preferably', 'was', 'Table']}, {'element_identifier': '60', 'terms': ['lime nitrogen is usually', 'reaction was', 'THF solution']}]","['1. A supported metal material in which a transition metal is supported on a support, wherein the support is a cyanamide compound represented by the following general formula (1): \u2003\u2003\u2003\u2003\u2003\u2003\u2003\u2003MCN2\u2003\u2003\u2003\u2003\u2003(1) wherein M represents a group II element of the periodic table, and a specific surface area of the cyanamide compound is 1 m 2 g -1 or more.']",True,"['3', '5000', '4000', '3000', '2000', '1000', '20', '40', '60', '80', '100', '4', '100', '80', '60', '40', '20', '2', '2', '2', '200', '250', '300', '350', '400', '23']" 575,EP_3597293_A1.png,EP3597293A1,"TRANSITION METAL-CARRYING ZEOLITE AND PRODUCTION METHOD THEREFOR, AND NITROGEN OXIDE PURIFICATION CATALYST AND METHOD FOR USING SAME",['FIG1'],['FIG1 is a chart diagram showing an XRD pattern of an AEI-type zeolite used in Examples 1 and 2 and Comparative Examples 1 and 4'],"['The pre-reaction mixture was charged in a 1000-ml stainless autoclave equipped with a fluororesin inner cylinder, and reacted (for hydrothermal synthesis) therein at 180°C with stirring at 150 rpm for 24 hours. After the hydrothermal synthesis reaction, the reaction liquid was cooled and the formed crystal was collected through filtration. The collected crystal was dried at 100°C for 12 hours, and the resultant zeolite powder was analyzed through XRD, which confirmed synthesis of an AEI-type zeolite 1 that shows an XRD pattern with a peak and a relative intensity at the position shown in Table 2, in terms of lattice spacing. The XRD pattern of the zeolite 1 is shown in FIG1. The Si/Al molar ratio determined by XRF analysis was 5.5.Table 22 Theta/°d-spacing (Å)Relative Intensity [100 × I/I(0)]9.55729.2510010.69368.271816.17315.483416.94435.233017.24875.142219.70434.511120.75964.283321.4094.152423.98643.712526.13763.411527.86263.201331.29242.861732.22592.7811']",27,160,chart diagram,B,"[{'element_identifier': '35', 'terms': ['aqueous']}, {'element_identifier': '30', 'terms': ['preferably']}, {'element_identifier': '1', 'terms': ['preferably']}, {'element_identifier': '20', 'terms': ['preferably']}, {'element_identifier': '40', 'terms': ['Snowtex']}, {'element_identifier': '25', 'terms': ['preferably']}, {'element_identifier': '10', 'terms': ['preferably']}, {'element_identifier': '1000', 'terms': ['unit volume']}, {'element_identifier': '15', 'terms': ['preferably', 'less than', 'days with rotation']}, {'element_identifier': '200', 'terms': ['liquid after washing reaches']}]","['1. A transition metal-loaded zeolite, comprising zeolite having a structure designated as AEI or AFX according to a code system defined by International Zeolite Association (IZA), and containing at least a silicon atom and an aluminum atom in the framework structure thereof, and a transition metal M loaded thereon; and satisfying the following (1) and (2): (1) a ratio of absorption intensity based on ultraviolet-visible-near infrared spectroscopy (UV-Vis-NIR), which is obtained according to the following expression (I), is less than 0.4; Intensity 32,500 cm − 1 / Intensity 12,500 cm -1 (2) a peak intensity obtained according to ammonia temperature-programmed desorption (NH 3 -TPD) exists in at least each of a range of 200°C to 400°C and a range of 450°C to 600°C and the ratio of the maximum peak intensity in the range of 200°C to 400°C to the maximum peak intensity in the range of 450°C to 600°C (NH 3 -TPD 200∼400 /NH 3 -TPD 450∼600 ) is 1.0 or more and 2.0 or less.']",False,"['1', '1600', '1400', '1200', '1000', '800', '600', '400', '200', '10', '15', '20', '25', '30', '35', '40', '45', '2500', '2000', '1500', '1000', '500', '10', '15', '20', '25', '30', '40', '45', '26']" 576,EP_3597294_A1 (4).png,EP3597294A1,POLYETHYLENE COMPOSITIONS HAVING IMPROVED PROPERTIES,['FIG5'],"[""FIG5 is a graph of g' v molecular weight for polymers of embodiments of the instant invention and comparative polymers ""]","[""FIG5 is a graph of g'avg v. molecular weight for polymers of embodiments of the instant invention (using (C4H8)Si(C5Me4)(C5H4)ZrMe2 as the catalyst) and comparative polymers. As seen from this Figure, polymers of embodiments of the instant invention satisfy the following relations: 0.5 ≤ g'avg ≤ 0.9 and Mw/Mn ≤ 4.6.""]",21,59,graph,B,"[{'element_identifier': '1', 'terms': ['from']}, {'element_identifier': '6', 'terms': ['Patent No.']}]","['4. The process of claim 1, wherein the achiral cyclic bridged metallocene catalyst compound is represented by the formula: \u2003\u2003\u2003\u2003\u2003\u2003\u2003\u2003 LA(R\'AxR\')LBMQn\u2003\u2003\u2003\u2003\u2003(I) wherein M is a Group 4, 5, 6 transition metal, LA and LB is an unsubstituted or substituted, cyclopentadienyl ligand or cyclopentadienyl-type ligand bonded to M; (R 1 AxR\') is a cyclic bridging group wherein A is one or more of, or a combination of carbon, germanium, silicon or tin bridging LA and LB, and the two R""s form a cyclic ring or ring system with A; Qn is dimethyl and x is an integer from 1 to']",False,"['6', '33', '1']" 577,EP_3597313_A1 (3).png,EP3597313A1,ULTRASOUND IMAGING SYSTEM USING AN ARRAY OF TRANSDUCER ELEMENTS AND AN IMAGING METHOD,"['FIG10', ' FIG9']","['FIG10 shows a schematic representation of the transducer die of FIG4 indicating the direction in which image slices are obtained from the imaging region ', 'FIG9 shows a schematic representation of the transducer die of FIG4 indicating the first and second element groups of transducers']","['FIG10 illustrates the direction in which the first and second element groups are fired when generating the cross-sectional and longitudinal views in a line-by-line imaging cycle. It should be noted that the transducer die shown in FIG10 is rotated at 90° to the transducer die shown in FIG4. ', 'FIG9 shows a schematic of the transducer die 54, wherein the transducers 56 are grouped into first and second element groups. As discussed above, the transducers need not be arrayed in a grid pattern and may be arranged in a dense packing pattern, a hexagonal packing pattern or any other suitable pattern.']",44,114,schematic,A,"[{'element_identifier': '9', 'terms': ['system']}, {'element_identifier': '20', 'terms': ['beamformer']}, {'element_identifier': '56', 'terms': ['transducers', 'transducer']}, {'element_identifier': '76', 'terms': ['in direction']}, {'element_identifier': '59', 'terms': ['second circuits']}, {'element_identifier': '10', 'terms': ['array transducer probe']}, {'element_identifier': '58', 'terms': ['first circuits']}, {'element_identifier': '54', 'terms': ['transducer die']}]","['1. An ultrasound system (9), comprising: an array (55) of transducer elements (56) grouped into element groups, wherein the element groups comprise: a plurality of first element groups having a first orientation; and a plurality of second element groups having a second orientation, different from the first orientation; a set of first conductors (70) with a first conductor shared between elements in each first element group and a set of second conductors (72) with a second conductor shared between elements in each second element group; a first plurality of bias voltage circuits (V B ); and a second plurality of transmit and receive circuits (T/R); wherein each element group is adapted to be activated for transmission or reception by the application of a bias voltage from a bias voltage circuit and controlled by a transmit and receive circuit, wherein the system is adapted to acquire: first ultrasound data in which the element groups of the array, or the element groups of a sub-array of the element groups, are activated by a bias voltage circuit via a first conductor; and second ultrasound data in which the element groups of the array, or the element groups of a sub-array of the element groups, are activated by a bias voltage circuit via a second conductor.']",True,"['56', '59', '58', '9', '56', '00', '00', '54', '76', '59', '58', '10', '20']" 578,EP_3597313_A1 (6).png,EP3597313A1,ULTRASOUND IMAGING SYSTEM USING AN ARRAY OF TRANSDUCER ELEMENTS AND AN IMAGING METHOD,['FIG13'],['FIG13 shows a schematic representation of a transducer die divided into sub-arrays'],"['FIG13 shows an embodiment of the transducer die 54, wherein the transducers 56 are divided into sub-arrays.', 'In the example shown in FIG13, the transducer die 54 is separated into one longitudinal sub-array 90 and two cross-sectional sub-arrays 92. By dividing the die into dedicated areas, such as those shown in FIG13, it is possible to generate a simultaneous biplane view. In other words, both a cross-sectional and a longitudinal view may be available at the same time.']",14,98,schematic,A,"[{'element_identifier': '72', 'terms': ['second conductors', 'second conductor']}, {'element_identifier': '98', 'terms': ['first bias voltage line']}, {'element_identifier': '92', 'terms': ['cross-sectional sub-arrays']}, {'element_identifier': '94', 'terms': ['circuit block']}, {'element_identifier': '96', 'terms': ['T/R line']}, {'element_identifier': '100', 'terms': ['second bias voltage line']}, {'element_identifier': '56', 'terms': ['transducers', 'transducer']}, {'element_identifier': '76', 'terms': ['in direction']}, {'element_identifier': '90', 'terms': ['longitudinal sub-array']}, {'element_identifier': '58', 'terms': ['first circuits']}, {'element_identifier': '54', 'terms': ['transducer die']}, {'element_identifier': '59', 'terms': ['second circuits']}, {'element_identifier': '13', 'terms': ['cell', 'cells']}]","['1. An ultrasound system (9), comprising: an array (55) of transducer elements (56) grouped into element groups, wherein the element groups comprise: a plurality of first element groups having a first orientation; and a plurality of second element groups having a second orientation, different from the first orientation; a set of first conductors (70) with a first conductor shared between elements in each first element group and a set of second conductors (72) with a second conductor shared between elements in each second element group; a first plurality of bias voltage circuits (V B ); and a second plurality of transmit and receive circuits (T/R); wherein each element group is adapted to be activated for transmission or reception by the application of a bias voltage from a bias voltage circuit and controlled by a transmit and receive circuit, wherein the system is adapted to acquire: first ultrasound data in which the element groups of the array, or the element groups of a sub-array of the element groups, are activated by a bias voltage circuit via a first conductor; and second ultrasound data in which the element groups of the array, or the element groups of a sub-array of the element groups, are activated by a bias voltage circuit via a second conductor.']",True,"['92', '90', '56', '13', '72', '92', '54', '58', '59', '54', '56', '90', '98', '76', '96', '100', '92', '58', '14', '94', '23']" 579,EP_3597345_A1 (1).png,EP3597345A1,WELDING STATE DETERMINATION SYSTEM AND WELDING STATE DETERMINATION METHOD,['FIG2'],['FIG2 is a block diagram illustrating a configuration of a robot controller'],"['Next, a configuration of the robot controller 30 will be described. The robot controller 30 controls an operation of the welding robot 20. FIG2 is a block diagram illustrating the configuration of the robot controller 30. The robot controller 30 includes a CPU 301, a memory 302, an operation panel 303 including a plurality of switches, a teaching pendant 304, an input/output unit 305, and a communication unit 306.']",12,81,block diagram,B,"[{'element_identifier': '30', 'terms': ['robot controller']}, {'element_identifier': '306', 'terms': ['communication unit']}, {'element_identifier': '304', 'terms': ['teaching pendant']}, {'element_identifier': '303', 'terms': ['operation panel']}, {'element_identifier': '301', 'terms': ['CPU']}, {'element_identifier': '20', 'terms': ['welding robot']}, {'element_identifier': '42', 'terms': ['welding current detector']}, {'element_identifier': '302', 'terms': ['memory']}, {'element_identifier': '27', 'terms': ['Equation']}, {'element_identifier': '330', 'terms': ['control program']}, {'element_identifier': '305', 'terms': ['input/output unit']}]","['11. The welding state determination system according to claim 1 or 2, further comprising: an abnormality communication unit configured to notify the abnormality when the determination unit determines that the welding state is abnormal.']",False,"['30', '301', '303', '304', '42', '305', '20', '302', '330', '306', '27']" 580,EP_3597345_A1.png,EP3597345A1,WELDING STATE DETERMINATION SYSTEM AND WELDING STATE DETERMINATION METHOD,['FIG1'],['FIG1 is a schematic view illustrating a configuration of a welding system according to Embodiment 1'],"['FIG1 is a schematic view illustrating a configuration of a welding system according to the present embodiment. The welding system 10 includes a welding robot 20, a robot controller 30, a power supply 40, and a welding state determination system 100. The welding state determination system 100 determines the welding state by the welding robot 20.']",16,62,schematic view,B,"[{'element_identifier': '30', 'terms': ['robot controller']}, {'element_identifier': '100', 'terms': ['welding state determination system']}, {'element_identifier': '45', 'terms': ['memory']}, {'element_identifier': '40', 'terms': ['power supply']}, {'element_identifier': '47', 'terms': ['power control program']}, {'element_identifier': '43', 'terms': ['switch']}, {'element_identifier': '26', 'terms': ['Equation']}, {'element_identifier': '44', 'terms': ['CPU']}, {'element_identifier': '46', 'terms': ['communication unit']}]","['1. A welding state determination system that determines a welding state in arc welding by a weaving operation in which a welding torch is oscillated in cycles, the welding state determination system comprising: an acquisition unit configured to acquire, for each cycle, a characteristic amount that pertains to a physical quantity that changes according to the cycle of the weaving operation; a calculation unit configured to calculate a degree of abnormality based on an observation value that is the characteristic amount acquired in one cycle by the acquisition unit and an average and standard deviation of a plurality of past values that are the characteristic amounts acquired prior to the one cycle by the acquisition unit; and a determination unit configured to determine the welding state based on the degree of abnormality calculated by the calculation unit.', '11. The welding state determination system according to claim 1 or 2, further comprising: an abnormality communication unit configured to notify the abnormality when the determination unit determines that the welding state is abnormal.']",False,"['40', '44', '47', '45', '46', '43', '30', '100', '26']" 581,EP_3597392_A1 (2).png,EP3597392A1,CONTROLLER ARRANGEMENT FOR INJECTION MOLDING SYSTEM,['FIG2A'],"['FIG2A is a generic schematic diagram of an arrangement of signal communications between an injection molding machine controller, sensors, a signal converter and electric actuators or the interface of a proportional directional control valve']","['As shown in a generic schematic form in FIG2A, a system 10 according to the invention incorporates a signal converter 1500 that can receives standardized injection machine generated start of cycle and end of cycle signals VS (such as 0 volts, 24 volts or 120 volts) and converts the received standardized signal VS to an output power signal MOCPS or PDCVS that is compatible for receipt and use by an electric motor or a proportional direction control valve power signal. The two different actuator based systems, namely electric motor and proportional directional control valve, are shown together in the generic FIG2A for illustration purposes only. More typically, a practical implementation of a system as shown in FIG2A would be such that the converter 1500 would contain a single microcontroller and an interconnected driver that is configured to work with one or the other of an electric actuator based system or a proportional directional control valve system.']",36,166,schematic diagram,B,"[{'element_identifier': '1500', 'terms': ['converter']}]","['1. An injection molding apparatus (10) comprising an injection molding machine (IMM) having a drivably rotatable barrel screw (BS) that generates an injection fluid (18), a heated manifold (40) that receives the injection fluid (18) from the injection molding machine (IMM) and distributes the injection fluid (18) to one or more gates (32, 34, 36), a mold (42) having a cavity (30) communicating with the gates to receive the injection fluid (18), the injection molding machine (IMM) including a machine controller (MC) or control unit (HPU) that generates one or more standardized signals (VS), wherein the standardized signals (VS) are compatible for receipt and use by a signal receptor, interface or driver of a standard directional control valve (12) to instruct the fluid directional control valve (12) to move to a position that routes a source of drive fluid to flow in a direction that drives an interconnected fluid drivable actuator (940f, 941f, 942f) to move in a direction that operates to begin an injection cycle and to end an injection cycle, a signal converter (1500) interconnected to the machine controller (MC) or control unit (HPU), the signal converter (1500) being adapted to convert the standardized signals (VPS) to a command signal (MOPCS, PDCVS) that is compatible with a signal receptor or interface of an electrically powered actuator (940e, 941e, 942e), wherein the command signals (MOPCS, PDCVS) are converted by the signal converter (1500) into a form, frequency, power or format that is usable by the signal receptor or interface of the electrically powered actuator (940e, 941e, 942e) to cause the electrically powered actuator (940e, 941e, 942e) or the proportional directional control valve (V, V1, V2) to be driven in a direction that operates to either begin an injection cycle or to end an injection cycle, wherein the apparatus (10) further comprises one or more sensors (950, 951, 952, SN, SC, SPSR, BPSR) that detect and generate one or more sensor signals indicative of one or more of rotational or linear position of an actuator (940e, 941e, 942e, 940p, 941p, 942p) or its associated valve pin (1040, 1041, 1042), pressure or temperature of the injection fluid 18 within a fluid channel (19) of the manifold (40) or within a nozzle channel (42, 44, 46) or within the cavity (30) of the mold (33) or within a barrel of the injection molding machine (IMM), the apparatus (10) including an actuator controller (16) that receives and uses the one or more sensor signals in a program that: instructs the actuator (940e, 941e, 942e, 940p, 941p, 942p) or its associated valve pin (1040, 1041, 1042) to travel during the course of the injection cycle to positions that correspond to a predetermined profile of injection fluid pressures, linear or rotational pin positions, linear actuator or valve pin positions, barrel screw positions, barrel pressures or actuator drive fluid pressures or that, instructs the actuator (940e, 941e, 942e, 940p, 941p, 942p) or its associated valve pin (1040, 1041, 1042) such that the valve pin is withdrawn from a closed gate position upstream at a reduced velocity over a selected path of upstream travel, or that, instructs the actuator (940e, 941e, 942e, 940p, 941p, 942p) or its associated valve pin (1040, 1041, 1042) to travel such that the valve pin is driven downstream at a reduced velocity over a selected path of travel where a distal tip end of the pin travel from upstream of the gate to a gate closed position, or that, instructs the actuator (940e, 941e, 942e, 940p, 941p, 942p) or its associated valve pin (1040, 1041, 1042) to travel such that the valve pin is driven upstream or downstream to an intermediate position between a gate closed position and a fully upstream position where the valve pin is maintained in the intermediate position for a selected period of time during the course of the injection cycle wherein, in the intermediate position, the distal tip end of the valve pin restricts flow of injection of the injection to less than a maximum flow.']",False,"['952', '17', '1500']" 582,EP_3597544_A1 (1).png,EP3597544A1,FUEL TANK WITH WATER BLADDER,['FIG4'],['FIG4 is a schematic illustration of a fuel tank assembly at an intermediate operational state in accordance with embodiments'],"['As shown in FIG4, while the aircraft 10 idles on the ground, taxis or is flying at low altitude, the engine 11 is run and the fuel is beginning to be slowly spent so that volume within the housing volume starts to become available. Meanwhile, humidity at or near the ground results in water (e.g., condensed water) being collected in the water separation component 12 and, instead of this water being used immediately as in conventional systems, the water is stored in the bladder 14. This is accomplished by the controller 20 controlling the first flow control element 30 to allow a flow of water into the bladder 14 while controlling the second flow control element 31 to prevent a flow of the water from the bladder 14. This results in the bladder inflating by a volume that is equal to or less than the volume of the spent fuel which has been drawn out of the housing volume.']",19,172,schematic,B,"[{'element_identifier': '171', 'terms': ['heat exchanger']}, {'element_identifier': '17', 'terms': ['ACM']}, {'element_identifier': '12', 'terms': ['water separation component']}, {'element_identifier': '151', 'terms': ['second portion']}, {'element_identifier': '20', 'terms': ['controller']}, {'element_identifier': '31', 'terms': ['second flow control element', 'second flow control elements']}, {'element_identifier': '16', 'terms': ['coolant flow system']}, {'element_identifier': '162', 'terms': ['outlet pipe', 'outlet pipes']}, {'element_identifier': '3', 'terms': ['US']}, {'element_identifier': '150', 'terms': ['first portion']}, {'element_identifier': '170', 'terms': ['compressor']}, {'element_identifier': '161', 'terms': ['inlet pipe']}]","['5. The tank assembly according to any preceding claim, further comprising a controller (20) configured to sense the volume of the first fluid and to control the flow system accordingly, wherein the controller is further configured to control the flow system to draw at least a portion of the volume of the second fluid from the bladder and the housing based on an external requirement.', '7. The tank assembly according to any preceding claim, wherein the flow system comprises: inlet (161) and outlet (162) pipes which are respectively fluidly communicative with the bladder; and flow control elements (30, 31) respectively disposed along the inlet and outlet pipes and respectively controllable to control a flow of the second fluid through the inlet and outlet pipes.']",True,"['3', '12', '17', '170', '171', '161', '16', '162', '151', '20', '4', '17', '170', '171', '16', '20', '150', '162', '151', '31', '8']" 583,EP_3597544_A1 (2).png,EP3597544A1,FUEL TANK WITH WATER BLADDER,['FIG5'],['FIG5 is a schematic illustration of a fuel tank assembly at an intermediate operational state in accordance with embodiments'],"['As shown in FIG5, while the aircraft 10 is in a high power mode during climbing operations or combat (in the case of a fighter jet), engine temperatures and/or thermal loads increase substantially in relatively short amounts of time and water is pumped out of the bladder 14 in order to support cooling in various systems such as environmental cooling systems and the ACM 17 even while the fuel is spent. In such cases, the controller 20 may control the first flow control element 30 to prevent a flow of water into the bladder 14 and may control the second flow control element 31 to allow a flow of the water from the bladder 14. This results in the bladder deflating and, in some cases, deflating as a substantially increased rate as compared to its inflation rate (i.e., bladder 14 inflation may require hours versus minutes during which the bladder 14 can be deflated). At this point, the controller 20 may control the first and second flow control elements 30 to allow or prevent flows of water relative to the bladder 14 but may, in particular, control the second flow control element 31 to allow a flow of water from the bladder 14 to the environmental cooling systems and the ACM 17 in order to save power during final minutes of flight time.']",19,240,schematic,B,"[{'element_identifier': '171', 'terms': ['heat exchanger']}, {'element_identifier': '17', 'terms': ['ACM']}, {'element_identifier': '12', 'terms': ['water separation component']}, {'element_identifier': '151', 'terms': ['second portion']}, {'element_identifier': '20', 'terms': ['controller']}, {'element_identifier': '16', 'terms': ['coolant flow system']}, {'element_identifier': '162', 'terms': ['outlet pipe', 'outlet pipes']}, {'element_identifier': '31', 'terms': ['second flow control element', 'second flow control elements']}, {'element_identifier': '150', 'terms': ['first portion']}, {'element_identifier': '170', 'terms': ['compressor']}, {'element_identifier': '161', 'terms': ['inlet pipe']}]","['5. The tank assembly according to any preceding claim, further comprising a controller (20) configured to sense the volume of the first fluid and to control the flow system accordingly, wherein the controller is further configured to control the flow system to draw at least a portion of the volume of the second fluid from the bladder and the housing based on an external requirement.', '7. The tank assembly according to any preceding claim, wherein the flow system comprises: inlet (161) and outlet (162) pipes which are respectively fluidly communicative with the bladder; and flow control elements (30, 31) respectively disposed along the inlet and outlet pipes and respectively controllable to control a flow of the second fluid through the inlet and outlet pipes.']",True,"['5', '17', '170', '17', '161', '16', '150', '162', '151', '31', '20', '9', '12', '17', '170', '171', '161', '16', '20', '150', '151', '162']" 584,EP_3597544_A1.png,EP3597544A1,FUEL TANK WITH WATER BLADDER,['FIG2'],['FIG2 is a schematic illustration of a controller of the aircraft of FIG1'],"['As shown in FIG2, the controller 20 may include a processing unit 201, a memory unit 202, a networking unit 203, an optional sensing element 204 to sense the volume of the fuel in the fuel tank housing 13 at any given time and a servo control element 205. The controller 20 may be provided as a flight computer for the aircraft 10 or as a stand-alone component. The processing unit 201 may be provided as a central processing unit (CPU), which is coupled with the memory unit 202 and is communicative with the sensing element 204 and the servo control element 205 by way of the networking unit 203. The memory unit 202 has the minimal volume of the bladder 14 and the volume of the portion 160 of the coolant flow system 16 that is within the fuel tank housing 13 stored thereon in one or more first storage units and has executable instructions stored thereon in one or more second storage units. When executed, the executable instructions cause the processing unit to operate as described herein.']",13,194,schematic,B,"[{'element_identifier': '171', 'terms': ['heat exchanger']}, {'element_identifier': '201', 'terms': ['processing unit']}, {'element_identifier': '14', 'terms': ['bladder']}, {'element_identifier': '202', 'terms': ['memory unit']}, {'element_identifier': '203', 'terms': ['networking unit']}, {'element_identifier': '11', 'terms': ['engine']}, {'element_identifier': '130', 'terms': ['rigid fuel tank housing']}, {'element_identifier': '204', 'terms': ['sensing element']}, {'element_identifier': '20', 'terms': ['controller']}, {'element_identifier': '10', 'terms': ['aircraft']}, {'element_identifier': '131', 'terms': ['inflatable fuel tank housing']}, {'element_identifier': '15', 'terms': ['fuel system']}, {'element_identifier': '205', 'terms': ['servo control element']}, {'element_identifier': '150', 'terms': ['first portion']}, {'element_identifier': '13', 'terms': ['fuel tank housing']}]","['5. The tank assembly according to any preceding claim, further comprising a controller (20) configured to sense the volume of the first fluid and to control the flow system accordingly, wherein the controller is further configured to control the flow system to draw at least a portion of the volume of the second fluid from the bladder and the housing based on an external requirement.', '6. The aircraft according to claim 5, wherein the controller comprises a sensing element (204).']",True,"['10', '171', '11', '11', '20', '15', '14', '13', '131', '130', '150', '20', '202', '201', '204', '203', '205']" 585,EP_3597567_A1 (1).png,EP3597567A1,"ACCUMULATION MANAGEMENT APPARATUS, ACCUMULATION MANAGEMENT METHOD, AND PROGRAM",['FIG2'],['FIG2 is a diagram showing a hardware configuration example of an accumulation management apparatus according to the first embodiment'],"['FIG2 is a diagram showing a hardware configuration example of the accumulation management apparatus according to the first embodiment.', 'As shown in FIG2, the accumulation management apparatus 1 may include a central processing unit (CPU) 101, a read-only memory (ROM) 102, a random-access memory (RAM) 103, an HDD (solid state drive) 104 and an interface 105 as an example of hardware components. The interface 105 may be a liquid crystal touch panel, a button or the like, for example.']",19,101,diagram,B,"[{'element_identifier': '105', 'terms': ['interface']}, {'element_identifier': '112', 'terms': ['identification information acquisition unit']}, {'element_identifier': '113', 'terms': ['instruction unit']}]","['1. An accumulation management apparatus, comprising: an identification information acquisition unit configured to acquire identification information of accumulation targets sequentially disposed in an accumulation location; and an instruction unit configured to perform control of radiating optical information corresponding to the identification information to the accumulation targets on the basis of the identification information.']",True,"['0', '102', '103', '104', '105', '11', '112', '113', '13']" 586,EP_3597576_A1.png,EP3597576A1,SOLID PARTICLE CARRYING METHOD AND CARRYING SYSTEM,['FIG1'],['FIG1 is a schematic diagram showing an example of a conveying system that is suitably used for a conveying method of the present invention '],"['Hereinafter, the conveying method and the conveying system will be described in more detail with reference to FIG1 related to the conveying system 10 of solid particles.', 'The conveying system 10 shown in FIG1 includes a delivering means 21 to which solid particles that are to be conveyed have been introduced and that supplies the solid particles to a conveying path 24, the conveying path 24 that is connected to the delivering means 21 and that conveys the solid particles supplied from the delivering means 21, a receiving means 20 that is connected to the conveying path 24 and receives the solid particles from the conveying path 24, and a solid particle supply path 23 that supplies the solid particles to the delivering means 21.', 'Furthermore, as shown in FIG1, the system 10 is preferably such that the gas returning path 26 and the conveying path 24 are connected to each other via a detour path 27 detouring around the delivering means 21. The detour path 27 is connected to each of the gas returning path 26 and the conveying path 24 near the delivering means 21. The portion of the gas returning path 26 between the point connected to the detour path 27 and the delivering means 21 (hereinafter, also referred to as a ""first branch portion"") 26a, and the portion of the conveying path 24 between the point connected to the detour path 27 and the delivering means 21 (hereinafter, also referred to as a ""second branch portion"") 24a are respectively provided with valves 26b and 24b. Furthermore, the detour path 27 is also provided with a valve 27b. With these valves, the first branch portion 26a, the second branch portion 24a, and the detour path 27 can be opened and closed independently of each other. Furthermore, if the detour path 27 is provided, it is preferable to use a pressure-feeding blower as the blower 22.', 'The conveying system 10 shown in FIG1 was used. The environment was at an ambient temperature of 10°C.']",24,376,schematic diagram,B,"[{'element_identifier': '24', 'terms': ['conveying path']}, {'element_identifier': '20', 'terms': ['receiving means']}, {'element_identifier': '25', 'terms': ['gas supply path']}, {'element_identifier': '27', 'terms': ['detour path']}, {'element_identifier': '26', 'terms': ['gas returning path']}, {'element_identifier': '21', 'terms': ['delivering means']}, {'element_identifier': '23', 'terms': ['solid particle supply path']}]","['5. The conveying method according to any one of claims 1 to 4, wherein the gas flow is circulated in a closed conveying path, and the solid particles are conveyed by the gas flow.']",False,"['23', '27', '26', '25', '20', '21', '24']" 587,EP_3597838_A1 (2).png,EP3597838A1,"SCAFFOLDING PLATE, FALLING OBJECT RECEPTION DEVICE, AND PANEL FOR FALLING OBJECT RECEPTION DEVICE",['FIG4'],['FIG4 is a view illustrating a fully retractable scaffold board'],"['FIG4 is a view illustrating a fully-retractable scaffold board 100. In the scaffold board 100 illustrated in FIG4, the scaffold body 10 is pivotably attached to a frame 30. A pivot axis of the scaffold body 10 is provided in a direction along a longitudinal direction of the scaffold board 100. The scaffold body 10 may be pivotably attached to the frame 30 via a pivot support 32. The hook members 12 may be provided in ends of the frame 30 in the longitudinal direction of the scaffold board 100. Uneven portions 14 are formed on the front surface 16 of the scaffold body 10 of this example. On the back surface 17 side of the scaffold body 10, reinforcement cross beams 18 and reinforcement vertical beams 19 which are framed in the form of parallel crosses may be provided as reinforcement parts.']",10,154,view,B,"[{'element_identifier': '30', 'terms': ['frame']}, {'element_identifier': '14', 'terms': ['uneven portions', 'uneven portion']}, {'element_identifier': '12', 'terms': ['hook members', 'hook member']}, {'element_identifier': '19', 'terms': ['reinforcement vertical beams']}, {'element_identifier': '18', 'terms': ['reinforcement cross beams']}, {'element_identifier': '100', 'terms': ['scaffold board', 'scaffold boards']}, {'element_identifier': '10', 'terms': ['scaffold body']}, {'element_identifier': '32', 'terms': ['pivot support']}]","['1. A scaffold board comprising: a board serving as a scaffold; and a polyurea resin layer that covers at least a front surface of surfaces of the board.', '4. The scaffold board according to claim 2, wherein: the board is formed of the foamed synthetic resin; and the foamed synthetic resin is provided with a hook member formed of metal or reinforced plastic so as to fix the board to an external scaffold construction body.', '7. The scaffold board according to claim 6, wherein uneven portions for slip prevention are formed on a front surface of the sheet member.']",False,"['10', '18', '19', '100', '100', '32', '12', '30', '12', '14', '12']" 588,EP_3597838_A1 (3).png,EP3597838A1,"SCAFFOLDING PLATE, FALLING OBJECT RECEPTION DEVICE, AND PANEL FOR FALLING OBJECT RECEPTION DEVICE",['FIG5'],['FIG5 is a plan view illustrating a scaffold board 150 of a second embodiment of the present invention'],"['FIG5 is a plan view illustrating a scaffold board 150 of a second embodiment of the present invention. In the first embodiment described above, the case where the polyurea resin layer 24 is formed on the surface of the board 20 via the primer coating 22, or the case where the polyurea resin layer 24 is formed directly on the surface of the board 20 is described. However, the present invention is not limited to this case. The scaffold board 150 of this example has a sheet member 40 including a coating layer of polyurea resin attached to a surface of a board 50.']",18,111,plan view,B,"[{'element_identifier': '14', 'terms': ['uneven portions', 'uneven portion']}, {'element_identifier': '12', 'terms': ['hook members', 'hook member']}, {'element_identifier': '40', 'terms': ['sheet member']}, {'element_identifier': '42', 'terms': ['first sheet member']}, {'element_identifier': '10', 'terms': ['scaffold body']}, {'element_identifier': '50', 'terms': ['board']}, {'element_identifier': '46', 'terms': ['sides']}, {'element_identifier': '150', 'terms': ['scaffold board']}]","['4. The scaffold board according to claim 2, wherein: the board is formed of the foamed synthetic resin; and the foamed synthetic resin is provided with a hook member formed of metal or reinforced plastic so as to fix the board to an external scaffold construction body.', '6. The scaffold board according to any one of claims 1 to 5, wherein the scaffold board comprises a sheet member removably attached to a surface of the board; the sheet member includes a base material of foamed synthetic resin and a coating layer covering a surface of the base material; and the polyurea resin layer is formed as the coating layer.', '7. The scaffold board according to claim 6, wherein uneven portions for slip prevention are formed on a front surface of the sheet member.']",False,"['12', '14', '46', '10', '50', '14', '12', '12', '42', '40', '150', '13']" 589,EP_3597838_A1 (5).png,EP3597838A1,"SCAFFOLDING PLATE, FALLING OBJECT RECEPTION DEVICE, AND PANEL FOR FALLING OBJECT RECEPTION DEVICE",['FIG7'],['FIG7 is a view illustrating a partial cross-sectional view of the sheet member'],"['FIG7 is a view illustrating a partial cross-sectional view of the sheet member 40. In FIG7, a cross section along an X-axis direction of the sheet member 40 is illustrated. The sheet member 40 has a base material 60 and a coating layer 62. The base material 60 is formed of foamed synthetic resin.']",15,63,view,B,"[{'element_identifier': '16', 'terms': ['front surface']}, {'element_identifier': '62', 'terms': ['coating layer']}, {'element_identifier': '60', 'terms': ['base material']}, {'element_identifier': '40', 'terms': ['sheet member']}]","['1. A scaffold board comprising: a board serving as a scaffold; and a polyurea resin layer that covers at least a front surface of surfaces of the board.', '6. The scaffold board according to any one of claims 1 to 5, wherein the scaffold board comprises a sheet member removably attached to a surface of the board; the sheet member includes a base material of foamed synthetic resin and a coating layer covering a surface of the base material; and the polyurea resin layer is formed as the coating layer.']",False,"['62', '16', '62', '60', '40', '15']" 590,EP_3597838_A1 (6).png,EP3597838A1,"SCAFFOLDING PLATE, FALLING OBJECT RECEPTION DEVICE, AND PANEL FOR FALLING OBJECT RECEPTION DEVICE",['FIG8'],['FIG8 is a view illustrating a falling object receiving device of a third embodiment of the present invention'],['FIG8 is a view illustrating a falling object receiving device 200 of a third embodiment of the present invention. The falling object receiving device 200 is provided so as to project outward from a work space when working at a high place in the work space of the scaffold construction body 1 at a construction site or the like. The falling object receiving device 200 receives a falling object when an object falls from the work space to an outer space. This prevents objects from falling to the ground. The falling object receiving device 200 is called a morning glory device.'],18,106,view,B,"[{'element_identifier': '210', 'terms': ['panel part']}, {'element_identifier': '230', 'terms': ['support', 'supports']}, {'element_identifier': '220', 'terms': ['attachment part']}, {'element_identifier': '2', 'terms': ['cross member', 'cross members']}, {'element_identifier': '232', 'terms': ['connecting part']}, {'element_identifier': '20', 'terms': ['board']}, {'element_identifier': '16', 'terms': ['front surface']}, {'element_identifier': '3', 'terms': ['vertical members', 'vertical member']}, {'element_identifier': '200', 'terms': ['falling object receiving device']}]","['1. A scaffold board comprising: a board serving as a scaffold; and a polyurea resin layer that covers at least a front surface of surfaces of the board.', '10. A falling object receiving device, comprising: a panel part that projects from a scaffold construction body toward an external space; and an attachment part that attaches a proximal end side of the panel part to the scaffold construction body, wherein the panel part includes a base material of foamed synthetic resin and a coating layer that covers a surface of the base material, the coating layer formed of polyurea resin.']",False,"['20', '200', '210', '3', '220', '00', '2', '232', '3', '230', '2', '16']" 591,EP_3597838_A1.png,EP3597838A1,"SCAFFOLDING PLATE, FALLING OBJECT RECEPTION DEVICE, AND PANEL FOR FALLING OBJECT RECEPTION DEVICE",['FIG1'],['FIG1 is a view illustrating a part of scaffold construction bodies 1 framed at a construction work site'],"['FIG1 is a view illustrating a part of scaffold construction body 1 at a construction work site. A scaffold construction body 1 includes a cross member 2, vertical members 3, and reinforcement members 4. The cross member 2 is connected between the pair of vertical members 3. The reinforcement members 4 reinforce corners where the cross member 2 and the vertical members 3 are connected. The scaffold construction bodies 1 are joined to form a plurality of vertical stages. However, the scaffold construction body 1 is not limited to the case of FIG1. A scaffold board 100 is bridged across cross members 2, 2 of opposing scaffold construction bodies 1, 1 provided upright at regular intervals to provide a working passage. In one example, scaffold boards 100 are bridged across cross members 2, 2 in parallel in pairs. The scaffold board 100 includes a scaffold body 10 and hook members 12.']",18,167,view,B,"[{'element_identifier': '12', 'terms': ['hook members', 'hook member']}, {'element_identifier': '100', 'terms': ['scaffold board', 'scaffold boards']}, {'element_identifier': '2', 'terms': ['cross member', 'cross members']}, {'element_identifier': '10', 'terms': ['scaffold body']}, {'element_identifier': '3', 'terms': ['vertical members', 'vertical member']}]","['1. A scaffold board comprising: a board serving as a scaffold; and a polyurea resin layer that covers at least a front surface of surfaces of the board.', '4. The scaffold board according to claim 2, wherein: the board is formed of the foamed synthetic resin; and the foamed synthetic resin is provided with a hook member formed of metal or reinforced plastic so as to fix the board to an external scaffold construction body.']",False,"['2', '100', '10', '12', '3', '100', '2', '2', '12', '100', '3', '3', '10']" 592,EP_3597873_A1.png,EP3597873A1,STABILITY MARGIN AND CLEARANCE CONTROL USING POWER EXTRACTION AND ASSIST OF A GAS TURBINE ENGINE,['FIG1'],"['FIG1 is a cross sectional schematic view of a gas turbine engine, in accordance with various embodiments']","['Referring now to the drawings, FIG1 schematically illustrates a gas turbine engine 20. The gas turbine engine 20 is disclosed herein as a two-spool turbofan that generally incorporates a fan section 22, a compressor section 24, a combustor section 26 and a turbine section 28. Alternative engines might include an augmenter section (not shown) among other systems or features. The fan section 22 drives air along a bypass flow path B in a bypass duct defined within a nacelle 15, while the compressor section 24 drives air along a primary or core flow path C for compression and communication into the combustor section 26 and then expansion through the turbine section 28. Although depicted as a two-spool turbofan gas turbine engine in the disclosed non-limiting embodiment, it will be understood that the concepts described herein are not limited to use with two-spool turbofans as the teachings may be applied to other types of turbine engines, including three-spool architectures.', 'The gas turbine engine 320 further includes a low spool power assist 360 and a high spool power assist 362. In various embodiments, the low spool power assist 360 is connected to the low speed spool 330 by a low spool tower shaft 302 and the high spool power assist 362 is connected to the high speed spool 332 by a high spool tower shaft 304. In various embodiments, the low spool tower shaft 302 includes a low spool bevel gear 310 in meshing engagement with a low spool gear pedestal 312. The low spool gear pedestal 312 is coupled to the low speed spool 330, which is similar to the low speed spool 30 described above with reference to FIG1. Similarly, the high spool tower shaft 304 includes a high spool bevel gear 306 in meshing engagement with a high spool gear pedestal 308. The high spool gear pedestal 308 is coupled to the high speed spool 332, which is similar to the high speed spool 32 described above with reference to FIG1. In various embodiments, the high spool gear pedestal 308 and the low spool gear pedestal 312 are mounted on the high speed spool 332 and the low speed spool 330, respectively.']",18,401,cross-sectional schematic view,F,"[{'element_identifier': '30', 'terms': ['low speed spool']}, {'element_identifier': '38', 'terms': ['several bearing systems']}, {'element_identifier': '48', 'terms': ['fan drive gear system']}, {'element_identifier': '15', 'terms': ['nacelle']}, {'element_identifier': '36', 'terms': ['engine static structure']}]","['1. A method of maintaining rotor tip clearance during a transient operation of a gas turbine engine, comprising: applying high spool auxiliary power to a high speed spool for a first time period; applying low spool auxiliary power to a low speed spool for a second time period; sensing one or more operational parameters of the gas turbine engine during the transient operation; and ceasing application of power to the high speed spool, based on the one or more operational parameters.']",False,"['15', '48', '38', '30', '36']" 593,EP_3597880_A1 (1).png,EP3597880A1,WATER PUMP,['FIG2'],['FIG2 is a cross-sectional view illustrating a state in which a check valve of a water pump according to an embodiment of the present disclosure is closed'],"['In particular, referring to FIG2, the check valve 1150 may include a valve cylinder 1151, a latching protrusion 1152, and a sealing ball 1153.', 'The latching protrusion 1152 protrudes inward from an inner surface of the valve cylinder 1151. A protruding shape may vary and is not limited to that shown in FIG2.', 'According to movement of the piston 1310, some of the cooling water inside the hydraulic space 1200a is introduced into the check valve 1150. In this case, as shown in FIG2, the sealing ball 1153 is caught at the latching protrusion 1152 by pressure applied by the cooling water inside the hydraulic space 1200a. Accordingly, the sealing ball 1153 closes the flow path 1151a and movement of the cooling water through the flow path 1151a is not realized.']",29,147,cross-sectional view,F,"[{'element_identifier': '1150', 'terms': ['check valve']}, {'element_identifier': '1153', 'terms': ['sealing ball']}]","['7. The water pump of claim 5, wherein the body portion further comprises a check valve accommodated inside the housing to face a cooling water flow hole of which one end is connected to the cylinder portion and the other end is provided at the impeller cover, and preventing the cooling water from being introduced from the cylinder portion to the body portion by being closed when the piston moves in a direction towards the body portion.', '8. The water pump of claim 7, wherein the check valve comprises: a valve cylinder having therein a flow path communicating the body portion and the cylinder portion; a latching protrusion protruding from an inner surface of the valve cylinder; and a sealing ball located on the flow path and closing the flow path by being caught at the latching protrusion by the cooling water flowing from the cylinder portion to the body portion.']",False,"['1150', '1153', '151', '152', '8']" 594,EP_3597880_A1 (2).png,EP3597880A1,WATER PUMP,['FIG3'],['FIG3 is a cross-sectional view illustrating a state in which a discharge port of a water pump according to an embodiment of the present disclosure is opened'],"['Referring to FIG3, the motor control unit that received a signal from the temperature sensor controls the linear motor 1300 to move the piston 1310 in a direction away from the body portion 1100. In this case, a space of the hydraulic space 1200a is increased and some of the cooling water inside the pressurizing space 1142a is introduced towards the hydraulic space 1200a, and accordingly, the pressure applied to the impeller cover 1141 by the cooling water inside the pressurizing space 1142a is reduced.']",29,91,cross-sectional view,F,"[{'element_identifier': '1100', 'terms': ['body portion']}, {'element_identifier': '1130', 'terms': ['rotation shaft']}, {'element_identifier': '1141', 'terms': ['impeller cover']}, {'element_identifier': '1430', 'terms': ['stator']}, {'element_identifier': '1150', 'terms': ['check valve']}, {'element_identifier': '1440', 'terms': ['motor casing']}, {'element_identifier': '1000', 'terms': ['water pump']}, {'element_identifier': '1420', 'terms': ['rotor']}, {'element_identifier': '1110', 'terms': ['housing']}, {'element_identifier': '1500', 'terms': ['lock preventing member']}, {'element_identifier': '1200', 'terms': ['cylinder portion']}]","['1. A water pump comprising: a body portion comprising a housing where an inlet port and a discharge port through which cooling water is introduced and discharged are provided, an impeller accommodated inside the housing and introducing or discharging the cooling water via rotation, a rotation shaft coupled to the impeller and rotating the impeller by receiving external driving power, and a cooling water flow rate control unit arranged above the impeller and operating to selectively open or close the discharge port; a cylinder portion provided above the cooling water flow rate control unit and formed therein a hydraulic space accommodating cooling water that applies pressure to the cooling water flow rate control unit; a piston located inside the hydraulic space and pressurizing the cooling water present inside the hydraulic space; a driving unit coupled to a side surface of the cylinder portion and moving the piston forward or backward; and a lock preventing member located at an inner surface of the cylinder portion that faces a front surface or a rear surface of the piston, and formed of an elastic material.', '2. The water pump of claim 1, wherein the driving unit comprises: a linear shaft coupled to the piston and moving the piston inside the hydraulic space; a rotor coupled to a thread formed on an outer surface of the linear shaft and moving the linear shaft forward and backward via rotation; a stator arranged to surround the rotor and rotating the rotor; and a motor casing accommodating the linear shaft, the rotor, and the stator therein.', '5. The water pump of any one of claims 1 to 4, wherein the cooling water flow rate control unit comprises: an impeller cover arranged above the impeller, formed in a cylinder shape of which an end portion facing the impeller is opened, and operating such that a side surface selectively opens or closes the discharge port; a chamber cover arranged above the impeller cover, having a pressurizing space communicating with the hydraulic space therein, and applying pressure to the impeller cover through the cooling water introduced to the pressurizing space; and a pressurizing member arranged in a pressurizing space between the impeller cover and the chamber cover to seal a gap between the impeller cover and the chamber cover, and transmitting the pressure applied by the cooling water introduced to the pressurizing space to the impeller cover.', '7. The water pump of claim 5, wherein the body portion further comprises a check valve accommodated inside the housing to face a cooling water flow hole of which one end is connected to the cylinder portion and the other end is provided at the impeller cover, and preventing the cooling water from being introduced from the cylinder portion to the body portion by being closed when the piston moves in a direction towards the body portion.']",False,"['400', '10', '1430', '1420', '1440', '300', '1500', '1200', '1150', '1130', '120', '1000', '1100', '143', '140', '1141', '4', '1110']" 595,EP_3597880_A1 (3).png,EP3597880A1,WATER PUMP,['FIG4'],['FIG4 is a cross-sectional view illustrating a state in which a check valve of a water pump according to an embodiment of the present disclosure is opened '],"['Referring to FIG4, when the cooling water flowing through the cooling water flow hole 1141a applies the pressure to the bottom of the sealing ball 1153, the sealing ball 1153 is separated from the latching protrusion 1152 and thus the flow path 1151a may be opened. Accordingly, the cooling water introduced to the flow path 1151a through the bottom of the sealing ball 1153 may be filled in the hydraulic space 1200a.']",29,77,cross-sectional view,F,"[{'element_identifier': '1150', 'terms': ['check valve']}, {'element_identifier': '1153', 'terms': ['sealing ball']}, {'element_identifier': '1151', 'terms': ['valve cylinder']}]","['7. The water pump of claim 5, wherein the body portion further comprises a check valve accommodated inside the housing to face a cooling water flow hole of which one end is connected to the cylinder portion and the other end is provided at the impeller cover, and preventing the cooling water from being introduced from the cylinder portion to the body portion by being closed when the piston moves in a direction towards the body portion.', '8. The water pump of claim 7, wherein the check valve comprises: a valve cylinder having therein a flow path communicating the body portion and the cylinder portion; a latching protrusion protruding from an inner surface of the valve cylinder; and a sealing ball located on the flow path and closing the flow path by being caught at the latching protrusion by the cooling water flowing from the cylinder portion to the body portion.']",False,"['1150', '1153', '1151', '10']" 596,EP_3597880_A1.png,EP3597880A1,WATER PUMP,['FIG1'],['FIG1 is a cross-sectional view illustrating a state in which a discharge port of a water pump according to an embodiment of the present disclosure is closed'],"['Referring to FIG1, a water pump 1000 according to an embodiment of the present disclosure includes a body portion 1100, a cylinder portion 1200, and a linear motor 1300.', 'The elastic member 1144 is provided between the impeller cover 1141 and the impeller 1120, and applies an elastic restoring force to the impeller cover 1141 towards the pressurizing space 1142a. Accordingly, the impeller cover 1141 that moved downward may return upward. In FIG1, the elastic member 1144 is shown as a coil-shaped spring, but this is only an embodiment of the present disclosure and a material and shape of the elastic member 1144 may vary.', 'Referring to FIG1, a temperature sensor (not shown) that measures a temperature of the engine outputs a predetermined signal and transmits the signal to a motor control unit (not shown). Then, when the motor control unit applies a current to the linear motor 1300 based on the signal, the rotor 1330 moves the piston 1310 towards the pressurizing space 1142a via rotation.']",29,191,cross-sectional view,F,"[{'element_identifier': '1300', 'terms': ['piston']}, {'element_identifier': '1120', 'terms': ['impeller']}, {'element_identifier': '1100', 'terms': ['body portion']}, {'element_identifier': '1130', 'terms': ['rotation shaft']}, {'element_identifier': '1400', 'terms': ['driving unit']}, {'element_identifier': '1143', 'terms': ['pressurizing member']}, {'element_identifier': '1150', 'terms': ['check valve']}, {'element_identifier': '1000', 'terms': ['water pump']}, {'element_identifier': '1500', 'terms': ['lock preventing member']}, {'element_identifier': '1200', 'terms': ['cylinder portion']}]","['1. A water pump comprising: a body portion comprising a housing where an inlet port and a discharge port through which cooling water is introduced and discharged are provided, an impeller accommodated inside the housing and introducing or discharging the cooling water via rotation, a rotation shaft coupled to the impeller and rotating the impeller by receiving external driving power, and a cooling water flow rate control unit arranged above the impeller and operating to selectively open or close the discharge port; a cylinder portion provided above the cooling water flow rate control unit and formed therein a hydraulic space accommodating cooling water that applies pressure to the cooling water flow rate control unit; a piston located inside the hydraulic space and pressurizing the cooling water present inside the hydraulic space; a driving unit coupled to a side surface of the cylinder portion and moving the piston forward or backward; and a lock preventing member located at an inner surface of the cylinder portion that faces a front surface or a rear surface of the piston, and formed of an elastic material.', '5. The water pump of any one of claims 1 to 4, wherein the cooling water flow rate control unit comprises: an impeller cover arranged above the impeller, formed in a cylinder shape of which an end portion facing the impeller is opened, and operating such that a side surface selectively opens or closes the discharge port; a chamber cover arranged above the impeller cover, having a pressurizing space communicating with the hydraulic space therein, and applying pressure to the impeller cover through the cooling water introduced to the pressurizing space; and a pressurizing member arranged in a pressurizing space between the impeller cover and the chamber cover to seal a gap between the impeller cover and the chamber cover, and transmitting the pressure applied by the cooling water introduced to the pressurizing space to the impeller cover.', '7. The water pump of claim 5, wherein the body portion further comprises a check valve accommodated inside the housing to face a cooling water flow hole of which one end is connected to the cylinder portion and the other end is provided at the impeller cover, and preventing the cooling water from being introduced from the cylinder portion to the body portion by being closed when the piston moves in a direction towards the body portion.']",False,"['1400', '410', '420', '140', '1300', '1500', '1200', '1150', '1130', '1120', '1000', '1100', '1143', '140', '110']" 597,EP_3597901_A1 (2).png,EP3597901A1,ROTOR BLADE FOR WIND TURBINE,"['FIG3', ' FIG4']","['FIG3 is a schematic view of a cross-section of a sub-blade of the blade in FIG2 ', 'FIG4 is a perspective view of a connector of the blade in FIG2']","['Referring now to FIG3, showing a cross-section of a sub-blade 108, the sub-blade 108 of the blade 104 will be further described. The sub-blade 108 may have an airfoil-shaped cross-section in order to generate a lift force when subject to a blowing wind. The airfoil shape comprises a leading edge 116, which is a point at a front of the airfoil that has maximum curvature, and a trailing edge 118, which is a point at a rear of the airfoil that has maximum curvature. A chord line 120 is defined by a straight line connecting the leading edge 116 and the trailing edge 118. The angle of attack of the sub-blade 108 is defined by an angle of the chord line 120 in relation to the wind direction. ', 'Referring now to FIG4, a connector 110 of the blade 104 will be further described. The connector 110 may be a relatively thin structure, which is arranged to extend in a cross-section of the blade 104. The thin structure of the connector 110 may thus ensure that the connector 110 has a small surface facing the wind direction in order to limit a drag force on the blade 104 caused by the connector 110. The connector 110 may further have a stream-lined shape with the surface facing the wind direction being rounded so that the drag force on the blade 104 is further limited.', 'According to an embodiment, an outer portion 134 of the plate-like structure 126 may be attached to an inner portion 136 of the plate-like structure 126 during assembly of the blade 104. A separation of the outer portion 134 and the inner portion 136 is indicated by the dashed line 138 in FIG4. Walls of the outer portion 134 and the inner portion 136 may each partly define the through-going hole 132. This implies that, during assembly of the blade 104, the inner portion 136 of the plate-like structure 126 may first be arranged in relation to the sub-blade 108. Then, when the sub-blade 108 is properly positioned in relation to the plate-like structure 126, the outer portion 134 may be attached to the inner portion 136 so that the outer portion 134 and the inner portion 136 together encompass a cross-section of the sub-blade 108. According to this arrangement, the sub-blade 108 does not need to be guided through the through-going hole 132 for mounting of the sub-blade 108 in relation to the connector 110.']",33,479,"perspective view, schematic view",F,"[{'element_identifier': '122', 'terms': ['shell']}, {'element_identifier': '128', 'terms': ['joining parts']}, {'element_identifier': '136', 'terms': ['inner portion']}, {'element_identifier': '116', 'terms': ['leading edge']}, {'element_identifier': '130', 'terms': ['large hole']}, {'element_identifier': '3', 'terms': ['blade are']}, {'element_identifier': '126', 'terms': ['plate-like structure', 'plate-like structures']}, {'element_identifier': '118', 'terms': ['trailing edge']}, {'element_identifier': '138', 'terms': ['dashed line']}, {'element_identifier': '134', 'terms': ['outer portion']}, {'element_identifier': '132', 'terms': ['through-going hole', 'through-going holes']}, {'element_identifier': '110', 'terms': ['connector', 'connectors']}, {'element_identifier': '124', 'terms': ['supporting structure']}, {'element_identifier': '120', 'terms': ['chord line']}]","['1. A blade for a rotor of a wind turbine, said blade (104) comprising a plurality of interconnected blade sections, each blade section comprising: a truss-like three-dimensional structure comprising a plurality of longitudinal strut members (108) extending substantially along the longitudinal direction of the blade (104), at least two connectors (110) extending in a cross-sectional direction of the blade (104), and diagonal strut members (112) extending diagonally through the blade (104) between two of the at least two connectors (112), thereby forming the truss-like three-dimensional structure, wherein the plurality of longitudinal strut members (108) are separated along an entire longitudinal direction of the blade (104), wherein the at least two connectors (110) are connected to the plurality of longitudinal strut members (108), and wherein the plurality of blade sections are interconnected by means of a connector of a first section being attached to a connector of a second section.']",True,"['122', '124', '118', '116', '120', '3', '110', '132', '126', '134', '138', '128', '130', '136', '4', '18']" 598,EP_3597901_A1 (3).png,EP3597901A1,ROTOR BLADE FOR WIND TURBINE,['FIG5'],['FIG5 is a perspective view of a section of the blade in FIG2'],"['According to another embodiment, sections of the blade 104 are pre-assembled and transported in the pre-assembled state. Then, the sections of the blade 104 may be attached to each other at the site for final assembly of the blade 104. A section 200 may be formed as illustrated in FIG5. The section 200 comprises a first connector 110a and a second connector 110b, the first and second connectors 110a, 110b being adjacent connectors in the blade 104. The section 200 further comprises the longitudinal strut members 108 and the diagonal strut members 112 between the connectors 110a, 110b. Hence, the longitudinal strut members 108 and the diagonal strut members 112 are mounted to the connectors 110 before transport to the site. At the site, sections 200 may be attached to each other for final assembly of the blade 104.']",13,157,perspective view,F,"[{'element_identifier': '142', 'terms': ['hub connecting part']}, {'element_identifier': '19', 'terms': ['weighs']}, {'element_identifier': '148', 'terms': ['diagonal strut members']}, {'element_identifier': '112', 'terms': ['diagonal strut members', 'diagonal strut member']}, {'element_identifier': '108', 'terms': ['sub-blade', 'sub-blades']}, {'element_identifier': '140', 'terms': ['root connector']}, {'element_identifier': '144', 'terms': ['blade connecting part']}, {'element_identifier': '200', 'terms': ['sections', 'section']}, {'element_identifier': '146', 'terms': ['longitudinal strut members', 'longitudinal strut member']}]","['1. A blade for a rotor of a wind turbine, said blade (104) comprising a plurality of interconnected blade sections, each blade section comprising: a truss-like three-dimensional structure comprising a plurality of longitudinal strut members (108) extending substantially along the longitudinal direction of the blade (104), at least two connectors (110) extending in a cross-sectional direction of the blade (104), and diagonal strut members (112) extending diagonally through the blade (104) between two of the at least two connectors (112), thereby forming the truss-like three-dimensional structure, wherein the plurality of longitudinal strut members (108) are separated along an entire longitudinal direction of the blade (104), wherein the at least two connectors (110) are connected to the plurality of longitudinal strut members (108), and wherein the plurality of blade sections are interconnected by means of a connector of a first section being attached to a connector of a second section.']",True,"['200', '108', '112', '5', '140', '142', '146', '144', '148', '9', '19']" 599,EP_3597952_A1 (2).png,EP3597952A1,SLIDING-TYPE CONSTANT VELOCITY UNIVERSAL JOINT FOR REAR-WHEEL DRIVE SHAFT,['FIG3A'],['FIG3A is a longitudinal sectional view (sectional view taken along the line X-X of FIG3B) for illustrating a plunging type constant velocity universal joint incorporated into the above-mentioned rear-wheel drive shaft'],"['The outer joint member 21 integrally comprises a mouth section 21a and a stem section 21b. The mouth section 21a has a cup shape that is open toward one side in an axial direction of the joint (outboard side or left side in FIG3A). The stem section 21b extends from a bottom portion of the mouth section 21a to another side in the axial direction (inboard side or right side in FIG3A). Eight linear track grooves 21d extending in the axial direction are formed in a cylindrical inner peripheral surface 21c of the mouth section 21a. A spline 21e to be inserted into a spline hole of the differential gear G is formed in an outer peripheral surface of an inboard-side end portion of the stem section 21b. The mouth section 21a and the stem section 21b may be integrally made of the same material, or may be joined to each other by, for example, welding after the mouth section 21a and the stem section 21b are formed into separate sections.']",39,186,longitudinal sectional view,F,"[{'element_identifier': '21', 'terms': ['outer joint member']}, {'element_identifier': '24', 'terms': ['cage']}, {'element_identifier': '23', 'terms': ['balls', 'ball']}, {'element_identifier': '22', 'terms': ['member']}]","['1. A plunging type constant velocity universal joint for a rear-wheel drive shaft, comprising: an outer joint member having a cylindrical inner peripheral surface in which eight track grooves extending in an axial direction of the plunging type constant velocity universal joint are formed; an inner joint member having a spherical outer peripheral surface in which eight track grooves extending in the axial direction are formed, and having a spline hole formed along an axial center of the inner joint member; eight balls arranged in ball tracks formed by the track grooves of the outer joint member and the track grooves of the inner joint member; and a cage, which has eight pockets configured to receive the balls, and is held in slide contact with the inner peripheral surface of the outer joint member and the outer peripheral surface of the inner joint member, wherein a curvature center of a spherical portion formed on an outer peripheral surface of the cage and a curvature center of a spherical portion formed on an inner peripheral surface of the cage are offset to opposite sides in the axial direction with respect to a joint center by an equal distance, wherein a ratio PCD BALL /D BALL of a pitch circle diameter PCD BALL of the balls to a diameter D BALL of each of the balls is set from 3.3 to 3.6, and wherein a ratio T I /D BALL of a radial thickness T I of the inner joint member to the diameter D BALL of each of the balls is set from 0.30 to 0.']",True,"['24', '21', '21', '23', '99', '21', '24', '22', '14', '23', '22']" 600,EP_3597952_A1 (3).png,EP3597952A1,SLIDING-TYPE CONSTANT VELOCITY UNIVERSAL JOINT FOR REAR-WHEEL DRIVE SHAFT,['FIG5A'],['FIG5A is a longitudinal sectional view (sectional view taken along the line Y-Y of FIG5B) for illustrating a fixed type constant velocity universal joint incorporated into the above-mentioned rear-wheel drive shaft'],"['The outer joint member 31 integrally comprises a mouth section 31a and a stem section 31b. The mouth section 31a has a cup shape that is open toward one side in an axial direction of the joint (inboard side or right side in FIG5A). The stem section 31b extends from a bottom portion of the mouth section 31a to another side in the axial direction (outboard side or left side in FIG5A). Eight arc-shaped track grooves 31d extending in the axial direction are formed in a spherical inner peripheral surface 31c of the mouth section 31a. A spline 31e to be inserted into a spline hole on the wheel W side is formed in an outer peripheral surface of the stem section 31b. The mouth section 31a and the stem section 31b may be integrally made of the same material, or may be joined to each other by, for example, welding after the mouth section 31a and the stem section 31b are formed into separate sections . Further, a through hole extending in the axial direction may be formed along the axial centers of the mouth section 31a and the stem section 31b.']",39,209,longitudinal sectional view,F,"[{'element_identifier': '3', 'terms': []}, {'element_identifier': '34', 'terms': ['cage']}, {'element_identifier': '33', 'terms': ['balls']}, {'element_identifier': '31', 'terms': ['outer joint member']}, {'element_identifier': '32', 'terms': []}]","['1. A plunging type constant velocity universal joint for a rear-wheel drive shaft, comprising: an outer joint member having a cylindrical inner peripheral surface in which eight track grooves extending in an axial direction of the plunging type constant velocity universal joint are formed; an inner joint member having a spherical outer peripheral surface in which eight track grooves extending in the axial direction are formed, and having a spline hole formed along an axial center of the inner joint member; eight balls arranged in ball tracks formed by the track grooves of the outer joint member and the track grooves of the inner joint member; and a cage, which has eight pockets configured to receive the balls, and is held in slide contact with the inner peripheral surface of the outer joint member and the outer peripheral surface of the inner joint member, wherein a curvature center of a spherical portion formed on an outer peripheral surface of the cage and a curvature center of a spherical portion formed on an inner peripheral surface of the cage are offset to opposite sides in the axial direction with respect to a joint center by an equal distance, wherein a ratio PCD BALL /D BALL of a pitch circle diameter PCD BALL of the balls to a diameter D BALL of each of the balls is set from 3.3 to 3.6, and wherein a ratio T I /D BALL of a radial thickness T I of the inner joint member to the diameter D BALL of each of the balls is set from 0.30 to 0.']",True,"['33', '31', '33', '34', '32', '16', '3', '32', '34', '33']" 601,EP_3597961_A1 (2).png,EP3597961A1,POWER TRANSMISSION SYSTEM AND ATTENUATION MECHANISM,"['FIG5', ' FIG6']","['FIG5 is a schematic diagram of an attenuation mechanism according to the modification and another modification ', 'FIG6 is a schematic diagram of an attenuation mechanism according to yet another modification']","['In the aforementioned preferred embodiment, the support member 71 of the attenuation mechanism 7 is formed by a single plate. However, the configuration of the support member 71 is not limited to this. For example, as shown in FIG5, the support member 71 may be composed of two or more members. Detailedly, the support member 71 includes an attachment hub 71a and a plate portion 71b. The plate portion 71b is attached to a flange portion 71d of the attachment hub 71a by, for instance, at least one rivet 75.', 'In the aforementioned preferred embodiment, the inertia member 72 is engaged by friction with the support member 71 through the friction materials 73. However, the configuration that the inertia member 72 is engaged by friction with the support member 71 is not limited to this. For example, as shown in FIG5, the inertia member 72 may be engaged by friction with the support member 71, while making direct contact therewith. According to this configuration, it is possible to omit installation of the friction materials. ', 'In the aforementioned preferred embodiment, the inertia member 72 interposes the support member 71 therein. However, the interposing configuration between the inertia member 72 and the support member 71 is not limited to this. For example, as shown in FIG6, the support member 71 may interpose the inertia member 72 therein. In this case, for instance, the support member 71 includes the attachment hub 71a and a clamp portion 71c. The attachment hub 71a is attached to the transmission shaft 6. The clamp portion 71c is attached to the flange portion 71d of the attachment hub 71a by the at least one rivet 75. The clamp portion 71c interposes and holds the inertia member 72 together with the attachment hub 71a therebetween. According to this configuration, the inertia member 72 can be simplified in structure. Hence, the inertia amount can be easily adjusted, and can be easily increased as well.']",30,365,schematic diagram,B,"[{'element_identifier': '723', 'terms': ['elastic portion']}, {'element_identifier': '72', 'terms': ['inertia member']}, {'element_identifier': '5', 'terms': ['drive wheel']}, {'element_identifier': '6', 'terms': ['transmission shaft']}, {'element_identifier': '75', 'terms': ['one rivet']}, {'element_identifier': '71', 'terms': ['support member']}]","['1. A power transmission system comprising: an electric motor; a drive wheel; a transmission shaft transmitting a torque between the electric motor and the drive wheel; and an attenuation mechanism attached to the transmission shaft, wherein the attenuation mechanism includes a support member attached to the transmission shaft, and an inertia member disposed to be rotatable relatively to the transmission shaft, the inertia member being engaged by friction with the support member.', '11. The power transmission system according to claim 9, wherein one of the inertia member and the support member includes an elastic portion as the urging means, the elastic portion pressing the other of the inertia member and the support member while being elastically deformed.']",True,"['72', '75', '71', '5', '72', '723', '75', '71', '6', '10']" 602,EP_3597961_A1 (3).png,EP3597961A1,POWER TRANSMISSION SYSTEM AND ATTENUATION MECHANISM,"['FIG7', ' FIG8']","['FIG7 is a schematic diagram of an attenuation mechanism according to further yet another modification ', 'FIG8 is a block diagram of a power transmission system according to still further yet another modification ']","['In the aforementioned preferred embodiment, the inertia member 72 is urged against the support member 71 by the elastic force thereof. However, the urging configuration between the inertia member 72 and the support member 71 is not limited to this. For example, as shown in FIG7, the attenuation mechanism 7 may further include an urging member 72e. The urging member 72e is, for instance, a disc spring. The urging member 72e urges the inertia member 72 and the support member 71 so as to make the both approach each other. ', 'In the aforementioned preferred embodiment, the power transmission system according to the present invention has been applied to the hybrid car. However, the power transmission system according to the present invention is applicable to an electric car as well. For example, as shown in FIG8, the power transmission system 100 applied to the electric car includes the electric motor 3, a reducer 8, a differential gear 9, the drive wheel 5, the transmission shaft 6 and the attenuation mechanism 7. It should be noted that the configurations of the electric motor 3, the drive wheel 5, the transmission shaft 6 and the attenuation mechanism 7 are similar to those in the aforementioned preferred embodiment. Hence, the detailed explanation thereof will be hereinafter omitted.']",32,240,"block diagram, schematic diagram",B,"[{'element_identifier': '8', 'terms': ['reducer']}, {'element_identifier': '7', 'terms': ['attenuation mechanism']}, {'element_identifier': '73', 'terms': ['friction materials']}, {'element_identifier': '100', 'terms': ['power transmission system']}, {'element_identifier': '76', 'terms': ['retaining ring']}, {'element_identifier': '3', 'terms': ['electric motor']}, {'element_identifier': '71', 'terms': ['support member']}]","['1. A power transmission system comprising: an electric motor; a drive wheel; a transmission shaft transmitting a torque between the electric motor and the drive wheel; and an attenuation mechanism attached to the transmission shaft, wherein the attenuation mechanism includes a support member attached to the transmission shaft, and an inertia member disposed to be rotatable relatively to the transmission shaft, the inertia member being engaged by friction with the support member.', '2. The power transmission system according to claim 1, further comprising: a gearbox or reducer disposed between the electric motor and the drive wheel.']",True,"['73', '76', '71', '7', '100', '3', '8', '11']" 603,EP_3597961_A1.png,EP3597961A1,POWER TRANSMISSION SYSTEM AND ATTENUATION MECHANISM,['FIG1'],['FIG1 is a block diagram of a power transmission system'],"['As shown in FIG1, a power transmission system 100 is applied to a hybrid car. The power transmission system 100 includes an engine 1, a clutch 2, an electric motor 3, a transmission 4 (exemplary gearbox), a drive wheel 5, a transmission shaft 6 and an attenuation mechanism 7. It should be noted that the power transmission system 100 does not include any clutch between the electric motor 3 and the drive wheel 5.']",10,85,block diagram,B,"[{'element_identifier': '8', 'terms': ['reducer']}, {'element_identifier': '72', 'terms': ['inertia member']}, {'element_identifier': '73', 'terms': ['friction materials']}, {'element_identifier': '1', 'terms': ['engine']}, {'element_identifier': '100', 'terms': ['power transmission system']}, {'element_identifier': '2', 'terms': ['clutch']}, {'element_identifier': '74', 'terms': ['one rivet']}, {'element_identifier': '71', 'terms': ['support member']}]","['1. A power transmission system comprising: an electric motor; a drive wheel; a transmission shaft transmitting a torque between the electric motor and the drive wheel; and an attenuation mechanism attached to the transmission shaft, wherein the attenuation mechanism includes a support member attached to the transmission shaft, and an inertia member disposed to be rotatable relatively to the transmission shaft, the inertia member being engaged by friction with the support member.', '2. The power transmission system according to claim 1, further comprising: a gearbox or reducer disposed between the electric motor and the drive wheel.']",True,"['100', '1', '74', '72', '71', '73', '2', '8']" 604,EP_3597975_A1 (1).png,EP3597975A1,COUPLING FOR FLUID LINE ASSEMBLY,['FIG2'],"['FIG2 is a side cross-sectional view of the fluid line assembly of FIG1, in accordance with an embodiment of the present disclosure ']","['A coupling between the second coupler 132 and the first coupler 130 may define a joint 290 therebetween. For facilitating fluid transmission through the passage 118, the first axial end face 162 and the second axial end face 240 may meet, and/or may contact each other at the joint 290. As may be noted in an enlarged callout 310 for the joint 290 in FIG2, a clearance between the first axial end face 162 and the second axial end face 240 is generally exaggerated. Such exaggeration is solely to assist with identifying the different portions and/or elements disposed close to the joint 290, as is discussed in the present disclosure. It may be appreciated that in an actual practice, and upon establishing the assembly between the first coupler 130 and the second coupler 132, such an exaggerated clearance may be non-existent.']",25,154,side cross-sectional view,F,"[{'element_identifier': '160', 'terms': ['first axis']}, {'element_identifier': '290', 'terms': ['joint']}, {'element_identifier': '158', 'terms': ['first conduit']}, {'element_identifier': '118', 'terms': ['passage']}, {'element_identifier': '152', 'terms': ['first axial end']}, {'element_identifier': '184', 'terms': ['first planar surface']}, {'element_identifier': '246', 'terms': ['channel']}, {'element_identifier': '136', 'terms': ['friction member']}, {'element_identifier': '294', 'terms': ['sealing surface']}, {'element_identifier': '234', 'terms': ['flanged end']}, {'element_identifier': '258', 'terms': ['second planar surface']}, {'element_identifier': '276', 'terms': ['inner threads']}, {'element_identifier': '310', 'terms': ['enlarged callout']}, {'element_identifier': '306', 'terms': ['friction surface']}, {'element_identifier': '162', 'terms': ['first axial end face']}, {'element_identifier': '134', 'terms': ['seal']}, {'element_identifier': '192', 'terms': ['second threaded portion']}, {'element_identifier': '110', 'terms': ['first fluid line']}, {'element_identifier': '210', 'terms': ['flange']}, {'element_identifier': '218', 'terms': ['second axis']}, {'element_identifier': '130', 'terms': ['first coupler']}, {'element_identifier': '168', 'terms': ['groove']}, {'element_identifier': '100', 'terms': ['fluid line assembly', 'coupling']}, {'element_identifier': '2', 'terms': ['andFIG.']}, {'element_identifier': '198', 'terms': ['threaded end']}, {'element_identifier': '138', 'terms': ['locking nut']}, {'element_identifier': '270', 'terms': ['axial end portions']}, {'element_identifier': '240', 'terms': ['second axial end face']}, {'element_identifier': '132', 'terms': ['second coupler']}, {'element_identifier': '212', 'terms': ['threaded connection']}]","['1. A coupling (114) for a fluid line assembly (100) including a first fluid line (110) and a second fluid line (112), the coupling (114) comprising: a first coupler (130) adapted to be connected to the first fluid line (110), and including a first axial end face (162) with a groove (168); a second coupler (132) adapted to be connected to the second fluid line (112), and being couplable with the first coupler (130) to combinedly define a passage (118) therethrough for fluidly connecting the first fluid line (110) with the second fluid line (112), the second coupler (132) including a second axial end face (240) with a channel (246), the second axial end face (240) being contactable with the first axial end face (162); a seal (134) at least partly received within the groove (168) and adapted to abut the second axial end face (240) of the second coupler (132) to prevent a leakage of fluid from the passage (118); and a friction member (136) at least partly received within the channel (246) and adapted to engage the first axial end face (162) of the first coupler (130) to restrict a torsional movement between the first coupler (130) and the second coupler (132).', '4. The coupling (114) of claim 1 further including a locking nut (138) for securing the first coupler (130) with the second coupler (132).', '8. The coupling (114) of claim 1, wherein the first axial end face (162) includes a first planar surface (184), the friction member (136) including a friction surface (306) to contact the first planar surface (184).', '9. The coupling (114) of claim 1, wherein the second axial end face (240) includes a second planar surface (258), the seal (134) including a sealing surface (294) to contact the second planar surface (258).']",False,"['290', '246', '306', '184', '162', '294', '26', '152', '11', '270', '138', '276', '310', '240', '136', '258', '134', '168', '130', '192', '100', '90', '110', '198', '8', '218', '160', '118', '212', '132', '234', '152', '158', '2', '210']" 605,EP_3598017_A1 (1).png,EP3598017A1,"AIR OUTLET STRUCTURE, AIR OUTLET METHOD FOR AIR CONDITIONER, AND THE AIR CONDITIONER","['FIG3', ' FIG4']","['FIG4 is a schematic diagram of a drive structure of a first air deflector of an optional air outlet structure in accordance with an embodiment of the disclosure ', 'FIG3 is a front view of an optional air conditioner in accordance with an embodiment of the disclosure']","['In order to control a motion of the first air deflector 41, as shown in FIG4, the air outlet structure may further include a drive motor 43. The drive motor 43 is connected with the first air deflector 41 in a driving manner, as to drive the first air deflector 41 to move to the first preset position or the second preset position. Specifically, a gear set 44 and a crank 45 are provided between the drive motor 43 and the first air deflector 41. One end of the crank 45 is connected with a side of a bottom end of first air deflector 41, and another end of the crank 45 is provided with a gear matching with the gear set 44. The drive motor 43 is connected with the gear on the crank 45 through the gear set 44 in the driving manner. In this way, the first air deflector 41 is driven to rotate. ', 'In order to ensure uniform air outlet effect of the auxiliary air outlet 30, as shown in FIG3, the auxiliary air outlet 30 may further include multiple first air holes 46, distributed on the panel 50 at intervals in a form of array. In this way, the air of the auxiliary air outlet 30 may be sent out through each of the first air holes 46, thereby improving the air supplying scope and comfort of the air conditioner.']",46,254,"front view, schematic diagram",B,"[{'element_identifier': '30', 'terms': ['auxiliary air outlet']}, {'element_identifier': '45', 'terms': ['crank']}, {'element_identifier': '50', 'terms': ['panel']}, {'element_identifier': '43', 'terms': ['drive motor']}, {'element_identifier': '41', 'terms': ['first air deflector']}]","['2. The air outlet structure as claimed in claim 1, wherein the auxiliary air outlet (30) is provided on a panel (50) of an air conditioner.', '6. The air outlet structure as claimed in claim 4, wherein the adjusting device (40) comprises: a first air deflector (41), provided between the auxiliary air outlet channel (60) and the main air outlet channel (10) in a foldable manner, wherein the main air outlet channel (10) is communicated with the auxiliary air outlet channel (60) when the first air deflector (41) moves to a first preset position, and the main air outlet channel (10) is disconnected with the auxiliary air outlet channel (60) by the first air deflector (41) when the first air deflector (41) moves to a second preset position.', '9. The air outlet structure as claimed in claim 6, wherein the air outlet structure further comprises a drive motor (43), the drive motor (43) is connected with the first air deflector (41) in a driving manner, as to drive the first air deflector (41) to move to the first preset position or the second preset position.']",True,"['50', '30', '45', '41', '45', '43', '4']" 606,EP_3598038_A1.png,EP3598038A1,HEAT PUMP APPARATUS,"['FIG1', ' FIG2']","['FIG2 is a perspective view illustrating an external appearance of the heat pump apparatus according to Embodiment 1 ', 'FIG1 is a piping system diagram of a hot-water storing hot-water supplying system including a heat pump apparatus according to Embodiment 1']","['FIG2 is a perspective view illustrating the external appearance of the heat pump apparatus 1 according to Embodiment 1. As illustrated in FIG2, the heat pump apparatus 1 includes a front panel 19, a side panel 20, a top panel 21, a grille 12, and leg portions 41. The heat pump apparatus 1 is fixed to a ground surface or a floor surface via the leg portions 41. In the description below, the ""upper direction"", the ""front direction"", and the ""right direction"" are defined as indicated by the arrows in FIG2 in order to facilitate the understanding of the drawings. The direction opposite to the ""upper direction"" is the ""lower direction"". The direction opposite to the ""front direction"" is the ""rear direction"". The direction opposite to the ""right direction"" is the ""left direction"". ', 'FIG1 is a piping system diagram of a hot-water storing hot-water supplying system 90 including a heat pump apparatus 1 according to Embodiment 1. As illustrated in FIG1, the hot-water storing hot-water supplying system 90 includes the heat pump apparatus 1 and a tank unit 91. The heat pump apparatus 1 is provided outdoors. The tank unit 91 may be provided outdoors or may be provided indoors.']",44,246,"diagram, perspective view",F,"[{'element_identifier': '98', 'terms': ['tank upper portion pipe']}, {'element_identifier': '19', 'terms': ['front panel']}, {'element_identifier': '12', 'terms': ['grille']}, {'element_identifier': '92', 'terms': ['hot water storage tank']}, {'element_identifier': '1', 'terms': ['heat pump apparatus']}, {'element_identifier': '22', 'terms': ['service panel']}, {'element_identifier': '94', 'terms': ['flow path switching valve']}, {'element_identifier': '96', 'terms': ['external piping']}, {'element_identifier': '2', 'terms': ['compressor']}, {'element_identifier': '93', 'terms': ['water pump']}, {'element_identifier': '20', 'terms': ['electrical equipment box']}, {'element_identifier': '6', 'terms': ['internal heat exchanger']}, {'element_identifier': '90', 'terms': []}, {'element_identifier': '42', 'terms': []}, {'element_identifier': '95', 'terms': ['bypass passage']}, {'element_identifier': '41', 'terms': ['leg portions']}, {'element_identifier': '21', 'terms': ['control board', 'top panel']}, {'element_identifier': '97', 'terms': ['external piping']}]","['1. A heat pump apparatus, comprising: an air-to-refrigerant heat exchanger configured to exchange heat between air and a refrigerant; a blower configured to blow air to the air-to-refrigerant heat exchanger; a compressor configured to compress the refrigerant; and an electrical unit comprising an electrical part for driving at least one of the blower and the compressor, wherein: the electrical unit comprises: an electrical circuit board comprising an upper surface, a lower surface, and the electrical part mounted on the lower surface; a receiving tray comprising a receiving portion that covers at least a part of the electrical circuit board from below; a framework that holds the electrical circuit board and the receiving tray; and an opening which is formed between the framework and the receiving portion of the receiving tray and through which air is capable of passing; a space between the electrical circuit board and the receiving portion of the receiving tray is an inner space of the electrical unit; and the inner space of the electrical unit communicates with outside of the electrical unit via the opening.']",True,"['1', '90', '6', '2', '97', '98', '95', '92', '96', '94', '93', '2', '21', '20', '22', '12', '42', '41', '19', '10']" 607,EP_3598088_A1 (3).png,EP3598088A1,PYROELECTRIC SENSOR,['FIG5'],['FIG5 is a schematic cross sectional view showing a substrate used in Example 2'],"['Instead of the plate-shaped Si substrate in Example 1, a cavity wafer including a hollow portion in which a pressure was reduced was used as a substrate. As the substrate 14, as shown in FIG5, a substrate in which a hollow portion 14a is provided in an Si wafer and thicknesses of an upper layer 14b and a lower layer 14c surrounding the hollow portion 14a were respectively 20 µm, and a thickness of the wafer was 500 µm was used.']",14,89,schematic cross-sectional view,G,"[{'element_identifier': '103', 'terms': ['infrared sensing portion']}, {'element_identifier': '5', 'terms': ['image sensor']}, {'element_identifier': '14', 'terms': ['substrate']}, {'element_identifier': '20', 'terms': ['laminated portion']}, {'element_identifier': '105', 'terms': ['cavity portion']}, {'element_identifier': '102', 'terms': ['Si substrate']}, {'element_identifier': '101', 'terms': ['infrared sensor']}, {'element_identifier': '500', 'terms': ['wafer was']}]","['1. A pyroelectric sensor comprising: an Si substrate; a laminated portion in which a heat absorption layer formed of an inorganic material, a lower electrode, a piezoelectric film, and an upper electrode are laminated in this order from one surface side of the Si substrate on the one surface; and an optical filter that is provided at a position of the other surface of the Si substrate corresponding to the laminated portion and selectively transmits an infrared ray, wherein an infrared ray incident to the laminated portion from the optical filter side through the Si substrate is sensed.']",True,"['5', '500', '20', '6', '101', '103', '102', '105', '14']" 608,EP_3598088_A1.png,EP3598088A1,PYROELECTRIC SENSOR,['FIG1'],['FIG1 is a schematic cross sectional view of a pyroelectric sensor of a first embodiment'],"['FIG1 is a schematic cross sectional view of a pyroelectric sensor 1 of a first embodiment of the invention. For the ease of recognition, a film thickness of each layer or a ratio thereof is suitably changed and does not reflect actual film thickness or ratio (the same applies to the following drawings).']",15,58,schematic cross-sectional view,G,"[{'element_identifier': '24', 'terms': ['upper electrode']}, {'element_identifier': '30', 'terms': ['optical filter']}, {'element_identifier': '11', 'terms': ['Si substrate']}, {'element_identifier': '22', 'terms': ['lower electrode', 'lower electrodes']}, {'element_identifier': '18', 'terms': ['heat absorption layer']}, {'element_identifier': '3', 'terms': ['pyroelectric sensor']}, {'element_identifier': '2', 'terms': ['Example']}, {'element_identifier': '20', 'terms': ['laminated portion']}, {'element_identifier': '25', 'terms': ['portion', 'portions']}, {'element_identifier': '10', 'terms': ['Si substrate']}, {'element_identifier': '23', 'terms': ['piezoelectric film']}]","['1. A pyroelectric sensor comprising: an Si substrate; a laminated portion in which a heat absorption layer formed of an inorganic material, a lower electrode, a piezoelectric film, and an upper electrode are laminated in this order from one surface side of the Si substrate on the one surface; and an optical filter that is provided at a position of the other surface of the Si substrate corresponding to the laminated portion and selectively transmits an infrared ray, wherein an infrared ray incident to the laminated portion from the optical filter side through the Si substrate is sensed.']",True,"['25', '24', '23', '22', '20', '18', '10', '30', '25', '20', '24', '23', '22', '3', '2', '30', '11']" 609,EP_3598118_A1 (2).png,EP3598118A1,CAPACITIVE GAS SENSORS AND MANUFACTURING METHOD THEREOF,['FIG6'],"[""FIG6 is a schematic cross-sectional side view of the capacitive gas sensor depicted in FIG5, along the direction AA' ""]","['As illustrated in FIG6, a dielectric-protective material 550 is applied on the surfaces of the interdigitated electrodes 510 and 520 that interface with the gas-sensitive dielectric material 540 for reducing the mechanical stress applied by two adjacent interdigitated electrodes, for e.g. electrodes 510a and 520b, on the gas-sensitive dielectric material 540 deposited in-between. However, the dielectric-protective material 550 may be formed so as to cover the interdigitated electrodes 510a-510c and 520a-520b only partially, for e.g. on the lateral surfaces of the electrodes which should exert more mechanical stress on the gas-sensitive dielectric material than the top surface.']",23,116,schematic cross-sectional view,G,"[{'element_identifier': '6', 'terms': ['-']}, {'element_identifier': '540', 'terms': ['dielectric material']}, {'element_identifier': '515', 'terms': ['electrically conducting strip']}, {'element_identifier': '530', 'terms': ['substrate']}, {'element_identifier': '525', 'terms': ['respective conducting strip']}, {'element_identifier': '510', 'terms': ['electrodes', 'electrode']}, {'element_identifier': '520', 'terms': ['electrodes', 'electrode']}, {'element_identifier': '550', 'terms': ['dielectric-protective material']}]","['1. A capacitive gas sensor, comprising: a first electrode (210; 310; 410; 510); a second electrode (220; 320; 420; 520); a gas-sensitive dielectric material (240; 340; 440; 540) arranged between the first and the second electrodes to form a gas sensitive capacitor, the gas-sensitive dielectric material (240; 340; 440; 540) having a permittivity that depends on an amount of gas compound absorbed from an environmental medium; and a dielectric-electrode interfacing material (250; 350; 450; 550) arranged at an interface between the gas-sensitive dielectric material (240; 340; 440; 540) and at least one of the first and second electrodes, the dielectric-electrode interfacing material (250; 350; 450; 550) being adapted to absorb thermally-induced dilatation of the at least one of the first and second electrodes for reducing the mechanical stress applied on the gas-sensitive dielectric material (240; 340; 440; 540).', '9. A capacitive gas sensor according to claim 8, wherein the capacitive gas sensor is integrated in a semiconductor circuit substrate (330), the second electrode (320) being arranged directly on the semiconductor circuit substrate (330), the first electrode (310) being connected to a patch in the semiconductor circuit substrate (330) through a via (360) that passes across the dielectric-electrode interfacing material (350) and the gas-sensitive dielectric material (340).']",True,"['560', '515', '510', '525', '5', '550', '520', '550', '540', '530', '9915', '6', '16']" 610,EP_3598145_A1 (1).png,EP3598145A1,PITOT STATIC SYSTEMS WITH ANGLE OF SIDESLIP DETERMINATION AND COMPENSATION,['FIG2C'],['FIG2C is a schematic view of an embodiment of an air data probe in accordance with this disclosure'],"['In certain embodiments, the AOS module 103 is configured to determine the LAOS by receiving the at least one total pressure value and the at least one static pressure value from the pitot static system 101 at each location. The AOS module 103 can be configured to receive the at least one differential static pressure value of the flow from the pitot static system 101 at each location or derive the at least one differential static pressure value from a plurality of static pressure values from the pitot static system at each location. The AOS module 103 can be configured to determine a local angle of attack (LAOA) value at each location based on the at least one differential static pressure value and compare total pressure to static pressure ratio (Pt/Ps) to the LAOA value to determine the LAOS value at each location based on stored LAOS correlation data for each location.In certain embodiments, as shown in FIG2C, the pitot static system 101 can include, e.g., at each location, a pitot tube 203 having at least one total pressure port 204 and at least two static pressure ports 207a, 207b that are disposed 180 degrees apart from each other to allow determination of differential pressure value, as appreciated by those having ordinary skill in the art in view of this disclosure. Such ports can be used to determine differential pressure to determine to allow the system to determine a first local flow angle (e.g., local angle of attack).']",18,271,schematic view,G,"[{'element_identifier': '100', 'terms': ['system']}, {'element_identifier': '203', 'terms': ['pitot tube']}, {'element_identifier': '101', 'terms': ['pitot static system', 'pitot static systems']}, {'element_identifier': '103', 'terms': ['module']}]","['1. An air data probe system (100), comprising: a pitot static system (101) configured to sense at least one total pressure value of a flow at one or more locations, at least one static pressure value of the flow at the one or more locations, and, directly or indirectly, at least one differential static pressure value of the flow at the one or more locations; and an angle of slip (AOS) module (103) configured to determine a local angle of slip (LAOS) value at each location based on the at least one total pressure value at each location, the at least one static pressure value at each location, and the at least one differential static pressure value at each location.', '9. The system of any preceding claim, wherein the pitot static system (101) includes a pitot tube (203) having at least one total pressure port (204) and at least two static pressure ports (207a,207b) 180 degrees apart from each other to allow determination of differential pressure value to allow the system (101) to determine a first local flow angle.']",True,"['101', '100', '103', '101', '203', '10']" 611,EP_3598170_A1 (1).png,EP3598170A1,SLOW TIME FREQUENCY DIVISION MULTIPLEXING WITH BINARY PHASE SHIFTERS,['FIG2'],['FIG2 schematically illustrates an example embodiment of a detector device'],"['FIG2 illustrates an example detector device 22. A plurality of transmitters 26, which are antenna in this example, are configured to transmit respective signals that are useful for detecting any objects in a vicinity of the vehicle 20 within the field of view of the detector 22. A plurality of receivers 28 are configured to receive reflected signals that are reflections of the transmitted signals after they reflect off an object.']",10,76,embodiment,G,"[{'element_identifier': '28', 'terms': ['receivers']}, {'element_identifier': '30', 'terms': ['controller']}, {'element_identifier': '38', 'terms': ['voltage controlled oscillator']}, {'element_identifier': '22', 'terms': ['detector device']}, {'element_identifier': '48', 'terms': ['digital converter']}, {'element_identifier': '34', 'terms': ['memory']}, {'element_identifier': '40', 'terms': ['binary phase shifter', 'binary phase shifters']}, {'element_identifier': '50', 'terms': ['DSP']}, {'element_identifier': '26', 'terms': ['transmitters', 'transmitter']}, {'element_identifier': '46', 'terms': ['low noise amplifier']}, {'element_identifier': '32', 'terms': ['processor', 'processors']}]","['1. A detector device (22), comprising: a plurality of transmitters (26); and a controller (30) that controls the transmitters (26) to transmit respective signals defined at least in part by a sequence of 2N pulses within a period, wherein: N is an integer greater than 1, a first one of the transmitters (26) transmits 2N first signal pulses within the period, each of the 2N first signal pulses have a first phase, a second one of the transmitters (26) transmits 2N second signal pulses within the period, each of the 2N first signal pulses is simultaneous with one of the 2N second signal pulses, N second signal pulses have a phase shift of 180° relative to the first phase, others of the second signal pulses have the first phase, and the N second signal pulses having the phase shift are immediately adjacent each other in the sequence.', '2. The detector device (22) of claim 1, comprising a binary phase shifter (40) that introduces the phase shift of the N second signal pulses having the phase shift.', '4. The detector device (22) of any of claims 1 - 3, comprising a plurality of receivers (28) and wherein the receivers (28) receive reflected signals that comprise the respective signals reflected by an object within a vicinity of the detector device (22); the reflected signals include a first portion corresponding to the 2N first signal pulses and a second portion corresponding to the 2N second signal pulses; the first portion has a single peak with a first magnitude at a first frequency; the second portion has two peaks separated by a second frequency; and the controller (30) discriminates between the first portion and the second portion based on the second frequency.']",False,"['22', '26', '26', '28', '40', '40', '1800', '28', '26', '800', '46', '11', '30', '32', '48', '50', '38', '34', '2']" 612,EP_3598176_A1 (5).png,EP3598176A1,METHODS FOR GEOSPATIAL POSITIONING AND PORTABLE POSITIONING DEVICES THEREOF,['FIG9'],['FIG9 shows a schematic view of a portable positioning device in accordance with an embodiment'],"['With reference to FIG9, a positioning device in accordance with another embodiment is described.', 'FIG9 shows a portable positioning device 900 including a GNSS receiving unit 910 and a display unit 940. The portable positioning device 900 includes also a body 905 in which the processing unit (not shown) of the positioning device 900 may be arranged. Alternatively, the processing unit of the positioning device may be arranged in the same unit as the display unit, such as for example at the backside of the display unit 940. In the embodiment shown in FIG9, the body 905 is in the form of a cylinder which may be convenient to be handheld by an operator. However, other geometries and arrangements may be envisaged.', 'In some embodiments, the element denoted 940 in FIG9 may be a smartphone including a display unit 940, a processing unit and an imaging device (not shown in this view). In the present example, the positioning device 900 may include the body 905 and a holder, or holding element (not denoted), attached to the body 905 and adapted to receive a unit including an imaging device, a display unit and a processing unit, such as e.g. a smartphone.', 'FIG9 illustrates also embodiments of the present disclosure in which the portable positioning device may be implemented based on an existing device 940 already including a processing unit, an imaging device and, optionally, a display unit, to which a module including the GNSS receiving unit is added. Expressed differently, embodiments of the present disclosure include an add-on module only including a GNSS receiving unit with its antenna, in which the processing unit of the existing device is adapted to operate in accordance with a method as defined in any one of the preceding embodiments.']",15,333,schematic view,G,"[{'element_identifier': '900', 'terms': ['positioning device']}, {'element_identifier': '1060', 'terms': ['first portion']}, {'element_identifier': '1070', 'terms': ['second portion']}, {'element_identifier': '1030', 'terms': ['imaging device']}, {'element_identifier': '975', 'terms': ['stabilization device']}, {'element_identifier': '1080', 'terms': ['hinge']}, {'element_identifier': '940', 'terms': ['display unit']}, {'element_identifier': '905', 'terms': ['body']}, {'element_identifier': '1000', 'terms': ['positioning device']}, {'element_identifier': '910', 'terms': ['GNSS receiving unit']}]","['1. A Method (1100) for determining a geospatial position of a point of interest, said method comprising: collecting (1110), by a data collector (150) of a positioning device (100), data from a global navigation satellite system, GNSS, receiving unit (110) of said positioning device and data from at least one of an imaging device (130) and an inertial measurement unit, IMU (170), of said positioning device for a plurality of positions of said positioning device in the vicinity of said point of interest; transmitting (1120), to a data fusing processor (190), said collected data for determining orientations and positions of said positioning device for said plurality of positions of said positioning device in a global coordinate system (X 1 , Y 1 , Z 1 ); obtaining (1130), by said data collector, a pointing input indicative of a position of said point of interest relative to said positioning device for at least one reference position of said positioning device; and transmitting (1140) said pointing input to the data fusing processor for identifying said point of interest and for determining (1150) said geospatial position of said point of interest in said global coordinate system based on the determined orientations and positions of the positioning device in the global coordinate system.', '4. The method of any one of the preceding claims, wherein said collected data includes GNSS data received at the GNSS receiving unit and gyroscopic and acceleration data received at the IMU for said plurality of positions.', '17. The positioning device of any one of claims 12-15, further including a display unit adapted to assist in capturing said series of images, or said video, and/or in identifying said point of interest.']",True,"['910', '900', '975', '940', '905', '9', '1080', '1000', '1020', '1070', '1010', '1040', '1060', '1030', '1050', '10', '22']" 613,EP_3598229_A1 (1).png,EP3598229A1,LIGHT SOURCE APPARATUS AND PROJECTION SYSTEM,['FIG4'],['FIG4 is a schematic diagram showing a principle of an angle correction of a fly-eye lens pair'],"['FIG4 is a schematic diagram showing a principle of an angle correction of a fly-eye lens pair, and the fly-eye lens pair has a good function of correcting the optical path. When the beam 1 is incident along an optical axis parallel with the fly-eye lens pair, the direction of the main optical axis of the emitted light remains unchanged and is still parallel with the optical axis of the fly-eye lens pair. When the beam 2 is incident at an angle α relative to the optical axis of the fly-eye lens pair, the main optical axis of the beam 2 of the emitted light is at an angle β with the optical axis of the fly-eye lens pair, α>β. That is, the fly-eye lens pair has a function of reducing an inclination angle of the beam. For example, when α is about 1° and β is about 0.2°, a magnitude of the angle β of the emitted light can be adjusted by adjusting a magnitude of α, and an adjustment accuracy is higher than an accuracy in the case where β is adjusted directly, such that a distance between an edge of the beam of the first exciting light L1 incident to the collecting lens 205 and the central axis of the collecting lens 205 can be as small as possible. In the practical application of the present disclosure, the distance between the edge of the beam of the first exciting light L1 incident to the collecting lens 205 and the central axis of the collecting lens 205 can be controlled to be within a range of 0.2 to 0.5 mm, thereby greatly improving the imaging quality of the light spot on the surface of the wavelength conversion device 206 and providing basic conditions for a subsequent uniform light distribution on an exiting surface of the entire light source device.']",19,346,schematic diagram,G,"[{'element_identifier': '201', 'terms': ['first light source']}, {'element_identifier': '202', 'terms': ['fly-eye lens pair']}, {'element_identifier': '209', 'terms': []}, {'element_identifier': '1', 'terms': ['Embodiment']}, {'element_identifier': '206', 'terms': ['wavelength conversion device']}, {'element_identifier': '4', 'terms': ['Embodiment']}, {'element_identifier': '204', 'terms': ['first light splitting assembly']}, {'element_identifier': '205', 'terms': ['collecting lens']}, {'element_identifier': '212', 'terms': ['integrator rod']}, {'element_identifier': '207', 'terms': ['relay lens']}]","['1. A light source device, comprising a first light source, a fly-eye lens pair, a light guiding system, and a wavelength conversion device; wherein the first light source is configured to emit first exciting light which is homogenized by the fly-eye lens pair and then incident to the light guiding system; the light guiding system is configured to guide the first exciting light to the wavelength conversion device; the wavelength conversion device comprises a wavelength conversion section and a reflective section and periodically moves in such a manner that the wavelength conversion section and the reflective section are periodically located on an optical path of the first exciting light in different time divisions, wherein the wavelength conversion section absorbs the first exciting light and emits excited light, and the first exciting light is obliquely incident to a surface of the reflective section and is reflected to form second exciting light; the light guiding system is further configured to collect the excited light and the second exciting light, and to guide the excited light and the second exciting light to exit along an exiting light channel; the light guiding system comprises an optical path correcting assembly located on an optical path of the second exciting light and configured to reflect the second exciting light in such a manner that a main optical axis of the reflected second exciting light coincides with that of the excited light; and the fly-eye lens pair comprises a first lens array and a second lens array that are sequentially disposed along a direction of the first exciting light, wherein lens units constituting the first lens array are configured to perform imaging with overlap on a surface of the wavelength conversion device.', '3. The light source device according to claim 1, wherein the light guiding system further comprises a collecting lens for converging the first exciting light onto the wavelength conversion device and collecting the excited light and the second exciting light from the wavelength conversion device; and wherein a distance between an edge of a beam of the first exciting light incident to the collecting lens and a central axis of the collecting lens is in a range of 0.2 to 0.5 mm.']",False,"['212', '207', '206', '202', '201', '209', '204', '205', '1', '4', '17']" 614,EP_3598229_A1 (4).png,EP3598229A1,LIGHT SOURCE APPARATUS AND PROJECTION SYSTEM,['FIG10A'],['FIG10A is a structural schematic diagram of a light source device according to Embodiment 6 of the present disclosure'],"['Referring to FIG10A, FIG10A is a structural schematic diagram of a light source device according to Embodiment 6 of the present disclosure. The light source device includes a first light source 201, a fly-eye lens pair 202, a light guiding system, and a wavelength conversion device 206. The light guiding system includes a first light splitting assembly 204, a collecting lens 205, a relay lens 207, and an optical path correcting assembly 209.']",19,85,structural schematic diagram,G,"[{'element_identifier': '201', 'terms': ['first light source']}, {'element_identifier': '7', 'terms': ['Embodiment']}, {'element_identifier': '202', 'terms': ['fly-eye lens pair']}, {'element_identifier': '209', 'terms': []}, {'element_identifier': '206', 'terms': ['wavelength conversion device']}, {'element_identifier': '204', 'terms': ['first light splitting assembly']}, {'element_identifier': '205', 'terms': ['collecting lens']}, {'element_identifier': '212', 'terms': ['integrator rod']}, {'element_identifier': '207', 'terms': ['relay lens']}]","['1. A light source device, comprising a first light source, a fly-eye lens pair, a light guiding system, and a wavelength conversion device; wherein the first light source is configured to emit first exciting light which is homogenized by the fly-eye lens pair and then incident to the light guiding system; the light guiding system is configured to guide the first exciting light to the wavelength conversion device; the wavelength conversion device comprises a wavelength conversion section and a reflective section and periodically moves in such a manner that the wavelength conversion section and the reflective section are periodically located on an optical path of the first exciting light in different time divisions, wherein the wavelength conversion section absorbs the first exciting light and emits excited light, and the first exciting light is obliquely incident to a surface of the reflective section and is reflected to form second exciting light; the light guiding system is further configured to collect the excited light and the second exciting light, and to guide the excited light and the second exciting light to exit along an exiting light channel; the light guiding system comprises an optical path correcting assembly located on an optical path of the second exciting light and configured to reflect the second exciting light in such a manner that a main optical axis of the reflected second exciting light coincides with that of the excited light; and the fly-eye lens pair comprises a first lens array and a second lens array that are sequentially disposed along a direction of the first exciting light, wherein lens units constituting the first lens array are configured to perform imaging with overlap on a surface of the wavelength conversion device.', '3. The light source device according to claim 1, wherein the light guiding system further comprises a collecting lens for converging the first exciting light onto the wavelength conversion device and collecting the excited light and the second exciting light from the wavelength conversion device; and wherein a distance between an edge of a beam of the first exciting light incident to the collecting lens and a central axis of the collecting lens is in a range of 0.2 to 0.5 mm.']",False,"['212', '207', '206', '202', '201', '205', '204', '212', '207', '202', '209', '204', '7', '205', '206', '20']" 615,EP_3598229_A1 (6).png,EP3598229A1,LIGHT SOURCE APPARATUS AND PROJECTION SYSTEM,['FIG11'],['FIG11 is a structural schematic diagram of a light source device according to Embodiment 7 of the present disclosure '],"['Referring to FIG11, FIG11 is a structural schematic diagram of a light source device according to Embodiment 7 of the present disclosure. The light source device includes a first light source 201, a fly-eye lens pair 202, a light guiding system, and a wavelength conversion device 206. The light guiding system includes a first light splitting assembly 204, a collecting lens 205, a relay lens 207, and an optical path correcting assembly 209. Further, the light source device further includes a second light source 203, and a compensation light guiding assembly 213.']",19,107,structural schematic diagram,G,"[{'element_identifier': '201', 'terms': ['first light source']}, {'element_identifier': '202', 'terms': ['fly-eye lens pair']}, {'element_identifier': '203', 'terms': ['second light source']}, {'element_identifier': '209', 'terms': []}, {'element_identifier': '213', 'terms': ['compensation light guiding assembly']}, {'element_identifier': '206', 'terms': ['wavelength conversion device']}, {'element_identifier': '204', 'terms': ['first light splitting assembly']}, {'element_identifier': '205', 'terms': ['collecting lens']}, {'element_identifier': '212', 'terms': ['integrator rod']}, {'element_identifier': '207', 'terms': ['relay lens']}]","['1. A light source device, comprising a first light source, a fly-eye lens pair, a light guiding system, and a wavelength conversion device; wherein the first light source is configured to emit first exciting light which is homogenized by the fly-eye lens pair and then incident to the light guiding system; the light guiding system is configured to guide the first exciting light to the wavelength conversion device; the wavelength conversion device comprises a wavelength conversion section and a reflective section and periodically moves in such a manner that the wavelength conversion section and the reflective section are periodically located on an optical path of the first exciting light in different time divisions, wherein the wavelength conversion section absorbs the first exciting light and emits excited light, and the first exciting light is obliquely incident to a surface of the reflective section and is reflected to form second exciting light; the light guiding system is further configured to collect the excited light and the second exciting light, and to guide the excited light and the second exciting light to exit along an exiting light channel; the light guiding system comprises an optical path correcting assembly located on an optical path of the second exciting light and configured to reflect the second exciting light in such a manner that a main optical axis of the reflected second exciting light coincides with that of the excited light; and the fly-eye lens pair comprises a first lens array and a second lens array that are sequentially disposed along a direction of the first exciting light, wherein lens units constituting the first lens array are configured to perform imaging with overlap on a surface of the wavelength conversion device.', '3. The light source device according to claim 1, wherein the light guiding system further comprises a collecting lens for converging the first exciting light onto the wavelength conversion device and collecting the excited light and the second exciting light from the wavelength conversion device; and wherein a distance between an edge of a beam of the first exciting light incident to the collecting lens and a central axis of the collecting lens is in a range of 0.2 to 0.5 mm.', '9. The light source device according to claim 1, further comprising a second light source for emitting compensation light and a compensation light guiding assembly disposed on an exiting optical path of the excited light, wherein wavelength range of the compensation light overlaps with that of the excited light, and the compensation light and the excited light are combined by the compensation light guiding assembly.']",False,"['213', '212', '203', '207', '206', '202', '201', '209', '204', '11', '205', '22']" 616,EP_3598230_A1 (1).png,EP3598230A1,LIGHT SOURCE DEVICE AND PROJECTION SYSTEM,"['FIG2', ' FIG3']","['FIG2 is a structural schematic diagram of a light source device according to Embodiment 1 of the present disclosure ', 'FIG3 is a structural schematic diagram of a light source device according to Embodiment 2 of the present disclosure']","['Referring to FIG2, FIG2 is a structural schematic diagram of a light source device according to Embodiment 1 of the present disclosure. The light source device includes a first light source 201, a light guiding system, and a wavelength conversion device 206. The light guiding system includes a first light splitting assembly 204, a collecting lens 205, a relay lens 207, and an optical path correcting assembly 209. In addition, the light source device further includes a light homogenizing device 202, a filter wheel 211, and an integrator rod 212. ', 'Referring to FIG3, FIG3 is a structural schematic diagram of a light source device according to Embodiment 2 of the present disclosure. The light source device includes a first light source 201, a light guiding system, and a wavelength conversion device 206. The light guiding system includes a first light splitting assembly 204a, a collecting lens 205, a relay lens 207 and an optical path correcting assembly 209. Further, the light source device further includes a second light source 203, a light homogenizing device 202, a filter wheel 211, and an integrator rod 212.']",38,210,structural schematic diagram,G,"[{'element_identifier': '201', 'terms': ['first light source']}, {'element_identifier': '211', 'terms': ['filter wheel']}, {'element_identifier': '202', 'terms': ['light homogenizing device']}, {'element_identifier': '203', 'terms': ['second light source']}, {'element_identifier': '209', 'terms': []}, {'element_identifier': '206', 'terms': ['wavelength conversion device']}, {'element_identifier': '204', 'terms': ['first light splitting assembly']}, {'element_identifier': '2', 'terms': ['Embodiment']}, {'element_identifier': '205', 'terms': ['collecting lens']}, {'element_identifier': '212', 'terms': ['integrator rod']}, {'element_identifier': '207', 'terms': ['relay lens']}]","['1. A light source device, comprising a first light source, a light guiding system, and a wavelength conversion device; wherein the first light source is configured to emit first exciting light, and the first exciting light is incident to the light guiding system along an incidence light channel; the light guiding system is configured to guide the first exciting light to the wavelength conversion device; the wavelength conversion device comprises a wavelength conversion section and a reflective section, and periodically moves in such a manner that the wavelength conversion section and the reflective section are periodically located on an optical path of the first exciting light in time division, wherein the wavelength conversion section absorbs the first exciting light and emits excited light, and the first exciting light is obliquely incident to a surface of the reflective section and is reflected to form second exciting light; and the light guiding system is further configured to collect the excited light and the second exciting light and guide the excited light and the second exciting light to exit along an exiting light channel; wherein the light guiding system comprises an optical path correcting assembly, which is located on an optical path of the second exciting light and configured to reflect the second exciting light in such a manner that a main optical axis of the reflected second exciting light coincides with a main optical axis of the excited light and further to change a beam angular distribution of the second exciting light in such a manner that imaging positions of the second exciting light and the excited light coincide in a direction of beam propagation.', '9. The light source device according to any one of claims 4, 5, 7 or 8, wherein the light source device further comprises a second light source configured to emit compensation light when the wavelength conversion section is located on the optical path of the first exciting light, wherein a wavelength range of the compensation light overlaps with that of the excited light, and wherein the first light splitting assembly comprises a compensation light guiding region for guiding the compensation light to the wavelength conversion device.']",True,"['212', '211', '202', '201', '207', '206', '209', '204', '2', '212', '211', '202', '201', '205', '207', '206', '203', '209', '205', '21']" 617,EP_3598230_A1 (2).png,EP3598230A1,LIGHT SOURCE DEVICE AND PROJECTION SYSTEM,"['FIG4', ' FIG4A']","['FIG4A is a structural schematic diagram of a wavelength conversion device in FIG4 ', 'FIG4 is a structural schematic diagram of a light source device according to an Embodiment 3 of the present disclosure']","['As shown in FIG4A, the wavelength conversion device 206 includes a fan-ring-shaped reflective section 2061, a red wavelength conversion section 2062, and a green wavelength conversion section 2063. The filter wheel 211 includes a fan-ring-shaped scattering-transmitting section 2111, a red color-retouching transmitting section 2112, and a green color-retouching transmitting section 2113. A fan-ring angle of the reflective section 2061 is the same as a fan-ring angle of the scattering-transmitting section 2111. A fan-ring angle of the red wavelength conversion section 2062 is the same as a fan-ring angle of the red color-retouching transmitting section 2112. A fan-ring angle of the green wavelength conversion section 2063 is the same as a fan-ring angle of the green color-retouching transmitting section 2113. In this embodiment, the reflective region 2061 is disposed at 180° opposite to the scattering-transmitting region 2111, and this technical solution makes the reflective region 2061 be farthest from the scattering-transmitting region 2111, so that there is sufficient space to arrange optical elements of an intermediate optical path. Without doubt, in other embodiments, the reflective region and the scattering-transmitting region may be disposed at an arbitrary angle of 0 to 180°, which is not limited in the present disclosure. ', 'Referring to FIG4, FIG4 is a structural schematic diagram of a light source device according to Embodiment 3 of the present disclosure. The light source device includes a first light source 201, a light guiding system, and a wavelength conversion device 206. The light guiding system includes a first light splitting assembly 204a, a collecting lens 205, a first relay lens 207, a reflective sheet 208, an optical path correcting assembly 209, and a second relay lens 210. Further, the light source device further includes a second light source 203, a light homogenizing device 202, a filter wheel 211, and an integrator rod 212.']",33,376,structural schematic diagram,G,"[{'element_identifier': '201', 'terms': ['first light source']}, {'element_identifier': '211', 'terms': ['filter wheel']}, {'element_identifier': '202', 'terms': ['light homogenizing device']}, {'element_identifier': '203', 'terms': ['second light source']}, {'element_identifier': '209', 'terms': []}, {'element_identifier': '210', 'terms': ['second relay lens']}, {'element_identifier': '2063', 'terms': []}, {'element_identifier': '2111', 'terms': []}, {'element_identifier': '2112', 'terms': ['red color-retouching transmitting section']}, {'element_identifier': '208', 'terms': ['reflective sheet', 'reflective element']}, {'element_identifier': '206', 'terms': ['wavelength conversion device']}, {'element_identifier': '4', 'terms': ['Embodiment']}, {'element_identifier': '2113', 'terms': []}, {'element_identifier': '2061', 'terms': ['reflective section', 'reflective region']}, {'element_identifier': '205', 'terms': ['collecting lens']}, {'element_identifier': '212', 'terms': ['integrator rod']}, {'element_identifier': '207', 'terms': ['relay lens']}, {'element_identifier': '2062', 'terms': ['red wavelength conversion section']}]","['1. A light source device, comprising a first light source, a light guiding system, and a wavelength conversion device; wherein the first light source is configured to emit first exciting light, and the first exciting light is incident to the light guiding system along an incidence light channel; the light guiding system is configured to guide the first exciting light to the wavelength conversion device; the wavelength conversion device comprises a wavelength conversion section and a reflective section, and periodically moves in such a manner that the wavelength conversion section and the reflective section are periodically located on an optical path of the first exciting light in time division, wherein the wavelength conversion section absorbs the first exciting light and emits excited light, and the first exciting light is obliquely incident to a surface of the reflective section and is reflected to form second exciting light; and the light guiding system is further configured to collect the excited light and the second exciting light and guide the excited light and the second exciting light to exit along an exiting light channel; wherein the light guiding system comprises an optical path correcting assembly, which is located on an optical path of the second exciting light and configured to reflect the second exciting light in such a manner that a main optical axis of the reflected second exciting light coincides with a main optical axis of the excited light and further to change a beam angular distribution of the second exciting light in such a manner that imaging positions of the second exciting light and the excited light coincide in a direction of beam propagation.', '9. The light source device according to any one of claims 4, 5, 7 or 8, wherein the light source device further comprises a second light source configured to emit compensation light when the wavelength conversion section is located on the optical path of the first exciting light, wherein a wavelength range of the compensation light overlaps with that of the excited light, and wherein the first light splitting assembly comprises a compensation light guiding region for guiding the compensation light to the wavelength conversion device.']",True,"['210', '208', '207', '202', '211', '212', '201', '206', '203', '209', '4', '2061', '205', '2112', '2113', '2062', '2111', '2063', '22']" 618,EP_3598230_A1 (3).png,EP3598230A1,LIGHT SOURCE DEVICE AND PROJECTION SYSTEM,['FIG5'],['FIG5 is a structural schematic diagram of a light source device according to Embodiment 4 of the present disclosure'],"['Referring to FIG5, FIG5 is a structural schematic diagram of a light source device according to Embodiment 4 of the present disclosure. The light source device includes a first light source 201, a light guiding system, and a wavelength conversion device 206. The light guiding system includes a first light splitting assembly 204b, a collecting lens 205, a first relay lens 207, a second light splitting assembly 208a, an optical path correcting assembly 209, and a second relay lens 210. Further, the light source device further includes a second light source 203, a light homogenizing device 202, a filter wheel 211, and an integrator rod 212.']",19,122,structural schematic diagram,G,"[{'element_identifier': '8', 'terms': ['Embodiment']}, {'element_identifier': '201', 'terms': ['first light source']}, {'element_identifier': '211', 'terms': ['filter wheel']}, {'element_identifier': '202', 'terms': ['light homogenizing device']}, {'element_identifier': '203', 'terms': ['second light source']}, {'element_identifier': '209', 'terms': []}, {'element_identifier': '210', 'terms': ['second relay lens']}, {'element_identifier': '206', 'terms': ['wavelength conversion device']}, {'element_identifier': '205', 'terms': ['collecting lens']}, {'element_identifier': '212', 'terms': ['integrator rod']}, {'element_identifier': '207', 'terms': ['relay lens']}]","['1. A light source device, comprising a first light source, a light guiding system, and a wavelength conversion device; wherein the first light source is configured to emit first exciting light, and the first exciting light is incident to the light guiding system along an incidence light channel; the light guiding system is configured to guide the first exciting light to the wavelength conversion device; the wavelength conversion device comprises a wavelength conversion section and a reflective section, and periodically moves in such a manner that the wavelength conversion section and the reflective section are periodically located on an optical path of the first exciting light in time division, wherein the wavelength conversion section absorbs the first exciting light and emits excited light, and the first exciting light is obliquely incident to a surface of the reflective section and is reflected to form second exciting light; and the light guiding system is further configured to collect the excited light and the second exciting light and guide the excited light and the second exciting light to exit along an exiting light channel; wherein the light guiding system comprises an optical path correcting assembly, which is located on an optical path of the second exciting light and configured to reflect the second exciting light in such a manner that a main optical axis of the reflected second exciting light coincides with a main optical axis of the excited light and further to change a beam angular distribution of the second exciting light in such a manner that imaging positions of the second exciting light and the excited light coincide in a direction of beam propagation.', '9. The light source device according to any one of claims 4, 5, 7 or 8, wherein the light source device further comprises a second light source configured to emit compensation light when the wavelength conversion section is located on the optical path of the first exciting light, wherein a wavelength range of the compensation light overlaps with that of the excited light, and wherein the first light splitting assembly comprises a compensation light guiding region for guiding the compensation light to the wavelength conversion device.']",True,"['210', '209', '207', '203', '211', '212', '206', '201', '202', '205', '8', '23']" 619,EP_3598230_A1 (4).png,EP3598230A1,LIGHT SOURCE DEVICE AND PROJECTION SYSTEM,"['FIG6', ' FIG7']","['FIG6 is a structural schematic diagram of a light source device according to Embodiment 5 of the present disclosure ', 'FIG7 is a structural schematic diagram of a light source device according to Embodiment 6 of the present disclosure']","['Referring to FIG6, FIG6 is a structural schematic diagram of a light source device according to Embodiment 5 of the present disclosure. The light source device includes a first light source 201, a light guiding system, and a wavelength conversion device 206. The light guiding system includes a first light splitting assembly 204, a collecting lens 205, a relay lens 207 and an optical path correcting assembly 209a. In addition, the light source device further includes a light homogenizing device 202, a filter wheel 211, and an integrator rod 212. ', 'Referring to FIG7, FIG7 is a structural schematic diagram of a light source device according to Embodiment 6 of the present disclosure. The light source device includes a first light source 201, a light guiding system, and a wavelength conversion device 206. The light guiding system includes a first light splitting assembly 204a, a collecting lens 205, a first relay lens 207, a reflective sheet 208, an optical path correcting assembly 209a, and a second relay lens 210. Further, the light source device further includes a second light source 203, a light homogenizing device 202, a filter wheel 211, and an integrator rod 212.']",38,222,structural schematic diagram,G,"[{'element_identifier': '201', 'terms': ['first light source']}, {'element_identifier': '7', 'terms': ['Embodiment']}, {'element_identifier': '202', 'terms': ['light homogenizing device']}, {'element_identifier': '211', 'terms': ['filter wheel']}, {'element_identifier': '203', 'terms': ['second light source']}, {'element_identifier': '210', 'terms': ['second relay lens']}, {'element_identifier': '208', 'terms': ['reflective sheet', 'reflective element']}, {'element_identifier': '206', 'terms': ['wavelength conversion device']}, {'element_identifier': '204', 'terms': ['first light splitting assembly']}, {'element_identifier': '6', 'terms': ['Embodiment']}, {'element_identifier': '205', 'terms': ['collecting lens']}, {'element_identifier': '212', 'terms': ['integrator rod']}, {'element_identifier': '207', 'terms': ['relay lens']}]","['1. A light source device, comprising a first light source, a light guiding system, and a wavelength conversion device; wherein the first light source is configured to emit first exciting light, and the first exciting light is incident to the light guiding system along an incidence light channel; the light guiding system is configured to guide the first exciting light to the wavelength conversion device; the wavelength conversion device comprises a wavelength conversion section and a reflective section, and periodically moves in such a manner that the wavelength conversion section and the reflective section are periodically located on an optical path of the first exciting light in time division, wherein the wavelength conversion section absorbs the first exciting light and emits excited light, and the first exciting light is obliquely incident to a surface of the reflective section and is reflected to form second exciting light; and the light guiding system is further configured to collect the excited light and the second exciting light and guide the excited light and the second exciting light to exit along an exiting light channel; wherein the light guiding system comprises an optical path correcting assembly, which is located on an optical path of the second exciting light and configured to reflect the second exciting light in such a manner that a main optical axis of the reflected second exciting light coincides with a main optical axis of the excited light and further to change a beam angular distribution of the second exciting light in such a manner that imaging positions of the second exciting light and the excited light coincide in a direction of beam propagation.', '9. The light source device according to any one of claims 4, 5, 7 or 8, wherein the light source device further comprises a second light source configured to emit compensation light when the wavelength conversion section is located on the optical path of the first exciting light, wherein a wavelength range of the compensation light overlaps with that of the excited light, and wherein the first light splitting assembly comprises a compensation light guiding region for guiding the compensation light to the wavelength conversion device.']",True,"['212', '211', '207', '206', '201', '202', '204', '6', '210', '208', '207', '203', '205', '211', '212', '206', '201', '202', '205', '7', '24']" 620,EP_3598230_A1 (5).png,EP3598230A1,LIGHT SOURCE DEVICE AND PROJECTION SYSTEM,['FIG6'],['FIG6 is a structural schematic diagram of a light source device according to Embodiment 5 of the present disclosure'],"['Referring to FIG6, FIG6 is a structural schematic diagram of a light source device according to Embodiment 5 of the present disclosure. The light source device includes a first light source 201, a light guiding system, and a wavelength conversion device 206. The light guiding system includes a first light splitting assembly 204, a collecting lens 205, a relay lens 207 and an optical path correcting assembly 209a. In addition, the light source device further includes a light homogenizing device 202, a filter wheel 211, and an integrator rod 212.']",19,102,structural schematic diagram,G,"[{'element_identifier': '201', 'terms': ['first light source']}, {'element_identifier': '211', 'terms': ['filter wheel']}, {'element_identifier': '202', 'terms': ['light homogenizing device']}, {'element_identifier': '203', 'terms': ['second light source']}, {'element_identifier': '210', 'terms': ['second relay lens']}, {'element_identifier': '206', 'terms': ['wavelength conversion device']}, {'element_identifier': '6', 'terms': ['Embodiment']}, {'element_identifier': '205', 'terms': ['collecting lens']}, {'element_identifier': '212', 'terms': ['integrator rod']}, {'element_identifier': '207', 'terms': ['relay lens']}]","['1. A light source device, comprising a first light source, a light guiding system, and a wavelength conversion device; wherein the first light source is configured to emit first exciting light, and the first exciting light is incident to the light guiding system along an incidence light channel; the light guiding system is configured to guide the first exciting light to the wavelength conversion device; the wavelength conversion device comprises a wavelength conversion section and a reflective section, and periodically moves in such a manner that the wavelength conversion section and the reflective section are periodically located on an optical path of the first exciting light in time division, wherein the wavelength conversion section absorbs the first exciting light and emits excited light, and the first exciting light is obliquely incident to a surface of the reflective section and is reflected to form second exciting light; and the light guiding system is further configured to collect the excited light and the second exciting light and guide the excited light and the second exciting light to exit along an exiting light channel; wherein the light guiding system comprises an optical path correcting assembly, which is located on an optical path of the second exciting light and configured to reflect the second exciting light in such a manner that a main optical axis of the reflected second exciting light coincides with a main optical axis of the excited light and further to change a beam angular distribution of the second exciting light in such a manner that imaging positions of the second exciting light and the excited light coincide in a direction of beam propagation.', '9. The light source device according to any one of claims 4, 5, 7 or 8, wherein the light source device further comprises a second light source configured to emit compensation light when the wavelength conversion section is located on the optical path of the first exciting light, wherein a wavelength range of the compensation light overlaps with that of the excited light, and wherein the first light splitting assembly comprises a compensation light guiding region for guiding the compensation light to the wavelength conversion device.']",True,"['210', '207', '202', '201', '211', '212', '206', '203', '205', '00', '212', '211', '207', '202', '201', '203', '205', '206', '6', '25']" 621,EP_3598230_A1 (6).png,EP3598230A1,LIGHT SOURCE DEVICE AND PROJECTION SYSTEM,"['FIG10', ' FIG9A']","['FIG9A is a structural schematic diagram of a first light splitting assembly in FIG9 ', 'FIG10 is a structural schematic diagram of a light source device according to Embodiment 9 of the present disclosure']","['As shown in FIG9A, in the present embodiment, the first light splitting assembly 204c includes a first region 204c1, a second region 204c2, a compensation light guiding region 204c3, and a fourth region 204c4. The first region 204cl reflects the first exciting light and transmits the excited light and the compensation light. The second region 204c2 reflects the second exciting light and transmits the excited light and the compensation light. The compensation light guiding region 204c3 reflects the compensation light and transmits the second exciting light and at least part of the excited light. The fourth region 204c4 transmits the excited light and the compensation light. ', 'Referring to FIG10, FIG10 is a structural schematic diagram of a light source device according to Embodiment 9 of the present disclosure. The light source device includes a first light source 201, a light guiding system, and a wavelength conversion device 206. The light guiding system includes a first light splitting assembly 204a, a collecting lens 205, a first relay lens 207, a reflective sheet 208, an optical path correcting assembly 209, and a second relay lens 210. Further, the light source device further includes a second light source 203, a light homogenizing device 202, a filter wheel 211, and an integrator rod 212.']",33,236,structural schematic diagram,G,"[{'element_identifier': '201', 'terms': ['first light source']}, {'element_identifier': '211', 'terms': ['filter wheel']}, {'element_identifier': '202', 'terms': ['light homogenizing device']}, {'element_identifier': '203', 'terms': ['second light source']}, {'element_identifier': '209', 'terms': []}, {'element_identifier': '210', 'terms': ['second relay lens']}, {'element_identifier': '208', 'terms': ['reflective sheet', 'reflective element']}, {'element_identifier': '206', 'terms': ['wavelength conversion device']}, {'element_identifier': '10', 'terms': ['Embodiment']}, {'element_identifier': '205', 'terms': ['collecting lens']}, {'element_identifier': '212', 'terms': ['integrator rod']}, {'element_identifier': '207', 'terms': ['relay lens']}]","['1. A light source device, comprising a first light source, a light guiding system, and a wavelength conversion device; wherein the first light source is configured to emit first exciting light, and the first exciting light is incident to the light guiding system along an incidence light channel; the light guiding system is configured to guide the first exciting light to the wavelength conversion device; the wavelength conversion device comprises a wavelength conversion section and a reflective section, and periodically moves in such a manner that the wavelength conversion section and the reflective section are periodically located on an optical path of the first exciting light in time division, wherein the wavelength conversion section absorbs the first exciting light and emits excited light, and the first exciting light is obliquely incident to a surface of the reflective section and is reflected to form second exciting light; and the light guiding system is further configured to collect the excited light and the second exciting light and guide the excited light and the second exciting light to exit along an exiting light channel; wherein the light guiding system comprises an optical path correcting assembly, which is located on an optical path of the second exciting light and configured to reflect the second exciting light in such a manner that a main optical axis of the reflected second exciting light coincides with a main optical axis of the excited light and further to change a beam angular distribution of the second exciting light in such a manner that imaging positions of the second exciting light and the excited light coincide in a direction of beam propagation.', '9. The light source device according to any one of claims 4, 5, 7 or 8, wherein the light source device further comprises a second light source configured to emit compensation light when the wavelength conversion section is located on the optical path of the first exciting light, wherein a wavelength range of the compensation light overlaps with that of the excited light, and wherein the first light splitting assembly comprises a compensation light guiding region for guiding the compensation light to the wavelength conversion device.']",True,"['210', '208', '207', '202', '201', '211', '212', '206', '203', '209', '10', '205', '26']" 622,EP_3598239_A1 (1).png,EP3598239A1,IMAGE FORMING APPARATUS,['FIG2'],['FIG2 is a diagram illustrating a specific example of a hardware configuration of the image forming apparatus according to the embodiment'],"['FIG2 is a diagram illustrating a specific example of a hardware configuration of the image forming apparatus 100 according to the embodiment. The image forming apparatus 100 includes a processor 11, a memory 12 and an auxiliary storage device 13 connected by a bus line 90. The processor 11 executes programs stored in the memory 12 and the auxiliary storage device 13 to function as a control section 1 that controls each component of the image forming apparatus 100. Specifically, the control section 1 controls the control panel 120, the display 110, the printer 130 and a fixing section 150. Furthermore, all or part of each function of the image forming apparatus 100 may be realized using hardware such as an ASIC (Application Specific Integrated Circuit), a PLD (Programmable Logic Device), and a FPGA (Field Programmable Gate Array). The program may be recorded on a computer-readable recording medium. The computer-readable recording medium is, for example, a storage device such as a flexible disk, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, a hard disk built in a computer system. The program may be transmitted via an electric communication line.']",21,228,diagram,G,"[{'element_identifier': '130', 'terms': ['printer']}, {'element_identifier': '100', 'terms': ['apparatus']}, {'element_identifier': '110', 'terms': ['display']}, {'element_identifier': '120', 'terms': ['control panel']}, {'element_identifier': '13', 'terms': ['auxiliary storage device']}]","['1. An image forming apparatus, comprising: an image forming section configured to form an image on a sheet; a fixing section configured to heat the sheet having the image formed thereon to a fixing temperature; and a control section configured to adjust parameters of the image forming section to reduce deterioration in image quality of the image formed by the image forming section and to carry out the adjustment while a temperature of the fixing section is being changed by greater than a predetermined amount and to not carry out the adjustment while the temperature of the fixing section is changed by less than a predetermined amount.']",False,"['100', '110', '120', '130', '13', '13']" 623,EP_3598239_A1.png,EP3598239A1,IMAGE FORMING APPARATUS,['FIG1'],['FIG1 is a schematic external view illustrating an image forming apparatus according to an embodiment'],"['FIG1 is a schematic external view illustrating a specific example of an image forming apparatus 100 according to the embodiment. The image forming apparatus 100 is, for example, an MFP (Multi-Function Peripheral) . The image forming apparatus 100 includes a display 110, a control panel 120, a printer 130, a sheet housing section 140 and an image reading section 200. Furthermore, the printer 130 of the image processing apparatus 100 may be a device for fixing a toner image.', 'The control panel 120 includes a plurality of buttons. The control panel 120 receives an operation input from a user. The control panel 120 outputs a signal corresponding to an operation input by the user to a control section of the image forming apparatus 100. In the example of FIG1, the display 110 and the control panel 120 are separately provided. However, both of the display 110 and the control panel 120 may be integrally provided as a touch panel display. For example, the control panel 120 acquires information (hereinafter, referred to as ""image formation instruction information"") instructing the image forming apparatus 100 to form an image. The image formation instruction information is input to the control panel 120 by a user.']",15,230,schematic external view,G,"[{'element_identifier': '12', 'terms': ['memory']}, {'element_identifier': '130', 'terms': ['printer']}, {'element_identifier': '1', 'terms': ['control section']}, {'element_identifier': '100', 'terms': ['apparatus']}, {'element_identifier': '140', 'terms': []}, {'element_identifier': '110', 'terms': ['display']}, {'element_identifier': '200', 'terms': ['image reading section']}, {'element_identifier': '120', 'terms': ['control panel']}]","['1. An image forming apparatus, comprising: an image forming section configured to form an image on a sheet; a fixing section configured to heat the sheet having the image formed thereon to a fixing temperature; and a control section configured to adjust parameters of the image forming section to reduce deterioration in image quality of the image formed by the image forming section and to carry out the adjustment while a temperature of the fixing section is being changed by greater than a predetermined amount and to not carry out the adjustment while the temperature of the fixing section is changed by less than a predetermined amount.']",False,"['1', '100', '200', '110', '120', '130', '140', '12']" 624,EP_3598247_A1 (2).png,EP3598247A1,NETWORK TIMING METHOD AND DEVICE,"['FIG3', ' FIG4']","['FIG4 is a schematic diagram of a linear fitting curve according to an embodiment of the present application ', 'FIG3 is a schematic diagram of a process of recording historical time correction data each time according to an embodiment of the present application']","['Assuming that the recorded historical time correction data includes the time correction data of 32 historical time-correction time points, wherein the time-correction difference value of each of historical time-correction time points is 2.1 seconds; the historical time-correction time points are set to orders of historical time corrections determined in chronological order of the historical time corrections, and the average time-correction time point of the historical time-correction time points is an average value of the orders of all the historical time corrections. The average time-correction time point of all the historical time-correction time points is: x‾=∑i=132i3216.5,the average total time-correction difference value of all the historical time-correction time points is: y‾=2.1×∑i=132i32=34.65. By calculation, the first parameter b=2.1 and the second parameter a=0 can be obtained, and thus the linear fitting equation y=2.1x can be obtained. The linear fitting curve as shown in FIG4 can be obtained. The abscissa of the curve shown in FIG4 is the orders of historical time-correction time points, and the ordinate of the curve is a total historical time-correction difference value corresponding to each of the historical time-correction time points. ', 'FIG3 shows a process of recording each piece of historical time correction data according to the embodiment. A to-be-time-corrected network device 101 sends a time correction request to a time correction server 102 and records time T1 when the time correction request is sent. The time correction server 102 receives the time correction request, and records time T2 when the time correction request is received. The time correction server 102 analyses the time correction request, sends the time correction data to the to-be-time-corrected network device 101, and records time T3 when the time correction data is sent. The to-be-time-corrected network device 101 receives the time correction data and records the time T4 when the time correction data is received. The time correction data between the to-be-time-corrected network device 101 and the time correction server satisfies the following formula (7): {T2=T1+θ+δ1T4=T3−θ+δ2δ=δ1+δ2 where T2 is the time when the time correction server 102 receives the time correction request sent by the to-be-time-corrected network device 101; T1 is the time when the to-be-time-corrected network device 101 sends the time correction request; θ is the time-correction difference value of the to-be-time-corrected network device 101 with respect to the time correction server 102 at time T1; δ1 is the time consumed by the transmission of the time correction request over the network; T4 is the time when the time correction server 102 sends the time correction data; T3 is the time when the to-be-time-corrected network device 101 receives the time correction data sent by the time correction server 102; δ2 is the time consumed by the transmission of the time correction data over the network; δ is a round-trip transmission delay between the to-be-time-corrected network device 101 and the time correction server 102. The time correction data includes the time-correction difference value of the to-be-time-corrected network device 101 with respect to the time correction server 102 at time T1.']",42,627,schematic diagram,G,"[{'element_identifier': '8', 'terms': ['formula']}, {'element_identifier': '30', 'terms': ['correction is performed every']}, {'element_identifier': '4', 'terms': ['formula']}, {'element_identifier': '2', 'terms': ['formula', 'time-correction time points is', 'current moment plus']}, {'element_identifier': '3', 'terms': ['formula']}]","['7. The method of claim 1, wherein, obtaining a total current time-correction difference value for the current moment by a preset algorithm, according to the total historical time-correction difference value corresponding to each of the historical time-correction time points, comprises: determining an average time-correction time point of all the historical time-correction time points; determining an average total time-correction difference value for all the historical time-correction time points, according to the total historical time-correction difference value corresponding to each of the historical time-correction time points; obtaining a first parameter by a first calculation formula, according to each of the historical time-correction time points, the total historical time-correction difference value corresponding to each of the historical time-correction time points, the average time-correction time point and the average total time-correction difference value, wherein the first calculation formula is: b = ∑ i = 1 n x i y i − n xy ‾ ∑ i = 1 n x i 2 − n x ‾ 2 , where, b is the first parameter, x i is the i -th historical time-correction time point, y i is a time-correction difference value for the i -th historical time-correction time point, n is the total number of the historical time-correction time points, x is the average time-correction time point, y is the average total time-correction difference value; obtaining a second parameter by a second calculation formula, according to the average time-correction time point, the average total time-correction difference value and the first parameter, wherein the second calculation formula is: a = y ‾ − b x ‾ , where, a is the second parameter, y is the average total time-correction difference value, b is the first parameter, x is the average time-correction time point; obtaining a total current time-correction difference value y for the current moment by substituting the first parameter and the second parameter into the following linear fitting equation: y = bx + a wherein, y is the total current time-correction difference value for the current moment, b is the first parameter, x is the time-correction time point of the current moment, and a is the second parameter.']",True,"['8', '8', '2', '3', '20', '30', '40', '50', '60', '70', '80', '4', '28']" 625,EP_3598269_A1 (6).png,EP3598269A1,COMPUTER POWER SAVING METHOD AND COMPUTER WAKING METHOD,['FIG5'],['FIG5 is a hardware architecture diagram of a computer with a power saving function according to another embodiment of the present disclosure '],"['The computer power saving methods according to the first to third embodiments may also be performed with another computer having different hardware architecture. FIG5 is a hardware architecture diagram of a computer with a power saving function according to another embodiment of the present disclosure. A difference between a hardware architecture of a computer 300 and the hardware architecture of the computer 100 is that the Bluetooth signal transceiver 40 is embedded in the motherboard 10 and is electrically connected with the Bluetooth signal receiving port 16. The computer power saving methods according to the first to third embodiments can be performed with the computer 300, and the operation and principle thereof are the same as described above.']",22,123,diagram,G,"[{'element_identifier': '17', 'terms': ['monitor port']}, {'element_identifier': '30', 'terms': ['hard disk']}, {'element_identifier': '12', 'terms': ['power management controller']}, {'element_identifier': '14', 'terms': ['random access memory']}, {'element_identifier': '20', 'terms': ['power supply']}, {'element_identifier': '40', 'terms': ['transceiver']}, {'element_identifier': '16', 'terms': ['Bluetooth signal receiving port']}, {'element_identifier': '300', 'terms': ['computer']}, {'element_identifier': '50', 'terms': ['monitor']}, {'element_identifier': '15', 'terms': ['hard disk port']}, {'element_identifier': '200', 'terms': ['mobile device']}, {'element_identifier': '13', 'terms': ['processor']}]","['1. A computer waking method, applied to a computer(100,300) having a Bluetooth signal receiving port(16), with the computer waking method comprising: determining whether the computer(100,3 00) receives a trigger instruction when a processor(13) of the computer(100,300) stops working and the computer(100,300) is in a power saving mode; determining whether an intensity of a communication signal(CS) related to a registered mobile device obtained by the Bluetooth signal receiving port(16) falls within a working intensity range; and enabling the processor(13) to make the computer(100,300) operate in a working mode when the computer(100,300) receives the trigger instruction and the intensity of the communication signal(CS) falls within a working intensity range.', '5. The method in claim 1, wherein the Bluetooth signal receiving port(16) is a USB port, and the USB port is configured to connect with a Bluetooth signal transceiver(40).', '15. The method in claim 8, further comprising turning off a monitor(50) electrically connected with the computer(100,300) after disabling the processor(13) to make the computer(100,300) operate in the power saving mode; and further comprising turning on the monitor(50) electrically connected with the computer(100,300) after enabling the processor(13) to make the computer(100,300) operate in the working mode.']",False,"['300', '20', '15', '30', '12', '15', '200', '40', '16', '13', '14', '17', '50']" 626,EP_3598287_A1 (1).png,EP3598287A1,HYBRIDIZATION OF VOICE NOTES AND CALLING,['FIG2'],"['FIG2 is a diagram illustrating a communication hybridization system, according to some example embodiments']","['In FIG2, in various embodiments, the communication hybridization system 160 can be implemented as a standalone system and is not necessarily included in the social messaging system 130. The communication hybridization system 160 is shown to include a communication module 210, a presentation module 220, a sensor module 230, a determination module 240, a management module 250, and a data module 260. All, or some, of the modules 210-260, communicate with each other, for example, via a network coupling, shared memory, and the like. Each module of modules 210-260 can be implemented as a single module, combined into other modules, or further subdivided into multiple modules. Other modules not pertinent to example embodiments can also be included, but are not shown.']",15,147,diagram,G,"[{'element_identifier': '210', 'terms': ['module']}, {'element_identifier': '230', 'terms': ['sensor module']}, {'element_identifier': '160', 'terms': ['hybridization system']}, {'element_identifier': '220', 'terms': ['presentation module']}, {'element_identifier': '2', 'terms': ['Example']}, {'element_identifier': '250', 'terms': ['management module']}, {'element_identifier': '240', 'terms': ['determination module']}, {'element_identifier': '260', 'terms': ['data module']}]","['1. A communication hybridization system (160) comprising a memory (1730) that stores instructions (1716) and one or more processors (1710) configured by the instructions to perform operations for causing transitions, the system basing said transitions on user actions such that a user action on one client device of one party can cause a change in communication mode of another client device of another party to the communication.']",False,"['160', '160', '210', '240', '220', '250', '260', '230', '2', '25']" 627,EP_3598287_A1 (2).png,EP3598287A1,HYBRIDIZATION OF VOICE NOTES AND CALLING,['FIG3'],"['FIG3 is a flow diagram illustrating an example method for hybridizing communications using gestures in association with a user interface, according to some example embodiments']","['FIG3 depicts a flow diagram illustrating an example method 300 for hybridizing communications using gestures in association with a user interface. The operations of method 300 may be performed by components of the communication hybridization system 160, and are so described below for purposes of illustration.']",26,49,flow diagram,G,"[{'element_identifier': '310', 'terms': ['operation']}, {'element_identifier': '4', 'terms': ['Example']}, {'element_identifier': '300', 'terms': ['method', 'methods']}, {'element_identifier': '320', 'terms': ['in operation']}, {'element_identifier': '340', 'terms': ['telephone call. In operation']}, {'element_identifier': '330', 'terms': ['client device. In operation', 'operations', 'operation']}]","['1. A communication hybridization system (160) comprising a memory (1730) that stores instructions (1716) and one or more processors (1710) configured by the instructions to perform operations for causing transitions, the system basing said transitions on user actions such that a user action on one client device of one party can cause a change in communication mode of another client device of another party to the communication.', '5. A method of hybridizing communications in a messaging system that provides synchronous and asynchronous modes of communication among parties who are users using respective client devices (110), the messaging system including one or more processors (1710) and a memory (1730) that stores instructions by which said processors are configured to implement the method, the method comprising: receiving a user action from the client device of one party; and based on the received user interaction, causing a change in communication mode of another client device of another party to the communication.']",False,"['300', '310', '320', '4', '330', '340', '3', '26']" 628,EP_3598296_A1.png,EP3598296A1,SMART BROADCAST DEVICE,['FIG2'],"['FIG2 is a schematic diagram illustrating scanning a payment graphic code on a smart broadcast device, according to an example implementation of the present specification']","['In the present implementation, to help a user scan the payment graphic code 1011, an included angle between the first surface 101 and a lower surface of the device body can be set to be less than 90 degrees. Referring to FIG2, because height of a common desktop usually ranges from 70 cm to 1 m, to adapt to posture of using an end-user device such as a mobile phone when the user stands, the included angle between the first surface 101 and the lower surface of the device body can be set from 20 degrees to 70 degrees to help the user scan the payment graphic code 1011, and the user does not need to excessively adjust the posture of holding the mobile phone. As such, user experience can be improved.']",26,144,schematic diagram,G,"[{'element_identifier': '103', 'terms': ['volume adjustment key']}, {'element_identifier': '100', 'terms': ['device body']}, {'element_identifier': '104', 'terms': ['LED status indicator']}, {'element_identifier': '1011', 'terms': ['payment graphic code']}, {'element_identifier': '102', 'terms': ['power key']}, {'element_identifier': '101', 'terms': ['first surface']}, {'element_identifier': '1071', 'terms': ['speaker holes']}, {'element_identifier': '10', 'terms': ['payment result parameter']}]","['1. A smart broadcast device, comprising: a device body, wherein the device body comprises a first surface that comprises a payment graphic code; a communication module, installed inside the device body and communicating with outside through a wireless link and/or a wired link; a processing module, installed inside the device body and electrically connected to the communication module; and a speaker, installed inside the device body and electrically connected to the processing module, wherein the processing module outputs payment result audio signal to the speaker when receiving an external trigger signal by using the communication module, to drive the speaker to output payment result audio.', '6. The smart broadcast device according to claim 1, wherein speaker holes of the speaker are distributed on the left and right sides of the payment graphic code on the first surface.', '8. The smart broadcast device according to claim 1, further comprising: an LED status indicator, installed on the device body and configured to output a corresponding light prompt based on a light drive signal output by the processing module.']",False,"['103', '102', '104', '101', '100', '1071', '1011', '1350', '450', '2', '10']" 629,EP_3598303_A1 (1).png,EP3598303A1,"METHOD FOR MULTI-PATH COPYING AND PASTING, AND MOBILE TERMINAL",['FIG4'],['FIG4 is a schematic view showing a mobile terminal according to a third embodiment of the present disclosure'],"['As shown in FIG4, the present disclosure provides in this embodiment a mobile terminal, which includes: a first detection module 401 configured to detect a selection operation made by a user on a to-be-copied content in a first file; a first output module 402 configured to output a first prompt box in accordance with the selection operation, a first option indicating the addition of the to-be-copied content into a pasting source list and a second option indicating the addition of the to-be-copied content into a target file in a pasting destination list being included in the first prompt box; a first reception module 403 configured to receive a first selection operation made by the user on at least one of the first option and the second option; and a first response module 404 configured to, in response to the first selection operation, add the to-be-copied content into the pasting source list as a to-be-pasted content, and/or paste the to-be-copied content to the selected target file.']",18,200,schematic view,G,"[{'element_identifier': '201', 'terms': ['Steps']}, {'element_identifier': '202', 'terms': ['Step']}, {'element_identifier': '403', 'terms': ['first reception module']}, {'element_identifier': '402', 'terms': ['first output module']}, {'element_identifier': '404', 'terms': ['first response module']}, {'element_identifier': '401', 'terms': ['first detection module']}]","['6. A mobile terminal, comprising: a first detection module configured to detect a selection operation made by a user on a to-be-copied content in a first file; a first output module configured to output a first prompt box in accordance with the selection operation, wherein the first prompt box comprises a first option indicating the addition of the to-be-copied content into a pasting source list and a second option indicating the addition of the to-be-copied content into a target file in a pasting destination list; a first reception module configured to receive a first selection operation made by the user on at least one of the first option and the second option; and a first response module configured to, in response to the first selection operation, add the to-be-copied content into the pasting source list as a to-be-pasted content, and/or paste the to-be-copied content to the selected target file.']",True,"['201', '4', '4', '4', '202', '203', '204', '401', '402', '403', '404', '4', '14']" 630,EP_3598303_A1 (2).png,EP3598303A1,"METHOD FOR MULTI-PATH COPYING AND PASTING, AND MOBILE TERMINAL",['FIG6'],['FIG6 is yet another schematic view showing the mobile terminal according to a fifth embodiment of the present disclosure'],"['As shown in FIG6, the present disclosure further provides in this embodiment a mobile terminal 700 which includes at least one processor 701, a memory 702, at least one network interface 704 and a user interface 703. The components of the mobile terminal 700 may be coupled together through a bus system 705. It should be appreciated that, the bus system 705 is configured to achieve connection and communication among the components. Apart from a data bus, the bus system 705 may further include a power source bus, a control bus and a state signal bus. For clarification, all these buses in FIG6 may be collectedly called as bus system 705.']",19,123,schematic view,G,"[{'element_identifier': '513', 'terms': ['third output module']}, {'element_identifier': '501', 'terms': ['first detection module']}, {'element_identifier': '512', 'terms': ['second previewing module']}, {'element_identifier': '503', 'terms': ['first reception module']}, {'element_identifier': '704', 'terms': []}, {'element_identifier': '7022', 'terms': ['application']}, {'element_identifier': '705', 'terms': ['bus system']}, {'element_identifier': '506', 'terms': ['second output module']}, {'element_identifier': '701', 'terms': ['processor']}, {'element_identifier': '509', 'terms': ['first previewing module']}, {'element_identifier': '514', 'terms': ['shortcut pasting module']}, {'element_identifier': '505', 'terms': ['second detection module']}, {'element_identifier': '511', 'terms': ['destination list extension module']}, {'element_identifier': '502', 'terms': ['first output module']}, {'element_identifier': '507', 'terms': ['second reception module']}, {'element_identifier': '508', 'terms': ['second response module']}, {'element_identifier': '7021', 'terms': ['operating system']}, {'element_identifier': '702', 'terms': ['memory']}, {'element_identifier': '504', 'terms': ['first response module']}, {'element_identifier': '703', 'terms': ['user interface']}, {'element_identifier': '510', 'terms': ['source list extension module']}, {'element_identifier': '700', 'terms': ['mobile terminal']}]","['6. A mobile terminal, comprising: a first detection module configured to detect a selection operation made by a user on a to-be-copied content in a first file; a first output module configured to output a first prompt box in accordance with the selection operation, wherein the first prompt box comprises a first option indicating the addition of the to-be-copied content into a pasting source list and a second option indicating the addition of the to-be-copied content into a target file in a pasting destination list; a first reception module configured to receive a first selection operation made by the user on at least one of the first option and the second option; and a first response module configured to, in response to the first selection operation, add the to-be-copied content into the pasting source list as a to-be-pasted content, and/or paste the to-be-copied content to the selected target file.', '7. The mobile terminal according to claim 6, further comprising: a second detection module configured to detect a selection operation made by the user on a to-be-pasted position in a second file; a second output module configured to output a second prompt box in accordance with the selection operation, wherein the second prompt box comprises a third option indicating the addition of the second file into the pasting destination list and a fourth option indicating the to-be-pasted content in the pasting source list into the second file; a second reception module configured to receive a second selection operation made by the user on at least one of the third option and/or the fourth option; and a second response module configured to, in response to the second selection operation, add the second file into the pasting destination list as a target file, and/or paste the selected to-be-pasted content to the second file.', '8. The mobile terminal according to claim 6 or 7, further comprising: a first previewing module configured to, after the to-be-copied content has been pasted by the first response module to the selected target file, display context information about the pasted content in the second file for the preview of a pasting result; and a source list extension module configured to, after the to-be-copied content has been added by the first response module into the pasting source list as the to-be-pasted content, display the to-be-pasted content in the pasting source list, and set the pasting source list to be in an editable state.', '9. The mobile terminal according to claim 7 or 8, further comprising: a destination list extension module configured to, after the second file has been added by the second response module into the pasting destination list as the target file, display information about the target file in the pasting destination list and set the pasting destination list to be in an editable state; and a second previewing module configured to, after the selected to-be-pasted content has been pasted by the second response module to the to-be-pasted position in the second file, display context information about a pasted content in the second file for the subsequent preview of a pasting result.', '10. The mobile terminal according to any one of claims 7 to 9, further comprising: a third output module configured to, after the second detection module has detected the selection operation made by the user on the to-be-pasted position in the second file, output a shortcut pasting prompt option in accordance with the selection operation; and a shortcut pasting module configured to, upon the receipt of a selection operation made by the user on the prompt option, add a newly-added to-be-pasted content in the pasting source list to the to-be-pasted position in the second file.', '11. A mobile terminal, comprising a processor, a memory, and a computer program stored in the memory and executed by the processor, wherein the processor is configured to execute the computer program so as to implement the multi-path copying and pasting method according to any one of claims 1 to']",True,"['505', '513', '514', '506', '507', '508', '511', '501', '502', '503', '504', '509', '510', '512', '700', '701', '702', '7021', '7022', '705', '703', '704', '6', '15']" 631,EP_3598373_A1.png,EP3598373A1,DETERMINING PRODUCT RELEVANCY,['FIG2'],['FIG2 illustrates a schematic representation of product relevancy determination system according to an embodiment'],"['FIG2 illustrates a schematic representation of a system for determining relevant products to a user according to an embodiment. As a user 101 performs various actions 102 on, for example, an e-commerce platform using the client device 100, an action history comprising these actions 102 can be saved into a user profile 210. An action 102 may be, for example, a product purchase, viewing a product, placing a product into a shopping cart, or a product review. The user profile 210 can be stored, for example, in the memory of the computing apparatus 200. Product information database 220 can also be stored, for example, to the memory of the computing apparatus 200. Herein, any information/data that may be stored to the memory of the computing apparatus 200 may also be stored in some other manner, for example, to an external database. The product information database 220 can be obtained and/or updated from, for example, external data 221 or by inputting data 222. The external data 221 may be provided, for example, by a manufacturer of a product. The product information database 220 can comprise information about plurality of products, and each product can be associated with various attributes.']",14,231,schematic,G,"[{'element_identifier': '103', 'terms': ['communication channel', 'communication channels']}, {'element_identifier': '210', 'terms': ['user profile', 'user profiles']}, {'element_identifier': '221', 'terms': ['external data']}, {'element_identifier': '230', 'terms': ['procedures']}, {'element_identifier': '100', 'terms': ['client device', 'client devices']}, {'element_identifier': '220', 'terms': ['product information database']}, {'element_identifier': '222', 'terms': ['inputting data']}, {'element_identifier': '102', 'terms': ['actions', 'action']}, {'element_identifier': '101', 'terms': ['user', 'users']}, {'element_identifier': '240', 'terms': ['relevant products']}, {'element_identifier': '200', 'terms': ['computing apparatus']}]","['1. A computing apparatus (200), configured to: calculate a user attribute profile vector (212) based on a user action history (211) of a user (101); and calculate a similarity score between the user attribute profile vector and a product attribute vector (223) of a product, wherein only attributes that are relevant to the product are used for the calculation from the user attribute profile vector.', '3. The computing apparatus of any preceding claim, further configured to: transmit data indicating the processed order of the plurality of products to a client device (100).', '12. The computing apparatus of any preceding claim, further configured to: store the user attribute profile vector in a user profile (210) of the user.']",False,"['103', '103', '100', '200', '101', '102', '210', '220', '230', '240', '221', '222', '16']" 632,EP_3598375_A1 (3).png,EP3598375A1,SYSTEM AND METHOD FOR PROVIDING PLAYERS WITH LOCATION OF LOTTERY TICKETS WITH SPECIFIC GAME PLAY CHARACTERS,['FIG5'],['FIG5 is a diagram of a mobile smart device embodiment of the present system and method'],"[""Referring to FIG5, in a particular system and method configuration, the application running on the mobile smart device 60 enables recognition and receipt by the smart device 60 of a unique ID signal 68 emitted by a transmitter 64 located at the retail establishment. Once the player is within the retail establishment and within range of the transmitter device 64, the bin 44 within the array 42 containing the lottery ticket 10 having the game play characters 21 chosen by the player is revealed to the player via the mobile smart device 60. The signal 68 is unique to the retail establishment and is transmitted to the central server 54 by the player's mobile smart device 60, which uses the store identification to further filter the search previous results to the particular retail establishment in order to provide the specific bin 44 and ticket location within the bin 44 to the player. This information may be revealed to the player via their mobile smart device 60 or another display 56 within the retail location, such as a stand-alone monitor or screen in the retail establishment or a display configured with a lottery terminal kiosk 58 in the retail establishment.""]",16,211,diagram,G,"[{'element_identifier': '14', 'terms': ['""Your Numbers""', 'lottery tickets', 'lottery ticket']}, {'element_identifier': '64', 'terms': ['transmitter']}, {'element_identifier': '79', 'terms': ['matrix']}, {'element_identifier': '20', 'terms': ['area']}, {'element_identifier': '16', 'terms': ['code', 'codes']}, {'element_identifier': '21', 'terms': ['characters']}, {'element_identifier': '44', 'terms': ['bin', 'bins']}, {'element_identifier': '62', 'terms': ['display']}, {'element_identifier': '68', 'terms': ['signal']}]","['1. A lottery ticket dispensing system configured to reveal one or more game play characters on scratch-off lottery tickets to players prior to purchase of the scratch-off lottery tickets, comprising: a dispenser array at a retail establishment, the dispenser array having one or more bins each configured to house and dispense a pack of the scratch-off lottery tickets, wherein each of the scratch-off lottery tickets includes a set of game play characters covered by a scratch-off coating; a scanner associated with the array and configured to read a ticket pack code of each of the packs loaded into the array, wherein each ticket pack code is associated with a computer database file that includes identification of all or some of the game play characters for each of the scratch-off lottery tickets in the pack and location of the pack; a central server in communication with the scanner for receipt of the ticket pack codes and a signal that identifies bin location of the pack in the array; and a display at the retail establishment in communication with the central server, wherein, based on ticket location information from the central server, the display is configured to reveal one or more of the game play characters of at least certain ones of the scratch-off lottery tickets remaining in the array.', '11. The lottery ticket dispensing system as in claim 9 or 10, wherein the application enables recognition and receipt by the mobile smart device of a unique ID signal emitted by a transmitter device at the retail establishment, wherein once the player is within the retail establishment and within range of the transmitter device, the bin within the array containing the scratch-off lottery ticket having the game play characters chosen by the player is revealed to the player via the mobile smart device display.']",False,"['62', '1', '12', '66', '68', '64', '20', '16', '12', '19', '15', '14', '21', '79', '79', '44', '5', '14']" 633,EP_3598444_A1 (1).png,EP3598444A1,METHOD AND SYSTEM FOR MUTING CLASSIFIED INFORMATION FROM AN AUDIO,['FIG2'],"['FIG2 illustrates a functional block diagram of the information muting system of FIG1, according to some embodiments of the present disclosure']","['FIG2 illustrates a functional block diagram of the information muting system 102 of FIG1, according to some embodiments of the present disclosure. The information muting system 102 includes or is otherwise in communication with one or more hardware processors such as a processor(s) 202, at least one memory such as a memory 208, and an I/O interface 204. The processor 202 (hardware processor), the memory 208, and the I/O interface(s) 204 may be coupled by a system bus such as a system bus 206 or alike mechanism. The memory 208 further may include modules 210.', 'The modules 210 can be an Integrated Circuit (IC), external to the memory 208 (not shown), implemented using a Field-Programmable Gate Array (FPGA) or an Application-Specific Integrated Circuit (ASIC). The names of the modules of functional block within the modules 210 referred herein, are used for explanation and are not a limitation. Further, the memory 208 can also include the repository 112 (internal to the information muting system 102 as shown in FIG2). The modules 210 may include computer-readable instructions that supplement applications or functions performed by the information muting system 102. The repository 112 may store data that is processed, received, or generated as a result of the execution of one or more modules in the module(s) 210.']",22,260,block diagram,G,"[{'element_identifier': '210', 'terms': ['modules', 'module']}, {'element_identifier': '214', 'terms': ['classified word detection module']}, {'element_identifier': '202', 'terms': ['processor']}, {'element_identifier': '216', 'terms': ['subwords module']}, {'element_identifier': '218', 'terms': ['module']}, {'element_identifier': '1', 'terms': ['Table', 'equation']}, {'element_identifier': '208', 'terms': ['memory']}, {'element_identifier': '206', 'terms': ['system bus']}, {'element_identifier': '204', 'terms': ['I/O interface']}, {'element_identifier': '112', 'terms': ['repository']}, {'element_identifier': '102', 'terms': ['information muting system']}, {'element_identifier': '212', 'terms': ['conversion module']}]","['1. A processor-implemented method for muting classified information in an audio signal, the method comprises: receiving, an audio signal from the data source; converting, the audio signal into text using a speech recognition engine; identifying a plurality of classified words from the text using a repository of predefined classified words; obtaining, a first set of parameters associated with each classified word among the plurality of classified words; identifying, a plurality of subwords associated with each classified word; obtaining, a second set of parameters associated with each subword among the plurality of subwords of corresponding classified word among the plurality of classified words; computing, a relative score for each subword associated with the corresponding classified word based on a plurality of similar pairs for the corresponding classified word; generating, a fuzzy muting function using the first set of parameters, the second set of parameters and the relative score associated with each subword; and muting, the plurality of subwords associated with each classified word in accordance with the generated fuzzy muting function.', '5. An information muting system (102) for muting classified information in an audio signal, wherein the information muting system (102) comprises: a processor (202); an Input/output (I/O) interface (204); and a memory (208) coupled to the processor (202), the memory (208) comprising: a conversion module (212) is configured to convert the audio signal into text using a speech recognition engine; a classified word detection module (214) is configured to: identify, a plurality of classified words from the text using a repository of predefined classified words; obtain, a first set of parameters associated with each classified word among the plurality of classified words; a subwords module (216) is configured to: identify, a plurality of subwords associated with each classified word; obtain, a second set of parameters associated with each subword among the plurality of subwords of corresponding classified word among the plurality of classified words; compute, a relative score for each identified subword associated with the classified word based on a plurality of similar pairs for the classified word; a fuzzy muting module (218) is configured to: generate, a fuzzy muting function using the first set of parameters, the second set of parameters and the relative score associated with each subword; and mute, the plurality of subwords associated with each classified word in accordance with the generated fuzzy muting function.']",False,"['102', '202', '204', '1', '206', '208', '210', '212', '214', '216', '218', '112', '15']" 634,EP_3598455_A1.png,EP3598455A1,A COMPUTER-IMPLEMENTED METHOD AND APPARATUS FOR DETERMINING A TARGET ACTIVITY RATE FOR A SUBJECT,['FIG1'],['FIG1 is a block diagram illustrating an apparatus according to an exemplary embodiment'],"['FIG1 is a block diagram of an apparatus 2 that can be used to implement the techniques described herein. The apparatus 2 may take any desired form, and in some embodiments, the apparatus 2 is in the form of, or part of, a device that can be worn or carried by a subject (the person to whom the techniques described herein are to be applied), for example a smart watch, a smart phone, a tablet computer, or any other type of portable electronic device. In other embodiments, the apparatus 2 can be in the form of, or part of, a laptop, a desktop computer, a television set-top box, a server, etc.', 'It will be appreciated that a practical implementation of an apparatus 2 may include additional components to those shown in FIG1. For example the apparatus 2 may also include a power supply, such as a battery, or components for enabling the apparatus 2 to be connected to a mains power supply.']",13,189,block diagram,G,"[{'element_identifier': '14', 'terms': ['sensors']}, {'element_identifier': '12', 'terms': ['movement sensors']}, {'element_identifier': '1', 'terms': ['ranges between']}, {'element_identifier': '4', 'terms': ['unit']}, {'element_identifier': '10', 'terms': ['user interface']}]","['9. 9. An apparatus for managing a heart rate of a subject, the apparatus comprising a processing unit configured to: receive information indicative of a first activity that is being performed by the subject or that is to be performed by the subject, wherein performing the first activity comprises repeating a first activity cycle; determine an energy amount to be exerted by the subject in performing each first activity cycle; determine a target activity rate at which the subject should repeat the first activity cycle such that the heart rate of the subject is in a target range, wherein the target activity rate is determined based on the determined energy amount and a first criterion relating to the target range; and output an indication to the subject relating to the determined target activity rate.']",False,"['4', '10', '12', '14', '12', '1']" 635,EP_3598465_A1 (1).png,EP3598465A1,PHOTOVOLTAIC CELL WITH FIBER MESH SUPPORT AND CHARGER FOR PORTABLE ELECTRONICS,['FIG4'],['FIG4 shows a view from below of the part of the photovoltaic charger shown in FIG3'],"['The second conducting layer 16 has a bottom surface facing the bottom sheet 5b. The second conductor is in mechanical and electrical contact with the bottom surface, and the second conductor extends along the bottom surface. In this example, the photovoltaic charger has only one second conductor 20. Alternatively, the photovoltaic charger can have a plurality of second conductors extending across the bottom surface of the second conducting layer 16. In this example, the second conductor 20 extends along an edge of the bottom side of the solar cell unit 2, as shown in FIG4. However, the second conductor 20 can be arranged in many different ways as long as it is in electrical contact with the second conducting layer, since the second conductor 20 is not visible from the outside of the photovoltaic charger 1a.']",16,149,view,H,"[{'element_identifier': '5', 'terms': ['than', 'encapsulation']}, {'element_identifier': '22', 'terms': ['boost converter']}, {'element_identifier': '18', 'terms': ['first conductor']}, {'element_identifier': '2', 'terms': ['solar cell unit']}, {'element_identifier': '4', 'terms': ['between']}, {'element_identifier': '20', 'terms': ['between']}, {'element_identifier': '3', 'terms': ['connection elements']}]","['1. A photovoltaic charger (1;1a;1b) specially adapted for charging an electronic device, comprising: • a solar cell unit (2) comprising: - a working electrode comprising a porous light-absorbing layer (10) including dyed TiO 2 , - a porous first conducting layer (12) for extracting photo-generated electrons from the light-absorbing layer (10), wherein the light-absorbing layer is arranged on top of the first conducting layer, - a porous substrate (14) made of an insulating material and extending through the entire solar cell unit, wherein the first conducting layer (12) is formed on one side of the porous substrate (14), - a counter electrode including a second conducting layer (16), wherein the second conducting layer is formed on the opposite side of the porous substrate (14), and - a conducting medium for transferring charges between the counter electrode and the light-absorbing layer, • an encapsulation (5) encapsulating the solar cell unit, • a first conductor (18) electrically connected to the first conducting layer (12), and • at least one second conductor (20) electrically connected to the second conducting layer (16), wherein the photovoltaic charger contains only one single solar cell unit (2) and a boost converter (22) electrically connected to the first and second conductors (12, 16), and the boost converter is adapted to step up the voltage from the solar cell unit while stepping down the current from the solar cell unit.']",True,"['20', '18', '2', '3', '22', '2', '5', '20', '4', '19']" 636,EP_3598465_A1 (2).png,EP3598465A1,PHOTOVOLTAIC CELL WITH FIBER MESH SUPPORT AND CHARGER FOR PORTABLE ELECTRONICS,['FIG9'],['FIG9 shows a diagram based on measured values for generated power per area (µW/cm2) for light intensities between 200 and 20 000 Lux for the first example of the solar cell unit'],"['FIG9 shows a diagram of generated power per area (µW/cm2) for light intensities between 200 and 20 000 Lux calculated based on the measured values of voltage and current of table 1. As seen from the diagram, the measured power is substantially proportional to the incoming light intensity in the interval 200 - 20 000 Lux.']",36,63,diagram,H,"[{'element_identifier': '24', 'terms': ['insulating gap']}, {'element_identifier': '5', 'terms': ['than', 'encapsulation']}, {'element_identifier': '12', 'terms': ['layer', 'layers']}, {'element_identifier': '14', 'terms': ['substrate']}, {'element_identifier': '18', 'terms': ['first conductor']}, {'element_identifier': '2', 'terms': ['solar cell unit']}, {'element_identifier': '20', 'terms': ['between']}, {'element_identifier': '16', 'terms': ['second conducting layer']}, {'element_identifier': '10', 'terms': ['light-absorbing layer']}, {'element_identifier': '26', 'terms': ['through holes']}]","['1. A photovoltaic charger (1;1a;1b) specially adapted for charging an electronic device, comprising: • a solar cell unit (2) comprising: - a working electrode comprising a porous light-absorbing layer (10) including dyed TiO 2 , - a porous first conducting layer (12) for extracting photo-generated electrons from the light-absorbing layer (10), wherein the light-absorbing layer is arranged on top of the first conducting layer, - a porous substrate (14) made of an insulating material and extending through the entire solar cell unit, wherein the first conducting layer (12) is formed on one side of the porous substrate (14), - a counter electrode including a second conducting layer (16), wherein the second conducting layer is formed on the opposite side of the porous substrate (14), and - a conducting medium for transferring charges between the counter electrode and the light-absorbing layer, • an encapsulation (5) encapsulating the solar cell unit, • a first conductor (18) electrically connected to the first conducting layer (12), and • at least one second conductor (20) electrically connected to the second conducting layer (16), wherein the photovoltaic charger contains only one single solar cell unit (2) and a boost converter (22) electrically connected to the first and second conductors (12, 16), and the boost converter is adapted to step up the voltage from the solar cell unit while stepping down the current from the solar cell unit.']",True,"['10', '18', '12', '14', '16', '2', '20', '5', '10', '12', '14', '26', '18', '2', '24', '16', '20', '9', '20']" 637,EP_3598465_A1 (3).png,EP3598465A1,PHOTOVOLTAIC CELL WITH FIBER MESH SUPPORT AND CHARGER FOR PORTABLE ELECTRONICS,"['FIG10', ' FIG9']","['FIG10 shows a diagram of measured values for generated voltage (mV) for light intensities between 200 and 50 000 Lux for a second example of a solar cell unit having an electrolyte comprising copper ions ', 'FIG9 shows a diagram based on measured values for generated power per area (µW/cm2) for light intensities between 200 and 20 000 Lux for the first example of the solar cell unit']","['FIG10 shows a diagram of generated voltage (mV) for light intensities between 200 and 50 000 Lux based on the measured values of table 2. As seen from the diagram and table 2, the solar cell unit is capable of generating a voltage of 699 mV in an open circuit when the light intensity received by the solar cell unit is 200 Lux. Further, the photovoltaic charger is capable to generate a voltage of 943 mV in an open circuit when the light intensity received by the solar cell unit is 20 000 Lux. As seen from the diagram, the generated voltage is substantially linear between 3000 and 50 000 Lux. As seen from the table 2, the difference in generated voltage between 200 and 20 000 Lux is only 244 mV. Accordingly, the difference in generated voltage between 200 and 20 000 Lux is about 35%. The difference in generated voltage between 200 and 50 000 Lux is only 259 mV. Thus, the solar cell unit generates a voltage varying less than 300 mV in an open circuit when the light intensity received by the light-absorbing layer is varying between 200 and 50 000 Lux. Accordingly, the difference in generated voltage between 200 and 50 000 Lux is about 37%. ', 'FIG9 shows a diagram of generated power per area (µW/cm2) for light intensities between 200 and 20 000 Lux calculated based on the measured values of voltage and current of table 1. As seen from the diagram, the measured power is substantially proportional to the incoming light intensity in the interval 200 - 20 000 Lux.']",73,294,diagram,H,"[{'element_identifier': '22', 'terms': ['boost converter']}, {'element_identifier': '100', 'terms': ['than']}, {'element_identifier': '600', 'terms': ['between']}, {'element_identifier': '300', 'terms': ['voltage varying less than']}, {'element_identifier': '10', 'terms': ['light-absorbing layer']}, {'element_identifier': '1000', 'terms': ['irradiation is', 'linear with intensities between']}, {'element_identifier': '5000', 'terms': ['solar cell unit is']}, {'element_identifier': '200', 'terms': ['between']}, {'element_identifier': '700', 'terms': ['than']}]","['1. A photovoltaic charger (1;1a;1b) specially adapted for charging an electronic device, comprising: • a solar cell unit (2) comprising: - a working electrode comprising a porous light-absorbing layer (10) including dyed TiO 2 , - a porous first conducting layer (12) for extracting photo-generated electrons from the light-absorbing layer (10), wherein the light-absorbing layer is arranged on top of the first conducting layer, - a porous substrate (14) made of an insulating material and extending through the entire solar cell unit, wherein the first conducting layer (12) is formed on one side of the porous substrate (14), - a counter electrode including a second conducting layer (16), wherein the second conducting layer is formed on the opposite side of the porous substrate (14), and - a conducting medium for transferring charges between the counter electrode and the light-absorbing layer, • an encapsulation (5) encapsulating the solar cell unit, • a first conductor (18) electrically connected to the first conducting layer (12), and • at least one second conductor (20) electrically connected to the second conducting layer (16), wherein the photovoltaic charger contains only one single solar cell unit (2) and a boost converter (22) electrically connected to the first and second conductors (12, 16), and the boost converter is adapted to step up the voltage from the solar cell unit while stepping down the current from the solar cell unit.', '6. The photovoltaic charger according to any of the previous claims, wherein the solar cell unit (2) generates a voltage varying less than 40% when the light intensity received by the light-absorbing layer is varying between 200 and 50 000 Lux.', '7. The photovoltaic charger according to any of the previous claims, wherein the solar cell unit (2) produces a current of at least 15 µA/cm 2 when the light intensity received by the light-absorbing layer is 200 Lux, and the current produced by the solar cell unit is linearly increasing when the light intensity received by the light-absorbing layer increases from 200 to 20 000 Lux.']",True,"['800', '700', '600', '500', '400', '300', '200', '100', '5000', '10000', '15000', '9', '20000', '25000', '1200', '1000', '800', '600', '400', '200', '10000', '20000', '30000', '40000', '50000', '60000', '10', '22']" 638,EP_3598465_A1 (4).png,EP3598465A1,PHOTOVOLTAIC CELL WITH FIBER MESH SUPPORT AND CHARGER FOR PORTABLE ELECTRONICS,"['FIG11', ' FIG12']","['FIG12 shows a diagram based on measured values for generated power per area (µW/cm2) for light intensities between 200 and 50 000 Lux for the second example of solar cell unit ', 'FIG11 shows a diagram based on measured values for generated current (µA/cm2) for light intensities between 200 and 50 000 Lux for the second example of the solar cell unit']","['FIG12 shows a diagram of generated power per area (µW/cm2) for light intensities between 200 and 50 000 Lux calculated based on the measured values of voltage and current of table 1. As seen from the diagram, the measured power is substantially proportional to the incoming light intensity in the interval 200 - 20 000 Lux. ', 'FIG11 shows a diagram of generated current (µA/cm2) for light intensities between 200 and 50 000 Lux based on the measured values of table 2. As seen from the figure, the current increases linearly.']",69,104,diagram,H,"[{'element_identifier': '12', 'terms': ['layer', 'layers']}, {'element_identifier': '11', 'terms': ['photovoltaic charger']}, {'element_identifier': '3000', 'terms': ['between']}, {'element_identifier': '2000', 'terms': ['than']}, {'element_identifier': '1000', 'terms': ['irradiation is', 'linear with intensities between']}, {'element_identifier': '5000', 'terms': ['solar cell unit is']}, {'element_identifier': '23', 'terms': ['x']}, {'element_identifier': '1500', 'terms': ['about']}]","['1. A photovoltaic charger (1;1a;1b) specially adapted for charging an electronic device, comprising: • a solar cell unit (2) comprising: - a working electrode comprising a porous light-absorbing layer (10) including dyed TiO 2 , - a porous first conducting layer (12) for extracting photo-generated electrons from the light-absorbing layer (10), wherein the light-absorbing layer is arranged on top of the first conducting layer, - a porous substrate (14) made of an insulating material and extending through the entire solar cell unit, wherein the first conducting layer (12) is formed on one side of the porous substrate (14), - a counter electrode including a second conducting layer (16), wherein the second conducting layer is formed on the opposite side of the porous substrate (14), and - a conducting medium for transferring charges between the counter electrode and the light-absorbing layer, • an encapsulation (5) encapsulating the solar cell unit, • a first conductor (18) electrically connected to the first conducting layer (12), and • at least one second conductor (20) electrically connected to the second conducting layer (16), wherein the photovoltaic charger contains only one single solar cell unit (2) and a boost converter (22) electrically connected to the first and second conductors (12, 16), and the boost converter is adapted to step up the voltage from the solar cell unit while stepping down the current from the solar cell unit.', '6. The photovoltaic charger according to any of the previous claims, wherein the solar cell unit (2) generates a voltage varying less than 40% when the light intensity received by the light-absorbing layer is varying between 200 and 50 000 Lux.', '7. The photovoltaic charger according to any of the previous claims, wherein the solar cell unit (2) produces a current of at least 15 µA/cm 2 when the light intensity received by the light-absorbing layer is 200 Lux, and the current produced by the solar cell unit is linearly increasing when the light intensity received by the light-absorbing layer increases from 200 to 20 000 Lux.']",True,"['8000', '7000', '6000', '5000', '4000', '3000', '2000', '1000', '10000', '20000', '30000', '40000', '50000', '60000', '11', '5000', '4500', '4000', '3500', '3000', '2500', '2000', '1500', '1000', '500', '10000', '20000', '30000', '40000', '50000', '60000', '12', '23']" 639,EP_3598471_A1 (1).png,EP3598471A1,COMBINED ELECTRIC APPARATUS HAVING CONTACTOR AND FUSE,['FIG2'],['FIG2 is a structural schematic diagram intended to illustrate another schematic embodiment of a combined electric apparatus having a contactor and a fuse '],"['In the embodiment shown in FIG2, in each of the functional components, the upper wire outlet 121, the lower wire outlet 123, the contactor 14 and the fuse 16 are located in the same vertical plane; the second connection end 164, relative to the first connection end 162, is close to the contactor 14 and remote from the top face 125 of the housing 12.']",23,73,structural schematic diagram,H,"[{'element_identifier': '125', 'terms': ['top face']}, {'element_identifier': '121', 'terms': ['upper wire outlet']}, {'element_identifier': '124', 'terms': ['operating side']}, {'element_identifier': '123', 'terms': []}]","['1. A combined electric apparatus having a contactor and a fuse, characterized by comprising: a housing (12), having a wire outlet side (122) and an operating side (124) opposite the wire outlet side (122); and a functional component, comprising: an upper wire outlet (121), disposed at the wire outlet side (122); a lower wire outlet (123), disposed at the wire outlet side (122), and located below the upper wire outlet (121); a contactor (14), placed horizontally inside the housing (12), and having a first contact end (142) close to the wire outlet side (122) and a second contact end (144) close to the operating side (124), with the first contact end (142) being connected to the lower wire outlet (123); and a fuse (16), disposed in the housing (12) in such a way as to be inclined relative to the contactor (14), and having a first connection end (162) close to the wire outlet side (122) and a second connection end (164) close to the operating side (124), with the first connection end (162) being connected to the upper wire outlet (121).', '4. The combined electric apparatus as claimed in claim 1, characterized in that in a vertical direction, the distance between the second connection end (164) and a top face (125) of the housing (12) is greater than 120 mm.']",False,"['121', '125', '123', '124', '2']" 640,EP_3598498_A1.png,EP3598498A1,A PIXEL ARCHITECTURE AND AN IMAGE SENSOR,['FIG2'],['FIG2 is a schematic view of control signals for performing time-of-flight sensing by the image sensor'],"['As illustrated in FIG2, pulsed light is emitted by the light source. The pulsed light is emitted during a time period T0. The pulsed light will be reflected by a target and the reflected light is received and detected by the image sensor 100.', 'As illustrated in FIG2, the first exposure time and the second exposure time may be set such that part of the reflected light pulse is received by the pixel 110 during the first exposure time and part of the reflected light pulse is received by the pixel 110 during the second exposure time. A relation between the received light during the first exposure time and the received light during the second exposure time may form a measure of the distance to the target.', 'As further illustrated in FIG2, a sequence of light pulses may be emitted. The first and second exposure times may have an identical relation to each of the light pulses in the sequence. This implies that the amount of light detected in a series of first exposure times may be accumulated within each pixel 110 and the amount of light detected in a series of second exposures times may be accumulated within each pixel 110. Thus, each pixel 110 may perform lock-in sensing so as to improve a signal-to-noise ratio for determining the distance to the target and hence improve accuracy of determining the distance.']",20,253,schematic view,H,"[{'element_identifier': '100', 'terms': ['image sensor']}, {'element_identifier': '110', 'terms': ['pixel', 'pixels']}, {'element_identifier': '150', 'terms': ['control unit']}]","['1. A pixel architecture for detection of incident light; said pixel architecture comprising: an absorption layer (112), which is configured to extend in a first plane, the absorption layer (112) being configured for back-side illumination and being configured to generate charges in response to incident light on an interface of the absorption layer (112) and to transport charges in a direction perpendicular to the first plane; a semiconductor charge-transport layer (118) with a charge-dispatch region (120) and a charge node (128, 130); the charge-transport layer (118) being arranged to extend in a second plane parallel to the first plane, the charge-transport layer (118) being configured to receive generated charges from the absorption layer (112) and to transport the generated charges through the charge-transport layer (118), wherein one or more doped regions (122) are arranged in the charge-transport layer (118), wherein said charge-transport layer further comprises a bias region (121), and wherein the charge-dispatch region (120), which forms a dedicated region in a lateral direction parallel to the second plane of the charge-transport layer (118) is associated with the bias region (121); an electric connection (132) connecting to the bias region (121) for providing a selectable bias voltage to the bias region (121); and at least one transfer gate (124, 126) associated with an area adjoining to the charge-dispatch region (120) in the lateral direction, wherein the doped regions (122) and the bias region (121) have a different doping in relation to a bulk substrate of the charge-transport layer (118) and wherein the doped regions (122) and the bias region (121) are differently biased for driving transport of the generated charges towards the charge-dispatch region (120), and for controlling, together with the at least one transfer gate (124, 126), transfer of charges from the charge-dispatch region (120) in the lateral direction to the charge node (128, 130).', '12. An image sensor (100) comprising: an array of pixels (110), each having a pixel architecture according to any one of the preceding claims; and a control unit (150), which is configured to provide control signals for controlling transfer of charges from the charge-dispatch region (120) to the charge node (128, 130) of each pixel (110).']",True,"['100', '110', '150', '1', '1', '2', '2', '14']" 641,EP_3598508_A1.png,EP3598508A1,SOLAR CELL,['FIG2'],['FIG2 is a schematic cross-sectional view of a solar cell according to another exemplary embodiment of the present invention'],"['Meanwhile, as shown in the solar cell 200 illustrated in FIG2, the I-VII compound photovoltaic layer 110 may further include an undoped I-VII compound layer 113 formed between the first type I-VII compound layers 111 and the second type I-VII compound layers 112.', 'In FIG2, although both of the undoped I-VII compound layer 113 and the undoped silicon layer 123 are formed, only one of the undoped I-VII compound layer 113 and the undoped silicon layer 123 may formed.']",21,98,schematic cross-sectional view,H,"[{'element_identifier': '122', 'terms': ['second type silicon layer']}, {'element_identifier': '121', 'terms': ['first type silicon layer']}, {'element_identifier': '11', 'terms': []}, {'element_identifier': '130', 'terms': ['second electrode']}, {'element_identifier': '123', 'terms': ['undoped silicon layer']}, {'element_identifier': '100', 'terms': ['solar cell']}, {'element_identifier': '112', 'terms': ['type I-VII compound layer', 'type I-VII compound layers']}, {'element_identifier': '10', 'terms': ['Equation']}, {'element_identifier': '140', 'terms': ['electrode']}, {'element_identifier': '200', 'terms': ['solar cell']}, {'element_identifier': '120', 'terms': ['silicon photovoltaic layer']}, {'element_identifier': '13', 'terms': ['following Equation']}]","['1. A solar cell comprising: a I-VII compound photovoltaic layer including a first type I-VII compound layer and a second type I-VII compound layer, the first type I-VII compound layer having a first type impurities, the second type I-VII compound layer having a second type impurities of which polarity is opposite to a polarity of the first type impurities, and the second type I-VII compound layer being disposed under the first type I-VII compound layer; a silicon photovoltaic layer including a first type silicon layer and a second type silicon layer, the first type silicon layer having first type dopants, the second type silicon layer having second type dopants of which polarity is opposite to a polarity of the first type dopants, the first type silicon layer being disposed under the second type I-VII compound layer, and the second type silicon layer being disposed under the first type silicon layer; a first electrode formed under the second type silicon layer; and a second electrode formed on a portion of the first type I-VII compound layer to expose remaining portion of the first type I-VII compound layer;', '5. The solar cell of claim 1, further comprising: an undoped silicon layer between the first type silicon layer and the second type silicon layer.']",True,"['11', '100', '130', '130', '130', '121', '120', '122', '140', '200', '130', '130', '130', '13', '10', '112', '121', '123', '120', '122', '40', '11']" 642,EP_3598519_A1.png,EP3598519A1,ORGANIC ELECTROLUMINESCENT APPARATUS AND ELECTRODE THEREFOR,['FIG4'],['FIG4 is a schematic structural diagram of an organic light-emitting device according to a fourth embodiment of the present disclosure '],"['As shown in FIG4, when a second electrode 20 laminated with the electrode is a reflective electrode, the light is reflected between the reflective electrode 20 and the transflective conductive layer 11. A microcavity structure is formed by the reflective electrode and the transflective conductive layer to generate a microcavity effect, resulting in occurrence of the destructive interference and constructive interference of the light, and finally only an intensity of light of a preset wavelength is maintained and an intensity of light of other wavelength is reduced. When the microcavity structure is adjusted, the reflectivity and the light transmittance in the transflective conductive layer may be controlled by adjusting the thickness of the transflective conductive layer, thereby adjusting the phase difference generated when the light is reflected in the transflective conductive layer. As shown in FIG4, at the same time, the work function of the first conductive layer 11 is 5.1 eV. The first conductive layer 11 is made of a material having a large work function, enabling to reduce an energy level barrier, and the holes are injected into the organic functional layer 30 easily.', 'As shown in FIG4, when a second electrode 20 laminated with the electrode is a reflective electrode, a microcavity structure is formed by the first conductive layer 11 and the reflective electrode to generate a microcavity effect, resulting in occurrence of the destructive interference and constructive interference of the light, and finally only an intensity of light of a preset wavelength is maintained and an intensity of light of other wavelength is reduced. The second conductive layer 12 is used for improving the injection of the holes, thereby reducing the absorption of the OLED photon energy by a metal surface coupling of the electrode.', 'As shown in FIG4, an organic light-emitting device (OLED) is provided in this embodiment. The OLED in this embodiment is a bottom light-emitting device. A first electrode 10 is a transparent positive electrode made of indium tin oxide. A second electrode 20 is a metal negative electrode, functioning as a reflective electrode and made of LiF/Al.', 'In this embodiment, as shown in FIG4, the first electrode 10 includes a first conductive layer 11 and a second conductive layer 12 and a third conductive layer 13 laminated at both opposite sides of the first conductive layer 11.']",22,427,schematic structural diagram,H,"[{'element_identifier': '30', 'terms': ['organic functional layer']}, {'element_identifier': '12', 'terms': ['second conductive layer']}, {'element_identifier': '11', 'terms': ['conductive layer']}, {'element_identifier': '2', 'terms': ['is']}, {'element_identifier': '20', 'terms': ['electrode']}, {'element_identifier': '40', 'terms': ['substrate']}, {'element_identifier': '10', 'terms': ['first electrode']}, {'element_identifier': '13', 'terms': ['third conductive layer']}]","['1. An organic light-emitting device, comprising a first electrode, an organic functional layer and a second electrode sequentially laminated on a substrate, characterized in that the first electrode has a first side and a second side opposite to the first side, and comprises: a first conductive layer; and a second conductive layer, laminated at the first side of the first conductive layer, the second conductive layer being a transparent conductive layer.', '2. The organic light-emitting device according to claim 1, characterized in that the first electrode further comprises a third conductive layer laminated at the second side of the first conductive layer; and the third conductive layer is a transparent conductive layer.']",True,"['12', '11', '13', '11', '13', '2', '12', '11', '20', '30', '12', '11', '13', '40', '4', '10', '8']" 643,EP_3598553_A1 (1).png,EP3598553A1,"SEALED BATTERY, BATTERY PACK AND BATTERY FOR ENGINE IGNITION","['FIG3', ' FIG4']","['FIG4 is a schematic top view of an assembled battery or a battery for engine starting according to one embodiment of the present invention ', 'FIG3 is a schematic sectional view of the sealed battery according to one embodiment of the present invention']","['The assembled battery 50 according to the present embodiment or the battery 51 for engine starting according to the present embodiment may be constituted by a plurality of sealed batteries 40. For example, the assembled battery 50 and the battery 51 for engine starting can be formed by connecting a plurality of sealed batteries 40a to 40d in series as in the assembled battery 50 (battery 51 for engine starting) shown in FIG4.', 'For example, in the assembled battery 50 (battery 51 for engine starting) shown in FIG4, an external connection section 15a of the sealed battery 40a may be connected to an external connection section 14b of the sealed battery 40b. An external connection section 15d of the sealed battery 40d may be connected to a battery connection terminal 37b of a device.', 'At least a part of the conduction sections 20 and 21 included in the first sealed battery 40 may be directly in contact with the outer surface of the case 1 included in the second sealed battery 40. Alternatively, at least a part of the conduction sections 20 and 21 included in the first sealed battery 40 may be indirectly in contact with the outer surface of the case 1 included in the second sealed battery 40 with the intermediate layer 35 therebetween. With this configuration, even if the first sealed battery 40 is discharged with a large current and the first lead terminal 8 or the second lead terminal 9 generates heat, the generated heat from the lead terminal 8 or 9 can be dissipated to the case 1 of the second sealed battery 40. For example, a conduction section of a lead terminal 9d of the sealed battery 40d included in the assembled battery 50 (battery 51 for engine starting) shown in FIG4 can be provided to be directly or indirectly in contact with the outer surface of the case 1 of the adjacent sealed battery 40c. Further, at least a part of the conduction sections 20 and 21 included in the first sealed battery 40 may be sandwiched between the first sealed battery 40 and the second sealed battery 40. ', 'The conduction sections 20 and 21 can be provided, for example, to in contact with the outer surface of the case 1 indirectly with the intermediate layer 35 therebetween as in the sealed battery 40 shown in FIG3. The intermediate layer 35 can be provided to be in direct contact with the outer surface of the case, and to be in direct contact with the conduction sections 20 and 21.']",42,457,"schematic sectional view, schematic view",F,"[{'element_identifier': '24', 'terms': ['positive-electrode current collector']}, {'element_identifier': '23', 'terms': ['positive-electrode active material layer']}, {'element_identifier': '14', 'terms': ['external connection section', 'external connection sections']}, {'element_identifier': '50', 'terms': ['assembled battery']}, {'element_identifier': '26', 'terms': ['negative-electrode active material layer']}, {'element_identifier': '33', 'terms': ['adhesive layers', 'adhesive layer']}, {'element_identifier': '3', 'terms': ['positive electrode', 'positive electrodes']}]","['1. A sealed battery comprising: an electrode assembly including a positive electrode, a negative electrode, and a separator; an electrolyte; a case which contains the electrode assembly and the electrolyte; a first lead terminal; and a second lead terminal, wherein each of the first lead terminal and the second lead terminal comprises an electrode connection section which is connected to the positive electrode or the negative electrode inside the case, an external connection section positioned outside the case, and a sealing section to which the case is bonded via an adhesive layer, the first lead terminal or the second lead terminal comprises a conduction section serving as a conduction path between the sealing section and the external connection section, the conduction section is provided to be at least partially in contact with an outer surface of the case directly or provided to be at least partially in contact with the outer surface of the case indirectly via an intermediate layer, the case has a conductivity or an apparent thermal conductivity of from 10 W/(m·K) to 250 W/(m·K) inclusive, and the electrode assembly and the electrolyte contained in the case have an effective thermal conductivity of from 10 W/(m·K) to 100 W/(m·K) inclusive in a steady state.', '9. An assembled battery comprising a plurality of the sealed batteries according to any one of claims 1 to 8, wherein the external connection section included in a first sealed battery is electrically connected to the external connection section included in a second sealed battery.']",True,"['26', '33', '26', '23', '24', '3', '50', '14']" 644,EP_3598557_A1 (3).png,EP3598557A1,"NONAQUEOUS ELECTROLYTE, NONAQUEOUS SECONDARY BATTERY, CELL PACK, AND HYBRID SYSTEM",['FIG4'],['FIG4 is a schematic explanatory diagram illustrating a hybrid power system according to a forty fifth embodiment'],"['An example of a specific configuration of the forty fifth embodiment will now be described. FIG4 is a schematic explanatory diagram illustrating a hybrid power system according to the present invention. Here, the reference numeral 1 refers to a ""non-aqueous secondary battery (LIB)"", the reference numeral 2 refers to a voltage monitoring circuit (BMS), the reference numeral 4a refers to a ""capacitor (secondary battery other than the LIB)"", and the reference numeral 5 refers to a small-sized hybrid power system. This small-sized hybrid power system 5 can be repeatedly charged and discharged.', 'Specifically, as illustrated in FIG4, this small-sized hybrid power system 5 includes non-aqueous secondary batteries (LIB) 1 in which four cells are connected in series, and a voltage monitoring circuit (BMS) 2 that individually monitors terminal voltages of each of the plurality of non-aqueous secondary batteries. In addition, a capacitor 4a (as a secondary battery other than the LIB) is connected in parallel to the LIB 1. The capacitor preferably includes an electric double layer capacitor, a lithium ion capacitor, or the like.']",17,221,schematic explanatory diagram,H,"[{'element_identifier': '4', 'terms': ['electrode']}, {'element_identifier': '2', 'terms': ['reference numeral']}, {'element_identifier': '142', 'terms': ['Examples']}, {'element_identifier': '1', 'terms': ['per']}]","['32. A non-aqueous secondary battery comprising: a positive electrode having a positive-electrode active material layer formed on one surface or both surfaces of a current collector; a negative electrode having a negative-electrode active material layer formed on one surface or both surfaces of a current collector; and a non-aqueous electrolyte solution, wherein the non-aqueous electrolyte solution contains acetonitrile and LiPO 2 F 2 , and a value obtained by dividing a bulk resistance at a temperature of -30°C by an internal resistance value in measurement of electrochemical impedance spectroscopy for the non-aqueous secondary battery is 0.05 to 0.', '46. The non-aqueous secondary battery according to any one of claims 31 to 41, wherein a gas generation amount in a storage test at 60°C for 200 hours is 0.008 ml or less per 1 mAh.']",False,"['4', '2', '1', '1', '1', '142']" 645,EP_3598579_A1 (5).png,EP3598579A1,COMMUNICATION DEVICE,['FIG21'],['FIG21 is a diagram illustrating an exemplary configuration of an antenna apparatus according to an eighth variant'],"['As illustrated in FIG21, the element 2203 forms a square loop and a plurality of loop antennas 2201 (or loop antennas 2201a and 2201b) with mutually different aspect ratios of the element 2203 is provided in the antenna apparatus 2200.', 'Specifically, the loop antenna 2201a is formed with the element 2203 such that a direction in which the ground plane 2209 extends (or the horizontal direction of FIG21) is the longitudinal direction. Thereby, the loop antenna 2201a more dominantly transmits or receives the polarized wave RH the polarization direction of which substantially matches with the longitudinal direction than the polarized wave RV the polarization direction of which substantially matches with the short direction. That is, the loop antenna 2201a can transmit or receive the polarized wave RH in wireless signals transmitted or received by the antenna apparatus 2190.', 'To the contrary, the loop antenna 2201b is formed with the element 2203 such that a direction (or the vertical direction of FIG21) orthogonal to the direction in which the ground plane 2209 extends is the longitudinal direction. Thereby, the loop antenna 2201b more dominantly transmits or receives the polarized wave RV the polarization direction of which substantially matches with the longitudinal direction than the polarized wave RH the polarization direction of which substantially matches with the short direction. That is, the loop antenna 2201b can transmit or receive the polarized wave RV in wireless signals transmitted or received by the antenna apparatus 2190.']",17,264,diagram,H,"[{'element_identifier': '2209', 'terms': ['ground plane']}, {'element_identifier': '2203', 'terms': ['element']}, {'element_identifier': '2200', 'terms': ['antenna apparatus']}, {'element_identifier': '2201', 'terms': ['loop antenna', 'loop antennas']}, {'element_identifier': '2205', 'terms': ['power supply point']}]","['6. The communication apparatus according to claim 5, wherein at least any of the first antenna device and the second antenna device is configured as any of a monopole antenna, a dipole antenna, a one-side short-circuit planar antenna, a notch antenna, an inverted F-antenna, a loop antenna, and a slot antenna.']",True,"['20', '2203', '2205', '2201', '2209', '21', '2200', '2209', '43']" 646,EP_3598622_A1 (1).png,EP3598622A1,DRIVE DEVICE AND DISTANCE MEASURING DEVICE,['FIG20'],"['FIG20 is a perspective view illustrating a structure of a base, a first magnet, a second magnet, a first facing member, and a second facing member according to Example 5']","['FIG20 is a perspective view illustrating the structures of the base 12, the first magnet 41, the second magnet 42, the first facing member 51, and the second facing member 52 according to Example 5. In the figure, the drive unit 20, the first coil 31, and the second coil 32 are omitted. The drive device 10 according to this example is the same as the drive device 10 according to at least one of the embodiment and Examples 1 to 4 except for the structures of the first magnet 41, the first facing member 51, and the second facing member 52. Further, the distance measurement apparatus 90 according to this example has the same configuration as the distance measurement apparatus 90 according to Example 1.']",34,140,perspective view,G,"[{'element_identifier': '221', 'terms': ['reference surface']}, {'element_identifier': '12', 'terms': ['base']}, {'element_identifier': '412', 'terms': ['surface']}, {'element_identifier': '2', 'terms': ['in Example']}, {'element_identifier': '20', 'terms': ['drive unit']}, {'element_identifier': '411', 'terms': ['surface']}, {'element_identifier': '42', 'terms': ['second magnet', 'second magnets']}, {'element_identifier': '31', 'terms': ['first coil']}, {'element_identifier': '10', 'terms': ['drive device']}, {'element_identifier': '50', 'terms': ['magnetic member', 'magnetic members']}, {'element_identifier': '41', 'terms': ['first magnet']}, {'element_identifier': '23', 'terms': ['support']}, {'element_identifier': '32', 'terms': ['second coil', 'second coils']}]","['1. A drive device comprising: a support; a first movable portion swingable in two axial directions with respect to the support; a first magnet positioned inside the first movable portion and a second magnet positioned outside the first movable portion when viewed from a first direction; and a first coil on which magnetic flux from the first magnet acts and a second coil on which magnetic flux from the second magnet acts.', '2. The drive device according to claim 1, further comprising: a magnetic member including one or more facing members facing at least one of the first magnet and the second magnet, wherein the first coil is fixed to the first movable portion, passes between the first magnet and the magnetic member, and does not pass between the second magnet and the magnetic member when viewed from the first direction, and the second coil is fixed to the first movable portion, passes between the second magnet and the magnetic member, and does not pass between the first magnet and the magnetic member when viewed from the first direction.', '8. The drive device according to any one of claims 2 to 7, wherein a second movable portion is swingably attached to the first movable portion, and the second movable portion is swingable with a first axis as an axis such that an angle of a reference surface is variable with respect to the first movable portion.']",True,"['10', '31', '50', '42', '10', '42', '42', '23', '23', '32', '50', '50', '221', '42', '2', '50', '411', '23', '20', '50', '10', '41', '12', '412', '10', '23', '12', '18']" 647,EP_3598662_A1 (2).png,EP3598662A1,"TRANSMISSION WAVE BEAM DETERMINATION METHOD, TRANSMISSION END AND RECEPTION END","['FIG5', ' FIG6']","['FIG6 is a schematic view showing a transmitting end device according to some embodiments of the present disclosure ', 'FIG5 is a flow chart of a transmission beam determination method according to some embodiments of the present disclosure']","['The present disclosure further provides in some embodiments a transmitting end device 600 which, as shown in FIG6, includes: a transmission module 601 configured to transmit beam training signals for N number of transmission beams to a receiving end device, N being a positive integer; a reception module 602 configured to receive identification information about Q number of transmission beams in the N number of transmission beams and group information about each transmission beam in the Q number of transmission beams from the receiving end device, the Q number of transmission beams including G number of transmission beam groups, the G number of transmission beam groups being acquired by the receiving end device in accordance with a measurement result, the measurement result being a measurement result acquired after the receiving end device has received and measured the beam training signals from the transmitting end device, Q and G being each a positive integer; and a first determination module 603 configured to determine that a signal is capable of being transmitted simultaneously to the receiving end device via transmission beams in the Q number of transmission beams belonging to different transmission beam groups. ', 'The present disclosure further provides in some embodiments a transmission beam determination method which, as shown in FIG5, includes: Step 501 of receiving and measuring, by a receiving end device, beam training signals for N number of transmission beams from a transmitting end device, selecting Q number of transmission beams from the N number of transmission beams in accordance with a measurement result, and dividing the Q number of transmission beams into G number of transmission beam groups, N, Q and G being each a positive integer; and Step 502 of transmitting, by the receiving end device, identification information about the Q number of transmission beams and group information about each transmission beam in the Q number of transmission beams to the transmitting end device, so as to enable the transmitting end device to determine that a signal is capable of being transmitted simultaneously to the receiving end device via transmission beams in the Q number of transmission beams belonging to different transmission beam groups.']",37,382,"flowchart, schematic view",H,"[{'element_identifier': '601', 'terms': ['transmission module']}, {'element_identifier': '502', 'terms': ['Step']}, {'element_identifier': '600', 'terms': ['transmitting end device']}, {'element_identifier': '501', 'terms': ['Step']}, {'element_identifier': '602', 'terms': ['reception module']}, {'element_identifier': '603', 'terms': ['first determination module']}]","['17. A transmitting end device, comprising: a transmission module configured to transmit beam training signals for N number of transmission beams to a receiving end device, N being a positive integer; a reception module configured to receive identification information about Q number of transmission beams in the N number of transmission beams and group information about each transmission beam in the Q number of transmission beams from the receiving end device, the Q number of transmission beams comprising G number of transmission beam groups, the G number of transmission beam groups being acquired by the receiving end device in accordance with a measurement result, the measurement result being a measurement result acquired after the receiving end device has received and measured the beam training signals from the transmitting end device, Q and G being each a positive integer; and a first determination module configured to determine that a signal is capable of being transmitted simultaneously to the receiving end device via transmission beams in the Q number of transmission beams belonging to different transmission beam groups.']",True,"['502', '501', '5', '600', '601', '602', '603', '6', '35']" 648,EP_3598662_A1 (3).png,EP3598662A1,"TRANSMISSION WAVE BEAM DETERMINATION METHOD, TRANSMISSION END AND RECEPTION END","['FIG7', ' FIG8']","['FIG8 is a schematic view showing a receiving end device according to some embodiments of the present disclosure ', 'FIG7 is another schematic view showing the transmitting end device according to some embodiments of the present disclosure']","['The present disclosure further provides in some embodiments a receiving end device 800 which, as shown in FIG8, includes: a measurement module 801 configured to receive and measure beam training signals for N number of transmission beams from a transmitting end device, select Q number of transmission beams from the N number of transmission beams in accordance with a measurement result, and divide the Q number of transmission beams into G number of transmission beam groups, N, Q and G being each a positive integer; and a transmission module 802 configured to transmit identification information about the Q number of transmission beams and group information about each transmission beam in the Q number of transmission beams to the transmitting end device, so as to enable the transmitting end device to determine that a signal is capable of being transmitted simultaneously to the receiving end device via transmission beams in the Q number of transmission beams belonging to different transmission beam groups. ', 'As shown in FIG7, the transmitting end device 600 may further include a second determination module 604 configured to determine that a signal is capable of being transmitted simultaneously to the receiving end device via the transmission beams belonging to a same transmission beam subgroup in the Q number of transmission beams.']",36,225,schematic view,H,"[{'element_identifier': '601', 'terms': ['transmission module']}, {'element_identifier': '801', 'terms': ['measurement module']}, {'element_identifier': '600', 'terms': ['transmitting end device']}, {'element_identifier': '802', 'terms': ['transmission module']}, {'element_identifier': '604', 'terms': ['second determination module']}, {'element_identifier': '602', 'terms': ['reception module']}, {'element_identifier': '800', 'terms': ['receiving end device']}, {'element_identifier': '603', 'terms': ['first determination module']}]","['17. A transmitting end device, comprising: a transmission module configured to transmit beam training signals for N number of transmission beams to a receiving end device, N being a positive integer; a reception module configured to receive identification information about Q number of transmission beams in the N number of transmission beams and group information about each transmission beam in the Q number of transmission beams from the receiving end device, the Q number of transmission beams comprising G number of transmission beam groups, the G number of transmission beam groups being acquired by the receiving end device in accordance with a measurement result, the measurement result being a measurement result acquired after the receiving end device has received and measured the beam training signals from the transmitting end device, Q and G being each a positive integer; and a first determination module configured to determine that a signal is capable of being transmitted simultaneously to the receiving end device via transmission beams in the Q number of transmission beams belonging to different transmission beam groups.', '20. The transmitting end device according to any one of claims 17 to 19, wherein the reception module is further configured to receive the identification information about the Q number of transmission beams in the N number of transmission beams as well as the group information and subgroup information about each transmission beam in the Q number of transmission beams from the receiving end device, and the transmission beams corresponding to a same reception beam in each transmission beam group belong to one transmission beam subgroup, wherein the transmitting end device further comprises a second determination module configured to determine that a signal is capable of being transmitted simultaneously to the receiving end device via the transmission beams belonging to a same transmission beam subgroup in the Q number of transmission beams.', '23. A receiving end device, comprising: a measurement module configured to receive and measure beam training signals for N number of transmission beams from a transmitting end device, select Q number of transmission beams from the N number of transmission beams in accordance with a measurement result, and divide the Q number of transmission beams into G number of transmission beam groups, N, Q and G being each a positive integer; and a transmission module configured to transmit identification information about the Q number of transmission beams and group information about each transmission beam in the Q number of transmission beams to the transmitting end device, so as to enable the transmitting end device to determine that a signal is capable of being transmitted simultaneously to the receiving end device via transmission beams in the Q number of transmission beams belonging to different transmission beam groups.']",True,"['600', '601', '602', '603', '604', '7', '800', '801', '802', '8', '36']" 649,EP_3598662_A1 (4).png,EP3598662A1,"TRANSMISSION WAVE BEAM DETERMINATION METHOD, TRANSMISSION END AND RECEPTION END","['FIG10', ' FIG9']","['FIG10 is another schematic view showing the receiving end device according to some embodiments of the present disclosure ', 'FIG9 is another schematic view showing the receiving end device according to some embodiments of the present disclosure']","['In some possible embodiments of the present disclosure, as shown in FIG10, the selection unit 8012 may include: a first selection sub-unit 80121 configured to select Qg measurement results with top Qg reception quality levels in the measurement results of each transceiver unit group to acquire Q number of measurement results, Qgs for different transceiver unit groups being a same positive integer or different positive integers, and a sum of Qgs corresponding to the G number of transmission beam groups being Q; and a second selection sub-unit 80122 configured to select the Q number of transmission beams corresponding to the Q number of measurement results from the N number of transmission beams, and divide the Qg transmission beams corresponding to the Qg measurement results of each transceiver unit group into a transmission beam group corresponding to the transceiver unit group. ', 'In some possible embodiments of the present disclosure, as shown in FIG9, the measurement module 801 may include: a measurement unit 8011 configured to receive and measure the beam training signal for each transmission beam in the N number of transmission beams from the transmitting end device using the G number of transceiver unit groups to acquire measurement results of the G number of transceiver unit groups, the measurement result of each transceiver unit group including a measurement result acquired after the receiving end device has received and measured the beam training signals for the N number of transmission beams using the transceiver unit group; and a selection unit 8012 configured to select the Q number of transmission beams from the N number of transmission beams in accordance with the measurement results of the G number of transceiver unit groups, and divide the Q number of transmission beams into the G number of transmission beam groups.']",36,315,schematic view,H,"[{'element_identifier': '8012', 'terms': ['selection unit']}, {'element_identifier': '801', 'terms': ['measurement module']}, {'element_identifier': '8011', 'terms': ['measurement unit']}, {'element_identifier': '80121', 'terms': ['first selection sub-unit']}, {'element_identifier': '80122', 'terms': ['second selection sub-unit']}, {'element_identifier': '802', 'terms': ['transmission module']}, {'element_identifier': '800', 'terms': ['receiving end device']}]","['17. A transmitting end device, comprising: a transmission module configured to transmit beam training signals for N number of transmission beams to a receiving end device, N being a positive integer; a reception module configured to receive identification information about Q number of transmission beams in the N number of transmission beams and group information about each transmission beam in the Q number of transmission beams from the receiving end device, the Q number of transmission beams comprising G number of transmission beam groups, the G number of transmission beam groups being acquired by the receiving end device in accordance with a measurement result, the measurement result being a measurement result acquired after the receiving end device has received and measured the beam training signals from the transmitting end device, Q and G being each a positive integer; and a first determination module configured to determine that a signal is capable of being transmitted simultaneously to the receiving end device via transmission beams in the Q number of transmission beams belonging to different transmission beam groups.', '25. The receiving end device according to claim 24, wherein the measurement module comprises: a measurement unit configured to receive and measure the beam training signal for each transmission beam in the N number of transmission beams from the transmitting end device using the G number of transceiver unit groups to acquire measurement results of the G number of transceiver unit groups, the measurement result of each transceiver unit group comprising a measurement result acquired after the receiving end device has received and measured the beam training signals for the N number of transmission beams using the transceiver unit group; and a selection unit configured to select the Q number of transmission beams from the N number of transmission beams in accordance with the measurement results of the G number of transceiver unit groups, and divide the Q number of transmission beams into the G number of transmission beam groups.', '27. The receiving end device according to claim 25, wherein the selection unit comprises: a first selection sub-unit configured to select Q g measurement results with top Q g reception quality levels in the measurement results of each transceiver unit group to acquire Q number of measurement results, Q g s for different transceiver unit groups being a same positive integer or different positive integers, and a sum of Q g s corresponding to the G number of transmission beam groups being Q; and a second selection sub-unit configured to select the Q number of transmission beams corresponding to the Q number of measurement results from the N number of transmission beams, and divide the Q g transmission beams corresponding to the Q g measurement results of each transceiver unit group into a transmission beam group corresponding to the transceiver unit group.']",True,"['800', '801', '8011', '8012', '802', '9', '800', '801', '8011', '8012', '80121', '80122', '802', '10', '37']" 650,EP_3598662_A1 (5).png,EP3598662A1,"TRANSMISSION WAVE BEAM DETERMINATION METHOD, TRANSMISSION END AND RECEPTION END","['FIG11', ' FIG12']","['FIG12 is still yet another schematic view showing the receiving end device according to some embodiments of the present disclosure ', 'FIG11 is yet another schematic view showing the receiving end device according to some embodiments of the present disclosure']","['In some possible embodiments of the present disclosure, as shown in FIG12, the receiving end device 800 may further include: a selection module 803 configured to select one reception beam for each of the Q number of transmission beams from candidate reception beams for the receiving end device; and a division module 804 configured to divide transmission beams in each transmission beam group corresponding to a same reception beam into one transmission beam subgroup. The transmission module 802 is further configured to transmit the identification information about the Q number of transmission beams in the N number of transmission beams as well as the group information and subgroup information about each transmission beam in the Q number of transmission beams to the transmitting end device. ', 'In some possible embodiments of the present disclosure, each transceiver unit group of the receiving end device may include at least one transceiver unit, and each transceiver unit may include at least one reception beam. As shown in FIG11, the measurement unit 8011 may include: a measurement sub-unit 80111 configured to receive and measure the beam training signal for each transmission beam of the N number of transmission beams from the transmitting end device using each reception beam for the G number of transceiver unit group to acquire measurement result sets of the G number of transceiver unit groups, the measurement result set of each transceiver unit group including measurement results acquired by the receiving end device after receiving and measuring the beam training signals for the N number of transmission beams using each reception beam for the transceiver unit group; and a third selection sub-unit 80112 configured to select the measurement results of the G number of transceiver unit groups from the measurement result set of the G number of transceiver unit groups, the measurement results of each transceiver unit group including N measurement results, and the N measurement results including measurement results with best reception quality levels corresponding to each transmission beam in the measurement result sets of the transceiver unit group.']",39,359,schematic view,H,"[{'element_identifier': '801', 'terms': ['measurement module']}, {'element_identifier': '8012', 'terms': ['selection unit']}, {'element_identifier': '12', 'terms': ['receiving end device']}, {'element_identifier': '11', 'terms': ['transmitting end device']}, {'element_identifier': '804', 'terms': ['division module']}, {'element_identifier': '8011', 'terms': ['measurement unit']}, {'element_identifier': '802', 'terms': ['transmission module']}, {'element_identifier': '80112', 'terms': ['third selection sub-unit']}, {'element_identifier': '800', 'terms': ['receiving end device']}, {'element_identifier': '80111', 'terms': ['measurement sub-unit']}, {'element_identifier': '803', 'terms': ['selection module']}]","['17. A transmitting end device, comprising: a transmission module configured to transmit beam training signals for N number of transmission beams to a receiving end device, N being a positive integer; a reception module configured to receive identification information about Q number of transmission beams in the N number of transmission beams and group information about each transmission beam in the Q number of transmission beams from the receiving end device, the Q number of transmission beams comprising G number of transmission beam groups, the G number of transmission beam groups being acquired by the receiving end device in accordance with a measurement result, the measurement result being a measurement result acquired after the receiving end device has received and measured the beam training signals from the transmitting end device, Q and G being each a positive integer; and a first determination module configured to determine that a signal is capable of being transmitted simultaneously to the receiving end device via transmission beams in the Q number of transmission beams belonging to different transmission beam groups.', '25. The receiving end device according to claim 24, wherein the measurement module comprises: a measurement unit configured to receive and measure the beam training signal for each transmission beam in the N number of transmission beams from the transmitting end device using the G number of transceiver unit groups to acquire measurement results of the G number of transceiver unit groups, the measurement result of each transceiver unit group comprising a measurement result acquired after the receiving end device has received and measured the beam training signals for the N number of transmission beams using the transceiver unit group; and a selection unit configured to select the Q number of transmission beams from the N number of transmission beams in accordance with the measurement results of the G number of transceiver unit groups, and divide the Q number of transmission beams into the G number of transmission beam groups.', '28. The receiving end device according to any one of claims 25 to 27, wherein each transceiver unit group of the receiving end device comprises at least one transceiver unit, and each transceiver unit comprises at least one reception beam, wherein the measurement unit comprises: a measurement sub-unit configured to receive and measure the beam training signal for each transmission beam of the N number of transmission beams from the transmitting end device using each reception beam for the G number of transceiver unit group to acquire measurement result sets of the G number of transceiver unit groups, the measurement result set of each transceiver unit group comprising measurement results acquired by the receiving end device after receiving and measuring the beam training signals for the N number of transmission beams using each reception beam for the transceiver unit group; and a third selection sub-unit configured to select the measurement results of the G number of transceiver unit groups from the measurement result set of the G number of transceiver unit groups, the measurement results of each transceiver unit group comprising N measurement results, and the N measurement results comprising measurement results with best reception quality levels corresponding to each transmission beam in the measurement result sets of the transceiver unit group.', '29. The receiving end device according to any one of claims 23 to 27, further comprising: a selection module configured to select one reception beam for each of the Q number of transmission beams from candidate reception beams for the receiving end device; and a division module configured to divide transmission beams in each transmission beam group corresponding to a same reception beam into one transmission beam subgroup, wherein the transmission module is further configured to transmit the identification information about the Q number of transmission beams in the N number of transmission beams as well as the group information and subgroup information about each transmission beam in the Q number of transmission beams to the transmitting end device.']",True,"['800', '801', '8011', '80111', '80112', '8012', '802', '11', '800', '803', '804', '801', '802', '12', '38']" 651,EP_3598662_A1 (6).png,EP3598662A1,"TRANSMISSION WAVE BEAM DETERMINATION METHOD, TRANSMISSION END AND RECEPTION END","['FIG13', ' FIG14']","['FIG14 is still yet another schematic view showing the receiving end device according to some embodiments of the present disclosure ', 'FIG13 is yet another schematic view showing the transmitting end device according to some embodiments of the present disclosure']","['The present disclosure further provides in some embodiments a receiving end device which, as shown in FIG14, includes a processor 1400, a transceiver 1410, a memory 1420, a user interface 1430 and a bus interface. The processor 1400 is configured to read a program stored in the memory 1420, so as to: receive through the transceiver 1410 and measure beam training signals for N number of transmission beams from a transmitting end device, select Q number of transmission beams from the N number of transmission beams in accordance with a measurement result, and divide the Q number of transmission beams into G number of transmission beam groups, N, Q and G being each a positive integer; and transmit through the transceiver 1410 identification information about the Q number of transmission beams and group information about each transmission beam in the Q number of transmission beams to the transmitting end device, so as to enable the transmitting end device to determine that a signal is capable of being transmitted simultaneously to the receiving end device via transmission beams in the Q number of transmission beams belonging to different transmission beam groups. The transceiver 1410 is configured to receive and transmit data under the control of the processor 1400.', 'In FIG14, bus architecture may include a number of buses and bridges connected to each other, so as to connect various circuits for one or more processors 1400 and one or more memories 1420. In addition, as is known in the art, the bus architecture may be used to connect any other circuits, such as a circuit for a peripheral device, a circuit for a voltage stabilizer and a power management circuit. The bus interface may be provided, and the transceiver 1410 may consist of a plurality of elements, i.e., a transmitter and a receiver for communication with any other devices over a transmission medium. With respect to different UEs, the user interface 1430 may also be provided for devices which are to be arranged inside or outside the UE, and these devices may include but not limited to a keypad, a display, a speaker, a microphone and a joystick. The processor 1400 may take charge of managing the bus architecture as well as general processings. The memory 1420 may store therein data for the operation of the processor 1400. ', 'The present disclosure further provides in some embodiments a transmitting end device which, as shown in FIG13, includes a processor 1300, a transceiver 1310, a memory 1320, a user interface 1330 and a bus interface. The processor 1300 is configured to read a program stored in the memory 1320, so as to: transmit through the transceiver 1310 beam training signals for N number of transmission beams to a receiving end device, N being a positive integer; receive through the transceiver 1310 identification information about Q number of transmission beams in the N number of transmission beams and group information about each transmission beam in the Q number of transmission beams from the receiving end device, the Q number of transmission beams including G number of transmission beam groups, the G number of transmission beam groups being acquired by the receiving end device in accordance with a measurement result, the measurement result being a measurement result acquired after the receiving end device has received and measured the beam training signals from the transmitting end device, Q and G being each a positive integer; and determine that a signal is capable of being transmitted simultaneously to the receiving end device via transmission beams in the Q number of transmission beams belonging to different transmission beam groups. The transceiver 1310 is configured to receive and transmit data under the control of the processor 1300.', 'In FIG13, bus architecture may include a number of buses and bridges connected to each other, so as to connect various circuits for one or more processors 1300 and one or more memories 1320. In addition, as is known in the art, the bus architecture may be used to connect any other circuits, such as a circuit for a peripheral device, a circuit for a voltage stabilizer and a power management circuit. The bus interface may be provided, and the transceiver 1310 may consist of a plurality of elements, i.e., a transmitter and a receiver for communication with any other devices over a transmission medium. With respect to different UEs, the user interface 1330 may also be provided for devices which are to be arranged inside or outside the UE, and these devices may include but not limited to a keypad, a display, a speaker, a microphone and a joystick. The processor 1300 may take charge of managing the bus architecture as well as general processings. The memory 1320 may store therein data for the operation of the processor 1300.']",39,873,schematic view,H,"[{'element_identifier': '1300', 'terms': ['processor', 'processors']}, {'element_identifier': '14', 'terms': ['andFIG.']}, {'element_identifier': '1400', 'terms': ['processor', 'processors']}, {'element_identifier': '1310', 'terms': ['transceiver']}, {'element_identifier': '1410', 'terms': ['transceiver']}, {'element_identifier': '1420', 'terms': ['memory', 'memories']}]","['2. The transmission beam determination method according to claim 1, wherein the G number of transmission beam groups correspond to G number of transceiver unit groups of the receiving end device respectively.', '33. A transmitting end device, comprising a processor, a transceiver, a memory, a user interface and a bus interface, wherein the processor is configured to read a program stored in the memory, so as to implement the transmission beam determination method according to any one of claims 1 to']",True,"['1300', '320', '1310', '330', '13', '1400', '1420', '1410', '430', '14', '39']" 652,EP_3598669_A1 (1).png,EP3598669A1,MC-CDMA WITH LOW PEAK-TO-AVERAGE POWER RATIO MULTI-CARRIER WAVEFORM,['FIG2'],['FIG2 is a block diagram of a user device according to an embodiment of the present disclosure'],"['FIG2 shows one embodiment of a user device 102 for implementing the methods and modules described herein. The device 102 may include a processor 202, a memory 204, a power source 206 and a wireless communications interface 208 for sending and receiving data in the communications network 100, which components may or may not be arranged as shown in FIG2. The wireless communications interface 208 includes a transmitter 210 and a receiver 212 coupled to an antenna 214. It will be appreciated that the functions of the wireless communications interface 208 may be carried out by different transceiver or modem components including multiple transmitter, receiver, digital signal processor (DSP) and antenna components or arrays. In one embodiment, the user device 102 includes a user interface 220 and various inputs/outputs (I/O) 222 such as a display, audio input, audio output, keypads, buttons, microphones or other inputs or outputs. The memory 204 may store programming and/or instructions for the processor 202 including instructions for sending, receiving, processing and supporting different services and types of data, such as but not limited to video, VoIP calls, web browsing data, email and other text communications.']",17,221,block diagram,H,"[{'element_identifier': '210', 'terms': ['transmitter']}, {'element_identifier': '214', 'terms': ['antenna']}, {'element_identifier': '202', 'terms': ['processor']}, {'element_identifier': '18', 'terms': ['spreading sequences.Optional Embodiment']}, {'element_identifier': '220', 'terms': ['user interface']}, {'element_identifier': '208', 'terms': ['communications interface']}, {'element_identifier': '206', 'terms': ['power source']}, {'element_identifier': '204', 'terms': ['memory']}, {'element_identifier': '102', 'terms': ['devices', 'device']}, {'element_identifier': '212', 'terms': ['receiver']}]","['1. A method for operating a device in a wireless network, the method comprising: spreading data with a spreading sequence, using discrete Fourier transform-spread orthogonal division multiplexing, DFT-S-OFDM, to generate multi-carrier spread data on subcarriers corresponding to non-zero subcarrier elements of the spreading sequence, the spreading sequence having sparsity of non-zero subcarrier elements and an equal spacing between adjacent non-zero subcarrier elements; and transmitting the multi-carrier spread data, wherein the spreading sequence is selected from a plurality of spreading sequences, each spreading sequence of the plurality having a respective equal spacing between adjacent non-zero subcarrier elements, the spreading sequences of the plurality differing from one another in at least one of: sparsity level in the frequency domain; sparsity pattern in the frequency domain; and pulse offset in the time domain.', '9. A transmitter device comprising: a spreader configured to spread data with a spreading sequence, using discrete Fourier transform-spread orthogonal division multiplexing, DFT-S-OFDM, to generate multi-carrier spread data on subcarriers corresponding to non-zero subcarrier elements of the spreading sequence, the spreading sequence having sparsity of non-zero subcarrier elements and an equal spacing between adjacent non-zero subcarrier elements; and a transmitter configured to transmit the multi-carrier spread data, wherein the spreading sequence is selected from a plurality of spreading sequences, each spreading sequence of the plurality having a respective equal spacing between adjacent non-zero subcarrier elements, the spreading sequences of the plurality differing from one another in at least one of: sparsity level in the frequency domain; sparsity pattern in the frequency domain; and pulse offset in the time domain.']",False,"['102', '208', '210', '212', '214', '220', '222', '204', '206', '202', '18']" 653,EP_3598669_A1.png,EP3598669A1,MC-CDMA WITH LOW PEAK-TO-AVERAGE POWER RATIO MULTI-CARRIER WAVEFORM,['FIG1'],['FIG1 is a block diagram of a communications network according to an embodiment of the present disclosure'],"['FIG1 illustrates a communications network 100 comprising multiple user devices 102A, 102B, 102C, 102D and a network node 104. The network 100 may operate according to one or more communications or data standards or technologies including but not limited to fourth generation (4G) telecommunications networks such as Long-Term Evolution (LTE) networks, Universal Mobile Telecommunications System (UMTS) and other wireless or mobile communications networks. The user devices 102, sometimes known as user equipment (UEs), are generally any device capable of providing wireless communications such as a wireless transmit/receive unit (WTRU), mobile station (MS), smartphone, cellular telephone, sensor, or other wireless enabled computing or mobile device. In some embodiments, the user devices 102 comprise machines which perform other primary functions and have the capability to send, receive, or send and receive data in the communications network 100. In one embodiment, a machine includes an apparatus or device with means to transmit and/or receive data through the communications network 100 but such apparatus or device is not typically operated by a user for the primary purpose of communications. It will be appreciated that the systems and methods described herein also may be applied to other low data rate transmission scenarios or applications and devices operating with unscheduled data transmissions. The network node 104 may comprise a base station (BS), evolved Node B (eNB), access point (AP), or other network interface which functions as a transmission and/or reception point for user devices 102 in the network 100. The network node 104 is connected to a backhaul network 110 which enables data to be exchanged between the network node 104 and other remote networks, nodes and devices (not shown).']",17,326,block diagram,H,"[{'element_identifier': '17', 'terms': []}, {'element_identifier': '1', 'terms': ['Optional Embodiment']}, {'element_identifier': '100', 'terms': ['network']}, {'element_identifier': '104', 'terms': ['network node']}, {'element_identifier': '110', 'terms': ['backhaul network']}]","['1. A method for operating a device in a wireless network, the method comprising: spreading data with a spreading sequence, using discrete Fourier transform-spread orthogonal division multiplexing, DFT-S-OFDM, to generate multi-carrier spread data on subcarriers corresponding to non-zero subcarrier elements of the spreading sequence, the spreading sequence having sparsity of non-zero subcarrier elements and an equal spacing between adjacent non-zero subcarrier elements; and transmitting the multi-carrier spread data, wherein the spreading sequence is selected from a plurality of spreading sequences, each spreading sequence of the plurality having a respective equal spacing between adjacent non-zero subcarrier elements, the spreading sequences of the plurality differing from one another in at least one of: sparsity level in the frequency domain; sparsity pattern in the frequency domain; and pulse offset in the time domain.']",False,"['100', '104', '110', '1', '17']" 654,EP_3598674_A1 (4).png,EP3598674A1,"ENCODING METHOD, DECODING METHOD, APPARATUS AND DEVICE","['FIG10', ' FIG9']","['FIG10 is a structural diagram of a physical device according to an embodiment of this application ', 'FIG9 is a structural diagram of a virtual device according to an embodiment of this application']","['As shown in FIG10, this application further provides a communications device 1000. The communications device may be a base station or a terminal, or a DSP, an ASIC, or a chip that implements a related decoding function. The communications device 1000 further includes: ', 'It should be noted that an device 900 shown in FIG9 may implement processes such as steps 210 to 230. A first determining unit 910 is configured to perform step 210, a second determining unit 920 is configured to perform step 220, an encoding unit 930 is configured to perform an encoding process in step 230, and a processing unit 940 is configured to perform a shortening or puncturing process in step 230. The device 900 may be a base station BS or a mobile station MS, and the device may alternatively be an application-specific integrated circuit (English: Application Specific Integrated Circuit, ASIC for short), a digital signal processor (English: Digital Signal Processor, DSP for short), a system-on-a-chip, or software that implements related functions. If the device 900 is the ASIC, the DSP, or the system-on-a-chip, the components 910 to 940 may be circuits or parts. If the device 900 is the software, the components 910 to 940 may be program code.']",32,250,structural diagram,H,"[{'element_identifier': '1002', 'terms': ['memory']}, {'element_identifier': '900', 'terms': ['device']}, {'element_identifier': '1004', 'terms': ['bus']}, {'element_identifier': '920', 'terms': ['second determining unit']}, {'element_identifier': '940', 'terms': ['processing unit']}, {'element_identifier': '10', 'terms': ['andFIG.']}, {'element_identifier': '1001', 'terms': ['processor']}, {'element_identifier': '1000', 'terms': ['communications device']}, {'element_identifier': '1003', 'terms': ['part']}, {'element_identifier': '930', 'terms': ['encoding unit']}, {'element_identifier': '910', 'terms': ['components']}]","['11. A rate matching device, applied to a wireless network, wherein the device comprises: a first determining unit, configured to determine a transmission code rate R, wherein R=K/M, K is an information bit length, M is a target code length, and K and M are positive integers; a second determining unit, configured to: when the transmission code rate R is greater than a first code rate threshold, use a shortening mode for a bit sequence whose length is N, or when the transmission code rate R is less than the first code rate threshold, use a puncturing mode for a bit sequence whose length is N, wherein N is a mother code length, and N is a positive integer; an encoding unit, configured to polar encode the bit sequence whose length is N, to obtain a first encoded sequence whose length is N; and a processing unit, configured to shorten or puncture the first encoded sequence, to obtain a second encoded sequence whose length is M.', '23. A communications device, comprising: a memory, a processor, and a computer program that is stored on the memory and run on the processor, wherein when executing the program, the processor executes the method according to any one of claims 1 to']",True,"['910', '920', '930', '9', '940', '900', '1000', '1001', '1003', '1002', '1004', '10', '22']" 655,EP_3598720_A1 (3).png,EP3598720A1,METHOD AND DEVICE FOR GENERATING FORWARDING INFORMATION,"['FIG4', ' FIG5']","['FIG4 is a flowchart of a third network element for requesting a first content from a second network element in a method for generating forwarding information in the present application ', 'FIG5 is a schematic diagram of a structure of an implementation manner of a generating device in the present application']","['If a third network element also requests the first content in the second network element when the first network element requests the first content in the second network element, then the third network element may request the first content in the second network element by a method as shown in FIG4. The method of this implementation manner is illustrated by taking a generating device as a main body, which includes the following steps. ', 'See FIG5. FIG5 is a schematic diagram of a structure of an implementation manner of a generating device in the present application. The generating device in the implementation manner includes a receiving module 310, a determining module 320, a path generating module 330 and a flow table generating module 340.']",50,132,"flowchart, schematic diagram",H,"[{'element_identifier': '310', 'terms': ['receiving module']}, {'element_identifier': '5', 'terms': ['controller.Embodiment']}, {'element_identifier': '4', 'terms': ['different.Embodiment']}, {'element_identifier': '320', 'terms': ['determining module']}, {'element_identifier': '340', 'terms': ['flow table generating module']}, {'element_identifier': '330', 'terms': ['path generating module']}]","['9. A generating device, comprising: a receiving module, configured to receive a first request message used for requesting a first content for a first network element, wherein the first request message comprises a first content identifier; a determining module, configured to determine that a second network element is a provider of the first content according to first registration information sent by the second network element, wherein the first registration information comprises information indicating that the second network element is the provider of the first content; a path generating module, configured to determine a first path from the second network element to the first network element according to a network topology, wherein the first path comprises a first forwarding device; and a flow table generating module, configured to generate first forwarding information for the first forwarding device, wherein the first forwarding information comprising first matching information and first operating information, the first operating information is used for instructing to obtain a first encapsulation message according to a first data message after determining that the first data message matches the first matching information, and send the first encapsulation message to the first network element via the first path.']",True,"['4', '310', '320', '330', '340', '5', '25']" 656,EP_3598729_A1 (1).png,EP3598729A1,"IMAGE PROCESSING APPARATUS, CONTROL METHOD THEREOF, AND COMPUTER PROGRAM","['FIG2', ' FIG3']","['FIG3 is a diagram illustrating a recording head according to a first embodiment ', 'FIG2 is a block diagram illustrating a halftone processing unit according to the first embodiment']","['On the basis of the halftone image data, which is received from the image processing apparatus 10 through an input terminal 201, the image forming apparatus 20 forms an image on a recording medium such as recording paper by forming dots on the recording medium while moving the recording medium relative to a recording head 203. Here, the recording head 203 uses an ink jet recording method, and includes a recording-element array in which a plurality of recording elements capable of ejecting ink are arranged. FIG3 is a diagram illustrating an example of the configuration of the recording head 203. Although the recording head typically includes nozzles for four types of ink, namely cyan (C), magenta (M), yellow (Y), and black (K), only black (K) is illustrated for the sake of simplicity. The recording head is a long line head in which the nozzle arrangement covers the entire range of the rendering region in the recording medium width direction (the x direction), which is perpendicular to the recording medium feed direction (the y direction), and a printed image is formed by ejecting ink while moving the recording medium relative to the head once. A head drive unit 202 generates a drive signal for controlling the recording head 203 on the basis of the halftone image data. The recording head 203 records the actual ink dots on the recording medium, on the basis of the drive signal. It is assumed that the recording elements in the cyan (C), magenta (M), and yellow (Y) recording heads are arranged parallel to the black head that is illustrated. ', 'FIG2 is a block diagram illustrating the configuration of the halftone processing unit 103 in detail. The halftone processing unit 103 converts the image data stored in the input image buffer 102 into binary (1-bit) data for each nozzle group, and outputs the converted data. To achieve this processing, the halftone processing unit 103 includes a comparator 1031, a dither matrix 1032 (constituted by ROM or the like), and an output data generator 1033.']",28,395,"block diagram, diagram",G,"[{'element_identifier': '103', 'terms': ['halftone processing unit']}, {'element_identifier': '1031', 'terms': ['comparator']}, {'element_identifier': '1033', 'terms': ['output data generator']}, {'element_identifier': '1032', 'terms': ['dither matrix']}, {'element_identifier': '102', 'terms': ['input image buffer']}]","['1. An image processing apparatus that generates image data for an image forming apparatus, the image forming apparatus having a recording head in which a plurality of recording elements are arranged in a first direction, and that forms an image on a recording medium by ejecting ink from the recording elements of the recording head toward the recording medium while the recording medium is fed relatively in a second direction that is perpendicular to the first direction, the image processing apparatus comprising: acquiring means for acquiring multi-valued input image data; correction processing means for executing a density unevenness correction process in accordance with properties of each of the recording elements; and conversion means for converting the input image data into halftone image data indicating the presence/absence of a dot, by using a dither matrix, wherein the dither matrix is a dispersive dither matrix, and has characteristics in which when input image data having a uniform tone is converted into binary halftone image data, the same number of dots are present at each of locations in the first direction, in a predetermined range in the second direction, for a tone, among the tones which the input image data can take on, that is subject to the density unevenness correction process.']",True,"['2', '103', '102', '1033', '1031', '1032', '3', '290309002030500', '18']" 657,EP_3598744_A1.png,EP3598744A1,"PAN-TILT CONTROL METHOD, DEVICE AND SYSTEM","['FIG1', ' FIG2']","['FIG2 is a flowchart of a method for controlling a pan-tilt according to examples of the present disclosure ', 'FIG1 is a schematic structural diagram of a system for controlling a pan-tilt involved in a method for controlling a pan-tilt according to examples of the present disclosure']","['FIG2 is a flowchart of a method for controlling a pan-tilt according to examples of the present disclosure, applicable to the device for controlling a pan-tilt. As shown in FIG2, the method may include: ', 'FIG1 is a schematic structural diagram of a system for controlling a pan-tilt involved in a method for controlling a pan-tilt according to examples of the present disclosure. As shown in FIG1, the system for controlling a pan-tilt may include: a pan-tilt camera 101 and a signal source 102, wherein the pan-tilt camera 101 may include a pan-tilt 1011 and a camera 1012 attached to the pan-tilt 1011. The system for controlling a pan-tilt further includes: a device for controlling a pan-tilt (not shown in FIG1), which may be connected with the pan-tilt 1011 and the camera 1012 respectively and is configured to analyze monitored images shot by the camera 1012 so as to control the movement of the pan-tilt 1011. The monitored images are images obtained by the camera through shooting the monitored region.', 'Referring to FIG1, the pan-tilt camera may include a pan-tilt and a camera attached to the pan-tilt.']",52,236,"flowchart, schematic structural diagram",G,"[{'element_identifier': '201', 'terms': ['step']}, {'element_identifier': '1012', 'terms': ['camera']}, {'element_identifier': '203', 'terms': ['andstep']}, {'element_identifier': '1011', 'terms': ['pan-tilt']}, {'element_identifier': '101', 'terms': ['pan-tilt camera']}]","['1. A method for controlling a pan-tilt, used in a device for controlling a pan-tilt, the method comprising: detecting whether there is a signal source within a monitored region of a pan-tilt camera, the pan-tilt camera comprising a pan-tilt and a camera attached to the pan-tilt; judging, when there is a signal source within the monitored region, whether signals emitted from the signal source are position adjusting signals for indicating a position adjustment on the pan-tilt; and adjusting a position of the pan-tilt according to a position of the signal source when the signals emitted from the signal source are position adjusting signals.']",True,"['1011', '1012', '101', '4', '201', '202', '203', '2', '15']" 658,EP_3598758_A1 (5).png,EP3598758A1,ENCODER DECISIONS BASED ON RESULTS OF HASH-BASED BLOCK MATCHING,['FIG13'],['FIG13 is a diagram illustrating characteristics of blocks of natural video content and blocks of screen capture content'],"['FIG13 shows characteristics of typical blocks of natural video content and screen capture content, which depict the same general pattern. The block (1310) of natural video content includes gradually changing sample values and irregular lines. In contrast, the block (1320) of artificially-created video content includes sharper lines and patterns of uniform sample values. Also, the number of different color values varies between the block (1310) of natural video content and block (1320) of screen capture content. The block (1320) of screen capture content includes three colors, and the block (1310) of natural video content includes many more different colors.']",18,122,diagram,H,"[{'element_identifier': '14', 'terms': ['candidate block.Aspect']}, {'element_identifier': '1400', 'terms': ['technique']}, {'element_identifier': '1430', 'terms': ['encoder classifies']}, {'element_identifier': '1310', 'terms': ['block']}, {'element_identifier': '1410', 'terms': ['encoder measures']}, {'element_identifier': '1420', 'terms': ['encoder compares']}, {'element_identifier': '1440', 'terms': ['encoder classifies']}, {'element_identifier': '1320', 'terms': ['block']}, {'element_identifier': '13', 'terms': ['match.Aspect']}]","['1. A computer-implemented method comprising: encoding an image or video to produce encoded data, including: performing hash-based block matching for a current block of a current picture; using results of the hash-based block matching for the current block to determine whether to disable sample adaptive offset filtering for the current block, wherein the results of the hash-based block matching for the current block include whether a match is found during the hash-based block matching for the current block; and based on results of the determining, selectively disabling the sample adaptive offset filtering for the current block, including performing the sample adaptive offset filtering for the current block if no match is found during the hash-based block matching for the current block; and outputting the encoded data in a bitstream.']",True,"['13', '1300', '1310', '1320', '14', '1400', '1410', '1420', '1430', '1440', '40']" 659,EP_3598772_A1 (2).png,EP3598772A1,"PON CHANNEL ESTABLISHMENT METHOD, ONU, PLT AND SYSTEM",['FIG5'],['FIG5 is an exemplary flowchart of a method for establishing channels for a passive optical network according to an embodiment of the present disclosure'],"['FIG5 is an exemplary flowchart of a method for establishing channels for a passive optical network according to an embodiment of the present disclosure. As shown in FIG5, the method for establishing channels for a passive optical network provided in this embodiment is applied to an interaction between the ONU and the OLT. The OLT includes plural ports, each of which corresponding to one channel. Each channel uses one downlink wavelength and one uplink wavelength, and on each channel, one OLT port manages a group of ONUs. The group of ONUs transmit uplink data in a time division multiplexing access mode, and different groups of ONUs on different wavelength channels transmit data in a wavelength division multiplexing mode. One ONU can support data transmission and reception on plural channels simultaneously. The method may include the following steps 501-512:At step 501, the OLT sends registration messages to the ONU.']",24,165,flowchart,H,"[{'element_identifier': '511', 'terms': ['ONU normally. At step']}, {'element_identifier': '502', 'terms': ['step']}, {'element_identifier': '507', 'terms': ['ranging results. At step']}, {'element_identifier': '506', 'terms': []}, {'element_identifier': '508', 'terms': ['At step']}, {'element_identifier': '509', 'terms': ['downlink wavelength. At step']}, {'element_identifier': '501', 'terms': ['step']}, {'element_identifier': '504', 'terms': ['described herein. At step']}, {'element_identifier': '505', 'terms': ['OLT. At step']}, {'element_identifier': '510', 'terms': ['ONU itself. At step']}, {'element_identifier': '512', 'terms': ['OLT. At step']}, {'element_identifier': '503', 'terms': ['described herein. At step']}]","['3. The method according to claim 1, wherein the step of sending the message responding to the registration message to the OLT comprises: sending messages respectively responding to all of the intercepted registration messages to the OLT; and after sending the message responding to the registration message to the OLT, the method further comprises: receiving second parameter information sent from the OLT, the second parameter information comprising ONU identification information; wherein the second parameter information comprising the ONU identification information is configured by the OLT according to the messages respectively responding to all of the intercepted registration messages, and the messages respectively responding to all of the intercepted registration messages comprise the first parameter information for defining self-uniqueness.']",False,"['501', '502', '503', '504', '505', '506', '507', '508', '509', '510', '511', '512', '37']" 660,EP_3598772_A1 (5).png,EP3598772A1,"PON CHANNEL ESTABLISHMENT METHOD, ONU, PLT AND SYSTEM",['FIG11'],['FIG11 is an exemplary flowchart of a method for establishing channels for a passive optical network according to an embodiment of the present disclosure'],"['FIG11 is an exemplary flowchart of a method for establishing channels for a passive optical network according to an embodiment of the present disclosure. As shown in FIG11, the method for establishing channels for a passive optical network provided in this embodiment is applied to an interaction between the ONU and the OLT. The OLT includes plural ports, each of which corresponding to one channel. Each channel uses one downlink wavelength and one uplink wavelength and on each channel, one OLT port manages a group of ONUs. The group of ONUs transmit uplink data in a time division multiplexing access mode, and different groups of ONUs on different wavelength channels transmit data in a wavelength division multiplexing mode. One ONU can support data transmission and reception on plural channels simultaneously. The method may include the following steps 1101-1113:At step 1101, the OLT sends registration messages to the ONU.']",24,164,flowchart,H,"[{'element_identifier': '1104', 'terms': ['repeated herein. At step']}, {'element_identifier': '1107', 'terms': []}, {'element_identifier': '1111', 'terms': ['ONU itself. At step']}, {'element_identifier': '1112', 'terms': ['ONU normally. At step']}, {'element_identifier': '1113', 'terms': ['OLT. At step']}, {'element_identifier': '1109', 'terms': ['At step']}, {'element_identifier': '1101', 'terms': ['step']}, {'element_identifier': '1110', 'terms': ['downlink wavelength. At step']}, {'element_identifier': '1106', 'terms': ['repeated herein. At step']}, {'element_identifier': '1102', 'terms': ['OLT. At step']}, {'element_identifier': '1103', 'terms': ['repeated herein. At step']}, {'element_identifier': '1108', 'terms': ['ranging results. At step']}, {'element_identifier': '1105', 'terms': ['step']}]","['3. The method according to claim 1, wherein the step of sending the message responding to the registration message to the OLT comprises: sending messages respectively responding to all of the intercepted registration messages to the OLT; and after sending the message responding to the registration message to the OLT, the method further comprises: receiving second parameter information sent from the OLT, the second parameter information comprising ONU identification information; wherein the second parameter information comprising the ONU identification information is configured by the OLT according to the messages respectively responding to all of the intercepted registration messages, and the messages respectively responding to all of the intercepted registration messages comprise the first parameter information for defining self-uniqueness.']",False,"['1101', '1102', '1103', '1104', '1105', '1106', '1107', '1108', '1109', '1110', '1111', '1112', '1113', '40']" 661,EP_3598797_A1 (1).png,EP3598797A1,"METHOD AND DEVICE FOR DATA TRANSMISSION, AND COMPUTER STORAGE MEDIUM","['FIG3', ' FIG5']","['FIG5 is a schematic structural diagram of a data transmission apparatus applied to the UE according to embodiment 1 of the present application ', 'FIG3 is a schematic diagram of DU switching under the control of an identical CU in related technology']","['A data transmission apparatus, applied to the source DU, as shown in FIG5, includes:a triggering unit 51, used for reporting the PDCP transmission status report to the CU, and the PDCP transmission status report enables the CU to determine which PDCP PDU data is not successfully received by the UE and retransmit the PDCP PDU data which is not successfully received by the UE to the UE via the target DU. ', 'As shown in FIG3, due to the centralized deployment of CU, a CU of a serving cell may connect multiple DUs, and when a user moves from a service range of one DU controlled by a current CU to a service range of another DU controlled by the current CU, the user needs to switch from a current DU to a target DU. And this DU switching under the control of an intra-CU may be frequent because DUs are densely deployed.']",41,168,"schematic diagram, schematic structural diagram",H,"[{'element_identifier': '51', 'terms': ['triggering unit']}, {'element_identifier': '5', 'terms': ['transmission flow in embodiment']}, {'element_identifier': '3', 'terms': ['option']}, {'element_identifier': '4', 'terms': ['transmission flow in embodiment']}, {'element_identifier': '402', 'terms': ['UE. In step']}, {'element_identifier': '401', 'terms': ['described below. In step']}]","['2. A data transmission apparatus, comprising: a triggering unit, configured to report a packet data convergence protocol, PDCP, transmission status report to a centralized unit, CU, wherein the PDCP transmission status report enables the CU to determine which PDCP protocol data unit, PDU, data is not successfully received by a UE and retransmit the PDCP PDU data which is not successfully received by the UE to the UE via a target distributed unit, DU.']",True,"['3', '401', '402', '4', '51', '5', '16']" 662,EP_3598807_A1.png,EP3598807A1,"METHOD FOR CONTROLLING THE ACTIVITY OF A BASE STATION ENTITY IN A MOBILE COMMUNICATION NETWORK, BASE STATION ENTITY, MOBILE COMMUNICATION NETWORK AND PROGRAM COMPRISING A COMPUTER READABLE PROGRAM CODE",['FIG1'],['FIG1 schematically illustrates a mobile communication network comprising a base station entity and a mobile device '],"[""In FIG1, a mobile communication network 10 is schematically shown having a base station entity 11. The base station entity 11 typically comprises a transmitter chain and a receiver chain (or components providing the transmitting functionality of the base station entity, and components providing the transmitting functionality of the base station entity), and has a radio coverage area 11' and a mobile device 20 is depicted being located within the radio coverage area 11' of the base station entity 11. The base station entity 11 is able to be operated in at least a first operational mode and a second operational mode. The first operational mode corresponds to the base station entity 11 transmitting radio frequency signals such that a control channel is received in the radio coverage area 11' of the base station entity 11 by the mobile device 20. This corresponds to the normal (and standardized) behaviour and situation of both the mobile device 20 and the base station entity 11. According to the present invention, the base station entity is able to be operated in the second operational mode which corresponds to the base station entity 11 being at least partly switched off. This means that at least during power saving time intervals the control channel is not provided in the radio coverage area 11' of the base station entity 11 as the transmitter chain of the of base station entity 11 is switched off (or is deactivated) in the second operational mode. According to the normal (standardized) behaviour of the mobile device 20 and the base station entity 11 (or the mobile communication network 10), the mobile device 20 interprets this situation as a situation where a specific requested service of the mobile communication network 10 is not available and an attachment, e.g. to a high bitrate Packet Switched (PS) service, is not possible. According to the present invention, also the receiver chain of the base station entity 11 is switched off (or is deactivated) (during the second operational mode) at least during a predetermined inactivation time interval. During a predetermined sensitive time interval (during the second operational mode of the base station entiy), the receiver chain is switched on (or is activated).""]",16,410,schematic,H,"[{'element_identifier': '11', 'terms': ['base station entity']}, {'element_identifier': '22', 'terms': ['second reactivation information']}, {'element_identifier': '1', 'terms': ['aspect']}, {'element_identifier': '20', 'terms': ['mobile device']}, {'element_identifier': '10', 'terms': ['mobile communication network']}, {'element_identifier': '21', 'terms': ['first reactivation information']}]","[""1. Method for controlling the activity of a base station entity (11) in a mobile communication network (10) by means of a mobile device (20), wherein the base station entity (11) is able to be operated in at least a first and a second operational mode, wherein the base station entity (11) comprises a transmitter chain and a receiver chain, wherein the first operational mode corresponds to the base station entity (11) transmitting radio frequency signals such that a control channel is received in a radio coverage area (11') of the base station entity (11) by the mobile device (20), wherein the second operational mode corresponds to the base station entity (11) -- switching off the transmitter chain for only parts related to certain transmission channels of the base station entity (11), and not providing the control channel in the radio coverage area (11') of the base station entity (11), -- switching off the receiver chain of the base station entity (11) for a predetermined inactivation time interval, and -- switching on the receiver chain of the base station entity (11) for a predetermined sensitive time interval, wherein the method comprises the following steps: -- in a first step, the mobile device (20) receives a first reactivation information (21) from the base station entity (11), wherein an activated broadcast control channel to transmit the first reactivation information (21) is temporarily provided for some periods of time by the base station entity (11), the first reactivation information (21) being related to the possibility and/or to the manner for the mobile device (20) to activate the first operational mode of the base station entity (11) starting from the second operational mode of the base station entity (11), -- in a second step, the mobile device (20) transmits a second reactivation information (22) to the base station entity (11) during the predetermined sensitive time interval of the base station entity (11), wherein dependent on a reception of the second reactivation information (22) by the base station entity (11) the first operational mode of the base station entity (11) is applied, wherein the second reactivation information (22) is a message or signal compliant to a communication on a Random Access Channel, RACH, of the base station entity (11).""]",False,"['10', '11', '22', '21', '20', '1', '15']" 663,EP_3598816_A1 (5).png,EP3598816A1,USER TERMINAL AND RADIO COMMUNICATION METHOD,['FIG9'],['FIG9 is a diagram showing one example of a schematic configuration of a radio communication system according to this Embodiment'],"['FIG9 is a diagram showing one example of a schematic configuration of the radio communication system according to this Embodiment. In the radio communication system 1, it is possible to apply carrier aggregation (CA) to aggregate a plurality of base frequency blocks (component carriers) with a system bandwidth (e.g., 20 MHz) of the LTE system as one unit and/or dual connectivity (DC).']",20,74,diagram,H,"[{'element_identifier': '30', 'terms': ['higher station apparatus']}, {'element_identifier': '10', 'terms': ['radio base station']}, {'element_identifier': '20', 'terms': ['user terminal', 'user terminals']}, {'element_identifier': '40', 'terms': ['core network']}]","['1. A user terminal comprising: a receiving section that monitors downlink control channels transmitted in a plurality of different time regions and/or frequency regions to receive downlink control information (DCI); and a control section that controls reception and/or transmission of data scheduled by the DCI, wherein the control section controls reception timing and/or transmission timing of the data, based on at least timing information included in the DCI.']",False,"['40', '30', '10', '10', '20', '10', '28']" 664,EP_3598816_A1 (6).png,EP3598816A1,USER TERMINAL AND RADIO COMMUNICATION METHOD,['FIG10'],['FIG10 is a diagram showing one example of an entire configuration of a radio base station according to this Embodiment'],"['FIG10 is a diagram showing one example of an entire configuration of the radio base station according to this Embodiment. The radio base station 10 is provided with a plurality of transmitting/receiving antennas 101, amplifying sections 102, transmitting/receiving sections 103, baseband signal processing section 104, call processing section 105, and communication path interface 106. In addition, with respect to each of the transmitting/receiving antenna 101, amplifying section 102, and transmitting/receiving section 103, the radio base station may be configured to include at least one or more.']",20,106,diagram,H,"[{'element_identifier': '103', 'terms': ['transmitting/receiving section', 'transmitting/receiving sections']}, {'element_identifier': '30', 'terms': ['higher station apparatus']}, {'element_identifier': '104', 'terms': ['section']}, {'element_identifier': '105', 'terms': ['call processing section']}, {'element_identifier': '102', 'terms': ['amplifying section', 'amplifying sections']}, {'element_identifier': '10', 'terms': ['radio base station']}, {'element_identifier': '106', 'terms': ['communication path interface']}]","['1. A user terminal comprising: a receiving section that monitors downlink control channels transmitted in a plurality of different time regions and/or frequency regions to receive downlink control information (DCI); and a control section that controls reception and/or transmission of data scheduled by the DCI, wherein the control section controls reception timing and/or transmission timing of the data, based on at least timing information included in the DCI.']",False,"['106', '104', '105', '103', '103', '102', '102', '30', '10', '29', '10']" 665,EP_3598828_A1 (3).png,EP3598828A1,"DATA TRANSMISSION METHOD, RESOURCE SCHEDULING METHOD, APPARATUS, TERMINAL, AND NETWORK SIDE DEVICE","['FIG7', ' FIG8']","['FIG7 is a block diagram of an apparatus used for a data transmission method according to an exemplary embodiment ', 'FIG8 is a block diagram of an apparatus used for a resource scheduling method according to an exemplary embodiment ']","['FIG7 is a block diagram of an apparatus 700 used for a data transmission method according to an exemplary embodiment. The apparatus 700 may be a terminal. As shown in the figure, the apparatus 700 may include: a processor 701, a memory 702, and a communication component 705. ', 'FIG8 is a block diagram of an apparatus 800 used for a resource scheduling method according to an exemplary embodiment. The apparatus 800 may be a network-side device. As shown in the figure, the apparatus 800 may include: a processor 801, a memory 802, and a communication component 805.']",38,113,block diagram,H,"[{'element_identifier': '8', 'terms': ['andFig.']}, {'element_identifier': '801', 'terms': ['processor']}, {'element_identifier': '704', 'terms': ['I/O interface']}, {'element_identifier': '705', 'terms': ['communication component']}, {'element_identifier': '805', 'terms': ['communication component']}, {'element_identifier': '20', 'terms': ['be about']}, {'element_identifier': '701', 'terms': ['processor']}, {'element_identifier': '702', 'terms': ['memory']}, {'element_identifier': '802', 'terms': ['memory']}, {'element_identifier': '703', 'terms': ['multimedia component']}, {'element_identifier': '800', 'terms': ['apparatus']}, {'element_identifier': '700', 'terms': ['apparatus']}]","['10. A data transmission apparatus applied to a terminal, comprising: an information sending module, configured to send, to a network-side device, an operating band information list supported by the terminal and capability indication information indicating whether the terminal supports simultaneous data sending and data receiving in an operating band in the operating band information list, wherein the operating band information list is used by the network-side device to determine an actual operating band of the terminal, the actual operating band comprises at least one pair of an uplink frequency range and a downlink frequency range, and the capability indication information is used by the network-side device to determine a scheduling strategy for the terminal; and a data transmission module, configured to perform, when the terminal has a data service requirement, data transmission based on the actual operating band that is determined by the network-side device and comprises the at least one pair of the uplink frequency range and the downlink frequency range, and scheduling information corresponding to the scheduling strategy determined by the network-side device.']",True,"['700', '703', '701', '702', '704', '705', '7', '800', '801', '802', '805', '8', '20']" 666,EP_3598828_A1.png,EP3598828A1,"DATA TRANSMISSION METHOD, RESOURCE SCHEDULING METHOD, APPARATUS, TERMINAL, AND NETWORK SIDE DEVICE","['FIG1', ' FIG2']","['FIG1 is a schematic diagram of a wireless communication network according to an embodiment of the present disclosure ', 'FIG2 is a schematic flowchart of performing data transmission by a terminal according to an embodiment of the present disclosure']","['FIG1 is a schematic diagram of a wireless communication network according to an embodiment of the present disclosure. The wireless communication network 100 includes: a network-side device 101 and a terminal 102. The network-side device 101 is a device that communicates with the terminal 102, and may provide communication coverage over a particular physical area. The network-side device 101 may be a base station (BS), a certain network element of a core network, another access network device providing an access service and that is in the wireless communication network, or the like. ', 'FIG2 is a schematic flowchart of performing data transmission by a terminal according to an embodiment of the present disclosure.', 'Referring to FIG2, in an embodiment of the present disclosure, in step S21, the terminal sends, to a network-side device, an operating band information list supported by the terminal and capability indication information indicating whether the terminal supports simultaneous data sending and data receiving on an operating band in the operating band information list. The operating band information list is used by the network-side device to determine an actual operating band of the terminal (that is, an operating band used by the terminal to perform data transmission), and the actual operating band includes at least one pair of an uplink frequency range and a downlink frequency range. The capability indication information is used by the network-side device to determine a scheduling strategy for the terminal. The scheduling strategy is subsequently described in detail.']",38,283,"schematic diagram, schematic flowchart",H,"[{'element_identifier': '2', 'terms': ['Table']}, {'element_identifier': '102', 'terms': ['terminal']}, {'element_identifier': '101', 'terms': ['network-side device']}, {'element_identifier': '1', 'terms': ['band']}]","['1. A data transmission method applied to a terminal, comprising: sending, to a network-side device, an operating band information list supported by the terminal and capability indication information indicating whether the terminal supports simultaneous data sending and data receiving on an operating band in the operating band information list, wherein the operating band information list is used by the network-side device to determine an actual operating band of the terminal, the actual operating band comprises at least one pair of an uplink frequency range and a downlink frequency range, and the capability indication information is used by the network-side device to determine a scheduling strategy for the terminal; and performing, when the terminal has a data service requirement, data transmission based on the actual operating band that is determined by the network-side device and that comprises the at least one pair of the uplink frequency range and the downlink frequency range, and scheduling information corresponding to the scheduling strategy determined by the network-side device.']",True,"['101', '102', '102', '102', '101', '101', '1', '2', '17']" 667,EP_3598833_A1 (2).png,EP3598833A1,COMMUNICATION METHOD AND APPARATUS,['FIG5'],"['FIG5 shows an example of a schematic structural diagram of a media access control-control element (Media Access Control-Control Element, MAC CE for short) according to an embodiment of this application']","['In an embodiment, a new MAC CE format in an Msg2 is defined to carry a plurality of random backoff indicators corresponding to a plurality of random access groups. FIG5 shows an example of a MAC CE that carries random backoff indicators corresponding to five random access groups. BI-0 to BI-4 in the MAC CE are random backoff indicators respectively corresponding to a random access group 0 to a random access group 4. Optionally, quantities of bits occupied by the random backoff indicators are the same. A correspondence between a random backoff indicator included in the MAC CE and a random access group may be stipulated, for example, five random access groups are used as an example. In this case, the random backoff indicators included in the MAC CE sequentially correspond to the five random access groups in a stipulated order. A correspondence is shown in FIG5.', 'For another example, the base station may add a plurality of random backoff indicators corresponding to a plurality of logical channels or logical channel groups to the Msg2, and return the Msg2 to the terminal. One or more logical channels or logical channel groups correspond to one random backoff indicator. A MAC CE format in the Msg2 may be shown in FIG5. In another embodiment, the MAC CE in the Msg2 carries one random backoff indicator. A random backoff indicator (random backoff time) corresponding to each random access logical channel or logical channel group may be obtained through calculation in the following manner: using the random backoff indicator included in the MAC CE as a reference value, and multiplying a random access time coefficient corresponding to the random access logical channel or logical channel group, to obtain the random backoff time corresponding to the random access logical channel or logical channel group. A value range of the random access time coefficient may be set to (0, 1), in other words, the random access time coefficient is greater than 0 and less than 1.']",37,362,schematic,H,"[{'element_identifier': '5', 'terms': ['Table']}, {'element_identifier': '2', 'terms': ['random access group', 'logical channel']}, {'element_identifier': '701', 'terms': ['sending module']}, {'element_identifier': '702', 'terms': ['receiving module']}, {'element_identifier': '3', 'terms': ['Table', 'solution']}]","['2. The method according to claim 1, wherein the random access parameter set further comprises a random access preamble sequence, and the random access request comprises the random access preamble sequence; and after the receiving, by the base station, a random access request of the terminal in a connected mode or an inactive mode, the method further comprises: returning, by the base station, a random access response to the terminal, wherein the random access response comprises indication information of an uplink resource allocated to the terminal, the uplink resource is allocated by the base station based on a scheduling message size threshold value corresponding to a random access group, and the random access group is a random access group corresponding to the random access preamble sequence sent by the terminal.', '11. Abase station, comprising: a sending module, configured to send, by using dedicated signaling, at least one random access parameter set to a terminal in a connected mode or an inactive mode; and a receiving module, configured to receive a random access request of the terminal in a connected mode or an inactive mode, wherein one of the at least one random access parameter set is used in the random access request, and the random access parameter set comprises monitoring start time and/or a time window size of a random access response time window.']",True,"['2', '3', '5', '6', '701', '702', '7', '27']" 668,EP_3598833_A1 (4).png,EP3598833A1,COMMUNICATION METHOD AND APPARATUS,['FIG11'],['FIG11 shows an example of a schematic structural diagram of a base station according to another embodiment of this application'],"['Based on a same technical conception, an embodiment of this application further provides a base station. FIG11 shows an example of a structure of the base station.', 'As shown in FIG11, the network element includes a communications interface 1101, a processor 1102, and a memory 1103. The memory 1103 is configured to store program code that needs to be executed by the processor 1102. The communications interface 1101 performs message exchange. The processor 1102 is configured to execute the program code stored in the memory, and is specifically configured to perform the method performed on the base station side in the foregoing embodiment.', 'In this embodiment of this application, a specific connection medium among the communications interface 1101, the processor 1102, and the memory 1103 is not limited. In this embodiment of this application, the memory 1103, the processor 1102, and the communications interface 1101 are connected by using a bus 1104 in FIG11. The bus is represented by using a thick line in FIG11. A manner of connection between other components is merely an example for description, and imposes no limitation. The bus may be classified into an address bus, a data bus, a control bus, and the like. For ease of representation, only one thick line is used to represent the bus in FIG11, but this does not mean that there is only one bus or only one type of bus.']",20,264,schematic,H,"[{'element_identifier': '1104', 'terms': ['bus']}, {'element_identifier': '1002', 'terms': ['sending module']}, {'element_identifier': '1101', 'terms': ['communications interface']}, {'element_identifier': '1001', 'terms': ['receiving module']}, {'element_identifier': '1102', 'terms': ['processor']}, {'element_identifier': '1103', 'terms': ['memory']}]","['11. Abase station, comprising: a sending module, configured to send, by using dedicated signaling, at least one random access parameter set to a terminal in a connected mode or an inactive mode; and a receiving module, configured to receive a random access request of the terminal in a connected mode or an inactive mode, wherein one of the at least one random access parameter set is used in the random access request, and the random access parameter set comprises monitoring start time and/or a time window size of a random access response time window.', '21. Abase station, comprising a memory and a processor, wherein the memory is configured to store program code that needs to be executed by the processor, and the processor is configured to execute the program code stored in the memory, so that the base station performs the method according to any one of claims 1 to']",True,"['1001', '1002', '10', '1101', '1102', '1104', '1103', '11', '29']" 669,EP_3598934_A1 (4).png,EP3598934A1,"BIOMETRIC INFORMATION DETECTION DEVICE AND METHOD OF PRODUCING THE SAME, AND BIOMETRIC INFORMATION DETECTION MODULE AND METHOD OF PRODUCING THE SAME","['FIG7', ' FIG8']","['FIG8 is a cross-sectional view showing a schematic configuration example of a biometric information detection device as Modified Example 2 of the present disclosure ', 'FIG7 is a cross-sectional view showing a schematic configuration example of a biometric information detection device as Modified Example 1 of the present disclosure']","['FIG8 is a cross-sectional view showing a schematic configuration of a biometric information detection device 1B as Modified Example 2 of the present disclosure. In the biometric information detection device 1B, a strain sensor 31 is embedded in a part of the shell 10 covering a crown part TA of the teeth T. The strain sensor 31 is connected to the battery 6 through a power line and is connected to the signal processing unit 4 through a communication line. The strain sensor 31 receives supply of power from the battery 6 and transmits a detection signal to the signal processing unit 4. Except for these points, the biometric information detection device 1B has substantially the same configuration as the biometric information detection device 1 of the above embodiment. Therefore, also in the biometric information detection device 1B, the same effects as in the biometric information detection device 1 of the above embodiment are obtained. Moreover, when the strain sensor 31 is provided, it is possible to measure the biting strength when the teeth of the upper jaw and the teeth of the lower jaw of a subject are engaged and the pressure of the cheek or tongue of a subject in contact with the strain sensor 31. When information such as the biting strength and the pressure of the cheek and tongue is used, it is possible to obtain structural strength information and teeth alignment information necessary for artificial teeth, for example, dentures and implants. Here, as the strain sensor 31, for example, a magnetostriction sensor using magnetostriction can be applied. In addition, a pressure sensor using a piezoelectric element or the like can be applied in place of the strain sensor 31. ', 'The biometric information detection device 1 of the above embodiment emits light to the gums G, receives light reflected from the gums G, and thus detects biometric information. On the other hand, a biometric information detection device 1A of Modified Example 1 of the present disclosure shown in FIG7 emits light to an inner surface of a cheek CH in the oral cavity, receives light reflected from the inner surface of the cheek CH, and thus detects biometric information. In the biometric information detection device 1A, the light emitting element 5A is disposed to face the cheek CH with the first light-transmitting part 10T1 therebetween, and the light receiving element 5B is disposed near the light emitting element 5A so that it faces the cheek CH with the second light-transmitting part 10T2 therebetween. Therefore, the light-transmitting part 10T of the lower part 10B of the shell 10 covering the biometric information detection module 2 is provided on the side opposite to the gums G with the biometric information detection module 2 therebetween. Except for these points, the biometric information detection device 1A has substantially the same configuration as the biometric information detection device 1 of the above embodiment. Also in the biometric information detection device 1A, the same effects as in the biometric information detection device 1 of the above embodiment are obtained. For example, the biometric information detection device 1A of this modified example is beneficial when it is determined that a surface structure of the gums G of a subject is not favorable and it is difficult to obtain stable biometric information.']",52,597,cross-sectional view,A,"[{'element_identifier': '8', 'terms': ['receiving module']}, {'element_identifier': '7', 'terms': ['network connector']}, {'element_identifier': '14', 'terms': ['molding.']}, {'element_identifier': '10', 'terms': ['shell']}, {'element_identifier': '31', 'terms': ['strain sensor']}]","['12. A method of producing a biometric information detection device installed in the oral cavity, comprising: preparing a sensor including a light emitting element that is able to emit light and a light receiving element that is able to receive the light emitted from the light emitting element; after inserting the sensor between a pair of sealing films, heating and molding the pair of sealing films, and thereby forming a sealing member with which the sensor is sealed; and forming a holding member that is attached to at least one of the teeth and the gums and holds the sealing member.']",True,"['7', '10', '8', '31', '10', '14']" 670,EP_3598952_A2 (3).png,EP3598952A2,SYSTEMS AND METHODS FOR CREATING CURVED PATHS THROUGH BONE AND MODULATING NERVES WITHIN THE BONE,['FIG30'],['FIG30 is a top view of an embodiment of the slotted trocar of FIG27'],"['To ensure proper trajectory of the probe 550 in one embodiment, the indicia arrows (not shown) of the probe handle 552 may be lined up in the same direction as indicia arrows 540 (FIG30) on the trocar handle 522. In some embodiments, other indicia may be used (e.g., slots, lines, notches, ribs, or laser markings, or combinations thereof).']",14,74,view,A,"[{'element_identifier': '534', 'terms': ['recess']}, {'element_identifier': '30', 'terms': ['about']}, {'element_identifier': '522', 'terms': ['handle']}, {'element_identifier': '536', 'terms': ['handle']}, {'element_identifier': '29', 'terms': []}, {'element_identifier': '540', 'terms': ['Indicia', 'direction as indicia arrows']}, {'element_identifier': '532', 'terms': ['surface']}, {'element_identifier': '530', 'terms': ['slot']}, {'element_identifier': '528', 'terms': ['channel']}, {'element_identifier': '520', 'terms': ['trocar']}, {'element_identifier': '524', 'terms': ['hypotube']}]","['1. A system configured for navigation within and denervation of a vertebral body, the system comprising: an introducer comprising a proximal end, a distal end and a central channel, wherein the central channel extends from the proximal end toward the distal end, wherein the introducer comprises a distal opening at or near the distal end of the introducer, the distal opening being in communication with the central channel; a cannula sized to be received in said central channel and delivered from the proximal end of the introducer toward said distal opening of the introducer, wherein the cannula comprises a straight proximal body and a pre-curved or steerable distal end, wherein the distal end of the cannula is configured to be extended laterally outward from the distal opening in a curved path extending away from the introducer, wherein the cannula comprises a central passageway having a diameter configured to allow a treatment or diagnostic device to be delivered through the central passageway to a location beyond the curved path, and wherein the proximal end of the introducer comprises a handle comprising: a proximal recess, wherein the proximal recess is in communication with the central channel of the introducer to allow reciprocation of the cannula within the central channel of the introducer; and a lateral slot in communication with said proximal recess, the lateral slot extending radially outward from the proximal recess at a proximal surface of the handle, wherein the lateral slot is configured to allow insertion of the cannula such that a central axis of the straight proximal body is at an angle with respect to a central axis of the introducer when the distal end of the cannula is inserted into the proximal recess, wherein the lateral slot is configured to allow the distal end of the cannula to be slideably advanced into the proximal recess and the central channel without having to pre-straighten the cannula, and wherein a curvilinear surface of the lateral slot comprises a radius of curvature adapted to conform to a radius of curvature of the distal end of the cannula.', '7. The system of claim 6, wherein the handle of the introducer and the handle of the cannula comprise corresponding indicia that are adapted to be aligned when in use.', '15. A system for delivering a self-guided treatment device into bone, the system comprising: a trocar comprising a proximal end, distal end and a central channel; wherein the central channel is disposed along a central axis of the trocar and extends from the proximal end toward the distal end; wherein the trocar comprises a distal opening at or near the distal end of the trocar, the distal opening being in communication with the central channel; and a treatment probe; the treatment probe sized to be received in said central channel and delivered from the proximal end toward said distal opening; the treatment probe comprising a stylet comprising a straight proximal end and a curved distal end; the curved distal end being deformable so as to be delivered in a straight configuration through the trocar and deployed in a curved configuration outward from the distal opening at an angle with respect to the central axis of the trocar; wherein the curved distal end comprises a treatment device configured to deliver a therapeutic dose of energy to a treatment location.']",True,"['534', '530', '532', '522', '520', '536', '528', '520', '522', '534', '540', '530', '528', '30', '540', '524', '29', '71']" 671,EP_3598991_A1 (4).png,EP3598991A1,LOW-FLOW OXYGEN THERAPY HUMIDIFIER AND METHOD,['FIG6C'],"['FIG6C depicts a sectional view, at line A-A, of the embodiment depicted in FIG6A, showing an embodiment of reservoir 202, wherein the reservoir is in a first state']","['A plurality of retainers 638 extend inwardly into region 636. In some embodiments, retainers 638 are coupled to frame 631. More particularly, in some embodiments, retainers 638 attach directly to frame 631; in some other embodiments, the retainers are attached to a fixture (not depicted) that attaches to frame 631. In some embodiments, the fixture has the same shape as the frame, and has dimensions suitable for overlying (or underlying) frame 631. Retainers 638 receive WVP membrane 206 and maintain it in a predefined position. As depicted in FIG6C through 6F, in some embodiments, the predefined position of WVP membrane 206 is proximal to the ""bottom"" of the reservoir. The retainers are thus another structural adaptation that, in conjunction with the collapsibility of the reservoir, ensures that WVP membrane 206 remains at least partially in contact with liquid water regardless of the orientation of reservoir/cartridge.', 'As depicted most clearly in FIG6C through 6F, membranes 650 and 652, in conjunction with open region 636 as well as the inner surfaces of frame 631, collectively form reservoir 402, which is an implementation of reservoir 202. In some embodiments, both impermeable membranes 650 and 652 comprise urethanes.']",34,228,sectional view,A,"[{'element_identifier': '206', 'terms': ['membrane']}, {'element_identifier': '652', 'terms': ['membrane', 'membranes']}, {'element_identifier': '631', 'terms': ['frame']}, {'element_identifier': '402', 'terms': ['reservoir']}, {'element_identifier': '632', 'terms': ['""bottom"" surface']}, {'element_identifier': '638', 'terms': ['retainers']}]","['1. A humidification system for use with low-flow oxygen therapy, the humidification system comprising: a reservoir, wherein the reservoir receives a volume of liquid water, and further wherein a liquid capacity of the reservoir is alterable such that instantaneous liquid capacity of the reservoir is substantially equal to instantaneous volume of liquid water in the reservoir; and a tube comprising a water-vapor-permeable (WVP) membrane, wherein a major portion of the tube is contained in the reservoir.']",True,"['638', '421', '63', '631', '632', '652', '402', '206', '65', '206', '22']" 672,EP_3598991_A1 (5).png,EP3598991A1,LOW-FLOW OXYGEN THERAPY HUMIDIFIER AND METHOD,['FIG8'],"['FIG8 depicts a side view of humidification system 800, which is an embodiment of humidification system 100 of FIG2']","['In some embodiments, another structural adaptation the enables reservoir 202 to adapt its volume to the amount of liquid water present is an arrangement that applies a constant positive pressure to reservoir 202 (see, e.g., FIG8). In addition to its applicability to the aforementioned embodiments of reservoir 202, embodiments that include an arrangement for applying positive pressure can utilize a reservoir formed from two spaced-apart membranes and a frame wherein the upper membrane comprises a resilient material. The membrane will be capable of expanding to accommodate a maximum volume of water and, as liquid water in the reservoir decreases, the surface of the membrane will be capable of being forced ""downward"" (i.e., toward the ""bottom"" of the reservoir) due to the positive pressure, thereby reducing the volume of the reservoir.', 'FIG8 depicts humidification system 800, which is a further embodiment of humidification system 100. The salient features of system 800 include, in addition to the elements present in other embodiments discussed herein (e.g., reservoir 202, WVP membrane 206, an enclosure or housing, such as housing 420, 420\', or 420"", etc.), means 860 for applying positive pressure to the upper surface of reservoir 202. This is a further structural adaptation that may be used to promote collapse of reservoir 202 so that WVP membrane 206 remains in contact with liquid water.', 'In the embodiment depicted in FIG8, means 860 for applying positive pressure to reservoir 202 includes pressure plate 862 and resilient elements 864. The resilient elements are preloaded by compressing them between pressure plate 864 and the inside of the housing. The resilient elements therefore apply a force against pressure plate 864. Because liquid water is non-compressible, the water resists the applied pressure. However, as water evaporates and passes into WVP membrane 206, the pressure applied against reservoir 202 ensures that the volume of the reservoir will be no greater than is required to accommodate the remaining water. This is particularly useful for maintaining minimum reservoir volume when the reservoir is in a vertical or otherwise not horizontal orientation.']",20,392,side view,A,"[{'element_identifier': '634', 'terms': ['surface']}, {'element_identifier': '860', 'terms': ['means']}, {'element_identifier': '206', 'terms': ['membrane']}, {'element_identifier': '204', 'terms': ['water']}, {'element_identifier': '642', 'terms': ['fill port']}, {'element_identifier': '632', 'terms': ['""bottom"" surface']}, {'element_identifier': '423', 'terms': ['port']}, {'element_identifier': '864', 'terms': ['resilient elements', 'pressure plate']}, {'element_identifier': '800', 'terms': ['system']}, {'element_identifier': '631', 'terms': ['frame']}]","['1. A humidification system for use with low-flow oxygen therapy, the humidification system comprising: a reservoir, wherein the reservoir receives a volume of liquid water, and further wherein a liquid capacity of the reservoir is alterable such that instantaneous liquid capacity of the reservoir is substantially equal to instantaneous volume of liquid water in the reservoir; and a tube comprising a water-vapor-permeable (WVP) membrane, wherein a major portion of the tube is contained in the reservoir.', '3. The humidification system of claims 1 or 2 wherein the reservoir comprises two spaced-apart liquid-water-impermeable membranes, wherein a first one of the two membranes comprises a greater surface area than a second one of the two membranes.', '14. The humidification system as in any of the preceding claims wherein the reservoir comprises a fill port for filling the reservoir with water.']",True,"['631', '642', '423', '800', '860', '634', '632', '864', '204', '206', '23']" 673,EP_3598991_A1.png,EP3598991A1,LOW-FLOW OXYGEN THERAPY HUMIDIFIER AND METHOD,['FIG1'],['FIG1 depicts a block diagram showing humidification system 100 in accordance with the present teachings in use in conjunction with a low-flow oxygen therapy system'],"['FIG1 depicts humidification system 100 in accordance with the present teachings, in use, receiving cool dry oxygen 92 from oxygen source 90 and delivering humidified oxygen 94, or heated, humidified oxygen 96, to nasal cannula 98. In the illustrative embodiment, humidification system 100 provides sufficient humidification (as discussed below) for oxygen flow rates in the range of about 0.5 to about 6.0 liters per minute (lpm). Oxygen source 90 may be a canister of oxygen or an oxygen concentrator. Neither the oxygen source 90 nor nasal cannula 98 are part of the present invention.', 'WVP membrane 206, embodied as a flexible tube, is coupled at one end to oxygen inlet port 422 and at its other end to oxygen outlet port 423. The oxygen inlet port 422 is also connected to an oxygen line (not depicted) that conveys oxygen from oxygen source 90 (FIG1). And oxygen outlet port 423 is also connected to an oxygen outlet line, such as oxygen outlet line 210. Thus, oxygen flows through the interior of WVP membrane 206 while the exterior of the tube is exposed to water 204. The water level in reservoir 402 is observable via water gauge 640, which can be embodied as a simple sight gauge with a ball-float indicator.']",27,240,block diagram,A,"[{'element_identifier': '210', 'terms': ['line']}, {'element_identifier': '202', 'terms': ['reservoir']}, {'element_identifier': '92', 'terms': ['oxygen']}, {'element_identifier': '100', 'terms': ['humidification system']}, {'element_identifier': '206', 'terms': ['membrane']}, {'element_identifier': '204', 'terms': ['water']}, {'element_identifier': '90', 'terms': ['oxygen source']}]","['1. A humidification system for use with low-flow oxygen therapy, the humidification system comprising: a reservoir, wherein the reservoir receives a volume of liquid water, and further wherein a liquid capacity of the reservoir is alterable such that instantaneous liquid capacity of the reservoir is substantially equal to instantaneous volume of liquid water in the reservoir; and a tube comprising a water-vapor-permeable (WVP) membrane, wherein a major portion of the tube is contained in the reservoir.', '7. The humidification system as in any of the preceding claims and further comprising an oxygen outlet line coupled to an end of the tube.']",True,"['100', '92', '90', '86', '202', '204', '206', '1208', '100', '210', '17']" 674,EP_3599120_A1.png,EP3599120A1,SYSTEMS AND METHODS FOR MOUNTING A FUEL SYSTEM,['FIG1'],['FIG1 is a schematic of a fuel system carried on board a vehicle'],"['FIG1 is a schematic of a vehicle 100 with a fuel system 110 mounted thereon. A vehicle 100 may be any type of vehicle known in the art. A vehicle may be a truck, such as a light duty truck (e.g., class 1, class 2 or class 3), medium duty truck (e.g., class 4, class 5 or class 6), or heavy-duty truck (e.g., class 7 or class 8). In some embodiments, the vehicles may be cars, wagons, vans, buses, high-occupancy vehicles, dump trucks, tractor trailer trucks, transit, refuse or heavy-duty vehicles, or any other vehicles. The vehicle may have any weight. For example, the vehicle may weigh more than or equal to about 5000 lbs, 7,500 lbs, 10,000 lbs, 12,500 lbs, 15,000 lbs, 17,500 lbs, 20,000 lbs, 22,500 lbs, 25,000 lbs, 30,000 lbs, or 35,000 lbs.']",13,182,schematic,B,"[{'element_identifier': '110', 'terms': ['fuel system', 'fuel systems']}, {'element_identifier': '1', 'terms': ['clause']}]","['3. The system of claim 1, wherein the frame mountable vehicle equipment comprises a vehicle fuel system, the vehicle fuel system including one or more fuel tanks containing compressed natural gas or liquefied natural gas.']",False,"['001', '110', '1', '14']" 675,EP_3599260_A1 (1).png,EP3599260A1,COATING AGENT CONTAINING NANO PARTICLE AND METHODS FOR THEIR PREPARATION,['FIG2'],['FIG2 is a diagram illustrating a process of coating a substrate with a coating agent composition according to an example embodiment'],"['As a substrate of a packaging film, a polyethylene terephthalate (PET) film was used. A PET film with 10 × 10 cm2 was put into isopropyl alcohol, and cleaned with ultrasonic waves for 10 minutes. The cleaned PET substrate was fixed on a hot plate preheated to 80°C. The coating agent of Preparation Example 1 was applied onto the PET film using a casting rod as shown in FIG2, at a speed of 20 mm/s.']",21,87,diagram,C,"[{'element_identifier': '2', 'terms': ['prepared in Preparation Example']}, {'element_identifier': '10', 'terms': ['including']}]",['1. A coating agent composition comprising: a nanocomposite including nanoclay minerals and a polymer; and a solvent.'],False,"['2', '10']" 676,EP_3599260_A1 (2).png,EP3599260A1,COATING AGENT CONTAINING NANO PARTICLE AND METHODS FOR THEIR PREPARATION,['FIG3'],['FIG3 is a graph illustrating an analysis result of an X-ray diffraction (XRD) of bentonite that is a component of a nanocomposite according to an example embodiment'],"['A diffraction pattern of bentonite in a dry state (hereinafter, referred to as ""dry bentonite""), and a diffraction pattern of bentonite (hereinafter, referred to as ""wet bentonite"") prepared by adding distilled water were confirmed under the same treatment conditions. The diffraction patterns are shown in FIG3.']",31,59,graph,C,"[{'element_identifier': '10', 'terms': ['including']}]",['1. A coating agent composition comprising: a nanocomposite including nanoclay minerals and a polymer; and a solvent.'],False,"['8', '10', '12', '11']" 677,EP_3599260_A1 (3).png,EP3599260A1,COATING AGENT CONTAINING NANO PARTICLE AND METHODS FOR THEIR PREPARATION,['FIG4'],['FIG4 is a graph illustrating an XRD analysis result of a coating layer formed through the process of FIG2'],"['A diffraction pattern of the coating agent including 5 wt % of the nanocomposite, a diffraction pattern of the coating agent including 10 wt % of the nanocomposite, and a diffraction pattern of the coating agent including 20 wt % of the nanocomposite were analyzed, and were confirmed under the same treatment conditions. The diffraction patterns are shown in FIG4.']",19,65,graph,C,"[{'element_identifier': '10', 'terms': ['including']}]",['1. A coating agent composition comprising: a nanocomposite including nanoclay minerals and a polymer; and a solvent.'],False,"['4', '09', '4', '6', '8', '10', '12']" 678,EP_3599295_A1 (6).png,EP3599295A1,COMPOSITIONS AND METHODS FOR ACTIVATING TITANIUM SUBSTRATES,['FIG9'],['FIG9 is a schematic illustration of a system for strike plating a substrate in accordance with the method of FIG1'],"['Referring to FIG9, a strike plating system, generally designated 450, includes a bath 452, an electrolyte solution 454 received in the bath 452, a nickel anode 458 immersed in the electrolyte solution 454, and current source 460. The current source 460 may include first terminal 462 and a second terminal 464. The nickel anode 458 may be electrically coupled with the second terminal 464 by way of a lead 468.', 'As shown in FIG9, the substrate 456 is immersed (e.g., completely immersed) in the electrolyte solution 454 in the bath 452. Then, the substrate 456 is electrically coupled with the first terminal 462 of the current source 460 by way of a lead 466.']",20,131,schematic,C,"[{'element_identifier': '464', 'terms': ['second terminal']}, {'element_identifier': '466', 'terms': ['lead']}, {'element_identifier': '452', 'terms': ['bath']}, {'element_identifier': '458', 'terms': ['nickel anode']}, {'element_identifier': '462', 'terms': ['first terminal']}, {'element_identifier': '468', 'terms': ['lead']}, {'element_identifier': '456', 'terms': ['substrate']}, {'element_identifier': '460', 'terms': ['current source']}, {'element_identifier': '450', 'terms': ['generally designated']}]","['9. A method for pretreating a substrate prior to depositing a material thereon, the method comprising: immersing the substrate in the activation solution of Claim 1 for a predetermined period of time, wherein the substrate is preferably a titanium substrate.']",False,"['450', '460', '462', '464', '466', '468', '452', '456', '458', '21']" 679,EP_3599302_A1.png,EP3599302A1,RING/TRAVELER SYSTEM FOR RING SPINNING MACHINE,['FIG1C'],['FIG1C is a schematic perspective view showing a relationship between the traveler and the ring during spinning in this example configuration of a ring/traveler system for a ring spinning machine'],"['As shown in FIG1C, when yarn is wound onto a bobbin in the ring spinning machine, yarn Y is passed through the traveler 12. The yarn Y is fed from a drafting device, not shown in the figures, and wound onto a bobbin (not shown) via the traveler 12. At this time, a predetermined tension is applied to the yarn Y passing through the traveler 12. Accordingly, the traveler 12 is pulled by the yarn Y so as to contact the flange 11a of the ring 11, and while maintaining this state of contact, moves so as to revolve around the flange 11a. Therefore, while the yarn Y is being wound onto the bobbin, or in other words during spinning, the traveler 12 slides (travels) around the ring 11.']",32,149,schematic perspective view,C,"[{'element_identifier': '12', 'terms': ['traveler']}, {'element_identifier': '10', 'terms': ['not less than']}, {'element_identifier': '11', 'terms': ['ring', 'rings']}, {'element_identifier': '13', 'terms': ['chromium plating layer']}]","['1. A ring/traveler system for a ring spinning machine in which sliding is performed in an environment without liquid lubrication, wherein a plurality of dimples (15), each having a circular open end (15a), are formed in a sliding surface (14) on which a traveler (12) and a ring (11) slide as the traveler (12) travels, and the plurality of dimples (15) satisfy a condition according to which a dimple wall surface angle (θ) is not less than 10° and not more than 65° and satisfy a condition according to which a value of P/D, where P is a pitch (µm) at which the plurality of dimples (15) are arranged over the sliding surface (14) and D is a diameter (µm) of the circular open end (15a), is not less than 1.9 and not more than 4.']",True,"['11', '13', '11', '12', '13', '11', '10']" 680,EP_3599312_A1 (3).png,EP3599312A1,WORK VEHICLE WITH A VARIABLY POSITIONABLE CAMERA AND RELATED SYSTEMS,['FIG9'],"['FIG9 illustrates a close-up view of a further embodiment of the track of the imaging system according to aspects of the present disclosure, particularly illustrating a motor drivingly coupled to the camera via a belt']","['Referring now to FIG9, an embodiment of the imaging system 28 where the motor 78 is coupled to the arm 16 of the articulable implement 14 is illustrated according to aspects of the present disclosure. In such an embodiment, the motor 78 may be drivingly coupled to the camera 38 via a belt 80. It should be appreciated that, in other embodiments, the motor 78 may be drivingly coupled to the camera 38 via any suitable structure, such as a chain, pulley, track, or gear system. For instance, the belt 80 may drivingly couple the motor 78 to a gear positioned between the camera 38 and the rail 36 such that driving the belt 80 also positions the camera 38 between locations 40. In other embodiments, the motor 78 may have any other configuration that allows the motor 78 to slide the camera 38 along the track 34.']",38,163,close - up view,B,"[{'element_identifier': '28', 'terms': ['imaging system']}, {'element_identifier': '9', 'terms': ['U.S. Patent No.']}]","['1. A work vehicle (10), the work vehicle (10) comprising, a body (12), a controllable, articulable implement (14) coupled to the body (12), the articulable implement (14) including at least two arm (16) and a tool (18) positioned at a distal end (20) of the articulable implement (14), wherein the articulable implement (14) is positionable by an operator of the work vehicle (10) in an operating environment (26), the work vehicle (10) being characterized by : an imaging system (28) comprising: a display (30) housed within the operating environment (26) of the work vehicle (10) configured to display (30) images of a work area (32); a track (34) including a rail (36) coupled to at least one of the arms (16) of the articulable implement (14) and extending along a length of the at least one arm (16); and a camera (38) coupled to the track (34), the camera (38) communicatively coupled with the display (30), wherein the camera (38) captures at least one image of the work area (32) and communicates the image to the display (30), wherein the camera (38) is positionable at a plurality of locations (40) along the rail (36) to capture images of the work area (32).']",False,"['28', '9', '17']" 681,EP_3599312_A1 (4).png,EP3599312A1,WORK VEHICLE WITH A VARIABLY POSITIONABLE CAMERA AND RELATED SYSTEMS,['FIG10'],"['FIG10 illustrates a close-up view of the camera of the imaging system according to aspects of the present disclosure, particularly illustrating the camera within a camera housing']","['Referring now to FIG10 one embodiment of the camera 38 is illustrated according to aspects of the present disclosure. Particularly, FIG10 illustrates a camera 38 positioned within a camera housing 48. As illustrated, in certain embodiments, the camera housing 48 may surround the camera 38. For example, the camera housing 48 may include a number of walls 50 assembled around the camera 38. Further, in certain embodiments, the camera 38 may be coupled to one or more of the walls 50. It should be recognized that the camera housing 48 may protect the camera 38 from accidental contact that may damage the camera 38, prevent dirt and debris from blocking a lens of the camera 38, and/or prevent the camera 38 from being accidentally oriented such that the camera 38 does not capture image(s) of the work area 32. In the depicted embodiment, the camera housing 48 has a rectangular shape, or, more particularly, the camera housing 38 may have a square shape. It should be appreciated that, in other embodiments, the camera housing 48 may have any other suitable configuration or shape to house the camera 38.']",30,211,close - up view,B,"[{'element_identifier': '5', 'terms': ['five']}, {'element_identifier': '18', 'terms': ['tool', 'tools']}, {'element_identifier': '9', 'terms': ['U.S. Patent No.']}, {'element_identifier': '50', 'terms': ['wall', 'walls']}, {'element_identifier': '10', 'terms': ['vehicle']}, {'element_identifier': '49', 'terms': ['access panel']}]","['1. A work vehicle (10), the work vehicle (10) comprising, a body (12), a controllable, articulable implement (14) coupled to the body (12), the articulable implement (14) including at least two arm (16) and a tool (18) positioned at a distal end (20) of the articulable implement (14), wherein the articulable implement (14) is positionable by an operator of the work vehicle (10) in an operating environment (26), the work vehicle (10) being characterized by : an imaging system (28) comprising: a display (30) housed within the operating environment (26) of the work vehicle (10) configured to display (30) images of a work area (32); a track (34) including a rail (36) coupled to at least one of the arms (16) of the articulable implement (14) and extending along a length of the at least one arm (16); and a camera (38) coupled to the track (34), the camera (38) communicatively coupled with the display (30), wherein the camera (38) captures at least one image of the work area (32) and communicates the image to the display (30), wherein the camera (38) is positionable at a plurality of locations (40) along the rail (36) to capture images of the work area (32).']",False,"['50', '49', '9', '50', '50', '5', '10', '50', '18']" 682,EP_3599312_A1 (6).png,EP3599312A1,WORK VEHICLE WITH A VARIABLY POSITIONABLE CAMERA AND RELATED SYSTEMS,['FIG12'],"['FIG12 illustrates a close-up view of another embodiment of the camera of the imaging system according to aspects of the present disclosure, particularly illustrating the camera housing with an open side configuration']","['Referring now to FIG12, one embodiment of a camera housing 48 is illustrated in accordance with aspect of the present subject matter. Particularly, FIG12 illustrates the camera housing 48 with an open side configuration. Such a configuration may allow for the camera 38 to capture images of the work area 32 without viewing apertures 52 and/or slots 54. For example, the camera housing 48 may be configured such that there is an open side to the camera housing 48. In one embodiment, the camera housing 48 may not include a wall 50 at a bottom of the camera housing 48. In still other embodiments, the camera housing 48 may include at least one wall 50 configured as an at least partially transparent wall. Further, the at least partially transparent wall may provide a sight line between the work area 32 and the camera 38. The at least partially transparent wall may include a plastic material, a glass material, or any other material or combination of materials that substantially allow a line of sight between the camera 38 and the work area 32. It should be recognized that, in certain embodiments, the wall 50 at the bottom of the camera housing may be substantially fully transparent. Further, in additional embodiments, the wall 50 at the bottom of the camera housing 48 may be curved. For example, a fully or partially transparent wall may define at least a portion of a sphere.']",35,264,close - up view,B,"[{'element_identifier': '38', 'terms': ['camera']}, {'element_identifier': '12', 'terms': ['body']}, {'element_identifier': '50', 'terms': ['wall', 'walls']}, {'element_identifier': '20', 'terms': ['distal end']}]","['1. A work vehicle (10), the work vehicle (10) comprising, a body (12), a controllable, articulable implement (14) coupled to the body (12), the articulable implement (14) including at least two arm (16) and a tool (18) positioned at a distal end (20) of the articulable implement (14), wherein the articulable implement (14) is positionable by an operator of the work vehicle (10) in an operating environment (26), the work vehicle (10) being characterized by : an imaging system (28) comprising: a display (30) housed within the operating environment (26) of the work vehicle (10) configured to display (30) images of a work area (32); a track (34) including a rail (36) coupled to at least one of the arms (16) of the articulable implement (14) and extending along a length of the at least one arm (16); and a camera (38) coupled to the track (34), the camera (38) communicatively coupled with the display (30), wherein the camera (38) captures at least one image of the work area (32) and communicates the image to the display (30), wherein the camera (38) is positionable at a plurality of locations (40) along the rail (36) to capture images of the work area (32).']",False,"['38', '50', '50', '12', '20']" 683,EP_3599363_A1 (5).png,EP3599363A1,"CONTROL SYSTEM FOR COMPRESSION IGNITION ENGINE, METHOD OF CONTROLLING COMPRESSION IGNITION ENGINE, COMPUTER PROGRAM PRODUCT AND COMPRESSION IGNITION ENGINE",['FIG13'],"['FIG13 is a view illustrating one example of a configuration of a functional block of an ECU, according to the changing between Layer 2 and Layer 3']","['FIG13 illustrates a configuration of the functional blocks of the ECU 10. The functional block illustrated in FIG13 mainly relates to the changing between Layer 2 and Layer 3. The functional blocks include a target torque setting module 10a, a first mode module 10b, a second mode module 10c, a determining module 10d, and a changing module 10e. The ECU 10 is configured to execute the various software modules stored in the memory 102 to perform their respective functions, as described below.']",28,91,view,F,"[{'element_identifier': '56', 'terms': ['swirl control valve']}, {'element_identifier': '25', 'terms': ['ignition plug', 'ignition plugs']}, {'element_identifier': '57', 'terms': ['alternator']}, {'element_identifier': '10', 'terms': ['ECU']}, {'element_identifier': '43', 'terms': ['throttle valve']}, {'element_identifier': '54', 'terms': ['EGR valve']}, {'element_identifier': '13', 'terms': ['cylinder head']}]","['1. A control system for a compression ignition engine (1), comprising: a combustion chamber (17) of the engine (1) defined by a cylinder (11), a piston (3) configured to reciprocate inside the cylinder (11), and a cylinder head (13) closing one end of the cylinder (11); a throttle valve (43) configured to adjust an amount of air filled up in the combustion chamber (17); an injector (6) attached to the cylinder head (13) and configured to inject fuel to be supplied into the combustion chamber (17); an ignition plug (25) disposed so as to be oriented in the combustion chamber (17) and configured to ignite mixture gas inside the combustion chamber (17); a swirl control valve (56) configured to generate a swirl flow inside the combustion chamber (17); at least one sensor (SW1-SW17) configured to measure a parameter related to an operation of the engine (1); and a controller (10) having a circuitry connected with the throttle valve (43), the injector (6), the ignition plug (25), the swirl control valve (56), and the at least onesensor (SW1-SW17), configured to perform a calculation in response to a measurement signal from the sensor (SW1-SW17) and output signals to the throttle valve (43), the injector (6), the ignition plug (25), and the swirl control valve (56), wherein the controller (10) is configured to execute a first mode module (10b) to operate the engine (1) in a first mode, a second mode module (10c) to operate the engine (1) in a second mode, and a changing module (10e) to change the mode from the first mode to the second mode or from the second mode to the first mode in response to a change demand, wherein the first mode module (10b) outputs the signals to the injector (6) and the throttle valve (43) so that a fuel amount becomes an amount according to a load of the engine (1) and an air-fuel ratio of the mixture gas becomes a first air-fuel ratio, and outputs an ignition signal to the ignition plug (25) so that a part of the mixture gas starts combustion accompanied by flame propagation due to a forcible ignition of the ignition plug (25), and remaining unburnt mixture gas then combusts by self-ignition, wherein the second mode module (10c) outputs the signals to the injector (6) and the throttle valve (43) so that the fuel amount becomes the amount according to the load of the engine (1) and the air-fuel ratio of the mixture gas becomes a second air-fuel ratio higher than the first air-fuel ratio, and outputs the ignition signal to the ignition plug (25) so that a part of the mixture gas starts combustion accompanied by flame propagation due to a forcible ignition of the ignition plug (25), and remaining unburnt mixture gas then combusts by self-ignition, wherein the changing module (10e) outputs the signals to the throttle valve (43) and the injector (6) in response to the change demand so that the air-fuel ratio of the mixture gas becomes a stoichiometric air-fuel ratio or a substantially stoichiometric air-fuel ratio, and outputs the signal to the swirl control valve (56) so that the swirl flow becomes stronger than before the change demand when changing from the first mode to the second mode and that the swirl flow becomes weaker than before the change demand when changing from the second mode to the first mode, and wherein when the swirl flow is determined to be reached a given strength, the changing module (10e) causes the second mode module (10c) to start the second mode when changing from the first mode to the second mode and/or the changing module (10e) causes the first mode module (10b) to start the first mode when changing from the second mode to the first mode.']",False,"['10', '25', '43', '54', '56', '57', '13']" 684,EP_3599363_A1 (6).png,EP3599363A1,"CONTROL SYSTEM FOR COMPRESSION IGNITION ENGINE, METHOD OF CONTROLLING COMPRESSION IGNITION ENGINE, COMPUTER PROGRAM PRODUCT AND COMPRESSION IGNITION ENGINE",['FIG14'],['FIG14 is a flowchart illustrating a control according to the change from Layer 2 to Layer 3'],"['FIG14 illustrates a flowchart according to the change from Layer 2 to Layer 3. At Step S141, the ECU 10 first reads the signals of the sensors SW1-SW17, and at the subsequent Step S142, the ECU 10 determines whether the change from Layer 2 to Layer 3 is necessary.', 'Returning to the flowchart of FIG14, at Step S1410, the ECU 10 determines whether the calculated rich limit torque is not in agreement with the target torque. If the determination is YES (i.e., if the calculated rich limit torque is not in agreement with the target torque), the process shifts to Step S1411. On the other hand, if the determination is NO (i.e., if the calculated rich limit torque is in agreement with or substantially in agreement with the target torque), the process shifts to Step S1417.']",17,158,flowchart,F,"[{'element_identifier': '44', 'terms': ['supercharger']}, {'element_identifier': '17', 'terms': ['combustion chamber', 'combustion chambers']}, {'element_identifier': '14', 'terms': ['about', 'through respective connecting rods']}, {'element_identifier': '3', 'terms': ['Layer']}]","['1. A control system for a compression ignition engine (1), comprising: a combustion chamber (17) of the engine (1) defined by a cylinder (11), a piston (3) configured to reciprocate inside the cylinder (11), and a cylinder head (13) closing one end of the cylinder (11); a throttle valve (43) configured to adjust an amount of air filled up in the combustion chamber (17); an injector (6) attached to the cylinder head (13) and configured to inject fuel to be supplied into the combustion chamber (17); an ignition plug (25) disposed so as to be oriented in the combustion chamber (17) and configured to ignite mixture gas inside the combustion chamber (17); a swirl control valve (56) configured to generate a swirl flow inside the combustion chamber (17); at least one sensor (SW1-SW17) configured to measure a parameter related to an operation of the engine (1); and a controller (10) having a circuitry connected with the throttle valve (43), the injector (6), the ignition plug (25), the swirl control valve (56), and the at least onesensor (SW1-SW17), configured to perform a calculation in response to a measurement signal from the sensor (SW1-SW17) and output signals to the throttle valve (43), the injector (6), the ignition plug (25), and the swirl control valve (56), wherein the controller (10) is configured to execute a first mode module (10b) to operate the engine (1) in a first mode, a second mode module (10c) to operate the engine (1) in a second mode, and a changing module (10e) to change the mode from the first mode to the second mode or from the second mode to the first mode in response to a change demand, wherein the first mode module (10b) outputs the signals to the injector (6) and the throttle valve (43) so that a fuel amount becomes an amount according to a load of the engine (1) and an air-fuel ratio of the mixture gas becomes a first air-fuel ratio, and outputs an ignition signal to the ignition plug (25) so that a part of the mixture gas starts combustion accompanied by flame propagation due to a forcible ignition of the ignition plug (25), and remaining unburnt mixture gas then combusts by self-ignition, wherein the second mode module (10c) outputs the signals to the injector (6) and the throttle valve (43) so that the fuel amount becomes the amount according to the load of the engine (1) and the air-fuel ratio of the mixture gas becomes a second air-fuel ratio higher than the first air-fuel ratio, and outputs the ignition signal to the ignition plug (25) so that a part of the mixture gas starts combustion accompanied by flame propagation due to a forcible ignition of the ignition plug (25), and remaining unburnt mixture gas then combusts by self-ignition, wherein the changing module (10e) outputs the signals to the throttle valve (43) and the injector (6) in response to the change demand so that the air-fuel ratio of the mixture gas becomes a stoichiometric air-fuel ratio or a substantially stoichiometric air-fuel ratio, and outputs the signal to the swirl control valve (56) so that the swirl flow becomes stronger than before the change demand when changing from the first mode to the second mode and that the swirl flow becomes weaker than before the change demand when changing from the second mode to the first mode, and wherein when the swirl flow is determined to be reached a given strength, the changing module (10e) causes the second mode module (10c) to start the second mode when changing from the first mode to the second mode and/or the changing module (10e) causes the first mode module (10b) to start the first mode when changing from the second mode to the first mode.', '3. The control system of claim 1 or 2, wherein the swirl control valve (56) generates a flow having a swirl ratio of about 4:1 or higher.']",False,"['3', '17', '3', '14', '44']" 685,EP_3599369_A1 (1).png,EP3599369A1,CASCADE ARRAY VANES WITH ASSEMBLY FEATURES,['FIG2'],['FIG2 illustrates a side view of the aircraft of FIG1 including a nacelle in accordance with various embodiments'],"['In various embodiments and with reference to FIG2, a thrust reverser system of the aircraft 100 may be included in the nacelle assembly 122 and may include a translating sleeve 230 and a cascade, or cascade array, 240. The thrust reverser system may also comprise an air diversion system that is configured to direct airflow in the bypass duct through the cascade to create reverse thrust. The air diversion system may be any suitable system including, for example, blocker doors, diversion doors, and/or the like. An A-R-C axis as shown throughout the drawings to illustrate the axial, radial, and circumferential directions, respectively.', 'The aft cascade ring 380 may include a first aft cascade ring 500 and a second aft cascade ring 502. The first aft cascade ring 500 extends from the first hinge beam 504 to the latch beam 510 and has an arc shape. The second aft cascade ring 502 extends from the second hinge beam 506 to the latch beam 510 and likewise has an arc shape. Together, the first aft cascade ring 500 and the second aft cascade ring 502 form an entire aft cascade ring 380. The aft cascade ring 380 defines a plurality of actuator pathways 508. Actuators may extend through each of the plurality of actuator pathways 508 and may be coupled to, and actuate forward and aft, the translating sleeve 230 of FIG2.']",18,258,side view,B,"[{'element_identifier': '230', 'terms': ['translating sleeve']}, {'element_identifier': '11', 'terms': ['andFIG.', 'vane elements along section', '-']}, {'element_identifier': '220', 'terms': ['fan cowl']}, {'element_identifier': '100', 'terms': ['aircraft']}, {'element_identifier': '240', 'terms': ['cascade']}]","['1. A cascade array vane (341), comprising: a vane (404; 406) having an airfoil portion (408; 414) extending between a first end and a second end; a first longitudinal portion (410; 416) disposed at the first end of the vane (404; 406) extending outwardly from the vane (404; 406); a second longitudinal portion (412; 418) disposed at the second end of the vane (404; 406) extending outwardly from the vane (404; 406); and at least one coupling feature (430) incorporated with at least one of the first longitudinal portion (410; 416) or the second longitudinal portion (412; 418).']",False,"['100', '000000000', '240', '230', '220', '11']" 686,EP_3599413_A1 (1).png,EP3599413A1,FILAMENT STRUCTURE OF LED LIGHT BULB,['FIG2'],['FIG2 is a schematic view showing the assembly of a part of an LED light bulb according to another preferred embodiment of the present invention'],"['As shown in FIG2, in another embodiment, multiple LED filaments 30 are electrically connected with the first metal post 41 and the second metal post 42 of a filament support 40 in a parallel connecting manner, wherein and are intersected together so as to increase number of the multiple LED filaments 30 and to enhance lux of the LED light bulb.']",25,65,schematic view,F,"[{'element_identifier': '30', 'terms': ['LED filament', 'LED filaments']}, {'element_identifier': '11', 'terms': ['glass seat']}, {'element_identifier': '40', 'terms': ['filament support', 'filament supports']}, {'element_identifier': '42', 'terms': ['post']}, {'element_identifier': '41', 'terms': ['first metal post']}, {'element_identifier': '31', 'terms': ['first electrode pin']}, {'element_identifier': '32', 'terms': ['second electrode pin']}]","['1. A light-emitting diode (LED) light bulb comprising: a screw base, a transparent housing, at least one filament support, and at least one LED filament; the transparent housing being hollow and including an opening, and the screw base including a positive terminal and a negative terminal which are electrically connected with an external power supply so as to supply driving power to the at least one LED filament, wherein each of the at least one filament support includes a first metal post electrically connected with the positive terminal of the screw base and includes a second metal post electrically connected with the negative terminal so as to transmit the driving power; wherein each of the at least one LED filament includes a substrate, a first electrode pin and a second electrode pin which are arranged on two sides of the substrate respectively, a thermal radiation film formed on a back face of the substrate, at least one LED chip molded on a front face of the substrate, a wire, and a fluorescent; wherein the at least one LED chip is electrically connected with the first electrode pin and the second electrode pin in a series connecting manner by using the wire, wherein the first electrode pin is electrically connected with the first metal post, and the second electrode pin is electrically connected with the second metal post so that an LED drive circuit is defined; wherein the at least one LED filament and the at least one filament support are accommodated in the transparent housing, and the screw base is housed into the opening of the transparent housing, and the opening is closed.']",False,"['32', '30', '40', '31', '41', '42', '11']" 687,EP_3599413_A1 (2).png,EP3599413A1,FILAMENT STRUCTURE OF LED LIGHT BULB,['FIG3'],['FIG3 is a schematic view showing the assembly of a part of an LED light bulb according to another preferred embodiment of the present invention'],"['As illustrated in FIG3, the LED light bulb comprises two filament supports 40, 40a, wherein a first metal post 41 and a second metal post 42 of each of the two filament supports 40, 40a are electrically connected with a positive terminal 51 and a negative terminal 52 of a screw base 10 respectively.']",25,59,schematic view,F,"[{'element_identifier': '30', 'terms': ['LED filament', 'LED filaments']}, {'element_identifier': '11', 'terms': ['glass seat']}, {'element_identifier': '42', 'terms': ['post']}, {'element_identifier': '41', 'terms': ['first metal post']}, {'element_identifier': '31', 'terms': ['first electrode pin']}, {'element_identifier': '32', 'terms': ['second electrode pin']}]","['1. A light-emitting diode (LED) light bulb comprising: a screw base, a transparent housing, at least one filament support, and at least one LED filament; the transparent housing being hollow and including an opening, and the screw base including a positive terminal and a negative terminal which are electrically connected with an external power supply so as to supply driving power to the at least one LED filament, wherein each of the at least one filament support includes a first metal post electrically connected with the positive terminal of the screw base and includes a second metal post electrically connected with the negative terminal so as to transmit the driving power; wherein each of the at least one LED filament includes a substrate, a first electrode pin and a second electrode pin which are arranged on two sides of the substrate respectively, a thermal radiation film formed on a back face of the substrate, at least one LED chip molded on a front face of the substrate, a wire, and a fluorescent; wherein the at least one LED chip is electrically connected with the first electrode pin and the second electrode pin in a series connecting manner by using the wire, wherein the first electrode pin is electrically connected with the first metal post, and the second electrode pin is electrically connected with the second metal post so that an LED drive circuit is defined; wherein the at least one LED filament and the at least one filament support are accommodated in the transparent housing, and the screw base is housed into the opening of the transparent housing, and the opening is closed.']",False,"['31', '30', '32', '42', '41', '11', '41', '42', '8']" 688,EP_3599420_A1 (3).png,EP3599420A1,COOKING APPLIANCE,['FIG6'],['FIG6 is a view illustrating another example of the blocking member in FIG2'],"['As another example, as illustrated in FIG6, the second blocking unit 120 may be extended downward from the first blocking unit 110 such that the first blocking unit 110 and second blocking unit 120 are connected in the shape of ""┌"". In addition, an angle at which the first blocking unit 110 and second blocking unit 120 are connected may be properly set according to the sizes, shapes and the like of the fan motor 37d and cooling fan 37f.']",13,88,view,A,"[{'element_identifier': '100', 'terms': ['blocking member']}, {'element_identifier': '110', 'terms': ['first blocking unit']}, {'element_identifier': '120', 'terms': ['second blocking unit']}, {'element_identifier': '34', 'terms': ['rear space']}]","['1. A cooking appliance, comprising: a cabinet (10) including a cooking chamber (31); a convection fan (37c) installed inside of the cooking chamber (31); a fan motor (37d) installed outside of the cooking chamber (31) and configured to rotate the convection fan (37c); a cooling fan (37f) installed outside of the cooking chamber (31) for cooling the fan motor (37d), the cooling fan (37f) configured to be rotated by the fan motor (37d); an exhaust duct (40) connecting an inside of the cooking chamber (31) to an outside of the cabinet (10); and a duct (45) connecting the outside of the cooking chamber and the exhaust duct (40), wherein an opening (46) of the duct (45) is disposed outside of the cooking chamber (31) and opened toward the cooling fan (37f); characterized by : a blocking member (100) for blocking a path of airflow from the opening (46) to the cooling fan (37f), the blocking member (100) including a first blocking unit (110) between the opening (46) and the cooling fan (37f).', '5. The cooking appliance according to any one of the preceding claims, the cabinet (10) further including a rear space (34) separated from cooking chamber (31) by a partition surface (30a), wherein the first blocking unit (110) and/or the second blocking unit (120) have a length in a direction parallel to the rotation axis of the cooling fan (37f) being equal to or larger than a minimum distance between the partition surface (30a) and the fan motor (37d) in said direction.']",False,"['6', '110', '100', '120', '34', '18']" 689,EP_3599456_A1.png,EP3599456A1,CHANNEL UNIT AND MICROPARTICLE ANALYSIS DEVICE,['FIG2'],['FIG2 is a diagram illustrating an experimental system to analyze flow rate fluctuation that occurs in a case of pressure liquid feeding'],"['FIG2 illustrates an experimental system to analyze the flow rate fluctuation that occurs in the case of the pressure liquid feeding. A flow rate sensor used in the experimental system was SLS-1500 manufactured by SENSIRION AG. The shortest interval of flow rate sampling was 1 ms. In other words, the flow rate was measured every 1 ms at the shortest.']",22,65,diagram,G,"[{'element_identifier': '103', 'terms': ['device']}, {'element_identifier': '1', 'terms': ['Example']}, {'element_identifier': '100', 'terms': ['flow channel']}, {'element_identifier': '2', 'terms': ['Example']}, {'element_identifier': '104', 'terms': ['branch point']}, {'element_identifier': '105', 'terms': []}, {'element_identifier': '102', 'terms': ['pump']}, {'element_identifier': '101', 'terms': ['container']}, {'element_identifier': '108', 'terms': ['branched flow channel']}, {'element_identifier': '106', 'terms': ['portion']}, {'element_identifier': '107', 'terms': ['part']}]","['1. A flow channel unit comprising a flow rate fluctuation suppressing unit, wherein a cross-sectional area of at least part of a downstream flow channel of the flow rate fluctuation suppressing unit is smaller than a cross-sectional area of a remaining part of the flow channel.', '3. The flow channel unit according to claim 1, further comprising a pump on an upstream side of the flow rate fluctuation suppressing unit.', '12. The flow channel unit according to claim 1, wherein the flow channel unit is used to allow liquid to flow through in a microparticle analysis device.']",True,"['1', '100', '105', '108', '107', '102', '106', '104', '101', '103', '2', '16']" 690,EP_3599461_A2 (4).png,EP3599461A2,METHODS OF PERFORMING A SIZING ANALYSIS USING A CORRECTED SIZING LADDER,['FIG5'],"['FIG5 is a flow diagram of yet another method of performing a sizing analysis, in accordance with the present invention, the method correcting an archival sizing ladder using a real-time standard sizing ladder']","['FIG5 shows a flow diagram of a method of performing a sizing analysis in accordance with the present invention. An archival sizing ladder is provided, the archival sizing ladder including a plurality of archival ladder migration times (Block 510). A first channel of a fractionation device is loaded with a standard sizing ladder (Block 515). A second channel of the fractionation device is loaded with a sample (Block 520). The sample is separated into a plurality of separated components (Block 525). The standard sizing ladder is separated in parallel with the sample to yield a real-time ladder, the real-time ladder including a plurality of real-time ladder peaks (Block 530). A correction factor (CF) is calculated using the formula CF = (trt,i-trt,i-1)/(ta,i-ta,i-1), where trt,i is the time at which the most recent real-time ladder peak was detected, trt,i-1 is the time at which the previous real-time ladder peak was detected, and (ta,i - ta,i-1) is the migration time difference between the archival ladder peak corresponding to real-time ladder peak (i) and the archival ladder peak corresponding to real-time ladder peak (i-1) (Block 535). The correction factor is applied to each archival ladder migration time corresponding to a not-yet-detected real-time ladder peak, thereby providing one or more corrected archival ladder migration times (Block 540). A sizing analysis of the separated components is performed using a corrected archival sizing ladder consisting of detected real-time ladder peak migration times and corrected archival ladder migration times (Block 545). Steps in Blocks 535 through 545 are repeated for each of the plurality of real-time ladder peaks (Block 550). One or more of the separated components may be directed into a collection well. In alternative embodiments, the steps in Blocks 535 through 545 may be repeated only until immediately before, immediately after, or the time when the separated components are directed into the collection well.']",37,401,flow diagram,B,"[{'element_identifier': '535', 'terms': ['Steps in Blocks']}, {'element_identifier': '5', 'terms': ['collection well']}, {'element_identifier': '4', 'terms': ['clause']}, {'element_identifier': '545', 'terms': ['through']}]","['1. A method of performing a sizing analysis, the method comprising: providing an archival sizing ladder, the archival sizing ladder including archival ladder migration times; measuring migration times for a standard sizing ladder through a separation channel in a first fractionation device, the separation channel having a quantity of a first batch of sieving gel disposed therein, thereby providing a first sieving gel sizing ladder, the first sieving gel sizing ladder including first sieving gel ladder migration times; determining a ratio of the first sieving gel sizing ladder migration times to the archival ladder migration times, thereby providing a first correction; encoding the first correction into a first information storage means; attaching the first information storage means to a second fractionation device, a separation channel of the second fractionation device having a quantity of the first batch of sieving gel disposed therein; reading the first correction encoded into the information storage means; applying the first correction to each archival ladder migration time, thereby providing a first corrected archival sizing ladder; and performing a sizing analysis of the separated components of a sample disposed in the second fractionation device using the first corrected archival sizing ladder.', '2. The method of claim 1 further comprising: directing one or more of the separated components into a collection well.']",False,"['5', '510', '515', '520', '525', '530', '4', '5', '4', '535', '540', '545', '550', '16']" 691,EP_3599479_A1 (1).png,EP3599479A1,PROJECTILE DETECTION,['FIG2'],['FIG2 is a plan view of a sensor plate of a sensor of the illustrated embodiment'],"['The acoustic sensor 20 is of known type, as described in European Patent Application EP2884762A1. The acoustic sensor 20 includes a circular sensor plate 40, as illustrated in FIG2. The sensor plate 40 has five through holes 42 defined therein. The through holes 42 are arranged in a cruciform formation, centred with the sensor plate 40. Each through-hole 42 has a microphone 44 mounted therein, oriented so as to be directed to detect sound emanating from the exterior of the acoustic sensor 20.']",16,94,plan view,F,"[{'element_identifier': '42', 'terms': ['through holes']}, {'element_identifier': '44', 'terms': ['microphone', 'microphones']}, {'element_identifier': '40', 'terms': ['sensor plate']}]","['1. A method of detecting trajectory information for a subsonic projectile, comprising: collecting detection signals from an array of detection microphones, the detection microphones being established in a non co-linear spatial relationship with respect to each other; determining from at least one of the detection signals the existence of an acoustic waveform, a wake contribution, characteristic of the wake of a subsonic projectile passing on a trajectory nearby; obtaining a plurality of time samples of the wake contribution over a time period; processing the plurality of time samples to determine geometric characteristics of the trajectory of the projectile.']",False,"['44', '42', '40', '8']" 692,EP_3599479_A1.png,EP3599479A1,PROJECTILE DETECTION,['FIG1'],['FIG1 is a schematic illustration of an implementation of an embodiment'],"['FIG1 illustrates an embodiment, in which a vehicle 10 is equipped with an acoustic sensor 20 connected to a gunshot detector 30. The gunshot detector 30 may, in certain embodiments, be connected to other on-board electronic equipment, such as a navigation system, so that the outcome of gunshot detection can be integrated with navigation data so as to present location information to a user.']",11,73,schematic,F,"[{'element_identifier': '30', 'terms': ['detector']}, {'element_identifier': '12', 'terms': ['firearm']}, {'element_identifier': '1', 'terms': ['zero at', 'hand term in equation']}, {'element_identifier': '20', 'terms': ['sensor']}, {'element_identifier': '10', 'terms': ['vehicle']}]","['2. A method in accordance with claim 1 wherein the collecting of detection signals comprises establishing an array of acoustic detectors, the detectors being spaced in a fixed disposition with respect to each other, and deriving an electrical signal at each acoustic detector corresponding to acoustic waves incident thereon.']",False,"['12', '20', '30', '10', '1']" 693,EP_3599495_A1 (3).png,EP3599495A1,COLLIMATED VISUAL DISPLAY SYSTEM,['FIG4'],['FIG4 is a schematic view of the optical layout showing the uniform resolution according to the present invention'],"['The shape of the back-projection screen 23 is obtained in such a way that the parallel rays from the two eyes of a person in the design eye point of the visual display system, after reflection on the spherical mirror 22, converge on the back-projection screen 23 surface, as illustrated with the arrows on FIG4. This ensures the collimation property of the visual system. The shape of the back-projection screen is preferably optimized for providing a collimated beam to a pilot and a co-pilot.', 'This mapping is further also illustrated on FIG4, which shows the mapping of the projector 24 pixels onto the back-projection screen 23 by the freeform mirror 25. It also illustrates the mapping of the eyes of the viewer 21 in the design eye point on the back-projection screen 23 by the collimating mirror 22.']",18,160,schematic view,G,"[{'element_identifier': '24', 'terms': ['projector']}, {'element_identifier': '22', 'terms': ['mirror']}, {'element_identifier': '4', 'terms': ['projectors']}, {'element_identifier': '25', 'terms': ['freeform mirror']}, {'element_identifier': '21', 'terms': ['cockpit', 'viewer']}, {'element_identifier': '23', 'terms': ['screen']}]","['1. A collimated visual display system comprising - a back-projection screen, - a spherical mirror reflecting an image on the back-projection screen to be viewed by a viewer located in the design eye point, - wherein the back-projection screen is configured to provide a collimated beam to a viewer located in the design eye point, characterized in that - a single projector illuminates the back-projection screen to provide the image on the back-projection screen, - a freeform mirror located between the back-projection screen and the projector is configured to map all the pixels of the projector to the back-projection screen such that the resolution of the projector is sufficiently uniform on the back-projection screen.']",False,"['24', '23', '25', '22', '21', '4', '11']" 694,EP_3599539_A1 (6).png,EP3599539A1,RENDERING OBJECTS IN VIRTUAL VIEWS,['FIG9'],['FIG9 is a block diagram of components of a system in accordance with an exemplary embodiment'],"['The virtual ball view 54b and virtual cup view 56b that are projected on the first two-dimensional level 51 in the example embodiments described above may be two-dimensional representations of the ball 14 and cup 16. However, this is not essential to all embodiments. For example, the virtual ball view 54b and/or the virtual cup view 56b may be three-dimensional views that are located on the first two-dimensional level 51. For completeness, FIG9 is a schematic diagram of components of one or more of the modules for implementing the algorithms described above, which hereafter are referred to generically as processing systems 300. A processing system 300 may have a processor 302, a memory 304 coupled to the processor and comprised of a RAM 314 and ROM 312, and, optionally, viewer inputs 310 and a display 318. The processing system 300 may comprise one or more network interfaces 308 for connection to a network, e.g. a modem which may be wired or wireless.']",16,185,block diagram,G,"[{'element_identifier': '310', 'terms': ['viewer inputs']}, {'element_identifier': '304', 'terms': ['memory']}, {'element_identifier': '314', 'terms': ['RAM']}, {'element_identifier': '302', 'terms': ['processor']}, {'element_identifier': '16', 'terms': ['cup']}, {'element_identifier': '300', 'terms': ['processing system', 'processing systems']}, {'element_identifier': '318', 'terms': ['display']}, {'element_identifier': '308', 'terms': ['network interfaces']}, {'element_identifier': '315', 'terms': ['operating system']}, {'element_identifier': '316', 'terms': ['may store software applications']}, {'element_identifier': '312', 'terms': ['ROM']}]","['10. An apparatus as claimed in any one of the preceding claims, wherein the means comprise: at least one processor; and at least one memory including computer program code, the at least one memory and the computer program code configured, with the at least one processor, to cause the performance of the apparatus.']",False,"['304', '300', '314', '312', '316', '315', '308', '302', '318', '310', '9', '16']" 695,EP_3599581_A1 (4).png,EP3599581A1,METHOD AND APPARATUS FOR DISPLAYING A COMMODITY,['FIG6a'],['FIG6a is a block diagram illustrating an apparatus for displaying a commodity according to an exemplary embodiment of the present disclosure'],"['FIG6a is a block diagram illustrating an apparatus 60 for displaying a commodity according to an exemplary embodiment of the present disclosure. The apparatus 60 may be implemented as part or all of an electronic device by software, hardware, or a combination of both. As illustrated in FIG6a, the apparatus 60 may include a determining module 601, a first acquiring module 602 and a displaying module 603.']",21,74,block diagram,G,"[{'element_identifier': '601', 'terms': ['determining module']}, {'element_identifier': '6011', 'terms': ['first acquiring sub-module']}, {'element_identifier': '602', 'terms': ['first acquiring module']}, {'element_identifier': '60', 'terms': ['apparatus']}, {'element_identifier': '603', 'terms': ['displaying module']}]","['8. An apparatus (60) for displaying a commodity, applicable to a display terminal, comprising: a determining module (601), configured to determine whether a positional relationship between the display terminal and a user terminal satisfies a predetermined condition; a first acquiring module (602), configured to, when the positional relationship satisfies the predetermined condition, acquire purchase intention information of the user terminal, the purchase intention information including a commodity identifier of each of at least one commodity that a user intends to purchase; and a displaying module (603), configured to display the at least one commodity based on the purchase intention information.', '9. The apparatus (60) of claim 8, wherein the determining module (601) comprises: a first acquiring sub-module (6011), configured to acquire a distance between the user terminal and the display terminal; and a first determining sub-module (6012), configured to determine, based on the distance, whether the positional relationship satisfies the predetermined condition.']",True,"['60', '601', '602', '603', '60', '601', '6011', '601', '12', '602', '603', '23']" 696,EP_3599581_A1 (6).png,EP3599581A1,METHOD AND APPARATUS FOR DISPLAYING A COMMODITY,['FIG7a'],['FIG7a is a block diagram illustrating an apparatus for displaying a commodity according to an exemplary embodiment of the present disclosure'],"['FIG7a is a block diagram illustrating an apparatus 70 for displaying a commodity according to an exemplary embodiment of the present disclosure. The apparatus 70 may be implemented as part or all of an electronic device by software, hardware, or a combination of both. As illustrated in FIG7a, the apparatus 70 may include a third acquiring module 701, a fourth acquiring module 702, and a first sending module 703.']",21,77,block diagram,G,"[{'element_identifier': '601', 'terms': ['determining module']}, {'element_identifier': '6025', 'terms': ['receiving sub-module']}, {'element_identifier': '701', 'terms': ['third acquiring module']}, {'element_identifier': '702', 'terms': ['fourth acquiring module']}, {'element_identifier': '6023', 'terms': ['third acquiring sub-module']}, {'element_identifier': '602', 'terms': ['first acquiring module']}, {'element_identifier': '703', 'terms': ['first sending module']}, {'element_identifier': '6024', 'terms': ['sending sub-module']}, {'element_identifier': '70', 'terms': ['apparatus']}, {'element_identifier': '60', 'terms': ['apparatus']}, {'element_identifier': '603', 'terms': ['displaying module']}]","['8. An apparatus (60) for displaying a commodity, applicable to a display terminal, comprising: a determining module (601), configured to determine whether a positional relationship between the display terminal and a user terminal satisfies a predetermined condition; a first acquiring module (602), configured to, when the positional relationship satisfies the predetermined condition, acquire purchase intention information of the user terminal, the purchase intention information including a commodity identifier of each of at least one commodity that a user intends to purchase; and a displaying module (603), configured to display the at least one commodity based on the purchase intention information.', '13. The apparatus (60) of any one of claims 8 to 12, wherein the first acquiring module (602) comprises: a third acquiring sub-module (6023), configured to acquire a terminal identifier of the user terminal; a sending sub-module (6024), configured to send a query message to a server based on the terminal identifier, the query message including the terminal identifier of the user terminal, such that the server acquires a search record or a shopping cart of the user terminal corresponding to the terminal identifier and acquires the purchase intention information of the user terminal based on the search record or the shopping cart; and a receiving sub-module (6025), configured to receive a feedback message from the server, the feedback message including the purchase intention information.']",True,"['60', '601', '602', '6023', '6024', '6025', '603', '70', '701', '702', '703', '25']" 697,EP_3599758_A1 (1).png,EP3599758A1,"COLOR PREDICTION METHOD, PRINT DATA GENERATION APPARATUS, AND COLOR PREDICTION PROGRAM",['FIG3'],['FIG3 is a diagram showing a hardware configuration of a print data generation apparatus in the embodiment'],"['FIG3 is a diagram showing a hardware configuration of the print data generation apparatus 100 in the present embodiment. The print data generation apparatus 100 is implemented by a personal computer, and includes a CPU 11, a ROM 12, a RAM 13, an auxiliary storage device 14, an input operation unit 15 such as a keyboard, a display unit 16, an optical disk drive 17, and a network interface unit 18. The submitted data transmitted via the communication line 600 is inputted into the print data generation apparatus 100 via the network interface unit 18. Print data generated by performing the color prediction process and the like by the print data generation apparatus 100 is sent to the digital printing apparatus 400 through the communication line 600 via the network interface unit 18.']",17,145,diagram,B,"[{'element_identifier': '141', 'terms': ['program']}, {'element_identifier': '18', 'terms': ['network interface unit']}, {'element_identifier': '100', 'terms': []}, {'element_identifier': '2', 'terms': ['color']}, {'element_identifier': '600', 'terms': ['communication line']}, {'element_identifier': '300', 'terms': ['printing apparatus']}, {'element_identifier': '16', 'terms': ['display unit']}, {'element_identifier': '500', 'terms': ['colorimeter']}, {'element_identifier': '15', 'terms': ['Equation']}, {'element_identifier': '200', 'terms': ['plate making apparatus']}, {'element_identifier': '170', 'terms': ['optical disk']}, {'element_identifier': '13', 'terms': ['Equation']}]","['8. A print data generation apparatus (100) that generates print data in a format printable by a digital printing apparatus (400) on the basis of submitted data, the print data generation apparatus (100) comprising: color prediction means (S610 to S630) configured to perform a color prediction process in which pixel data is read from the submitted data on a pixel-by-pixel basis, and a color of the read pixel data is predicted; XYZ data generation means (S640) configured to generate XYZ data representing color tristimulus values X, Y, and Z on the basis of a result obtained by the color prediction process; first data conversion means (S650) configured to convert the XYZ data into Lab data that is data of a CIELAB color space; and second data conversion means (S660) configured to convert the Lab data into print data in a format printable by the digital printing apparatus, wherein the color prediction process includes a process for predicting a color obtained by sequentially overprinting, on a base material, inks of a first printing color to an Nth (N is an integer of 2 or more) printing color, the color prediction means (S610 to S630) includes first reflectance obtaining means (S10) configured to obtain, as a first reflectance, a reflectance of a unit region with a state where an ink of the first printing color is applied on the base material, and calculation means (S20) configured to perform a calculation process which is executed (N-1) times for pixel data of one pixel, and in the calculation process, during a Kth (K is an integer of 1 or more and N-1 or less) execution, a reflectance of the unit region with a state where inks of the first printing color to a (K+1)th printing color are sequentially overprinted on the base material is calculated, and the calculation means (S30) includes second reflectance calculation means (S310) configured to calculate, as a second reflectance, a reflectance of a printing region with a state where the ink of the first printing color is applied on the base material, when a value of the K is 1, and to calculate, as a second reflectance, a reflectance of a printing region with a state where an ink of a Kth printing color is overprinted on an ink of a (K-1)th printing color, when the value of the K is 2 or more, third reflectance calculation means (S320 and S330) configured to calculate, as a third reflectance, a reflectance of the unit region with a state where, assuming that a transparent ink is applied on the base material, an ink of a (K+1)th printing color is overprinted on the transparent ink, first conversion equation calculation means (S340) configured to obtain a first conversion equation representing a line connecting first coordinates and second coordinates regarding a color prediction coordinate system where an abscissa represents a product of a reflectance of a background and a reflectance of a foreground and an ordinate represents a reflectance of a state where the background and the foreground overlap, the first coordinates corresponding to a combination of a product of a fourth reflectance that is a reflectance of the base material and a fifth reflectance that is a reflectance of a state where the ink of the (K+1)th printing color is applied on the base material, and the third reflectance, the second coordinates corresponding to a combination of a product of a sixth reflectance that is a reflectance of a state where a black ink is applied on the base material and the fifth reflectance, and a seventh reflectance that is a reflectance of a state where the ink of the (K+1)th printing color is overprinted on the black ink, eighth reflectance calculation means (S350) configured to calculate, as an eighth reflectance, a reflectance of a printing region with a state where the ink of the (K+1)th printing color is overprinted on the ink of the Kth printing color on the basis of the second reflectance and the fifth reflectance, using the first conversion equation, second conversion equation calculation means (S360) configured to obtain a second conversion equation representing a line connecting third coordinates and fourth coordinates regarding the color prediction coordinate system, the third coordinates corresponding to a combination of a product of the second reflectance and the fifth reflectance, and the eighth reflectance, the fourth coordinates corresponding to a combination of a product of the fourth reflectance and the fifth reflectance, and the fifth reflectance, and first reflectance update means (S370) configured to calculate a reflectance of the unit region with a state where the inks of the first printing color to the (K+1)th printing color are sequentially overprinted on the base material on the basis of the first reflectance and the fifth reflectance, using the second conversion equation, and to update the first reflectance with the calculated reflectance.', '9. A color prediction program (141) for predicting a color obtained by sequentially overprinting, on a base material, inks of a first printing color to an Nth (N is an integer of 2 or more) printing color, the program comprising, a first reflectance obtaining step (S10) of obtaining, as a first reflectance, a reflectance of a unit region with a state where an ink of the first printing color is applied on the base material, and a calculation step (S30) of calculating a reflectance of the unit region, the calculation step being executed (N-1) times, and in the calculation step, during a Kth (K is an integer of 1 or more and N-1 or less) execution, the reflectance of the unit region with a state where inks of the first printing color to a (K+1)th printing color are sequentially overprinted on the base material is calculated, wherein the calculation step (S30) includes: a second reflectance calculation step (S310) of calculating, as a second reflectance, a reflectance of a printing region with a state where the ink of the first printing color is applied on the base material, when a value of the K is 1, and of calculating, as a second reflectance, a reflectance of a printing region with a state where an ink of a Kth printing color is overprinted on an ink of a (K-1)th printing color, when the value of the K is 2 or more; a third reflectance calculation step (S320 and S330) of calculating, as a third reflectance, a reflectance of the unit region with a state where, assuming that a transparent ink is applied on the base material, an ink of a (K+1)th printing color is overprinted on the transparent ink; a first conversion equation calculation step (S340) of obtaining a first conversion equation representing a line connecting first coordinates and second coordinates regarding a color prediction coordinate system where an abscissa represents a product of a reflectance of a background and a reflectance of a foreground and an ordinate represents a reflectance of a state where the background and the foreground overlap, the first coordinates corresponding to a combination of a product of a fourth reflectance that is a reflectance of the base material and a fifth reflectance that is a reflectance of a state where the ink of the (K+1)th printing color is applied on the base material, and the third reflectance, the second coordinates corresponding to a combination of a product of a sixth reflectance that is a reflectance of a state where a black ink is applied on the base material and the fifth reflectance, and a seventh reflectance that is a reflectance of a state where the ink of the (K+1)th printing color is overprinted on the black ink; an eighth reflectance calculation step (S350) of calculating, as an eighth reflectance, a reflectance of a printing region with a state where the ink of the (K+1)th printing color is overprinted on the ink of the Kth printing color on the basis of the second reflectance and the fifth reflectance, using the first conversion equation; a second conversion equation calculation step (S360) of obtaining a second conversion equation representing a line connecting third coordinates and fourth coordinates regarding the color prediction coordinate system, the third coordinates corresponding to a combination of a product of the second reflectance and the fifth reflectance, and the eighth reflectance, the fourth coordinates corresponding to a combination of a product of the fourth reflectance and the fifth reflectance, and the fifth reflectance; and a first reflectance update step (S370) of calculating a reflectance of the unit region with a state where the inks of the first printing color to the (K+1)th printing color are sequentially overprinted on the base material on the basis of the first reflectance and the fifth reflectance, using the second conversion equation, and of updating the first reflectance with the calculated reflectance.']",True,"['100', '2', '13', '15', '16', '141', '600', '18', '170', '200', '100', '300', '500', '30']" 698,EP_3599758_A1.png,EP3599758A1,"COLOR PREDICTION METHOD, PRINT DATA GENERATION APPARATUS, AND COLOR PREDICTION PROGRAM",['FIG2'],['FIG2 is a diagram showing an overall configuration of a printing system for achieving a color prediction method according to an embodiment of the present invention'],"['FIG2 is a diagram showing an overall configuration of a printing system for achieving a color prediction method according to one embodiment of the present invention. The printing system includes: a print data generation apparatus 100 that generates print data by performing various processes on submitted data such as a PDF file; a plate making apparatus 200 that produces a printing plate on the basis of the print data; a printing apparatus 300 that performs printing using the printing plate produced by the plate making apparatus 200; a digital printing apparatus 400 such as an inkjet printer/copier that performs printing on the basis of the print data which is digital data without using the printing plate; and a colorimeter 500 for measuring a color. The print data generation apparatus 100, the plate making apparatus 200, the digital printing apparatus 400, and the colorimeter 500 are communicably interconnected by a communication line 600. Note that the colorimeter 500 used in the present embodiment is assumed to be a spectral colorimeter.']",26,183,diagram,B,"[{'element_identifier': '100', 'terms': []}, {'element_identifier': '400', 'terms': ['digital printing apparatus']}, {'element_identifier': '600', 'terms': ['communication line']}, {'element_identifier': '300', 'terms': ['printing apparatus']}, {'element_identifier': '500', 'terms': ['colorimeter']}, {'element_identifier': '200', 'terms': ['plate making apparatus']}]","['8. A print data generation apparatus (100) that generates print data in a format printable by a digital printing apparatus (400) on the basis of submitted data, the print data generation apparatus (100) comprising: color prediction means (S610 to S630) configured to perform a color prediction process in which pixel data is read from the submitted data on a pixel-by-pixel basis, and a color of the read pixel data is predicted; XYZ data generation means (S640) configured to generate XYZ data representing color tristimulus values X, Y, and Z on the basis of a result obtained by the color prediction process; first data conversion means (S650) configured to convert the XYZ data into Lab data that is data of a CIELAB color space; and second data conversion means (S660) configured to convert the Lab data into print data in a format printable by the digital printing apparatus, wherein the color prediction process includes a process for predicting a color obtained by sequentially overprinting, on a base material, inks of a first printing color to an Nth (N is an integer of 2 or more) printing color, the color prediction means (S610 to S630) includes first reflectance obtaining means (S10) configured to obtain, as a first reflectance, a reflectance of a unit region with a state where an ink of the first printing color is applied on the base material, and calculation means (S20) configured to perform a calculation process which is executed (N-1) times for pixel data of one pixel, and in the calculation process, during a Kth (K is an integer of 1 or more and N-1 or less) execution, a reflectance of the unit region with a state where inks of the first printing color to a (K+1)th printing color are sequentially overprinted on the base material is calculated, and the calculation means (S30) includes second reflectance calculation means (S310) configured to calculate, as a second reflectance, a reflectance of a printing region with a state where the ink of the first printing color is applied on the base material, when a value of the K is 1, and to calculate, as a second reflectance, a reflectance of a printing region with a state where an ink of a Kth printing color is overprinted on an ink of a (K-1)th printing color, when the value of the K is 2 or more, third reflectance calculation means (S320 and S330) configured to calculate, as a third reflectance, a reflectance of the unit region with a state where, assuming that a transparent ink is applied on the base material, an ink of a (K+1)th printing color is overprinted on the transparent ink, first conversion equation calculation means (S340) configured to obtain a first conversion equation representing a line connecting first coordinates and second coordinates regarding a color prediction coordinate system where an abscissa represents a product of a reflectance of a background and a reflectance of a foreground and an ordinate represents a reflectance of a state where the background and the foreground overlap, the first coordinates corresponding to a combination of a product of a fourth reflectance that is a reflectance of the base material and a fifth reflectance that is a reflectance of a state where the ink of the (K+1)th printing color is applied on the base material, and the third reflectance, the second coordinates corresponding to a combination of a product of a sixth reflectance that is a reflectance of a state where a black ink is applied on the base material and the fifth reflectance, and a seventh reflectance that is a reflectance of a state where the ink of the (K+1)th printing color is overprinted on the black ink, eighth reflectance calculation means (S350) configured to calculate, as an eighth reflectance, a reflectance of a printing region with a state where the ink of the (K+1)th printing color is overprinted on the ink of the Kth printing color on the basis of the second reflectance and the fifth reflectance, using the first conversion equation, second conversion equation calculation means (S360) configured to obtain a second conversion equation representing a line connecting third coordinates and fourth coordinates regarding the color prediction coordinate system, the third coordinates corresponding to a combination of a product of the second reflectance and the fifth reflectance, and the eighth reflectance, the fourth coordinates corresponding to a combination of a product of the fourth reflectance and the fifth reflectance, and the fifth reflectance, and first reflectance update means (S370) configured to calculate a reflectance of the unit region with a state where the inks of the first printing color to the (K+1)th printing color are sequentially overprinted on the base material on the basis of the first reflectance and the fifth reflectance, using the second conversion equation, and to update the first reflectance with the calculated reflectance.']",True,"['100', '600', '200', '300', '400', '500', '29']" 699,EP_3599760_A1 (5).png,EP3599760A1,IMAGE PROCESSING METHOD AND APPARATUS,"['FIG6', ' FIG7']","['FIG7 is a schematic structural diagram of another image processing apparatus according to an embodiment of the present invention ', 'FIG6 is a schematic structural diagram of an image processing apparatus according to an embodiment of the present invention']","['FIG7 is a schematic structural diagram of an image processing apparatus according to an embodiment of this application. The apparatus 700 shown in FIG7 may be considered as a computer device, and the apparatus 700 may be an implementation of the image processing apparatus in the embodiments of this application, or may be an implementation of the image processing methods in the embodiments of this application. The apparatus 700 includes a processor 701, a memory 702, an input/output interface 703, and a bus 705, and may further include a communications interface 704. The processor 701, the memory 702, the input/output interface 703, and the communications interface 704 are communicatively connected to each other by using the bus 705.', 'It should be noted that, although only the processor 701, the memory 702, the input/output interface 703, the communications interface 704, and the bus 705 of the apparatus 700 are shown in FIG7, in a specific implementation process, a person skilled in the art should understand that the apparatus 700 further includes another component required for normal operation, for example, may further include a display that is configured to display to-be-played video data. In addition, according to a specific requirement, a person skilled in the art should understand that the apparatus 700 may further include hardware components for implementing other additional functions. In addition, a person skilled in the art should understand that the apparatus 700 may include only devices required for implementation of the embodiments of this application, but does not necessarily include all the devices shown in FIG7. ', 'The following describes an image processing apparatus in an embodiment of the present invention with reference to FIG6. As shown in FIG6, the image processing apparatus 600 includes:an obtaining module 601, an image photographing module 602, a mode selection module 603, and a processing module 604, where the mode selection module 603 is connected to both the obtaining module 601 and the image photographing module 602, the processing module 604 is connected to both the image photographing module 602 and the mode selection module 603, and the presentation module 605 is connected to the processing module 604.']",38,406,schematic structural diagram,H,"[{'element_identifier': '601', 'terms': ['obtaining module']}, {'element_identifier': '704', 'terms': ['communications interface']}, {'element_identifier': '605', 'terms': ['presentation module']}, {'element_identifier': '705', 'terms': ['bus']}, {'element_identifier': '600', 'terms': ['image processing apparatus']}, {'element_identifier': '701', 'terms': ['processor']}, {'element_identifier': '702', 'terms': ['memory']}, {'element_identifier': '604', 'terms': ['processing module']}, {'element_identifier': '602', 'terms': []}, {'element_identifier': '703', 'terms': ['input/output interface']}, {'element_identifier': '700', 'terms': ['apparatus']}, {'element_identifier': '603', 'terms': []}]","['1. An image processing apparatus, wherein the apparatus comprises: an obtaining module, wherein the obtaining module is configured to obtain status information of a terminal device; an image photographing module, wherein the image photographing module is configured to obtain photographing scene information of the terminal device; and a mode selection module, wherein the mode selection module is configured to determine an image processing mode based on the status information and the photographing scene information, wherein the image photographing module is further configured to obtain a to-be-displayed image based on the image processing mode.']",True,"['600', '603', '601', '602', '604', '605', '6', '700', '701', '702', '705', '703', '704', '7', '29']" 700,EP_3599763_A2 (4).png,EP3599763A2,METHOD AND APPARATUS FOR CONTROLLING IMAGE DISPLAY,['FIG10'],['FIG10 is a block diagram illustrating an apparatus for controlling image display according to an example of the present disclosure '],"['As shown in FIG10, an apparatus 1000 may be AR glasses, a mobile phone, a computer, a tablet device, a medical device, a fitness device, a personal digital assistant and the like.', 'Referring to FIG10, the apparatus 1000 may include one or more of the following components: a processing component 1002, a memory 1004, a power supply component 1006, a multimedia component 1008, an audio component 1010, an input/output (I/O) interface 1012, a sensor component 1014, and a communication component 1016.']",20,106,block diagram,H,"[{'element_identifier': '1016', 'terms': ['communication component']}, {'element_identifier': '1002', 'terms': ['processing component']}, {'element_identifier': '1012', 'terms': ['interface']}, {'element_identifier': '1004', 'terms': ['memory']}, {'element_identifier': '1010', 'terms': ['audio component']}, {'element_identifier': '1006', 'terms': ['power supply component']}, {'element_identifier': '1000', 'terms': ['apparatus']}, {'element_identifier': '1014', 'terms': ['sensor component']}, {'element_identifier': '1020', 'terms': []}, {'element_identifier': '1008', 'terms': ['multimedia component']}]","['10. An apparatus for controlling image display, comprising: a memory configured to store a computer program; a processor coupled with the memory and configured to execute the computer program stored in the memory and configured to: receive an image capture instruction from a client device, wherein the image capture instruction comprises a photographing direction, and the photographing direction is determined by the client device according to a relative position relationship between a position of the client device and a user-specified display position; control an image capture device to perform image capture according to the photographing direction, to obtain a depth image comprising a target object image; extract the target object image from the depth image; and send the target object image to the client device such that the client device displays the target object image at the user-specified display position.']",False,"['1000', '1002', '1004', '1016', '1006', '1008', '1020', '1014', '1010', '1012', '10', '18']" 701,EP_3599769_A1.png,EP3599769A1,REPLACABLE MEASUREMENT MICROPHONE,['FIG1'],['FIG1 shows a top view of part of a wing of an airplane with an array of surface mountable microphones'],"['FIG1 shows a top view of part of a wing 1 of an airplane with an array 2 of surface mountable microphones 3 attached to the wing 1. Each of these microphones 3 is connected by a coax-cable 4 to a signal analyzer 5. During a test flight or within a wind tunnel, wing 1 is exposed to a laminar air stream 6 that may cause turbulences in an area 7 and vibrations in an area 8. As a result of this test, wing 1 needs to be reworked to improve the aerodynamics, for which work microphones 3 need to be detached first. After the rework has been finished, microphones 3 need to be attached again for the next test to check the improvement. It is essential to attach each of the microphones 3 to exact the same position on wing 1 where it was attached during the first test to ensure comparability of the tests to detect whether or not the rework helped to reduce turbulences and vibrations on wing 1.']",20,184,view,H,"[{'element_identifier': '17', 'terms': ['attraction force']}, {'element_identifier': '5', 'terms': ['analyzer']}, {'element_identifier': '12', 'terms': ['Mounting means']}, {'element_identifier': '14', 'terms': ['screw']}, {'element_identifier': '11', 'terms': ['electrical connector']}, {'element_identifier': '19', 'terms': ['area']}, {'element_identifier': '18', 'terms': ['truncated cone areas']}, {'element_identifier': '9', 'terms': ['case']}, {'element_identifier': '2', 'terms': ['array']}, {'element_identifier': '20', 'terms': ['area']}, {'element_identifier': '21', 'terms': ['transparent plastic ring']}, {'element_identifier': '16', 'terms': ['metal ring', 'metal rings']}, {'element_identifier': '10', 'terms': ['microphone case part']}, {'element_identifier': '15', 'terms': ['magnets']}, {'element_identifier': '13', 'terms': ['case mounting means']}]","['5. Microphone (3) according to claim 4, wherein the positioning means are realized by truncated cone areas (18) of the case mounting means (13) and the surface mounting means (16).', '6. Microphone (3) according to any of the claims 2 to 5, wherein the case (9) comprises: a microphone case part (10) that protects the microphone (3) and is connected to case mounting means (13), which forms a back volume for the microphone (3).', '7. Microphone (3) according to any of the claims 2 to 6, wherein the electrical connector (11) is arranged on the case (9) separated from an area (19) of the case mounting means (13) that mechanically connects to an area (20) of surface mounting means (16) to enable electrically passive surface mounting means (16).']",True,"['2', '10', '21', '11', '14', '9', '15', '12', '13', '20', '17', '18', '19', '16', '5']" 702,EP_3602576_B1 (1).png,EP3602576B1,DETECTOR ARRANGEMENT FOR AN X-RAY PHASE CONTRAST SYSTEM AND METHOD FOR X-RAY CONTRAST IMAGING,['FIG7'],['FIG7 shows a schematic view of an embodiment of a computer readable medium with an embodiment of a computer program element for performing at least one embodiment of the method '],"['According to a further exemplary embodiment of the present invention shown in FIG7, a computer readable medium 26, such as a CD-ROM, is presented wherein the computer readable medium 26 has a computer program element 25 stored on it which computer program element 25 is described by the preceding section. A computer program may be stored and/or distributed on a suitable medium, such as an optical storage medium or a solid-state medium supplied together with or as part of other hardware, but may also be distributed in other forms, such as via the internet or other wired or wireless telecommunication systems.']",30,113,schematic view,G,"[{'element_identifier': '7', 'terms': ['opaque element', 'opaque elements']}, {'element_identifier': '14', 'terms': ['X-ray transparent wall']}, {'element_identifier': '12', 'terms': ['optical grating']}, {'element_identifier': '17', 'terms': ['signal line']}, {'element_identifier': '11', 'terms': ['scintillator']}, {'element_identifier': '18', 'terms': ['signal line']}, {'element_identifier': '25', 'terms': ['computer program element']}, {'element_identifier': '16', 'terms': ['polarizing unit']}, {'element_identifier': '26', 'terms': ['computer readable medium']}, {'element_identifier': '15', 'terms': ['active LCD pixel array']}, {'element_identifier': '13', 'terms': ['detector']}]","['1. A detector arrangement for an X-ray phase contrast system (5), the detector arrangement (1) comprising: - a scintillator (11); - an optical grating (12); and - a detector (13); - wherein the optical grating (12) is arranged between the scintillator (11) and the detector (13) and is configured to be electronically adjustable; wherein the scintillator (11) converts X-ray radiation (2) into optical radiation (3); wherein the optical grating (12) is configured to be an analyzer grating being adapted to a phase-grating (21) of an X-ray phase contrast system (5) and - characterised in that an optical path between the optical grating (12) and the scintillator (11) is free of focussing elements for optical radiation.', '3. Detector arrangement according to claim 2, wherein the detector arrangement (13) comprises an optical polarizing unit (16); wherein the optical polarizing unit (16) is positioned between the optical grating (12) and the scintillator (11); and wherein the LCD pixel array (15) is an active LCD pixel array (15) being configured to dynamically change a polarization of the analyzer grating.', '13. A computer program element for controlling an apparatus according to one of the claims 1 to 8, which, when being executed by a processing unit, is adapted to perform the method steps of one of the claims 9 to', '15. A computer readable medium having stored the program element of claim']",True,"['14', '11', '18', '15', '16', '12', '13', '17', '25', '26', '7', '12']" 703,EP_3602576_B1 (4).png,EP3602576B1,DETECTOR ARRANGEMENT FOR AN X-RAY PHASE CONTRAST SYSTEM AND METHOD FOR X-RAY CONTRAST IMAGING,['FIG5'],['FIG5 shows a schematic view of an embodiment of a method for X-ray phase contrast imaging'],"['FIG5 shows an embodiment of a method 100 for X-ray phase contrast imaging. In that embodiment of the method 100, the method 100 is performed with on optical grating 12 being provided by a pixel array. The pixel array may for example be provided by a bi-stable display 23 or an active LCD pixel array 15.']",18,64,schematic view,G,"[{'element_identifier': '103', 'terms': ['step']}, {'element_identifier': '5', 'terms': ['system']}, {'element_identifier': '9', 'terms': ['conversion elements']}, {'element_identifier': '100', 'terms': ['method']}, {'element_identifier': '104', 'terms': ['In step']}, {'element_identifier': '105', 'terms': ['in step']}, {'element_identifier': '102', 'terms': ['step']}, {'element_identifier': '101', 'terms': ['step', 'steps']}, {'element_identifier': '15', 'terms': ['active LCD pixel array']}, {'element_identifier': '106', 'terms': ['In step']}, {'element_identifier': '107', 'terms': ['In step']}]","['1. A detector arrangement for an X-ray phase contrast system (5), the detector arrangement (1) comprising: - a scintillator (11); - an optical grating (12); and - a detector (13); - wherein the optical grating (12) is arranged between the scintillator (11) and the detector (13) and is configured to be electronically adjustable; wherein the scintillator (11) converts X-ray radiation (2) into optical radiation (3); wherein the optical grating (12) is configured to be an analyzer grating being adapted to a phase-grating (21) of an X-ray phase contrast system (5) and - characterised in that an optical path between the optical grating (12) and the scintillator (11) is free of focussing elements for optical radiation.', '3. Detector arrangement according to claim 2, wherein the detector arrangement (13) comprises an optical polarizing unit (16); wherein the optical polarizing unit (16) is positioned between the optical grating (12) and the scintillator (11); and wherein the LCD pixel array (15) is an active LCD pixel array (15) being configured to dynamically change a polarization of the analyzer grating.', '9. A method (100) for X-ray phase contrast imaging, the method comprising the following steps: a) converting (101) X-ray radiation to optical radiation with a scintillator; b) subsampling (102) the optical radiation with an optical grating resulting in a subsampled optical radiation pattern, wherein the optical path between the optical grating and the scintillator is free of focussing elements for optical radiation; and c) detecting (103) the subsampled optical radiation pattern with a detector.', '10. Method according to claim 9, wherein the optical grating is provided by a pixel array, the method (100) comprising the step: d) changing (104) the position of the optical grating on the pixel array with a processing unit controlling the pixel array.']",True,"['100', '101', '100', '102', '101', '103', '102', '105', '103', '106', '104', '5', '107', '9', '15']" 704,EP_3602576_B1.png,EP3602576B1,DETECTOR ARRANGEMENT FOR AN X-RAY PHASE CONTRAST SYSTEM AND METHOD FOR X-RAY CONTRAST IMAGING,['FIG1'],['FIG1 shows a schematic view of an embodiment of the detector arrangement'],"['FIG1 shows an embodiment of a detector arrangement 1. The detector arrangement 1 comprises an X-ray transparent wall 14, a conversion unit, a subsampling unit, and a detection unit. The subsampling unit is arranged between the conversion unit and the detection unit.']",12,50,schematic view,G,"[{'element_identifier': '17', 'terms': ['signal line']}, {'element_identifier': '14', 'terms': ['X-ray transparent wall']}, {'element_identifier': '12', 'terms': ['optical grating']}, {'element_identifier': '23', 'terms': ['bi-stable display']}, {'element_identifier': '11', 'terms': ['scintillator']}, {'element_identifier': '1', 'terms': ['detector arrangement']}, {'element_identifier': '18', 'terms': ['signal line']}, {'element_identifier': '27', 'terms': ['transparent electrodes']}, {'element_identifier': '10', 'terms': ['light detection elements']}, {'element_identifier': '3', 'terms': ['optical radiation']}, {'element_identifier': '13', 'terms': ['detector']}]","['1. A detector arrangement for an X-ray phase contrast system (5), the detector arrangement (1) comprising: - a scintillator (11); - an optical grating (12); and - a detector (13); - wherein the optical grating (12) is arranged between the scintillator (11) and the detector (13) and is configured to be electronically adjustable; wherein the scintillator (11) converts X-ray radiation (2) into optical radiation (3); wherein the optical grating (12) is configured to be an analyzer grating being adapted to a phase-grating (21) of an X-ray phase contrast system (5) and - characterised in that an optical path between the optical grating (12) and the scintillator (11) is free of focussing elements for optical radiation.']",True,"['14', '11', '00000000', '12', '13', '17', '10', '1', '14', '11', '27', '12', '27', '13', '23', '3', '18', '17', '11']" 705,EP_3603220_B1 (4).png,EP3603220B1,QOS FLOWS INACTIVITY COUNTERS,['FIG7'],['FIG7 shows an example implementation flowchart according to the present disclosure'],"['FIG7 presents an implementation scenario 700 (which is non-limiting) described below. In the following, a simple example of how the inactivity counter can be used to release the mapping between a QoS flow and a DRB is provided. It is worth noting that this is just an illustrative example and that the same procedure can also be used in other scenarios (e.g., for removing QoS flows in the RAN 318). A similar procedure can also be used at handover to decide to release the mapping between QoS flows and DRBs and/or to not admit some QoS flows (and corresponding DRBs).', 'In FIG7, QFI3 is an (non-limiting) example for a QoS flow. DRB1 is a (non-limiting example) for a DRB.']",11,145,flowchart,H,"[{'element_identifier': '7', 'terms': ['andFig.']}, {'element_identifier': '704', 'terms': ['step']}, {'element_identifier': '710', 'terms': ['step']}, {'element_identifier': '706', 'terms': ['step']}, {'element_identifier': '708', 'terms': ['step']}, {'element_identifier': '702', 'terms': ['step']}, {'element_identifier': '23', 'terms': ['document 3GPP TR', 'document TS']}, {'element_identifier': '200', 'terms': ['method']}, {'element_identifier': '700', 'terms': ['implementation scenario']}]","['1. A method (200) for a device (100) to manage a data flow (608; 618) in a wireless communication system, comprising: obtaining (202) a time period for which the data flow (608; 618) has been inactive, characterized in that the data flow (608; 618) is defined by a Quality of Service, QoS, requirement of data associated with the data flow (608; 618); and determining (204), based on the time period, to release a mapping between the data flow (608; 618) and a radio bearer (610).']",False,"['700', '702', '704', '23', '706', '200', '708', '7', '710']" 706,EP_3603427_A1 (1).png,EP3603427A1,ULTRASONIC ELECTRONIC CIGARETTE ATOMIZER AND ELECTRONIC CIGARETTE USING SAME,['FIG2'],['FIG2 is an oblique cross-sectional view of Embodiment 1 of the atomizer'],"['A connecting sleeve 9 is further disposed in the housing 2, an air inlet tube 10 is disposed in the connecting sleeve 9, and the top of a side wall of the connecting sleeve 9 is provided with an air passing hole 91 for communicating the air inlet 303 with the air inlet tube 10; an inner sleeve 11 and an outer sleeve 12 which are connected with each other in a sleeved way are further disposed in the connecting sleeve 9, the e-liquid guide cotton 7 is cup-shaped, and the side wall of the e-liquid guide cotton 7 is sandwiched between the inner sleeve 11 and the outer sleeve 12; the connecting sleeve 9 is provided with a first e-liquid passing hole 92, the outer sleeve 12 is provided with a second e-liquid passing hole 121, and the e-liquid chamber 6, the first e-liquid passing hole 92, the second e-liquid passing hole 121, and the e-liquid guide cotton 7 are sequentially communicated; the air outlet channel 5 is formed between the inner wall of the inner sleeve 11 and the outer wall of the air inlet tube 10, and the top surface of the connecting sleeve 9 is provided with an air outlet 93 for communicating the air outlet channel 5 with the suction portion 302. The shaded arrows in FIG2 indicate an air flow direction, and small solid arrows indicate a splashing direction of large particles of e-liquid.']",14,276,oblique cross-sectional view,A,"[{'element_identifier': '11', 'terms': ['inner sleeve']}]","['4. The ultrasonic electronic cigarette atomizer according to claim 1 or 2, wherein an e-liquid chamber (6) and an e-liquid guide cotton (7) for communicating the e-liquid chamber (6) with an atomization surface of the ultrasonic atomization sheet (1) are disposed in the housing (2), a connecting sleeve (9) is disposed in the housing (2), an air inlet tube (10) is disposed in the connecting sleeve (9), and the top of a side wall of the connecting sleeve (9) is provided with an air passing hole (91) for communicating the air inlet (303) with the air inlet tube (10); the inner of the connecting sleeve (9) is further provided with an inner sleeve (11) and an outer sleeve (12) sleeved on the inner sleeve (11); the e-liquid guide cotton (7) is cup-shaped, and the side wall of the e-liquid guide cotton (7) is sandwiched between the inner sleeve (11) and the outer sleeve (12); the connecting sleeve (9) is provided with a first e-liquid passing hole (92), the outer sleeve (12) is provided with a second e-liquid passing hole (121), and the e-liquid chamber (6), the first e-liquid passing hole (92), the second e-liquid passing hole (121); the e-liquid guide cotton (7) are sequentially communicated; the air outlet channel (5) is formed between the inner wall of the inner sleeve (11) and the outer wall of the air inlet tube (10), and the top surface of the connecting sleeve (9) is provided with an air outlet (93) for communicating the air outlet channel (5) with the suction portion (302).']",False,['11'] 707,EP_3603434_A1 (3).png,EP3603434A1,HELMET,['FIG5A'],['FIG5A is a left side view of the helmet according to the exemplary embodiment of the present invention when the shield is closed and the chin guard is down'],"['FIG5A is a left side view of the helmet according to the exemplary embodiment of the present invention when the shield is closed and the chin guard is down. As shown in FIG5A, the cover member 15a is provided so as to cover the rear side of the turning mechanism 12a. In this case, if an upper face of the seal member 14 and an upper face of the cover member 15a form a continuous surface, the shield 20 can be formed as a continuous surface that corresponds with the continuous surface of the seal member 14 and the cover member 15a. Consequently, it is desirable, as there are fewer step shapes, the ingression prevention effect is improved, appearance is excellent, and fabrication is simple.']",29,137,left side view,A,"[{'element_identifier': '11', 'terms': ['aperture window']}, {'element_identifier': '20', 'terms': ['shield']}, {'element_identifier': '111', 'terms': ['aperture window upper edge']}, {'element_identifier': '10', 'terms': ['main hat body']}, {'element_identifier': '13', 'terms': ['chin guard']}]","['1. A helmet comprising: a substantially spherical main hat body including an aperture window that opens forward to provide a field of view to a wearer; a shield connected to a pair of turning mechanisms protruding from two side faces of the main hat body, the shield being movable between a closed position at which the shield closes off the aperture window and an open position at which the shield opens the aperture window; and a seal member that, when the shield is at the closed position, seals a gap between an upper edge of the shield and an upper edge of the aperture window from a vicinity of one of the turning mechanisms to a vicinity of another of the turning mechanisms of the main hat body, wherein at least a part of an upper end portion of the shield, at vicinities of upper edges of left and right end portions of the seal member, is inflected toward the main hat body, and the part of the upper end portion of the shield abuts the seal member when the shield is at the closed position.', '4. The helmet according to claim 3, wherein the helmet is a full-face type helmet including a chin guard below the aperture window, and the cover members are integral with the chin guard.']",False,"['10', '20', '111', '11', '13', '11']" 708,EP_3603434_A1 (4).png,EP3603434A1,HELMET,['FIG5B'],['FIG5B is a right side view showing a positional relationship between a cover member and a seal member when the chin guard is down'],"['FIG5B is a right side view of the helmet according to the exemplary embodiment of the present invention when the chin guard is down. As shown in FIG5B, in the present exemplary embodiment the cover member 15b at the right side is attached to the chin guard 13. Although not shown in the drawings, the cover member 15a at the left side is attached to the chin guard 13 similarly to the cover member 15b at the right side. When the chin guard 13 is down, an upper end portion 151b of the cover member 15b overlaps with the right end 141b of the seal member 14 and, although not shown in the drawings, an upper end portion 151a of the cover member 15a overlaps with the left end 141a of the seal member 14.']",24,144,right side view,A,"[{'element_identifier': '14', 'terms': ['seal member']}, {'element_identifier': '11', 'terms': ['aperture window']}, {'element_identifier': '111', 'terms': ['aperture window upper edge']}, {'element_identifier': '10', 'terms': ['main hat body']}, {'element_identifier': '13', 'terms': ['chin guard']}]","['1. A helmet comprising: a substantially spherical main hat body including an aperture window that opens forward to provide a field of view to a wearer; a shield connected to a pair of turning mechanisms protruding from two side faces of the main hat body, the shield being movable between a closed position at which the shield closes off the aperture window and an open position at which the shield opens the aperture window; and a seal member that, when the shield is at the closed position, seals a gap between an upper edge of the shield and an upper edge of the aperture window from a vicinity of one of the turning mechanisms to a vicinity of another of the turning mechanisms of the main hat body, wherein at least a part of an upper end portion of the shield, at vicinities of upper edges of left and right end portions of the seal member, is inflected toward the main hat body, and the part of the upper end portion of the shield abuts the seal member when the shield is at the closed position.', '4. The helmet according to claim 3, wherein the helmet is a full-face type helmet including a chin guard below the aperture window, and the cover members are integral with the chin guard.']",False,"['10', '14', '12', '111', '11', '13']" 709,EP_3603483_A1 (3).png,EP3603483A1,ENDOSCOPE SYSTEM AND METHOD FOR OPERATING SAME,"['FIG13', ' FIG14']","['FIG13 is a diagram illustrating a display screen of a display unit that displays the first marked image ', 'FIG14 is a diagram illustrating the display screen in which a warning indication has been changed in accordance with a discrimination result']","['For example, as illustrated in FIG13, the first marked image 90 is displayed on the display screen of the display unit 18. In FIG13, the endoscopic image 86 is displayed in addition to the first marked image 90. In the first marked image 90, the mark M1 indicating that the ROI R1 has been detected and the mark M2 indicating that the ROI R2 has been detected are displayed. Accordingly, the user is able to easily recognize the positions of the ROIs, and thus the diagnosis time taken to re-search for the ROIs R1 and R2 is further shortened.', 'In the first marked image 90, the insertion state L of the endoscope 12 is displayed at the corresponding position in the schematic diagram 92. In FIG13, the end of the insertion state L of the endoscope 12 is at the position of the mark M1. That is, it is indicated that the distal end portion 21 of the endoscope 12 in the lumen is at the detection position P1 at which the ROI R1 has been detected. Accordingly, the user is able to recognize the current insertion state of the endoscope 12, and is thus able to move the distal end portion 21 of the endoscope 12 to a desired position in a short time. As a result, the diagnosis time is further shortened.', 'The mark M1 and the mark M2 are displayed in different manners in accordance with a discrimination result acquired by the discrimination unit 82. In FIG13, the line of the mark M2 is thicker than the line of the mark M1. This enables the user to easily recognize the discrimination result.', 'On the display screen of the display unit 18, a warning indication 95 indicating that the distal end portion 21 is close to the ROI is displayed (see FIG13). Accordingly, the ROI is prevented from being overlooked.', 'The display mode of the warning indication 95 is changed in accordance with a discrimination result acquired by the discrimination unit 82. In FIG13, ""!"" is displayed as the warning indication 95 in a case where a discrimination result indicating an adenoma is acquired by the discrimination unit 82. ', 'On the other hand, in a case where the end of the insertion state L of the endoscope 12 is at the position of the mark M2 as illustrated in FIG14, that is, in a case where the distal end portion 21 of the endoscope 12 in the lumen is at the detection position P2 at which the ROI R2 has been detected, the warning indication 95 is changed to ""!!"". Because the ROI R2 is a region for which a discrimination result indicating a lesion portion is acquired by the discrimination unit 82, it is preferable to display the warning indication 95 that is further emphasized. This enables the user to recognize that the lesion needs a particular care, which makes it possible to more reliably prevent the ROI requiring a detailed examination or treatment from being overlooked.']",40,554,diagram,A,"[{'element_identifier': '14', 'terms': ['light source device']}, {'element_identifier': '92', 'terms': ['schematic diagram']}, {'element_identifier': '87', 'terms': ['endoscopic image']}, {'element_identifier': '86', 'terms': ['endoscopic image']}, {'element_identifier': '25', 'terms': ['angle knob']}, {'element_identifier': '90', 'terms': ['first marked image']}]","['1. An endoscope system comprising: an endoscope; an endoscopic image acquisition unit that acquires an endoscopic image acquired by capturing an image of a lumen with the endoscope; a region-of-interest detecting unit that detects a region of interest in the lumen by using the endoscopic image; a position information acquisition unit that acquires position information of the region of interest; and a display unit that displays the position information of the region of interest.', '2. The endoscope system according to claim 1, comprising: a first marked image generating unit that generates a first marked image having a marking at a position corresponding to the position information of the region of interest in a schematic diagram of the lumen, wherein the display unit displays the first marked image.']",True,"['13', '86', '90', '92', '14', '2', '87', '90', '25']" 710,EP_3603483_A1 (4).png,EP3603483A1,ENDOSCOPE SYSTEM AND METHOD FOR OPERATING SAME,"['FIG15', ' FIG16']","['FIG15 is a diagram illustrating a display screen that displays lumen portion information as position information of ROIs ', 'FIG16 is a diagram illustrating a display screen that displays distance information indicating the distance from a reference structure as position information of ROIs']","['FIG15 illustrates a specific example in which, in a case where the ROI R1 and the ROI R2 have been detected, the lumen portion information of the lumen portion in which the ROI R1 has been detected and the lumen portion information of the lumen portion in which the ROI R2 has been detected are displayed on the display screen of the display unit 18. In this example, the names of the lumen portions are displayed in text as the lumen portion information, and it is indicated that the ROI R1 has been detected in the descending colon and that the ROI R2 has been detected in the transverse colon.', 'In FIG15, a schematic diagram 94 of a lumen is displayed. The schematic diagram 94 is divided into six sections corresponding to the cecum, the ascending colon, the transverse colon, the descending colon, the sigmoid colon, and the rectum. In the schematic diagram 94, the section corresponding to the descending colon and the section corresponding to the transverse colon are displayed differently from the other sections. Furthermore, in FIG15, the difference between the section corresponding to the descending colon and the section corresponding to the transverse colon is represented by the difference in intervals of hatching. In this example, the schematic diagram 94 is also displayed on the display screen of the display unit 18, but the method for displaying the lumen portion information is not limited thereto. The display mode of the section in which a ROI has been detected may be changed in accordance with a discrimination result. ', 'FIG16 illustrates a specific example in which, in a case where the ROI R1 and the ROI R2 have been detected, the position of the ROI R1 is displayed as the distance from the anus and the position of the ROI R2 is displayed as the distance from the Bauhin\'s valve, on the display screen of the display unit 18. In FIG16, the distance information is displayed in the form of text and numerical values, that is, ""A cm from the anus"" is displayed for the ROI R1 and ""B cm from the Bauhin\'s valve"" is displayed for the ROI R2. In FIG16, the distance information is displayed in the form of text and numerical values and also a schematic diagram 96 of the lumen is displayed, but the method for displaying distance information indicating the distance from the reference structure is not limited thereto.']",42,446,diagram,A,"[{'element_identifier': '98', 'terms': ['schematic diagram']}, {'element_identifier': '86', 'terms': ['endoscopic image']}, {'element_identifier': '96', 'terms': ['schematic diagram']}, {'element_identifier': '16', 'terms': ['processor device']}, {'element_identifier': '26', 'terms': ['image storage operation unit']}]","['1. An endoscope system comprising: an endoscope; an endoscopic image acquisition unit that acquires an endoscopic image acquired by capturing an image of a lumen with the endoscope; a region-of-interest detecting unit that detects a region of interest in the lumen by using the endoscopic image; a position information acquisition unit that acquires position information of the region of interest; and a display unit that displays the position information of the region of interest.', '2. The endoscope system according to claim 1, comprising: a first marked image generating unit that generates a first marked image having a marking at a position corresponding to the position information of the region of interest in a schematic diagram of the lumen, wherein the display unit displays the first marked image.']",True,"['15', '98', '16', '86', '96', '26']" 711,EP_3603483_A1 (5).png,EP3603483A1,ENDOSCOPE SYSTEM AND METHOD FOR OPERATING SAME,"['FIG17', ' FIG18']","['FIG17 is a diagram illustrating a display screen that displays insertion lengths as position information of ROIs ', 'FIG18 is a block diagram illustrating the functions of a ROI searching image processing unit having a biological feature value calculating unit']","['FIG17 illustrates a specific example in which, in a case where the ROI R1 and the ROI R2 have been detected, the insertion length with which the ROI R1 has been detected and the insertion length with which the ROI R2 has been detected are displayed on the display screen of the display unit 18. In this example, the insertion lengths are displayed in the form of numerical values, that is, the insertion length with which the ROI R1 has been detected is X cm and the insertion length with which the ROI R2 has been detected is Y cm. In FIG17, the insertion lengths are displayed in the form of numerical values and also a schematic diagram 98 of the lumen is displayed, but the method for displaying the insertion lengths is not limited thereto. ', 'In this case, the ROI searching image processing unit 66 is replaced with a ROI searching image processing unit 100, as illustrated in FIG18. The ROI searching image processing unit 100 has a biological feature value calculating unit 102 in addition to the components of the ROI searching image processing unit 66. A description will not be given of the same components as those of the ROI searching image processing unit 66.']",39,223,"block diagram, diagram",A,"[{'element_identifier': '80', 'terms': ['ROI detecting unit']}, {'element_identifier': '98', 'terms': ['schematic diagram']}, {'element_identifier': '18', 'terms': ['display unit']}, {'element_identifier': '86', 'terms': ['endoscopic image']}, {'element_identifier': '84', 'terms': ['marked image generating unit']}, {'element_identifier': '85', 'terms': ['storage unit']}, {'element_identifier': '27', 'terms': ['mode switching unit']}, {'element_identifier': '102', 'terms': ['feature value calculating unit']}, {'element_identifier': '83', 'terms': ['warning unit']}]","['1. An endoscope system comprising: an endoscope; an endoscopic image acquisition unit that acquires an endoscopic image acquired by capturing an image of a lumen with the endoscope; a region-of-interest detecting unit that detects a region of interest in the lumen by using the endoscopic image; a position information acquisition unit that acquires position information of the region of interest; and a display unit that displays the position information of the region of interest.', '2. The endoscope system according to claim 1, comprising: a first marked image generating unit that generates a first marked image having a marking at a position corresponding to the position information of the region of interest in a schematic diagram of the lumen, wherein the display unit displays the first marked image.', '8. The endoscope system according to any one of claims 5 to 7, comprising: a discrimination result storage unit that stores the discrimination result.', '10. The endoscope system according to claim 4 or 9, comprising: a warning unit that provides a warning, based on the position information of the region of interest and the insertion state of the endoscope.', '12. The endoscope system according to any one of claims 4 to 11, comprising: a biological feature value calculating unit that calculates a biological feature value of the region of interest, wherein the display unit changes a display mode of the marking by using the biological feature value in addition to a discrimination result acquired by the discrimination unit.']",True,"['17', '86', '98', '18', '80', '102', '83', '84', '85', '27']" 712,EP_3603497_A1 (1).png,EP3603497A1,APPARATUS AND METHOD FOR ESTIMATING BIO-INFORMATION,['FIG2'],['FIG2 is a block diagram illustrating a bio-information estimating apparatus according to another embodiment'],"['FIG2 is a block diagram illustrating a bio-information estimating apparatus according to another exemplary embodiment.', 'Referring to FIG2, the bio-information estimating apparatus 200 includes a processor 120, a communicator 210, an output part 220, and a storage part 230.', 'Although a sensor for measuring a bio-signal is not illustrated in FIG2, the bio-information estimating apparatus 200 may include the sensor depending on an embodiment. In this case, under the control of the processor 120 or at the request of the external device 250, the bio-information estimating apparatus 200 may selective obtain a bio-signal. For example, the bio-information estimation apparatus 200 may obtain a bio-signal by receiving a bio-signal from the external device 250 or by directly driving the sensor.']",16,152,block diagram,A,"[{'element_identifier': '210', 'terms': ['communicator']}, {'element_identifier': '230', 'terms': ['storage part']}, {'element_identifier': '220', 'terms': ['output part']}, {'element_identifier': '250', 'terms': ['external device']}, {'element_identifier': '200', 'terms': ['apparatus', 'apparatuses']}, {'element_identifier': '120', 'terms': ['processor']}]","['1. An apparatus for estimating bio-information, the apparatus comprising: a sensor configured to measure a bio-signal; and a processor configured to obtain one or more characteristic points, related to one or more pulse waveform components constituting the bio-signal, based on a differential signal of the bio-signal, and to estimate bio-information based on the obtained one or more characteristic points.', '6. 6. The apparatus of one of claims 1 to 5, wherein the processor is configured to extract a feature by combining one or more of the obtained one or more characteristic points related to the one or more pulse waveform components, and estimate the bio-information based on the extracted feature, or wherein the sensor comprises a light source configured to emit light onto an object; and a detector configured to detect light scattered from the object, or wherein the bio-information comprises at least one of blood pressure, vascular age, arterial stiffness, aortic pressure waveform, stress index, and degree of fatigue, or further comprising an output part configured to output a processing result of the processor.', '15. A computer-readable medium having instructions that, when performed by a processor, cause the processor to perform the steps of: receiving, by a communicator, a bio-signal from an external device; and causing the processor to obtain one or more characteristic points, related to one or more pulse waveform components constituting the bio-signal, based on a differential signal of the received bio-signal, and to estimate bio-information based on the obtained one or more characteristic points.']",False,"['200', '120', '220', '210', '250', '15', '230']" 713,EP_3603505_A1 (1).png,EP3603505A1,"INFORMATION PROCESSING SYSTEM, INFORMATION PROCESSING DEVICE, AND INFORMATION PROCESSING METHOD",['FIG2'],['FIG2 is an explanatory diagram illustrating a configuration example of the information processing system 100'],"['FIG2 is an explanatory diagram illustrating a configuration example of the information processing system 100. The information processing system 100 includes the information processing device 101, data acquisition devices 201, hubs 202, and databases 203. The information processing device 101 and the data acquisition devices 201 are connected by a network 210 such as the Internet, a local area network (LAN), a wide area network (WAN), and the like, and the hubs 202.', 'The data acquisition devices 201 are devices which are attached to portions of a user and, each of which measures the movements of the corresponding portion. Then, each of the data acquisition devices 201 has the sensor 102, and measures the acceleration in three axes and the angular velocity in three axes of the portion to which the data acquisition device 201 is attached. In the example of FIG2, the plurality of data acquisition devices 201 is attached to portions of the user uA and a user uB.']",15,182,explanatory diagram,A,"[{'element_identifier': '201', 'terms': []}, {'element_identifier': '210', 'terms': ['network']}, {'element_identifier': '202', 'terms': ['hubs', 'hub']}, {'element_identifier': '203', 'terms': ['databases']}, {'element_identifier': '100', 'terms': ['information processing system']}, {'element_identifier': '2', 'terms': ['following expression']}, {'element_identifier': '25', 'terms': ['Vol.']}, {'element_identifier': '101', 'terms': ['information processing device']}]","['1. An information processing system comprising: a sensor configured to measure at least a motion among a state or the motion of a living body or an object; and an information processing device capable of communicating with the sensor, wherein the information processing device is configured to extract, from time-series data obtained by the sensor, a first data section, in which the state of the living body or the object is changed to a predetermined state or the living body or the object makes a predetermined motion, extract, from the time-series data, a second data section different from the first data section, calculate, based on a feature amount of the first data section and a feature amount of the second data section, a likelihood value that indicates likelihood that the second data section is an adjustment motion section during which a motion for adjusting a posture of the living body or the object is made for the first data section, and determine, based on the likelihood value that is calculated, whether the second data section is an adjustment motion section for the first data section.']",False,"['2', '203', '100', '203', '101', '210', '203', '202', '201', '201', '201', '202', '201', '201', '201', '25']" 714,EP_3603505_A1 (2).png,EP3603505A1,"INFORMATION PROCESSING SYSTEM, INFORMATION PROCESSING DEVICE, AND INFORMATION PROCESSING METHOD",['FIG3'],['FIG3 is an explanatory diagram illustrating a configuration example of hardware of an information processing device 101 and a data acquisition device 201'],"['The databases 203 store data acquired from the data acquisition devices 201, data obtained by converting the acquired data, and feature amounts extracted from the data obtained by the conversion. Next, the hardware configuration of the information processing device 101 will be described with reference to FIG3.', 'FIG3 is an explanatory diagram illustrating a configuration example of hardware of the information processing device 101 and the data acquisition device 201. In FIG3, the information processing device 101 includes a control unit 301, a main storage unit 302, an auxiliary storage unit 303, a drive device 304, a network interface (I/F) unit 306, an input unit 307, and an output unit 308. The control unit 301 to the drive device 304, and the network I/F unit 306 to the output unit 308 are connected to each other by a bus 309.']",23,163,explanatory diagram,A,"[{'element_identifier': '201', 'terms': []}, {'element_identifier': '202', 'terms': ['hubs', 'hub']}, {'element_identifier': '307', 'terms': ['input unit']}, {'element_identifier': '303', 'terms': ['auxiliary storage unit']}, {'element_identifier': '315', 'terms': ['bus']}, {'element_identifier': '313', 'terms': ['auxiliary storage unit']}, {'element_identifier': '304', 'terms': ['drive device']}, {'element_identifier': '302', 'terms': ['main storage unit']}, {'element_identifier': '314', 'terms': ['network I/F unit']}, {'element_identifier': '308', 'terms': ['output unit']}, {'element_identifier': '312', 'terms': ['main storage unit']}, {'element_identifier': '306', 'terms': ['unit']}, {'element_identifier': '301', 'terms': ['control unit']}, {'element_identifier': '305', 'terms': ['storage medium']}, {'element_identifier': '210', 'terms': ['network']}, {'element_identifier': '311', 'terms': ['control unit']}, {'element_identifier': '102', 'terms': ['sensor']}, {'element_identifier': '101', 'terms': ['information processing device']}, {'element_identifier': '3', 'terms': []}, {'element_identifier': '309', 'terms': ['bus']}]","['1. An information processing system comprising: a sensor configured to measure at least a motion among a state or the motion of a living body or an object; and an information processing device capable of communicating with the sensor, wherein the information processing device is configured to extract, from time-series data obtained by the sensor, a first data section, in which the state of the living body or the object is changed to a predetermined state or the living body or the object makes a predetermined motion, extract, from the time-series data, a second data section different from the first data section, calculate, based on a feature amount of the first data section and a feature amount of the second data section, a likelihood value that indicates likelihood that the second data section is an adjustment motion section during which a motion for adjusting a posture of the living body or the object is made for the first data section, and determine, based on the likelihood value that is calculated, whether the second data section is an adjustment motion section for the first data section.', '13. An information processing device capable of communicating with a sensor configured to measure at least a motion among a state or the motion of a living body or an object, comprising a control unit configured to extract, from time-series data obtained by the sensor, a first data section, in which the state of the living body or the object is changed to a predetermined state or the living body or the object makes a predetermined motion, extract, from the time-series data, a second data section different from the first data section, calculate, based on a feature amount of the first data section and a feature amount of the second data section, a likelihood value that indicates likelihood that the second data section is an adjustment motion section during which a motion for adjusting a posture of the living body or the object is made for the first data section, and determine, based on the likelihood value that is calculated, whether the second data section is an adjustment motion section for the first data section.']",False,"['3', '201', '315', '311', '312', '313', '101', '301', '309', '306', '302', '307', '303', '308', '304', '305', '102', '314', '202', '210', '26']" 715,EP_3603505_A1 (6).png,EP3603505A1,"INFORMATION PROCESSING SYSTEM, INFORMATION PROCESSING DEVICE, AND INFORMATION PROCESSING METHOD",['FIG17'],['FIG17 is an explanatory diagram illustrating an example of sensor data during walking of the patient uA in the first embodiment'],"['The data acquisition device 201 can also access a sensor data storage unit 410. The sensor data storage unit 410 is stored in an storage area of the main storage unit 312, the auxiliary storage unit 313, or the like. An example of the stored content of the sensor data storage unit 410 is illustrated in FIG17.', 'FIG17 is an explanatory diagram illustrating an example of sensor data during walking of the patient uA in the first embodiment. FIG17 illustrates a gyro value of each of the portions. Specifically, the sensor data pieces 1701-1 to 1701-4 indicate sensor data pieces of the left foot gyro value, the right foot gyro value, the waist gyro value, and the waist acceleration value respectively at each time. Here, the sensor 102 of the data acquisition device 201 measures the acceleration and the gyro value in the directions of three axes. However, in FIG17, in order to simplify the illustration, the gyro value is illustrated only in the frontal-horizontal axis rotation direction, and the acceleration is illustrated only in the up and down direction. The same applies to the following description unless otherwise specified. The information processing device 101 acquires sensor data of each portion from the sensor data storage unit 410.']",21,236,explanatory diagram,A,"[{'element_identifier': '400', 'terms': ['sensor data acquisition unit']}, {'element_identifier': '17', 'terms': ['No.']}, {'element_identifier': '410', 'terms': []}]","['9. The information processing system according to claim 8, wherein the living body is a patient, one motion model of the plurality of motion models has a ratio between a movement amount of the waist of the living body in the front and back direction and a movement amount of the waist of the living body in the left and right direction, a rotational speed of the foot of the living body, and a strength of stepping on the foot as the feature amounts, and in the one motion model, the calculating processing calculates the likelihood value higher when a condition is satisfied comparing to the likelihood value when the condition is not satisfied, the condition being that the movement amount of the waist in the front and back direction in the second data section is as large as the movement amount of the waist in the left and right direction multiplied by a predetermined threshold value, and/or the rotational speed of the foot in the first data section and the strength of stepping on the foot in the first data section is within a predetermined threshold value range.']",False,"['17', '400', '410', '40']" 716,EP_3603528_A1 (3).png,EP3603528A1,ULTRASONIC ENDOSCOPE,['FIG8'],['FIG8 is an external perspective view of a distal end rigid portion of an insertion section according to a second embodiment'],"['FIG8 is an external perspective view of a distal end rigid portion 134 of an insertion section of an ultrasonic endoscope according to a second embodiment. The distal end rigid portion 134 according to the second embodiment differs from the distal end rigid portion 34 according to the first embodiment in that the distal end rigid portion 134 does not have a standing wall portion and a light-guiding recessed wall portion. In embodiments described below, elements that are the same those of the first embodiment will be denoted by the same numerals and description of such elements may be omitted.', 'Even without a standing wall portion, in the positional relationship between an opening 158 from which a treatment tool is led to the outside and the observation window 44, by locating the position of the opening 158 on the distal end side relative to the observation window 44 in the distal end rigid portion 34 and locating, in the first direction indicated by arrow A in FIG8, a one-side opening position, which is the position of an end portion of the opening that is furthest toward the one-side in the first direction, below an axis 145 of the observation window 44, a treatment tool led out from the opening 158 can be placed within the field of view of the observation window 44. The axis 145 of the observation window 44 is a line extending from the center position of the observation window 44 toward the distal end side, and is a line that is parallel to an axis 138 of the distal end rigid portion 134.', 'In the first direction indicated by arrow A in FIG8, when the position of an end portion of the opening 158 that is furthest toward the other side in the first direction is defined as an other-side opening position, and the position of a vertex of the ultrasound transmitting/receiving surface 52 of the ultrasonic transducer 50 that is located furthest toward the one side in the first direction is defined as a vertex position, the vertex position is identical to the other-side opening position or is located on the one side in the first direction relative to (above) the other-side opening position. With such a structure, as with the first embodiment, a treatment tool can be led out so as to be close to the ultrasonic transducer 50.']",21,434,perspective view,A,"[{'element_identifier': '158', 'terms': ['opening']}, {'element_identifier': '52', 'terms': ['ultrasound transmitting/receiving surface']}, {'element_identifier': '90', 'terms': ['stent']}, {'element_identifier': '145', 'terms': ['axis']}, {'element_identifier': '68', 'terms': ['standing wall portion']}, {'element_identifier': '136', 'terms': ['end rigid portion body']}, {'element_identifier': '48', 'terms': ['air/water supply nozzle']}, {'element_identifier': '94', 'terms': ['body cavity wall']}, {'element_identifier': '78', 'terms': ['deflecting portion']}, {'element_identifier': '72', 'terms': ['observation means forming surface']}, {'element_identifier': '80', 'terms': ['treatment tool lead-out port']}, {'element_identifier': '96', 'terms': ['insertion point']}, {'element_identifier': '134', 'terms': ['distal end rigid portion']}, {'element_identifier': '44', 'terms': ['observation window']}, {'element_identifier': '62', 'terms': ['erecting base housing portion']}, {'element_identifier': '138', 'terms': ['axis']}, {'element_identifier': '50', 'terms': ['ultrasonic transducer']}, {'element_identifier': '58', 'terms': ['opening']}, {'element_identifier': '60', 'terms': ['erecting base']}]","['1. An ultrasonic endoscope comprising: a distal end rigid portion that is located at a distal end of an endoscope insertion section; an ultrasonic transducer that is disposed in the distal end rigid portion; a treatment tool lead-out portion that is disposed on a proximal end side of the ultrasonic transducer and that comprises an erecting base housing portion that has an opening whose opening direction is toward one side in a first direction that is perpendicular to an axial direction of the distal end rigid portion or whose opening direction is a direction that has a component toward the one side in the first direction and a component toward a distal end side in the axial direction of the distal end rigid portion, an opening forming surface in which the opening is formed and that has a normal component in the opening direction, a treatment tool lead-out port that communicates with an inside of the erecting base housing portion and from which a treatment tool is led out, and a treatment-tool erecting base that is disposed in the inside of the erecting base housing portion and that changes a lead-out direction of the treatment tool led out from the treatment tool lead-out port; and an observation window that is disposed on a proximal end side of the opening forming surface and that is disposed in an observation means forming surface that has a normal component toward the distal end side in the axial direction of the distal end rigid portion, wherein, when a position of an end portion of the opening that is furthest toward the one side in the first direction is defined as a one-side opening position, a position of the observation window in the first direction is located on the one side in the first direction relative to the one-side opening position.', '2. The ultrasonic endoscope according to claim 1, wherein the ultrasonic transducer has an ultrasound transmitting/receiving surface that is formed in a curved shape in the axial direction of the distal end rigid portion.', '5. The ultrasonic endoscope according to claim 1, wherein the ultrasonic endoscope has a standing wall portion around the opening, the standing wall portion standing from the opening, and wherein, when a position of an end portion of an upper edge of the standing wall portion that is furthest toward the one side in the first direction is defined as a one-side wall upper end position, the position of the observation window in the first direction is located on the one side in the first direction relative to the one-side wall upper end position.']",True,"['7', '94', '96', '90', '60', '58', '68', '134', '136', '44', '78', '72', '80', '62', '60', '158', '8', '48', '50', '145', '138', '52', '19']" 717,EP_3603529_A1 (6).png,EP3603529A1,ULTRASONIC ENDOSCOPE,['FIG9'],"['FIG9 is a sectional view of a distal end portion body, illustrating the disposition of signal cables according to a modification']","['FIG9 is sectional view of the distal end portion body 36, illustrating another example of the disposition of the signal cables 86A and 86B in the distal end portion body 36. As illustrated in FIG9, among the two signal cables 86, the signal cable 86A (at least one of the signal cables) is disposed on one side in the second direction indicated by arrow B relative to the erecting base housing portion 62, and the signal cable 86B (at least another of the signal cables) is disposed on the other side in the second direction relative to the erecting base housing portion 62. By disposing the signal cables 86A and 86B in this way, the erecting base housing portion 62 can be lowered in the distal end portion body 36, the distance between the cleaning communication hole 84 and the erecting base 60 can be reduced, and cleaning of the back side of the erecting base 60 and the surrounding part can be easily performed. Although the external view of the sectional view shown in FIG9 is omitted, the positions of the observation window 44, the illumination windows 46L and 46R, and the air/water supply nozzle 48 may be appropriately set.']",22,221,sectional view,A,"[{'element_identifier': '158', 'terms': ['opening']}, {'element_identifier': '20', 'terms': ['air/water supply button']}, {'element_identifier': '52', 'terms': ['ultrasound transmitting/receiving surface']}, {'element_identifier': '136', 'terms': ['distal end portion body']}, {'element_identifier': '48', 'terms': ['air/water supply nozzle']}, {'element_identifier': '78', 'terms': ['deflecting portion']}, {'element_identifier': '10', 'terms': ['operation unit']}, {'element_identifier': '170', 'terms': ['opening forming surface']}, {'element_identifier': '72', 'terms': ['observation means forming surface']}, {'element_identifier': '80', 'terms': ['treatment tool lead-out port']}, {'element_identifier': '162', 'terms': ['erecting base housing portion']}, {'element_identifier': '134', 'terms': ['distal end portion']}, {'element_identifier': '44', 'terms': ['observation window']}, {'element_identifier': '62', 'terms': ['erecting base housing portion']}, {'element_identifier': '84', 'terms': ['cleaning communication hole']}, {'element_identifier': '34', 'terms': ['distal end portion']}, {'element_identifier': '138', 'terms': ['axis']}, {'element_identifier': '50', 'terms': ['ultrasonic transducer']}, {'element_identifier': '60', 'terms': ['erecting base']}]","['1. An ultrasonic endoscope comprising: an ultrasonic transducer that has an ultrasonic vibrator; a distal end portion body that is disposed continuously with a proximal end side of the ultrasonic transducer; an erecting base housing portion that is disposed in the distal end portion body and that has an opening whose opening direction is a first direction that is perpendicular to an axial direction of the distal end portion body or whose opening direction is a direction that has a component toward one side in the first direction and a component toward a distal end side in the axial direction of the distal end portion body; a treatment tool lead-out port that communicates with an inside of the erecting base housing portion and from which a treatment tool is led out; an erecting base that is disposed in the inside of the erecting base housing portion and that changes a lead out direction of the treatment tool led out from the treatment tool lead-out port; and a cleaning communication hole that is formed in a wall surface on a side opposite to a side where the opening of the erecting base housing portion is disposed and that communicates with an outside.', '2. The ultrasonic endoscope according to claim 1, comprising: an observation window that is disposed in the distal end portion body and through which a subject is observed, wherein a position of the observation window in the axial direction of the distal end portion body is located on a proximal end side relative to the erecting base housing portion.', '10. The ultrasonic endoscope according to any one of claims 1 to 9, wherein the ultrasonic transducer has an ultrasound transmitting/receiving surface that is formed in a curved shape in the axial direction of the distal end portion body.']",True,"['60', '34', '72', '48', '80', '62', '84', '134', '136', '44', '78', '72', '80', '162', '170', '60', '158', '10', '48', '52', '138', '50', '20']" 718,EP_3603680_A1 (1).png,EP3603680A1,DIAGNOSTIC IMAGING HEPATIC TISSUE-SPECIFIC CONTRAST MEDIUM COMPRISING MANGANESE SILICATE NANOPARTICLE,['FIG2'],['FIG2 is a schematic diagram of T1-weighted image and function mechanism after intravenous injection of HMS (3 mg / kg) into a hepatocellular carcinoma (HCC) model'],"['As a result of FIG2, the significant contrast enhancement was observed for 0.5-6 hours after the injection of HMS, and then it slowly began to brighten from the periphery region to the center region for 6-24 hours, and the necrotic area was not enhanced.']",32,52,schematic diagram,A,"[{'element_identifier': '2', 'terms': ['Example', 'after', 'pre-injection level.', 'hours.']}]","['16. The liver tissue-specific MRI contrast agent according to claim 15, wherein the MRI change pattern over time obtained after administration of the contrast agent has a pattern in which is gradually brightened, and after reaching the maximum brightness, is gradually darken in normal liver tissue.']",False,"['2', '41', '21']" 719,EP_3603680_A1 (6).png,EP3603680A1,DIAGNOSTIC IMAGING HEPATIC TISSUE-SPECIFIC CONTRAST MEDIUM COMPRISING MANGANESE SILICATE NANOPARTICLE,['FIG9c'],['FIG9c is a graph showing the relationship between the concentration of Mn2+ ions and the contrast intensity (R1) of the image'],"['Next, the relationship between the concentration of Mn2+ ions and the contrast intensity R1 of the image is shown in the graph of FIG9c. The slope of this graph is expressed as r1, and is a unique value for each material. It was confirmed that the three particles had a similar slope within the range of 7.5 ∼ 8.2, and the increase in the contrast effect by Mn2+ ions was confirmed again by comparing with an r1 value of about 7.4 for pure Mn2+ ions (MnCl2 aqueous solution).']",24,99,graph,A,"[{'element_identifier': '3', 'terms': ['Example']}, {'element_identifier': '2', 'terms': ['Example', 'after', 'pre-injection level.', 'hours.']}]","['16. The liver tissue-specific MRI contrast agent according to claim 15, wherein the MRI change pattern over time obtained after administration of the contrast agent has a pattern in which is gradually brightened, and after reaching the maximum brightness, is gradually darken in normal liver tissue.']",False,"['3', '2', '7477', '7592', '048', '31']" 720,EP_3603690_A1 (1).png,EP3603690A1,BLOOD SEPARATION METHOD AND BLOOD SEPARATION FILTER,['FIG2'],['FIG2 is a longitudinal sectional view of the blood separation filter of FIG1'],"['As illustrated in FIG2, the blood separation filter 10A includes: the housing 18; a filter member 24 that partitions interior of the housing 18 in an up-down direction (thickness direction orthogonal to the extending direction of the housing 18) into a blood inflow chamber 20 and a blood outflow chamber 22 and that includes a filter medium 38; an inflow port 26 that allows blood to flow into the blood inflow chamber 20; and an outflow port 28 that allows blood from which a blood component has been separated (post-separation blood) by the filter member 24 to flow out from the blood outflow chamber 22.', 'As illustrated in FIG2, peripheral edge portions of the first case 30 and the second case 32 are joined together by welding (ultrasonic welding or the like) over the entire circumference. In order to facilitate the flow of blood into the blood inflow chamber 20, a plurality of protrusions 34 is provided on the inner surface of the first case 30 facing the filter member 24. In order to facilitate the flow of post-separation blood into the blood outflow chamber 22, a plurality of protrusions 36 is provided on the inner surface of the second case 32 facing the filter member 24. At least one of the protrusion 34 and the protrusion 36 may be omitted.', 'The filter medium 38 is formed of a sheet-like porous material having a large number of minute continuous pores communicating from one side to the other side. Examples of such a porous material include a sponge sheet formed of polyurethane, and a nonwoven fabric. The number of stacked sheets of the filter medium 38 is, for example, about two to ten. Note that the filter member 24 of FIG2 has six filter media 38 being stacked. The number of filter media 38 constituting the filter member 24 may be one.']",13,348,longitudinal sectional view,A,"[{'element_identifier': '24', 'terms': ['filter member']}, {'element_identifier': '28', 'terms': ['outflow port']}, {'element_identifier': '14', 'terms': ['inflow tube']}, {'element_identifier': '30', 'terms': ['first case']}, {'element_identifier': '38', 'terms': ['filter medium']}, {'element_identifier': '22', 'terms': ['blood outflow chamber']}, {'element_identifier': '18', 'terms': ['housing']}, {'element_identifier': '20', 'terms': ['blood inflow chamber']}, {'element_identifier': '34', 'terms': []}, {'element_identifier': '40', 'terms': ['first protrusion']}, {'element_identifier': '16', 'terms': ['outflow tube']}, {'element_identifier': '42', 'terms': ['second protrusion']}, {'element_identifier': '26', 'terms': ['inflow port']}, {'element_identifier': '36', 'terms': []}, {'element_identifier': '32', 'terms': ['second case']}, {'element_identifier': '13', 'terms': ['retainer groove']}]","['1. A blood separation method using a blood separation filter (10A to 10F) that separates a predetermined blood component from blood, the blood separation filter (10A to 10F) including: a housing (18, 62); a filter medium (38) disposed in the housing (18, 62) and partitioning the housing (18, 62) into a blood inflow chamber (20) and a blood outflow chamber (22) in a thickness direction of the housing (18, 62); an inflow port (26) provided in the housing (18, 62) to allow blood to flow into the blood inflow chamber (20); and an outflow port (28) provided in the housing (18, 62) to allow post-separation blood from which a blood component has been separated by the filter medium (38) to flow out from the blood outflow chamber (22), the blood separation method comprising: an arrangement step of arranging the housing (18, 62) such that the blood inflow chamber (20) is positioned vertically below the filter medium (38) and the blood outflow chamber (22) is positioned vertically above the filter medium (38); a blood treatment step of first allowing the blood to flow from the inflow port (26) into the blood inflow chamber (20) in a state of the arrangement step, allowing the blood to flow through the inside of the filter medium (38) upward from vertically below, and then allowing the post-separation blood inside the blood outflow chamber (22) to flow out to the outflow port (28); and a post residual treatment blood collection step of arranging the housing (18, 62) such that the outflow port (28) is positioned vertically below the blood outflow chamber (22) after the blood treatment step, thereby guiding post-separation residual blood in the housing (18, 62) to the outflow port (28).', '4. The blood separation method according to claim 3, wherein the housing (18, 62) includes, at a center portion of an outer surface (30a) on a side where the blood inflow chamber (20) is located, an outlet-side retainer (11b, 15b, 19b, 21b, 23b, 25b) to which an outflow tube (16) connected to the outflow port (28) is detachably mounted, and the arrangement step allows at least a portion of the outflow tube (16) to extend on the center-of-gravity line (Lg) in a state where the outflow tube (16) is mounted to the outlet-side retainer (11b, 15b, 19b, 21b, 23b, 25b).', '9. The blood separation filter (10A, 10B) according to claim 8, wherein at least one of the inlet-side retainer (11a, 15a) and the outlet-side retainer (11b, 15b) is a clip portion having a retainer groove to and from which the inflow tube (14) or the outflow tube (16) is attachable and detachable.']",False,"['2', '14', '24', '18', '36', '22', '32', '42', '28', '26', '12', '38', '30', '20', '34', '40', '13', '16']" 721,EP_3603690_A1 (2).png,EP3603690A1,BLOOD SEPARATION METHOD AND BLOOD SEPARATION FILTER,['FIG3'],['FIG3 is a schematic explanatory view of a blood separation method using the blood separation filter of FIG1'],"['The inflow tube 14 is an elongated flexible cylindrical tube connected to the inflow port 26. One end of the inflow tube 14 is connected to a blood bag 52 containing blood via a sealing member 50, while the other end of the inflow tube 14 is connected to the inflow port 26 (refer to FIG3).', 'The outflow tube 16 is an elongated flexible cylindrical tube connected to the outflow port 28. One end of the outflow tube 16 is connected to the outflow port 28, while the other end of the outflow tube 16 is connected to a storage bag 58 containing post-separation blood (refer to FIG3).', 'Next, a blood separation method using the blood separation filter 10A will be described. As illustrated in FIG3, when a predetermined blood component is to be separated from the blood, the blood bag 52 containing blood is first suspended from the suspension base and positioned at a high position. Furthermore, in the arrangement step, the housing 18 is suspended by using the inflow tube 14. With this arrangement, the housing 18 is in a state close to the horizontal state (laid-down state) allowing the blood inflow chamber 20 to be positioned below the filter member 24 and the blood outflow chamber 22 to be positioned above the filter member 24. At this time, at least a portion of the inflow tube 14 and at least a portion of the outflow tube 16 extend on the center-of-gravity line Lg.']",18,280,schematic view,A,"[{'element_identifier': '24', 'terms': ['filter member']}, {'element_identifier': '30', 'terms': ['first case']}, {'element_identifier': '52', 'terms': ['blood bag']}, {'element_identifier': '50', 'terms': ['sealing member']}, {'element_identifier': '26', 'terms': ['inflow port']}, {'element_identifier': '58', 'terms': ['storage bag']}, {'element_identifier': '32', 'terms': ['second case']}, {'element_identifier': '13', 'terms': ['retainer groove']}]","['1. A blood separation method using a blood separation filter (10A to 10F) that separates a predetermined blood component from blood, the blood separation filter (10A to 10F) including: a housing (18, 62); a filter medium (38) disposed in the housing (18, 62) and partitioning the housing (18, 62) into a blood inflow chamber (20) and a blood outflow chamber (22) in a thickness direction of the housing (18, 62); an inflow port (26) provided in the housing (18, 62) to allow blood to flow into the blood inflow chamber (20); and an outflow port (28) provided in the housing (18, 62) to allow post-separation blood from which a blood component has been separated by the filter medium (38) to flow out from the blood outflow chamber (22), the blood separation method comprising: an arrangement step of arranging the housing (18, 62) such that the blood inflow chamber (20) is positioned vertically below the filter medium (38) and the blood outflow chamber (22) is positioned vertically above the filter medium (38); a blood treatment step of first allowing the blood to flow from the inflow port (26) into the blood inflow chamber (20) in a state of the arrangement step, allowing the blood to flow through the inside of the filter medium (38) upward from vertically below, and then allowing the post-separation blood inside the blood outflow chamber (22) to flow out to the outflow port (28); and a post residual treatment blood collection step of arranging the housing (18, 62) such that the outflow port (28) is positioned vertically below the blood outflow chamber (22) after the blood treatment step, thereby guiding post-separation residual blood in the housing (18, 62) to the outflow port (28).', '9. The blood separation filter (10A, 10B) according to claim 8, wherein at least one of the inlet-side retainer (11a, 15a) and the outlet-side retainer (11b, 15b) is a clip portion having a retainer groove to and from which the inflow tube (14) or the outflow tube (16) is attachable and detachable.']",False,"['3', '52', '50', '46', '26', '32', '24', '30', '56', '58', '13']" 722,EP_3603708_A1 (2).png,EP3603708A1,NEEDLE-EQUIPPED OUTER CYLINDER AND METHOD FOR MANUFACTURING SAME,['FIG5'],['FIG5 is a longitudinal cross-sectional view of an outer cylinder member used in the needle-equipped outer cylinder of the present invention'],"['As illustrated in FIG5, the outer cylinder member 2 is provided with the outer cylinder main body 21 filled with the medicine solution and the distal end joint 22 to which the joining member 4 is fixedly joined. The outer cylinder main body 21 is formed into a substantially cylindrical shape having an inner accommodating portion. A flange 23 is formed on a proximal end side in the axial direction of the outer cylinder main body 21. That is, the outer cylinder member 2 is a syringe outer cylinder member capable of being filled with the medicine solution.']",25,104,longitudinal cross-sectional view,A,"[{'element_identifier': '28', 'terms': ['projection']}, {'element_identifier': '24', 'terms': ['portion']}, {'element_identifier': '17', 'terms': ['pressing member']}, {'element_identifier': '22', 'terms': ['distal end joint']}, {'element_identifier': '48', 'terms': ['abutment portion']}, {'element_identifier': '2', 'terms': ['outer cylinder member']}, {'element_identifier': '45', 'terms': ['heat welded portion']}, {'element_identifier': '21', 'terms': ['outer cylinder main body']}, {'element_identifier': '25', 'terms': ['portion']}, {'element_identifier': '27', 'terms': ['cylinder portion accommodating portion']}, {'element_identifier': '49', 'terms': ['needle tube locking portion']}, {'element_identifier': '26', 'terms': ['inner cavity']}, {'element_identifier': '33', 'terms': ['proximal end']}, {'element_identifier': '23', 'terms': ['flange']}]","['1. A needle-equipped outer cylinder comprising: a needle tube; a joining member including a needle tube accommodation hole for accommodating a proximal end side portion of the needle tube and a joining outer peripheral portion provided on an outer peripheral portion of the needle tube accommodation hole; and an outer cylinder member provided with a distal end joint including an inner cavity capable of receiving the joining outer peripheral portion of the joining member from a distal end side, wherein the needle tube accommodation hole penetrates the joining member from a distal end of the joining member to a proximal end of the joining member, the outer cylinder member is provided with a projection provided on a proximal end portion of the inner cavity and projecting in the inner cavity, the joining member is provided with an abutment portion which abuts the projection of the outer cylinder member on a proximal end portion of the joining member, at least the joining outer peripheral portion of the joining member is inserted into the inner cavity of the distal end joint of the outer cylinder member, and the abutment portion of the joining member abuts the projection of the outer cylinder member, and the joining outer peripheral portion of the joining member includes a heat welded portion formed in a position on a proximal end side by a predetermined length from a distal end of the distal end joint of the outer cylinder member, the joining outer peripheral portion of the joining member is fixedly joined to an inner peripheral surface of the distal end joint on an outer peripheral portion of the heat welded portion and is fixedly joined to an outer peripheral surface of the needle tube on an inner peripheral portion of the heat welded portion.', '4. The needle-equipped outer cylinder according to any one of claim 1 to 3, wherein the joining member is provided with a needle tube locking portion provided on a proximal end portion of the needle tube accommodation hole to lock a proximal end of the needle tube.', '9. The needle-equipped outer cylinder according to any one of claims 1 to 8, wherein the outer cylinder member is a syringe outer cylinder member including an outer cylinder main body capable of being filled with medicine solution.', '12. A method for manufacturing a needle-equipped outer cylinder provided with a needle tube, a joining member including a needle tube accommodation hole for accommodating the needle tube and a joining outer peripheral portion provided on an outer peripheral portion of the needle tube accommodation hole, and an outer cylinder member provided with a distal end joint including an inner cavity capable of receiving the joining outer peripheral portion of the joining member, the method for manufacturing the needle-equipped outer cylinder comprising: a preparing step of preparing the outer cylinder member provided with a projection projecting in the inner cavity on a proximal end portion of the inner cavity, the joining member provided with an abutment portion which abuts the projection of the outer cylinder member on a proximal end portion, and the needle tube; an assembling step of assembling the needle tube, the joining member, and the outer cylinder member such that the needle tube is inserted into or inserted to be fixed to the needle tube accommodation hole of the joining member, the joining member is inserted into the distal end joint of the outer cylinder member, and the abutment portion of the joining member abuts the projection of the outer cylinder member; and a welding step of heat welding the joining outer peripheral portion of the joining member to an inner peripheral surface of the distal end joint of the outer cylinder member and an outer peripheral surface of the needle tube by allowing the needle tube to generate heat by a heat generating device to allow the needle tube to generate heat while pressing a distal end portion of the joining member in a proximal end direction of the joining member by a pressing member.']",True,"['45', '33', '22', '28', '49', '48', '25', '22', '27', '26', '24', '28', '2', '21', '23', '17']" 723,EP_3603710_A1 (2).png,EP3603710A1,SYRINGE-TYPE EJECTOR,['FIG3'],['FIG3 is a perspective view including a partial cross section showing an enlarged engagement portion of a barrel and a nozzle of the syringe type ejection device according to the first embodiment'],"['FIG3 is a perspective view including a partial cross section showing an enlarged engagement portion of the barrel and the nozzle of the syringe type ejection device according to the first embodiment. As shown in FIG3, barrel 10 has a neck 13 having a small outer diameter. Large-diameter portion 11 is attached to neck 13. Neck 13 and large-diameter portion 11 are provided with a discharge space 11a.', 'Since the plurality of hooks 34 are flexible (elastic), and engage large-diameter portion 11 in the state shown in FIG3, the elasticity of biasing portion 31 can be utilized to press first surface 11f against packing 60.']",32,122,perspective view,A,"[{'element_identifier': '30', 'terms': ['nozzle']}, {'element_identifier': '11', 'terms': ['large-diameter portion']}, {'element_identifier': '62', 'terms': ['through hole']}, {'element_identifier': '34', 'terms': ['hooks', 'hook']}, {'element_identifier': '31', 'terms': ['biasing portion']}, {'element_identifier': '16', 'terms': ['bore']}, {'element_identifier': '61', 'terms': ['convex portions']}, {'element_identifier': '10', 'terms': ['barrel']}, {'element_identifier': '33', 'terms': ['nozzle body']}, {'element_identifier': '36', 'terms': ['holding space']}, {'element_identifier': '70', 'terms': ['core']}, {'element_identifier': '60', 'terms': ['packing']}, {'element_identifier': '32', 'terms': ['through holes', 'through hole']}, {'element_identifier': '13', 'terms': ['neck']}]","['1. A syringe type ejection device comprising: a barrel; a nozzle disposed to face the barrel; and an annular packing interposed between the barrel and the nozzle, the barrel having a tip end portion provided with a discharge space for discharging liquid, the tip end portion including a first surface facing the nozzle, the nozzle being provided with a holding space for holding a core, the holding space being in communication with the discharge space, the nozzle including a second surface facing the first surface, the annular packing being provided to be in contact with the first surface and the second surface to enable movement of the liquid from the discharge space to the holding space, and the syringe type ejection device further comprising a biasing portion that biases the first surface and the second surface toward the annular packing.', '4. The syringe type ejection device according to claim 2 or 3, wherein the tip end portion has a large-diameter portion, and the biasing portion engages the large-diameter portion.', '5. The syringe type ejection device according to claim 4, wherein the biasing portion has a plurality of hooks that engage the large-diameter portion.', '6. The syringe type ejection device according to claim 5, wherein the biasing portion is flexible, and a through hole extending through a thickness of the nozzle is provided in a portion of the nozzle in proximity of the biasing portion.']",False,"['10', '34', '31', '32', '30', '36', '33', '70', '16', '13', '11', '61', '60', '61', '62', '13']" 724,EP_3603746_A1 (3).png,EP3603746A1,IMAGERS IN RADIATION THERAPY ENVIRONMENT,['FIG5B'],['FIG5B is a diagram illustrating MV beam pulses being synchronous with the kV image readout'],"['In some embodiments, the above ""band"" artifact problem may be addressed by configuring the line readout of the imager 200 so that it is synchronized with the treatment beam pulses. FIG5B is a diagram illustrating MV beam pulses being synchronous with the kV image readout. As shown in the figure, the readout of the kV image signals is synchronized with the treatment beam pulses, so that there are always twelve scatter pulses (from the treatment beams) between corresponding lines of two consecutive image frames. For example, there are twelve scatter pulses between the readout of line 289 in the kV-FRAME N, and the readout of line 289 (i.e., the same line) in the KV-FRAME N+1. There are also twelve scatter pulses between the readout of line 654 in the kV-FRAME N, and the readout of line 654 in the KV-FRAME N+1. Accordingly, the imager always integrates twelve scatter pulses from the treatment beams between two consecutive image frames for each of the pixel lines. As a result, the heights 562 of the kV frame lines shown in the figure (representing the amount of MV scatter signal received in different lines of the imager 200) are the same, thereby eliminating the band artifacts.']",15,235,diagram,A,"[{'element_identifier': '562', 'terms': ['heights']}, {'element_identifier': '12', 'terms': ['gantry']}, {'element_identifier': '289', 'terms': ['line']}, {'element_identifier': '654', 'terms': ['line']}]","['9. The imager of claim 6, 7 or 8, wherein the readout and control circuit is configured to perform signal readout for one or more lines of the imager during a treatment session when the treatment beam source is not delivering treatment energy, and to suspend signal readout for another line of the imager when the treatment beam source is delivering treatment energy.']",True,"['562', '12', '13', '12', '768', '768', '562', '12', '12', '12', '654', '768', '768', '289', '16']" 725,EP_3603796_A1.png,EP3603796A1,CATALYTIC REACTOR,['FIG1'],['FIG1 is a perspective view of a catalytic reactor according to an embodiment of the present disclosure'],"['FIG1 is a perspective view of a catalytic reactor according to the present embodiment. As shown in FIG1, the catalytic reactor according to the present embodiment includes a reaction-side flow channel 10 and a plurality of structured catalysts 20. Note that the X, Y, and Z directions (axes) in the figure are orthogonal to each other.', 'The reaction-side flow channel 10 has a tubular structure, and forms a flow space 11 for a reaction fluid that is a gas or a liquid as a reaction target. The flow space 11 has a rectangular cross section orthogonal to the Z direction. As shown in FIG1, the flow space 11 extends in the Z direction and defines a flow direction of the reaction fluid. That is, the reaction fluid enters from an inlet 12, flows in the Z direction, and then flows out of an outlet 13. In the present embodiment, the flow space 11 has a rectangular cross section, which is orthogonal to the Z direction and has a length (height) h1 in the Y direction and a length (width) w1 in the X direction.']",17,213,perspective view,B,"[{'element_identifier': '12', 'terms': ['inlet']}, {'element_identifier': '1', 'terms': ['yield. Patent literatures']}, {'element_identifier': '20', 'terms': ['structured catalyst', 'structured catalysts']}, {'element_identifier': '10', 'terms': ['reaction-side flow channel', 'reaction-side flow channels']}, {'element_identifier': '15', 'terms': ['inner surface']}, {'element_identifier': '13', 'terms': ['outlet']}]","['1. A catalytic reactor comprising: a reaction-side flow channel in which a reaction fluid flows; a first structured catalyst and a second structured catalyst located in the reaction-side flow channel; wherein the first structured catalyst includes a first inclined surface in at least part of a surface of the first structured catalyst facing the second structured catalyst, the second structured catalyst includes a second inclined surface facing the first inclined surface, in at least part of a surface of the second structured catalyst facing the first structured catalyst, the first inclined surface and the second inclined surface are inclined in the same direction with respect to an arrangement direction of the first structured catalyst and the second structured catalyst, and the first structured catalyst and the second structured catalyst are tilted in the same direction with respect to the arrangement direction in a state where at least part of the first inclined surface and at least part of the second inclined surface are in contact with each other.', '3. The catalytic reactor according to claim 1 or 2, wherein the inner surface of the reaction-side flow channel is provided with a protrusion or a step configured to contact an end of the first inclined surface or an end of the second inclined surface.']",False,"['1', '13', '10', '12', '20', '15', '8']" 726,EP_3603803_A1.png,EP3603803A1,HYDRODESULFURIZATION CATALYST FOR HYDROCARBON OIL AND METHOD FOR MANUFACTURING HYDRODESULFURIZATION CATALYST,['FIG1'],['FIG1 is a diagram showing ultraviolet-visible light diffused reflection spectra of inorganic oxide carriers in Example 1 and Comparative Example 3 '],"['Further, the ultraviolet-visible light diffused reflection spectrum of the inorganic oxide carrier a was analyzed according to the following method. The analysis result is shown in FIG1. The absorption edge wavelength of the inorganic oxide carrier a was calculated from the analysis result, and was 346 nm.', 'The ultraviolet-visible light diffused reflection spectrum of the inorganic oxide carrier h was analyzed by the same method as in Example 1. The analysis result is shown in FIG1. The absorption edge wavelength of the inorganic oxide carrier h was calculated from the analysis result, and was 365 nm.']",23,110,diagram,B,"[{'element_identifier': '8', 'terms': ['group']}, {'element_identifier': '7', 'terms': ['pH became']}, {'element_identifier': '5', 'terms': ['being', 'diluting', 'TiO2 in', 'width was set at']}, {'element_identifier': '1', 'terms': ['Example']}, {'element_identifier': '400', 'terms': ['calcining temperature may be']}, {'element_identifier': '2', 'terms': ['being']}, {'element_identifier': '250', 'terms': ['is']}, {'element_identifier': '300', 'terms': ['reaction temperature is']}, {'element_identifier': '16', 'terms': ['Al2O3 with']}, {'element_identifier': '500', 'terms': ['may also be', 'were suspended in']}, {'element_identifier': '3', 'terms': ['Example']}, {'element_identifier': '200', 'terms': ['hydrogen atmosphere at']}, {'element_identifier': '450', 'terms': ['may also be']}]","['1. A hydrodesulfurization catalyst for hydrocarbon oil, the catalyst comprising: an inorganic oxide carrier comprising Si, Ti and Al; and at least one metal component, carried on the inorganic oxide carrier, being selected from the group consisting of group 6 elements, group 8 elements, group 9 elements and group 10 elements, wherein a content of Al in the inorganic oxide carrier is 50% by mass or higher in terms of Al 2 O 3 ; a content of Si therein is 1.0 to 10% by mass in terms of SiO 2 ; and a content of Ti therein is 12 to 28% by mass in terms of TiO 2 ; and in the inorganic oxide carrier, an absorption edge wavelength of an absorption peak from Ti is 364 nm or shorter as measured by ultraviolet spectroscopy.']",False,"['8', '7', '5', '3', '2', '1', '3', '16', '200', '250', '300', '350', '400', '450', '500']" 727,EP_3603835_A1.png,EP3603835A1,"HOLLOW STABILIZER, STABILIZER MANUFACTURING DEVICE, AND METHOD FOR MANUFACTURING HOLLOW STABILIZER",['FIG2'],['FIG2 is a plan view schematically showing an example of a hollow stabilizer according to one of embodiments'],"['FIG2 is a plan view schematically showing the hollow stabilizer 10. The material of the hollow stabilizer 10 is a pipe 40 formed of a metal (for example, spring steel) whose strength can be improved by heat treatment such as quenching. An example of an outer diameter of the pipe 40 is 22 mm and a thickness is 3 mm. An example of the radius of curvature (center radius of curvature r) of the bent parts 21 and 22 is 50 mm. In an endurance test (double swing test), one arm part 23 is fixed at fixed point A while a load in the vertical direction is applied to load point B of the other arm part 24.', 'As shown in FIG2, the hollow stabilizer 10 has a bilaterally symmetric shape with the center in the longitudinal direction used as an axis of symmetry X1. Since the shapes of the bent parts 21 and 22 are substantially common to each other, the bent part 21 will be explained as a representative in the following descriptions. Since the other bent part 22 has the same structure, its explanations will be omitted. A specific shape of the hollow stabilizer 10 may be a three-dimensionally bent shape or one or more bent parts may be formed in the arm parts 23 and 24. In addition, one or more bent parts may be formed in the middle of the longitudinal direction of the torsion part 20.']",18,267,plan view,B,"[{'element_identifier': '24', 'terms': ['arm parts', 'arm part']}, {'element_identifier': '12', 'terms': ['suspension mechanism part']}, {'element_identifier': '11', 'terms': ['vehicle']}, {'element_identifier': '22', 'terms': ['bent parts', 'bent part']}, {'element_identifier': '20', 'terms': ['torsion part']}, {'element_identifier': '40', 'terms': ['pipe']}, {'element_identifier': '10', 'terms': ['stabilizer']}, {'element_identifier': '21', 'terms': ['part', 'parts']}, {'element_identifier': '23', 'terms': ['arm parts', 'arm part']}, {'element_identifier': '13', 'terms': ['vehicle body']}]","['1. A hollow stabilizer (10) disposed in a vehicle suspension mechanism part, characterized by comprising: a torsion part (20); a bent part (21, 22) continuous with the torsion part (20); and an arm part (23, 24) continuous with the bent part (21, 22), and further comprising, when a center of bending inside is 0° and a center of bending outside is 180° in a cross section in a pipe radial direction of the bent part (21, 22), a first cross-sectional part (41) in a range from 60° to 300° centered at 0°; a second cross-sectional part (42) formed in a range from 120° to 240° centered at 180° and having a curvature smaller than that of the first cross-sectional part (41); a third cross-sectional part (43) formed in a range of more than 60° and less than 120° centered at 90° and having a curvature smaller than that of the second cross-sectional part (42); and a fourth cross-sectional part (44) formed in a range of more than 240° and less than 300° centered at 270° and having a curvature smaller than that of the second cross-sectional part (42).']",True,"['10', '21', '12', '13', '23', '24', '22', '40', '20', '01', '10', '11']" 728,EP_3603839_A1 (2).png,EP3603839A1,"SHEARING METHOD, SHEARING DEVICE, AND SHEARING FACILITY","['FIG3B', ' FIG3C']","['FIG3B is another schematic illustration comparable to FIG2B, showing the operation of the typical shearing machine and the behavior of the workpiece ', 'FIG3C is still another schematic illustration comparable to FIG2C, showing the operation of the typical shearing machine and the behavior of the workpiece']","['In the state shown in FIG3B, the work-hardening of the material inside the workpiece 6 occurs in a region R2B. It should be noted that, though the region R1B shown in FIG2B is enlarged at the lower side of the workpiece 6, there is no such enlargement in the region R2B shown in FIG3B. ', 'In the state shown in FIG3C, the work-hardening of the material inside the workpiece 6 occurs in a region R2C. It should be noted that, though the region R1C shown in FIG2C is further enlarged at the lower side of the workpiece 6, there is no such enlargement in the region R2C shown in FIG3C. In other words, the region R2C is a relatively narrow region extending along the plane connecting the lower blade 21 and the upper blade 31.']",47,146,schematic,B,"[{'element_identifier': '21', 'terms': ['lower blade']}, {'element_identifier': '61', 'terms': ['fractured surface']}, {'element_identifier': '31', 'terms': ['upper blade']}]","['1. A shearing method for applying a shear force on a plate-shaped workpiece in a thickness direction to cut the workpiece, the method comprising: starting application of the shear force on the workpiece with a clearance between action points in a surface direction orthogonal to the thickness direction of the workpiece; applying the shear force after starting applying the shear force until a fractured surface is created on the workpiece; and increasing the clearance depending on a deformation of the workpiece in the thickness direction after starting applying the shear force until the fractured surface is created on the workpiece.', '2. The shearing method according to claim 1, wherein the method is performed using a plurality of shearing machines each comprising a lower blade and an upper blade movable in the thickness direction of the workpiece relative to the lower blade, a clearance defined between the lower blade and the upper blade along the surface direction of the workpiece being different in each of the plurality of shearing machines, and in increasing the clearance, the shear force is sequentially applied on the workpiece from one of the plurality of shearing machines whose clearance is small to one of the plurality of shearing machines whose clearance is large.']",True,"['31', '21', '31', '21', '31', '61', '21', '16']" 729,EP_3603901_A1 (3).png,EP3603901A1,"SERIES ELASTIC ACTUATOR DEVICE, SERIES ELASTIC ACTUATOR CONTROL METHOD, AND SYSTEM USING SAME",['FIG6'],['FIG6 is a diagram for illustrating an embodiment of the configuration and operation of a sensor part provided in the SEA'],"['Referring to FIG6, in order to measure relative displacement (Δθ) between the motor-side rotation unit 100 and the load-side rotation unit 200, such as that described above, the magnetic body 400 for generating a magnetic field may be positioned in the motor-side rotation unit 100 and the hall sensor 410 may be positioned at a location of the load-side rotation unit 200 that faces the magnetic body 400.']",21,82,diagram,B,"[{'element_identifier': '710', 'terms': ['bearing']}, {'element_identifier': '100', 'terms': ['motor-side rotation unit']}, {'element_identifier': '400', 'terms': ['magnetic body']}, {'element_identifier': '320', 'terms': ['elastic members', 'elastic member']}, {'element_identifier': '720', 'terms': ['decelerator']}, {'element_identifier': '730', 'terms': ['decelerator fixing stage']}, {'element_identifier': '410', 'terms': ['hall sensor']}, {'element_identifier': '200', 'terms': ['load-side rotation unit']}, {'element_identifier': '700', 'terms': ['driving motor']}]","['1. A series elastic actuator, comprising: a motor-side rotation unit coupled to a driving motor and rotated by rotatory power of the driving motor; a load-side rotation unit coupled to the motor-side rotation unit to transfer the rotatory power of the driving motor to a load; and at least one pair of elastic members provided in spaces between the motor-side rotation unit and the load-side rotation unit, wherein a frame having accommodation spaces to which the pair of elastic members is fixed is formed in any one of the motor-side rotation unit and the load-side rotation unit.', '7. The series elastic actuator of claim 6, wherein the sensor part comprises a magnetic body and a hall sensor respectively positioned at corresponding positions of the motor-side rotation unit and the load-side rotation unit.']",True,"['400', '330', '410', '320', '100', '200', '6', '720', '730', '200', '700', '710', '100', '7', '15']" 730,EP_3603901_A1 (5).png,EP3603901A1,"SERIES ELASTIC ACTUATOR DEVICE, SERIES ELASTIC ACTUATOR CONTROL METHOD, AND SYSTEM USING SAME",['FIG10'],['FIG10 is a diagram for illustrating an embodiment of the operation of the SEA when an external force is applied to a load'],"['Referring to FIG10, when an external force (Fl) is applied to a load 1000 coupled to the load-side rotation unit 200, torque (τl) that rotates the load 1000 by the external force (Fl) occurs.']",23,45,diagram,B,"[{'element_identifier': '200', 'terms': ['load-side rotation unit']}, {'element_identifier': '10', 'terms': ['driving motor']}, {'element_identifier': '1000', 'terms': ['load']}]","['1. A series elastic actuator, comprising: a motor-side rotation unit coupled to a driving motor and rotated by rotatory power of the driving motor; a load-side rotation unit coupled to the motor-side rotation unit to transfer the rotatory power of the driving motor to a load; and at least one pair of elastic members provided in spaces between the motor-side rotation unit and the load-side rotation unit, wherein a frame having accommodation spaces to which the pair of elastic members is fixed is formed in any one of the motor-side rotation unit and the load-side rotation unit.']",True,"['1000', '11', '200', '10', '6', '11', '17']" 731,EP_3603970_A1 (4).png,EP3603970A1,METAL/FIBER-REINFORCED RESIN MATERIAL COMPOSITE BODY AND METHOD FOR PRODUCING SAME,['FIG6'],['FIG6 is an illustrative diagram showing a configuration of a sample of a metal-FRP composite body for a shear test in examples and comparative examples '],"['As shown in FIG6, two metal members 110 were prepared, respective parts of 10 mm from ends of the metal member 110 were bonded to a CFRP layer 120 formed to have a total thickness of 0.2 mm or 0.4 mm, and thereby samples of a metal-CFRP composite body for a shear test were produced. That is, the samples of a metal-CFRP composite body for a shear test were produced by inserting a CFRP layer 120 between vicinities of ends of two upper and lower metal members 101 and performing thermocompression bonding under conditions shown in examples and comparative examples. Two white arrows in FIG6 indicate a tensile load application direction.']",27,122,diagram,B,"[{'element_identifier': '5', 'terms': ['Patent Literature']}, {'element_identifier': '30', 'terms': ['preferably']}, {'element_identifier': '6', 'terms': ['Patent Literature', 'metal CFRP interface was', 'Preparation Example']}, {'element_identifier': '110', 'terms': ['metal member', 'metal members']}, {'element_identifier': '120', 'terms': ['layer']}]","['1. A method for producing a metal/fiber-reinforced resin material composite body including a metal member and a fiber-reinforced resin material which is laminated on at least one surface of the metal member and includes a reinforcing fiber substrate and a resin including a thermoplastic resin impregnated into the reinforcing fiber substrate as a matrix resin, the method comprising following a step A and a step B: the step A: forming a prepreg in which a partially fused structure of the resin including the thermoplastic resin is formed on at least one surface of the reinforcing fiber substrate; and the step B: performing a heat and pressure treatment when a surface on which the partially fused structure of the prepreg is formed is brought into contact with a surface of the metal member; and at the same time in which the resin including the thermoplastic resin is completely melted and wet and spreads on the surface of the metal member and the resin including the thermoplastic resin is impregnated into the reinforcing fiber substrate, thereby forming a metal/fiber-reinforced resin material composite body, wherein the fiber-reinforced resin material and the metal member are bonded to form the metal/fiber-reinforced resin material composite body.', '8. The method for producing a metal/fiber-reinforced resin material composite body according to claim 1, wherein, in the step B, a resin layer having a thickness of 20 µm or less and a fiber content of 5 weight% or less is formed using the resin including the thermoplastic resin between the surface of the metal member and the reinforcing fiber substrate as a part of the fiber-reinforced resin material.']",True,"['110', '120', '110', '5', '110', '120', '110', '6', '30']" 732,EP_3604005_A1 (1).png,EP3604005A1,WINDSHIELD,"['FIG3', ' FIG4']","['FIG4 is a side view showing the positional relationship between a head-up display device and a windshield ', 'FIG3 is a cross-sectional view of an interlayer']","['In order to prevent this, at least the display region of the windshield 1 onto which light is projected by a HUD device 500 is formed such that the thickness decreases downward as shown in FIG4. As a result, light that is reflected off the inner surface of the windshield 1 and then enters the inside of the vehicle and light that is reflected off the outer surface of the windshield and then enters the inside of the vehicle mostly match and the problem of generation of a double image is resolved. It should be noted that the wedge angle α of the windshield 1 in this case can be set to 0.01 to 0.04° (0.2 to 0.7 mrad), for example, although the wedge angle is set depending on the installation angle of the windshield 1. ', 'The interlayer 13 is constituted by at least one layer, and can be constituted by three layers, namely a soft core layer 131 and outer layers 132 that are harder than the core layer 131 and between which the core layer 131 is sandwiched as shown in FIG3, for example. However, the interlayer is not limited to this configuration, and may be constituted by a plurality of layers including the core layer 131 and at least one outer layer 132 that is arranged on the outer glass plate 11 side. For example, the interlayer 13 may be constituted by two layers, namely the core layer 131 and one outer layer 132 arranged on the outer glass plate 11 side. Alternatively, the interlayer 13 may be configured by arranging an even number of outer layers 132 on each side of the core layer 131 so that the core layer 131 is located at the center. Alternatively, the interlayer 13 may be configured by arranging an odd number of outer layers 132 on one side of the core layer 131 and arranging an even number of outer layers 132 on the other side so that the core layer 131 is sandwiched therebetween. It should be noted that if only one outer layer 132 is provided, the outer layer 132 is provided on the outer glass plate 11 side as described above, which is for the purpose of enhancing the breakage resistance performance with respect to an external force from the outside of a vehicle or a building. Moreover, when the number of outer layers 132 is increased, the sound insulation performance is improved.']",29,437,"cross-sectional view, side view",B,"[{'element_identifier': '4', 'terms': ['Aspect']}, {'element_identifier': '500', 'terms': ['device']}, {'element_identifier': '132', 'terms': ['outer layer', 'outer layers']}, {'element_identifier': '3', 'terms': ['horizontal direction. Aspect']}, {'element_identifier': '13', 'terms': ['interlayer']}]","['1. A windshield that has a display region onto which information is projected using light emitted from a head-up display device, the windshield comprising: an outer glass plate; an inner glass plate that is arranged opposite to the outer glass plate; and an interlayer that is arranged between the outer glass plate and the inner glass plate, wherein lattice points are defined at a pitch of no greater than 20 mm in the display region, and when wedge angles at the lattice points are measured using an interferometer with 240 × 240 pixels or more, a difference between the largest value and the smallest value of the wedge angles is no greater than 0.32 mrad.']",True,"['3', '13', '31', '132', '4', '500', '17']" 733,EP_3604005_A1 (2).png,EP3604005A1,WINDSHIELD,"['FIG5', ' FIG6']","['FIG5 is a side view showing one example of a manufacturing method of a glass plate ', 'FIG6 is a cross-sectional view showing one example of glass plates and an interlayer']","['Here, a mold will be described in detail with reference to FIG5. FIG5 is a side view of furnaces through which the mold passes. As shown in FIG5, a mold 800 includes a mold main body having the shape of a frame that mostly matches the external forms of the glass plates 11 and 12. Since this mold main body 810 has the shape of a frame, there is an interior space that vertically penetrates the inner side of the mold main body. Peripheral portions of the glass plates 11 and 12 each having the shape of a flat plate are placed on an upper surface of the mold main body 810. Accordingly, heat is applied to the glass plates 11 and 12 via the interior space by a heater (not shown) that is arranged below the glass plates. When heat is applied, the glass plates 11 and 12 soften and curve downward under their own weight. In some cases, a shield plate for shielding the glass plates from heat is arranged on an inner periphery of the mold main body 810 to enable adjustment of heat applied to the glass plates 11 and 12. The heater can be arranged above the mold 800 as well as below the mold.', 'After the above-described mask layer 2 is layered on the outer glass plate 11 and the inner glass plate 12 having the shape of a flat plate, the outer glass plate 11 and the inner glass plate 12 are superimposed and passed through a heating furnace 802 in a state of being supported by the above-described mold 800 as shown in FIG5. When the glass plates 11 and 12 are heated to around the softening point in the heating furnace 802, portions of the glass plates inward of peripheral portions curve downward under their own weight and thus the glass plates are molded into a curved shape. Subsequently, the glass plates 11 and 12 are conveyed from the heating furnace 802 to an annealing furnace 803 to be subjected to annealing treatment. Thereafter, the glass plates 11 and 12 are conveyed out of the annealing furnace 803 and cooled. ', 'It is thought that a double image is mainly generated in any of the following cases or a combination thereof. First, as shown in FIG6, there is a case where almost no irregularities are formed in the outer glass plate 11 and the inner glass plate 12 but irregularities are formed in surfaces of the interlayer 13. In this case, when the glass plates 11 and 12 and the interlayer 13 are permanently bonded as described above, irregularities may also be formed in the glass plates 11 and 12 due to the irregularities in the interlayer 13.']",32,493,"cross-sectional view, side view",B,"[{'element_identifier': '7', 'terms': ['less. Aspect']}, {'element_identifier': '5', 'terms': ['up-down direction. Aspect', 'aldehyde having']}, {'element_identifier': '12', 'terms': ['glass plates', 'glass plate']}, {'element_identifier': '810', 'terms': ['mold main body']}, {'element_identifier': '6', 'terms': ['glass. Aspect', 'OSLO Premium Edition Rev.']}, {'element_identifier': '802', 'terms': ['heating furnace']}, {'element_identifier': '803', 'terms': ['annealing furnace']}]","['1. A windshield that has a display region onto which information is projected using light emitted from a head-up display device, the windshield comprising: an outer glass plate; an inner glass plate that is arranged opposite to the outer glass plate; and an interlayer that is arranged between the outer glass plate and the inner glass plate, wherein lattice points are defined at a pitch of no greater than 20 mm in the display region, and when wedge angles at the lattice points are measured using an interferometer with 240 × 240 pixels or more, a difference between the largest value and the smallest value of the wedge angles is no greater than 0.32 mrad.']",True,"['5', '12', '802', '803', '810', '008', '6', '12', '7', '18']" 734,EP_3604013_A1 (3).png,EP3604013A1,HYBRID VEHICLE,['FIG4'],"['FIG4 is a table illustrating the respective states of a transmission, a clutch, an engine, and an electric motor of the vehicle of FIG1 in different modes']","['FIG4 is a table illustrating the respective states of the transmission 5, clutch 12, engine E, and electric motor M of the vehicle 1 of FIG1 in different modes. As shown in FIG4, the control mode of the vehicle 1 includes an engine-motor-driven travel mode, an engine-driven travel mode, and a motor-driven travel mode. Selection from among the modes is made by the program of the controller 24 or by the user.']",30,89,table,Y,"[{'element_identifier': '12', 'terms': ['clutch']}]","['2. The hybrid vehicle according to claim 1, further comprising: a sensor that detects which state the clutch is in or detects a command to actuate the clutch; and a controller that controls the electric motor based on an output from the sensor.']",False,['12'] 735,EP_3604013_A1 (5).png,EP3604013A1,HYBRID VEHICLE,['FIG7'],['FIG7 is a block diagram showing a modified example of the manner of connection of an electric motor'],"['The manner of connection of the electric motor M to the output shaft 7 may be different from that described above. FIG7 is a block diagram showing a modified example of the manner of connection of the electric motor M. In a transmission 105 shown in FIG7, gears 9A provided on the input shaft 6 are fitted on the input shaft 6 so as to corotate with the input shaft 6, while gears 9B and 9C provided on the output shaft 7 are rotatably fitted on the output shaft 7 so as to rotate independently of the output shaft 7. The gears 9B and 9C provided on the output shaft 7 are constantly in mesh with the gears 9A provided on the input shaft 6. Dog rings 42 provided on the output shaft 7 are fitted on the output shaft 7 so as to corotate with the output shaft 7. Upon rotation of a shift drum 40, a shift fork 41 moves along the output shaft 7 to cause the dog ring 42 to engage with one gear selected from the plurality of gears 9B and 9C, and the engaged gear corotates with the output shaft 7.', 'The electric motor M is connected to the gear 9C (rotating member) which is one of the gears 9B and 9C provided on the output shaft 7 via the second power transmission mechanism 17, so that power is constantly transmitted from the electric motor M to the gear 9C. When the dog ring 42 is not engaged with the gear 9C, the gear 9C rotates independently of the output shaft 7. Thus, power of the electric motor M is transmitted to the input shaft 6 via the gear 9C and gear 9A, and the resulting rotation of the input shaft 6 is transmitted to the output shaft 7 via the gear 9B corresponding to the desired gear position and engaged with the dog ring 42. That is, with the configuration of FIG7, the electric motor M can transmit power to the input shaft 6 through a route different from the route through which power from the engine E is transmitted to the input shaft 6. When the dog ring 42 is engaged with the gear 9C, the gear 9C corotates with the output shaft 7. Thus, power transmitted from the electric motor M to the gear 9C can be directly transmitted to the output shaft 7.']",18,428,block diagram,Y,"[{'element_identifier': '8', 'terms': ['output power transmission mechanism']}, {'element_identifier': '17', 'terms': ['second power transmission mechanism']}, {'element_identifier': '14', 'terms': ['slave cylinder']}, {'element_identifier': '12', 'terms': ['clutch']}, {'element_identifier': '6', 'terms': ['input shaft']}, {'element_identifier': '105', 'terms': ['transmission']}, {'element_identifier': '42', 'terms': ['dog ring']}, {'element_identifier': '40', 'terms': ['shift drum']}]","['1. A hybrid vehicle comprising: an internal combustion engine; an electric motor; a transmission comprising an input shaft that receives power inputted from the internal combustion engine and the electric motor and an output shaft that outputs power to a drive wheel; and a power cutting-off mechanism configured to cut off a power transmission route between the internal combustion engine and the output shaft, wherein the electric motor is connected to a rotating member provided on the output shaft in such a manner that the electric motor transmits power to the output shaft at a location downstream of the power cutting-off mechanism.', '2. The hybrid vehicle according to claim 1, further comprising: a sensor that detects which state the clutch is in or detects a command to actuate the clutch; and a controller that controls the electric motor based on an output from the sensor.', '5. The hybrid vehicle according to any one of claims 1 to 4, further comprising an output power transmission mechanism that transmits power from the output shaft to the drive wheel, wherein an end portion of the output shaft projects to one side in a vehicle width direction from a crankcase housing the transmission, the output power transmission mechanism is connected to the end portion of the output shaft, and the electric motor inputs power to the end portion of the output shaft.']",False,"['105', '6', '42', '12', '40', '17', '8', '14']" 736,EP_3604013_A1 (6).png,EP3604013A1,HYBRID VEHICLE,['FIG8'],['FIG8 is a side view showing a modified example of the manner of supporting of an electric motor '],"['The manner of supporting of the electric motor M may be different from that described above. FIG8 is a side view showing a modified example of the manner of supporting of the electric motor M. As shown in FIG8, the electric motor M disposed away from the crankcase 29 is supported by a motor supporting frame 150. The motor supporting frame 150 is provided separately from the pair of frame portions 127 which extend rearward from the head pipe portion 26 and which are spaced apart from each other in the vehicle width direction. The motor supporting frame 150 is fixed to the frame portions 127 by fastening members B (e.g., bolts). The motor supporting frame 150 serves also as a pivot frame that pivotally supports the swing arm 30. The motor supporting frame 150 is fixed to the crankcase 29 by fastening members. The motor supporting frame 150 may constitute a part of the crankcase 29.']",18,168,side view,Y,"[{'element_identifier': '30', 'terms': ['swing arm']}, {'element_identifier': '29', 'terms': ['crankcase']}, {'element_identifier': '2', 'terms': ['drive wheel']}, {'element_identifier': '10', 'terms': ['crankshaft']}, {'element_identifier': '26', 'terms': ['head pipe portion']}, {'element_identifier': '15', 'terms': ['biasing member']}, {'element_identifier': '31', 'terms': ['clutch operation sensor']}, {'element_identifier': '150', 'terms': []}, {'element_identifier': '127', 'terms': ['frame portions']}]","['1. A hybrid vehicle comprising: an internal combustion engine; an electric motor; a transmission comprising an input shaft that receives power inputted from the internal combustion engine and the electric motor and an output shaft that outputs power to a drive wheel; and a power cutting-off mechanism configured to cut off a power transmission route between the internal combustion engine and the output shaft, wherein the electric motor is connected to a rotating member provided on the output shaft in such a manner that the electric motor transmits power to the output shaft at a location downstream of the power cutting-off mechanism.', '3. The hybrid vehicle according to claim 1 or 2, wherein the electric motor is separately provided outside a crankcase housing the transmission.', '7. The hybrid vehicle according to any one of claims 1 to 6, further comprising a vehicle body frame comprising a pair of frame portions spaced apart from each other in a vehicle width direction, wherein the electric motor is disposed in such a manner that a drive shaft of the electric motor extends in the vehicle width direction, and opposite end portions of a casing of the electric motor in the vehicle width direction are supported by the pair of frame portions.']",False,"['26', '125', '127', '2', '150', '30', '31', '10', '29', '15']" 737,EP_3604013_A1.png,EP3604013A1,HYBRID VEHICLE,['FIG1'],['FIG1 is a block diagram of a hybrid vehicle according to an embodiment'],"['FIG1 is a block diagram of a hybrid vehicle 1 according to an embodiment. As shown in FIG1, the hybrid vehicle 1 is, for example, a motorcycle. The vehicle 1 includes an unillustrated driven wheel (front wheel) and a drive wheel 2 (rear wheel). The handle of the vehicle 1 includes a grip 3 equipped with a clutch operation member 4 (e.g., a clutch lever). The clutch operation member 4 is, for example, a clutch lever operated by a hand of the driver or a clutch pedal operated by a foot of the driver. The vehicle 1 includes an engine E (internal combustion engine) serving as a drive source for travel and as a drive source for electricity generation and an electric motor M serving as a drive source for travel and as an electricity generator.', 'The electric motor M is placed in such a manner that its drive shaft Ma (see FIG1) extends in the vehicle width direction. The opposite end portions of the casing Mb of the electric motor M in the vehicle width direction are fixed to the pair of frame portions 27. Each frame portion 27 has a motor supporting region 27a to which the electric motor M is fixed, and the motor supporting region 27a as viewed in the vehicle width direction is wider than the other regions of the frame portion 27 which are adjacent to the motor supporting region 27a. The electric motor M is disposed at such a location that the electric motor M as viewed in the vehicle width direction is enclosed by the frame portions 27.']",13,294,block diagram,Y,"[{'element_identifier': '24', 'terms': ['controller']}, {'element_identifier': '17', 'terms': ['second power transmission mechanism']}, {'element_identifier': '23', 'terms': ['wheel rotational speed sensor']}, {'element_identifier': '35', 'terms': ['engine ECU']}, {'element_identifier': '38', 'terms': ['electronic throttle valve']}, {'element_identifier': '22', 'terms': ['transmission sensor']}, {'element_identifier': '18', 'terms': ['battery']}, {'element_identifier': '37', 'terms': ['ignition plug']}, {'element_identifier': '2', 'terms': ['drive wheel']}, {'element_identifier': '20', 'terms': ['engine rotational speed sensor']}, {'element_identifier': '21', 'terms': ['clutch sensor']}, {'element_identifier': '16', 'terms': ['holding mechanism']}, {'element_identifier': '15', 'terms': ['biasing member']}, {'element_identifier': '36', 'terms': ['fuel injector']}, {'element_identifier': '31', 'terms': ['clutch operation sensor']}, {'element_identifier': '13', 'terms': ['master cylinder']}]","['1. A hybrid vehicle comprising: an internal combustion engine; an electric motor; a transmission comprising an input shaft that receives power inputted from the internal combustion engine and the electric motor and an output shaft that outputs power to a drive wheel; and a power cutting-off mechanism configured to cut off a power transmission route between the internal combustion engine and the output shaft, wherein the electric motor is connected to a rotating member provided on the output shaft in such a manner that the electric motor transmits power to the output shaft at a location downstream of the power cutting-off mechanism.', '2. The hybrid vehicle according to claim 1, further comprising: a sensor that detects which state the clutch is in or detects a command to actuate the clutch; and a controller that controls the electric motor based on an output from the sensor.']",False,"['35', '36', '37', '38', '15', '16', '31', '13', '20', '2', '21', '22', '17', '35', '24', '18', '23']" 738,EP_3604095_A1 (4).png,EP3604095A1,BATTERY SUPPORT STRUCTURE FOR SADDLE-TYPE VEHICLE,['FIG7'],['FIG7 is a side view that illustrates a lid of the tool box mounted on a vehicle body'],"['FIG7 is an enlarged view of the lid 31, as viewed from the left direction, for illustrating how the lid 31 is mounted. The lid 31 is formed like a trapezoid that is turned upside down. In addition, for making the front portion of the lid 31 higher and the rear portion of the lid 31 lower, the lid 31 is disposed diagonally along the lower surface of the main frame 7, which is disposed diagonally upward in the front direction as viewed in a side view.', 'Moreover, as illustrated in FIG7, since the tool box 13 including the lid 31 is directly fixed to the vehicle-body frame via the bolts 35a and 36a, the need for the tool box band used for the above-described slide-type battery case can be eliminated. As a result, the number of components and the weight can be reduced.']",18,165,side view,B,"[{'element_identifier': '8', 'terms': ['pivot frame']}, {'element_identifier': '7', 'terms': ['main frame']}, {'element_identifier': '17', 'terms': ['battery']}, {'element_identifier': '35', 'terms': ['front-side upper portion']}, {'element_identifier': '34', 'terms': ['hinge']}, {'element_identifier': '50', 'terms': ['engine hanger stay']}, {'element_identifier': '36', 'terms': ['rear-side upper portion']}, {'element_identifier': '31', 'terms': ['lid']}, {'element_identifier': '13', 'terms': ['tool box']}]","['1. A battery support structure for a saddle-type vehicle, comprising: a vehicle-body frame (1); an engine (10) supported by the vehicle-body frame (1); a battery case (16) supported below the vehicle-body frame (1); and a battery (17) housed in the battery case (16); the battery case (16) having a side opening (16a) opened toward one direction in a vehicle-width direction, the battery case (16) being disposed such that a longitudinal direction of the battery case (16) is equal to the vehicle-width direction, the battery (17) being housed in the battery case (16) such that the battery (17) is detachably attached to the battery case (16) along the vehicle-width direction, wherein a storage case (13) for containing a non-electrical component is disposed on the side opening (16a) side of the battery case (16) and adjacent to the battery (17), one portion of the storage case (13) fits in the side opening (16a) of the battery case (16), and protrudes inward from the side opening (16a), and the battery (17) is prevented by the storage case (13), from moving toward a direction in which the battery (17) is removed.', '4. The battery support structure according to claim 1, wherein the storage case (13) includes a storage case body (30) and a lid (31), wherein the storage case (13) is configured to contain a tool, and the storage case body (30) serves as an abutment portion that abuts against the battery (17).', '5. The battery support structure according to claim 1, wherein the engine (10) is supported by the vehicle-body frame (1) via an engine hanger (54) formed in an engine hanger stay (50) extending from the vehicle-body frame (1), the storage case (13) is fixed to the engine hanger stay (50), one surface of the battery case (16) in a front-and-rear direction is locked by the engine hanger (54), and the storage case (13) is fixed to the engine hanger stay (50) and the battery case (16) is locked by the engine hanger (54) with respect to the engine hanger stay (50).', '6. The battery support structure according to claim 1, wherein the vehicle-body frame (1) includes a main frame (7) disposed above the engine (10) and extending in the front-and-rear direction, and a pivot frame (8) disposed behind the engine (10) and extending in a vertical direction, the engine (10) includes a crank case (11) and a cylinder (12) protruding upward from an upper portion of the crank case (11), and when viewed in a side view of the vehicle, the battery case (16) is disposed in a space surrounded by the cylinder (12), the main frame (7), the pivot frame (8), and the crank case (11).']",False,"['7', '35', '8', '17', '13', '31', '36', '50', '34']" 739,EP_3604102_A1 (3).png,EP3604102A1,DUAL CROWN STEERING ASSEMBLY,['FIG4B'],['FIG4B is a bottom plan view of the lower cone in accordance with an illustrative embodiment'],"['As shown in FIG4B, the lower cone 125 includes a central hexagonal hole 410 that is configured to receive a hexagonal (hex) wrench such that the lower cone 125 can be tightened/loosened within the lower crown of the front fork. In an illustrative embodiment, the hexagonal hole 410 fits a 6 mm hex wrench. Alternatively, a different size of hole, a different type of hole, and/or a different type of wrench may be used to tighten/loosen the lower cone 125. The lower cone 125 also includes a plurality of openings 415 which reduce overall weight of the lower cone 125 and facilitate formation of the central hexagonal hole 410. In an alternative embodiment, the plurality of openings 415 may not be included.']",16,139,bottom plan view,B,"[{'element_identifier': '415', 'terms': ['openings']}, {'element_identifier': '400', 'terms': ['threaded portion']}, {'element_identifier': '15', 'terms': ['underside']}, {'element_identifier': '405', 'terms': ['bearing interface']}, {'element_identifier': '125', 'terms': ['lower cone']}, {'element_identifier': '410', 'terms': ['hexagonal hole']}, {'element_identifier': '407', 'terms': ['tapered portion']}]","['1. A steering assembly for a bicycle, comprising: a front fork that includes an upper crown, a lower crown, and a rigid crown connector that connects the upper crown to the lower crown; an upper cone configured to mount to the upper crown of the front fork, wherein the upper cone includes an upper cone bearing interface configured to interact with an upper bearing assembly seated in an upper portion of a head tube of a bicycle frame; and a lower cone configured to mount to the lower crown of the front fork, wherein the lower cone includes a lower cone bearing interface configured to interact with a lower bearing assembly seated in a lower portion of the head tube of the bicycle frame.', '3. The steering assembly of claim 1 or claim 2, wherein the lower cone includes a threaded portion that is threaded into a through hole in the lower crown.']",True,"['125', '405', '400', '407', '410', '15', '415']" 740,EP_3604102_A1 (4).png,EP3604102A1,DUAL CROWN STEERING ASSEMBLY,['FIG5B'],['FIG5B is a bottom plan view of the lower cone locknut in accordance with an illustrative embodiment'],"['As shown in FIG5B, the lower cone locknut 135 includes a through hole 505, a circumference of which includes a plurality of indentations 510. The plurality of indentations 510 are used to mate with a wrench such that the lower cone locknut 135 can be tightened and loosened. Additionally, the through hole 505 allows simultaneous placement and use of a hex wrench in the hexagonal hole 410 in the lower cone 125 and a lower cone locknut wrench that mates with the plurality of indentations 510. The hex wrench can be used to ensure that the lower cone 125 does not rotate while the lower cone locknut 135 is being tightened. The lower cone locknut can have a height of 4.5 mm and a diameter of 36 mm in one embodiment. Alternatively, a different size of lower cone locknut may be used.', 'In an operation 920, a lower cone locknut is mounted within the lower crown for the front fork. As discussed herein, the lower cone locknut is used to prevent movement of the lower cone once the lower cone is in a desired position. To prevent movement of the lower cone while the lower cone locknut is being mounted, a hex (or other) wrench used to mount the lower cone can be used to hold the lower in place during tightening of the lower cone locknut with a different wrench (e.g., a wrench that matches the internal configuration of the lower cone locknut 135 as depicted in FIG5B).']",17,271,bottom plan view,B,"[{'element_identifier': '16', 'terms': ['handlebars']}, {'element_identifier': '500', 'terms': ['includes threads']}, {'element_identifier': '505', 'terms': ['through hole']}, {'element_identifier': '510', 'terms': ['indentations']}, {'element_identifier': '135', 'terms': ['lower cone locknut']}]","['2. The steering assembly of claim 1, wherein the upper cone includes a through hole that is configured to receive one or more cables that are routed from a handlebar of the bicycle to an interior of the head tube of the bicycle.', '4. The steering assembly of claim 3, further comprising a lower cone locknut that is configured to thread into the through hole in the lower crown adjacent to the lower cone to prevent movement of the lower cone.']",True,"['135', '505', '16', '500', '510']" 741,EP_3604106_A1 (2).png,EP3604106A1,SADDLE-TYPE VEHICLE,['FIG3'],"['FIG3 is a plan view, as viewed from below, of the saddle riding vehicle in the state of FIG2']","['Specifically, the muffler 37 is disposed on transverse directionally one side (right side) in relation to the rear wheel 3 located on the imaginary line C (FIG3) passing through the crankcase split surface CS, whereas the arm section 31 is disposed on the transverse directionally other side (left side) in relation to the rear wheel 3.', 'The catalyst device accommodating exhaust pipe 131 includes an exhaust pipe section 131a which is formed in a curved shape such as to go from the rear side toward the left side in continuity with the upstream-side exhaust pipe 122, a catalyst case section 131b which is enlarged in diameter as compared to the exhaust pipe section 131a and inside which to accommodate the catalyst device 140, and a connection section 131h which connects the exhaust pipe section 131a and the catalyst case section 131b and which is gradually enlarged in diameter from the exhaust pipe section 131a. An upstream end portion 134a of the connection pipe 134 is united by welding with a downstream end portion 131d of the catalyst device accommodating exhaust pipe 131. As depicted in FIG3, the catalyst case section 131b is located on a lower side of the engine 30, and is disposed such that its longitudinal direction is oriented in the transverse direction of the saddle riding vehicle 1.']",21,240,plan view,B,"[{'element_identifier': '121', 'terms': ['exhaust pipe']}, {'element_identifier': '20', 'terms': ['seat frames', 'seat frame']}, {'element_identifier': '40', 'terms': ['air cleaner box']}, {'element_identifier': '31', 'terms': ['arm section']}, {'element_identifier': '120', 'terms': ['exhaust device']}, {'element_identifier': '30', 'terms': ['engine']}, {'element_identifier': '12', 'terms': ['body frame']}, {'element_identifier': '37', 'terms': ['muffler']}, {'element_identifier': '25', 'terms': ['rear cross member']}, {'element_identifier': '24', 'terms': ['upper cross member']}, {'element_identifier': '17', 'terms': ['head pipe']}, {'element_identifier': '19', 'terms': ['lower frames', 'lower frame']}, {'element_identifier': '22', 'terms': []}, {'element_identifier': '27', 'terms': ['support frames', 'support frame']}, {'element_identifier': '21', 'terms': ['slant sections', 'slant section']}, {'element_identifier': '140', 'terms': ['catalyst device']}, {'element_identifier': '23', 'terms': ['cross member']}, {'element_identifier': '13', 'terms': ['unit swing engine']}, {'element_identifier': '35', 'terms': ['cylinder section']}, {'element_identifier': '122', 'terms': ['upstream-side exhaust pipe']}, {'element_identifier': '2', 'terms': ['front wheel']}, {'element_identifier': '34', 'terms': ['crankcase']}, {'element_identifier': '26', 'terms': ['box support frame']}, {'element_identifier': '58', 'terms': ['cylinder cover']}, {'element_identifier': '3', 'terms': ['rear wheel']}]","['1. A saddle riding vehicle comprising: a body frame (12); a unit swing engine (13) having a cylinder section (35) disposed substantially horizontally and a crankcase (34), the unit swing engine (13) being swingably supported on the body frame (12) through a link member (38); and an exhaust device (120) connected to the unit swing engine (13) and including an exhaust pipe (121) and a catalyst device (140) disposed at an intermediate portion of the exhaust pipe (121), wherein the link member (38) is disposed on an upper side of the crankcase (34), in side view, at least part of the catalyst device (140) is disposed below the cylinder section (35) and is located in a region between an imaginary line (L1) connecting a link member coupling section (61) for coupling the link member (38) to the body frame (12) and a front end of the crankcase (34) and an imaginary line (L2) connecting an exhaust pipe connection section (35e) of the unit swing engine (13) connected with an end of the exhaust pipe (121) and the link member coupling section (61), and an exhaust device coupling section (135) for coupling the crankcase (34) and the exhaust device (120) is provided.']",False,"['120', '30', '27', '140', '37', '22', '25', '24', '20', '21', '26', '23', '19', '12', '35', '17', '2', '24', '3', '19', '22', '121', '122', '58', '20', '27', '31', '40', '13', '34']" 742,EP_3604167_A2 (2).png,EP3604167A2,PACKAGING HAVING A DAMPING ELEMENT,['FIG3'],['FIG3 provides a representational side view of a plurality of capsules containing dilatant fluid located between corresponding plates in the packaging which is the subject of the invention '],"['FIG3 provides a representational side view of a plurality of capsules (21) containing dilatant fluid (30) located between the corresponding plates in the packaging (1) which is the subject of the invention. In an alternative embodiment of the invention, the damping element (20) may have a plurality of capsules (21) positioned between a first plate (22) and a second plate (23) which correspond to one another. The structure of the said capsules (21) may be cylindrical, spherical, in the form of cubic prisms, polygonal prisms or similar forms. There may be at least one first extension (221) extending from the first plate (22) towards the second plate (23) and at least one second extension (231) extending from the second plate (23) towards the first plate (22). In order to ensure that there is a predetermined distance between the first plate (22) and the second plate (23), there may be on any one of the first extension (221) or the second extension (231) at least one resting surface (232) and at least one stopping surface (223) corresponding to and facing the other. The said stopping surface (223) provided on either the first plate (22) or the second plate (23) facing the other may be situated within an extension housing (224) forming a recess. It is thereby ensured that either the first extension (221) or the second extension (231) which engage telescopically is secured in an extension housing (224) provided opposite thereto to form a predetermined distance between the first plate (22) and the second plate (23).']",28,325,side view,B,"[{'element_identifier': '20', 'terms': ['damping element']}, {'element_identifier': '10', 'terms': ['storage volume']}, {'element_identifier': '231', 'terms': ['second extension']}, {'element_identifier': '21', 'terms': ['capsules', 'capsule']}, {'element_identifier': '23', 'terms': ['second plate']}]","['1. Packaging (1) having a plurality of walls (11) provided in a manner defining a storage volume (10) and for use in packaging of at least one product, particularly white goods, characterized by comprising dilatant fluid (30) enclosed in at least one damping element (20) provided on the side of at least one of said walls (11) which faces said storage volume (10).', '2. Packaging (1) according to Claim 1, wherein said damping element (20) is an elastic capsule (21).', '3. Packaging (1) according to Claim 1, wherein the damping element (20) has a first plate (22) and a second plate (23) provided in a corresponding arrangement, and at least one sealing element (24) is provided between said first plate (22) and said second plate (23) for providing sealing.', '4. Packaging (1) according to Claim 3, wherein at least one first extension (221) is provided which extends from the first plate (22) towards the second plate (23), and at least one second extension (231) is provided which extends from the second plate (23) towards the first plate (22), and a sealing element (24) is provided which is positioned between said first extension (221) and said second extension (231) extending in a manner in which they engage telescopically with each other.']",False,"['10', '20', '23', '231', '21', '3']" 743,EP_3604167_A2.png,EP3604167A2,PACKAGING HAVING A DAMPING ELEMENT,['FIG1'],['FIG1 provides a representational side view of a capsule containing dilatant fluid attached to the walls of the packaging which is the subject of the invention'],"['Referring to FIG1: the packaging (1) which is the subject of the invention comprises a plurality of walls (11) provided so as to define a storage volume (10) and a dilatant fluid (30) enclosed in at least one damping element (20) provided on the side of the said walls (11), at least one of which faces the said storage volume (10).']",26,78,side view,B,"[{'element_identifier': '21', 'terms': ['capsules', 'capsule']}, {'element_identifier': '30', 'terms': ['dilatant fluid']}, {'element_identifier': '10', 'terms': ['storage volume']}, {'element_identifier': '1', 'terms': ['packaging']}]","['1. Packaging (1) having a plurality of walls (11) provided in a manner defining a storage volume (10) and for use in packaging of at least one product, particularly white goods, characterized by comprising dilatant fluid (30) enclosed in at least one damping element (20) provided on the side of at least one of said walls (11) which faces said storage volume (10).', '2. Packaging (1) according to Claim 1, wherein said damping element (20) is an elastic capsule (21).']",False,"['10', '30', '21', '1', '5']" 744,EP_3604194_A1 (1).png,EP3604194A1,TRACKING SERVICE MECHANIC STATUS DURING ENTRAPMENT,['FIG2'],['FIG2 is a schematic illustration of an elevator system that may employ various embodiments of the present disclosure'],"['FIG2 is a perspective view of an elevator system 101 including an elevator car 103, a counterweight 105, a tension member 107, a guide rail 109, a machine 111, a position reference system 113, and a controller 115. The elevator car 103 and counterweight 105 are connected to each other by the tension member 107. The tension member 107 may include or be configured as, for example, ropes, steel cables, and/or coated-steel belts. The counterweight 105 is configured to balance a load of the elevator car 103 and is configured to facilitate movement of the elevator car 103 concurrently and in an opposite direction with respect to the counterweight 105 within an elevator shaft 117 and along the guide rail 109.']",18,137,schematic,B,"[{'element_identifier': '121', 'terms': ['controller room']}, {'element_identifier': '113', 'terms': ['position reference system']}, {'element_identifier': '105', 'terms': ['counterweight']}, {'element_identifier': '101', 'terms': ['elevator system']}, {'element_identifier': '10', 'terms': ['mouse']}, {'element_identifier': '125', 'terms': ['landings']}, {'element_identifier': '107', 'terms': ['tension member']}]","['1. A system for tracking service mechanic status, the system comprising: a controller of an elevator system that is operably coupled to an elevator, wherein the controller is configured to control the elevator and detect a status of the elevator; a processor operably coupled to the controller and a memory, wherein the memory is configured to store responder information, wherein the processor is configured to receive responder information from the memory and generate notification information based at least in part on the responder information; an interface unit for transmitting the notification information; and a notification unit operably coupled to the elevator, configured to provide the notification information.']",False,"['101', '113', '107', '121', '125', '125', '105', '125', '2', '10']" 745,EP_3604219_A1 (3).png,EP3604219A1,"SOLID ELECTROLYTE, LITHIUM BATTERY, BATTERY PACK, AND VEHICLE",['FIG7'],['FIG7 is a schematic diagram showing an electrode body manufactured by the manufacturing method shown in FIG6'],"['According to the structure, the surface of the electrolyte layer 12 is formed so that the surfaces of the electrolyte layer 12, and the positive electrode layer 11 and the negative electrode layer 13 are closely adhered to each other along the irregularities on the surfaces of the positive electrode layer 11 and the negative electrode layer 13, such that there are nearly no gaps between the electrolyte layer 12 and the positive electrode layer 11, and between the electrolyte layer 12 and the negative electrode layer 13. In particular, as shown in FIG7, when the inorganic solid particles 121A, which are a part of the inorganic solid particles 121, are included deeply in the concave part of the negative electrode layer 13, conductivity is excellently provided through the inorganic solid particles 121A on the surface including the concave part of the negative electrode layer 13. In addition, when the electrolyte layer 12 includes, for example, the inorganic solid particles 121B which are hard particles as the solid electrolyte particles, the hard inorganic solid particles 121B impart structural strength to the electrolyte layer 12, thereby securing some extent of thickness in the electrolyte layer 12. Thus, short-circuiting due to the positive electrode layer 11 and the negative electrode layer 13 becoming directly and closely adhered with each other can be prevented.']",17,242,schematic diagram,B,"[{'element_identifier': '122', 'terms': ['organic electrolyte']}, {'element_identifier': '121', 'terms': ['inorganic solid particles']}, {'element_identifier': '12', 'terms': ['electrolyte layer']}, {'element_identifier': '11', 'terms': ['positive electrode layer']}, {'element_identifier': '123', 'terms': ['composite electrolyte']}, {'element_identifier': '13', 'terms': ['negative electrode layer']}]","['6. The lithium battery (20) according to claim 4 or 5, wherein at least one of the positive electrode layer (11), the negative electrode layer (13), and the Li conductive layer includes a composite electrolyte (123), the composite electrolyte (123) including the solid electrolyte and an organic electrolyte (122), a weight ratio of the organic electrolyte (122) in the composite electrolyte (123) being from 0.1% to 20%.']",True,"['121', '123', '121', '122', '123', '121', '122', '13', '12', '11', '27']" 746,EP_3604222_A1.png,EP3604222A1,PROCESS FOR THE PURIFICATION OF HYDROGEN CYANIDE,['FIG2'],['FIG2 shows an embodiment of the process of the invention where first liquid stream (2) is heated by heat exchange with bottoms stream (6) before it is introduced into distillation column (4)'],"['The examples herein are performed using a computational model of a process based on the distillation process shown in FIG2. Process modelling is an established and reliable methodology used by engineers to simulate complex chemical processes before building the real plant. In the context of the examples herein the commercial modeling software Aspen Plus® (Aspen Technology, Inc., 20 Crosby Roads, Bedford, Massachusetts 01730, USA) was used in combination with physical property data available from public databases.', 'Using the modeling software Aspen Plus®, the purification of the acrolein comprising stream is simulated for a distillation process shown in FIG2: An aqueous feed stream (1) comprising ca. 6 wt.-% acrolein is split into a first liquid stream (2) and a second liquid stream (3) with a mass flow ratio of 85:25. The stream (2) is heated to a temperature of about 84°C in the heat exchanger (7) by use of the bottom stream (6) from the distillation column (4) to give a heated stream (8). Said stream (8) is introduced at the feed stage of the distillation column (4). The heat transmitted in the heat exchanger (7) is kept at 9765 kW for all mass ratios of stream (2) to stream (3). The thus obtained cooled bottom stream (11) is discarded. The stream (3) is introduced at the highest stage of the distillation column (4) with a temperature of 18.5°C. A bottom stream (11) enriched in water is feed to the heat exchanger (7).']",38,303,embodiment,C,"[{'element_identifier': '3', 'terms': ['stream']}, {'element_identifier': '2', 'terms': ['stream', 'streams']}, {'element_identifier': '10', 'terms': ['stream']}, {'element_identifier': '13', 'terms': ['liquefied stream']}]","['1. A process for the purification of hydrogen cyanide, comprising the steps of a) splitting a liquid feed stream (1) comprising hydrogen cyanide into at least a first liquid stream (2) and a second liquid stream (3), b) introducing the first liquid stream (2) with a temperature T1 into a distillation column (4) at a point between the top and the bottom of the distillation column, c) introducing the second liquid stream (3) with a temperature T2 into the distillation column (4) at the top of the distillation column (4), d) withdrawing an overhead vapor stream (5) enriched in hydrogen cyanide from the distillation column (4), and e) withdrawing a bottom stream (6) depleted in hydrogen cyanide from the distillation column (4), wherein the temperature T2 of the second liquid stream (3) in step c) is lower than the temperature T1 of the first liquid stream (2) in step b).', '13. The process according to any of claims 1 to 10, further comprising the steps of g) condensing at least a part of the overhead vapor stream (5) withdrawn from the distillation column (4) to give a liquefied stream (13) and, if applicable, a residual vapor stream (14), and h) feeding the liquefied stream (13) of step g) to a further processing or to a storage tank.']",True,"['3', '2', '3', '10', '2', '13']" 747,EP_3604359_A1.png,EP3604359A1,WATER-ABSORBENT RESIN PARTICLES,['FIG1'],['FIG1 is a schematic view illustrating a device for measuring a swelling force '],"['Using a device in FIG1, a swelling force test of the water-absorbent resin particles was performed. An acrylic resin-made cylinder 2 with an inner diameter of 20 mm and a height of 50 mm, which had openings at both ends and had a nylon mesh 1 (255 mesh) installed at one of the openings was prepared. 0.1 g of water-absorbent resin particles 3 were uniformly spread onto the nylon mesh 1 of the cylinder 2 in a state where the cylinder 2 was left to stand vertically in such a direction that the opening of the side having the nylon mesh 1 installed was positioned below. An acrylic resin-made cylindrical jig (weight) 4 with a diameter of 19.5 mm, a height of 59 mm, and a mass of 20.5 g was inserted.']",13,152,schematic view,A,"[{'element_identifier': '5', 'terms': ['dish']}, {'element_identifier': '9', 'terms': ['load cell']}, {'element_identifier': '2', 'terms': ['cylinder']}, {'element_identifier': '6', 'terms': ['glass filter']}, {'element_identifier': '10', 'terms': ['pressure-sensitive part']}, {'element_identifier': '3', 'terms': ['water-absorbent resin particles']}]","['1. Water-absorbent resin particles comprising a crosslinked polymer comprising a monomer unit derived from a water-soluble ethylenically unsaturated monomer, wherein an initial swelling force of the water-absorbent resin particles as measured according to a swelling force test conducted in the following order of i), ii), iii), iv), and v) is 8 N or more, and a ratio of particles having a particle diameter of more than 250 µm and 850 µm or less is 70% by mass or more and a ratio of particles having a particle diameter of 250 µm or less is 20% by mass or less, with respect to the total amount of the water-absorbent resin particles: i) preparing a cylinder with an inner diameter of 20 mm, which has openings at both ends and has a nylon mesh installed in one of the openings, spreading 0.1 g of the water-absorbent resin particles uniformly on the nylon mesh in the cylinder in the state where the cylinder is left to stand vertically in such a direction that a side having the nylon mesh installed thereon is positioned below, and placing a cylindrical jig with a diameter of 19.5 mm on the water-absorbent resin particles, ii) placing a glass filter with a thickness of 5 mm in a horizontally installed Petri dish and infiltrating physiological saline into the grass filter up to a position slightly below an upper surface of the glass filter, iii) placing a liquid-impermeable sheet on the upper surface of the glass filter having the physiological saline infiltrated thereinto and standing the cylinder containing the water-absorbent resin particles vertically on the liquid-impermeable sheet in a direction such that the nylon mesh is positioned below, iv) removing the liquid-impermeable sheet to initiate water absorption by the water-absorbent resin particles, and v) measuring a force to push up the cylindrical jig generated by the swelling of the water-absorbent resin particles at a time point of 10 seconds after the removal of the liquid-impermeable sheet with a load cell and recording it as an initial swelling force.']",False,"['9', '10', '17', '2', '3', '6', '5']" 748,EP_3604435_A1 (1).png,EP3604435A1,STRUCTURE COMPRISING LOW-RESILIENCE ELASTIC MEMBER AND HIGH-RESILIENCE ELASTIC MEMBER,['FIG4'],['FIG4 is a diagram schematically showing a rear view (back view) of the sportswear of FIG3'],['FIG4 shows a rear view (back view) of the sportswear of FIG3. The high-resilience elastic member 2 (mesh body) made of the high-resilience elastic thermoplastic elastomer (Y) is disposed in a cross shape at shoulder and arm base portions. The high-resilience elastic member 2 composed of the cross-shaped high-resilience elastic thermoplastic elastomer (Y) is disposed by being joined over the normal cloth 3.'],18,84,diagram,B,"[{'element_identifier': '3', 'terms': ['normal cloth']}, {'element_identifier': '2', 'terms': ['member', 'members']}]","['1. A structure comprising: one or more low-resilience elastic members 1 made of a thermoplastic elastomer (X); and one or more high-resilience elastic members 2 made of a thermoplastic elastomer (Y), wherein the thermoplastic elastomer (X) and the thermoplastic elastomer (Y) are each independently made of a resin composition containing (a) 100 parts by mass of a hydrogenated block copolymer having a weight average molecular weight of 200,000 or less for 50 to 100 mass% and formed by hydrogenating a block copolymer composed of at least two polymer blocks A made up of structural units derived from a vinyl aromatic compound and at least one polymer block B made up of structural units derived from a conjugated diene compound, (b) 50 to 300 parts by mass of a hydrocarbon softener, and (c) 3 to 50 parts by mass of a polyolefin resin relative to a total of 100 parts by mass of (a) and (b), wherein the thermoplastic elastomer (X) has a modulus of 1.0 MPa or less at elongation of 100 % and a hysteresis loss rate of 70 % or more, and wherein the thermoplastic elastomer (Y) has a modulus of 1.0 MPa or less at elongation of 100 % and a hysteresis loss rate of 40 % or less.']",True,"['3', '2', '3', '14']" 749,EP_3604528_A1 (1).png,EP3604528A1,CYCLIC NUCLEIC ACID MOLECULE HAVING GENE EXPRESSION CONTROL FUNCTION,['FIG2'],['FIG2 is an RP-HPLC chart of PA-0001-DSO'],"['160 µmol/L PA-0001 (250 µL), 10 mmol/L DSO-ONSu/DMSO solution (160 µL), isopropanol (255 µL), 1% triethylamine aqueous solution (35 µL) were mixed and stirred at 40°C for 4 hr. The reaction mixture was purified by HPLC (column: Develosil C8-UG-5, 5 µm, 10×50 mm; flow rate: 4.7 mL/min; detection: UV260 nm; column oven: 40°C; Buffer A: 50 mmol/L TEAA (pH 7.0), 5% CH3CN; Buffer B: CH3CN) and the peak of the desired product was collected. The collected fraction was subjected to ethanol precipitation and the resulting precipitate was dissolved in distilled water for injection (Otsuka Pharmaceutical, Co., Ltd.). PA-0001-DSO with purity 97.39% was obtained. Mass spectrometry: 16364.20 (Calculated: 16364.35). The HPLC chart after purification is shown in FIG2.']",11,183,flowchart,A,"[{'element_identifier': '16', 'terms': ['injection']}, {'element_identifier': '19', 'terms': ['about']}, {'element_identifier': '2', 'terms': ['preferably']}, {'element_identifier': '1', 'terms': ['Document', 'is', 'as', 'Example']}]","[""1. A cyclic nucleic acid molecule represented by the following formula (A): wherein R 1 , R 2 , R 1' and R 2' are each independently a hydrogen atom, an alkyl group, an alkoxy group or hydroxy; R 3 , R 4 , R 3' and R 4' are each independently a hydrogen atom, an alkyl group, an alkoxy group or hydroxy; X 1 and X 2 are each independently an optionally modified ribonucleotide residue or deoxyribonucleotide residue; Y 1 and Y 2 are each independently an optionally modified ribonucleotide residue or deoxyribonucleotide residue; Z 1 - Z 4 are each independently an optionally modified ribonucleotide residue or deoxyribonucleotide residue; W 1 - W 6 are each independently an optionally modified ribonucleotide residue or deoxyribonucleotide residue; Q and T are each a guide strand or a passenger strand (when one is a guide strand, the other is a passenger strand); L is a linker; m and m' are each independently an integer of 1 - 12; n and n' are each independently an integer of 1 - 10; x1 and x2 are each independently 0 or 1; y1 and y2 are each independently 0 or 1; z1 - z4 are each independently 0, 1 or 2; and w1 - w6 are each independently 0, 1 or""]",False,"['2', '025', '020', '065', '99', '16', '17', '1', '19']" 750,EP_3604528_A1 (2).png,EP3604528A1,CYCLIC NUCLEIC ACID MOLECULE HAVING GENE EXPRESSION CONTROL FUNCTION,['FIG3'],['FIG3 is an RP-HPLC chart of PA-0002-DSP'],"['120 µmol/L PA-0002 (350 µL), 10 mg/mL DSP-ONSu/DMF solution (65 µL), isopropanol (250 µL) and 1% triethylamine aqueous solution (35 µL) were mixed and stirred at 40°C for 4 hr. The reaction mixture was purified by HPLC (column: Develosil C8-UG-5, 5 µm, 10×50 mm; flow rate: 4.7 mL/min; detection: UV260 nm; column oven: 40°C; Buffer A: 50 mmol/L TEAA (pH 7.0), 5% CH3CN; Buffer and the peak of the desired product was collected. The collected fraction was subjected to ethanol precipitation and the resulting precipitate was dissolved in distilled water for injection (Otsuka Pharmaceutical, Co., Ltd.). Absorbance at UV260 nm was measured and the yield was calculated. PA-0002-DSP (0.25 mg) with purity 89.32% was obtained. Mass spectrometry: 16881.90 (Calculated: 16882.50). The HPLC chart after purification is shown in FIG3.']",11,195,flowchart,A,"[{'element_identifier': '67', 'terms': ['with purity']}, {'element_identifier': '3', 'terms': ['Example']}, {'element_identifier': '10', 'terms': ['-', 'reaction mixture was added']}, {'element_identifier': '20', 'terms': ['-']}]",['13. The method for inhibiting expression according to claim 9 or 10 wherein the nucleic acid molecule is administered to a non-human animal.'],False,"['3', '67', '10', '20']" 751,EP_3604528_A1.png,EP3604528A1,CYCLIC NUCLEIC ACID MOLECULE HAVING GENE EXPRESSION CONTROL FUNCTION,['FIG1'],['FIG1 is an RP-HPLC chart of PA-0001-DSP'],"['114 µmol/L PA-0001 (350 µL), 10 mg/mL DSP-ONSu/DMF solution (65 µL), ethanol (250 µL) and 1% triethylamine aqueous solution (35 µL) were mixed and stirred at 40°C for 6 hr. The reaction mixture was purified by HPLC (column: Develosil C8-UG-5, 5 µm, 10×50 mm; flow rate: 4.7 mL/min; detection: UV260 nm; column oven: 40°C; Buffer A: 50 mmol/L TEAA (pH 7.0), 5% CH3CN; Buffer B: CH3CN) and the peak of the desired product was collected. The collected fraction was subjected to ethanol precipitation and the resulting precipitate was dissolved in distilled water for injection (Otsuka Pharmaceutical, Co., Ltd.). PA-0001-DSP with purity 98.69% was obtained. Mass spectrometry: 16224.00 (Calculated: 16224.08). The HPLC chart after purification is shown in FIG1.']",11,183,flowchart,A,"[{'element_identifier': '65', 'terms': ['mg/mL DSP-ONSu/DMF solution']}, {'element_identifier': '1', 'terms': ['Document', 'is', 'as', 'Example']}]","[""1. A cyclic nucleic acid molecule represented by the following formula (A): wherein R 1 , R 2 , R 1' and R 2' are each independently a hydrogen atom, an alkyl group, an alkoxy group or hydroxy; R 3 , R 4 , R 3' and R 4' are each independently a hydrogen atom, an alkyl group, an alkoxy group or hydroxy; X 1 and X 2 are each independently an optionally modified ribonucleotide residue or deoxyribonucleotide residue; Y 1 and Y 2 are each independently an optionally modified ribonucleotide residue or deoxyribonucleotide residue; Z 1 - Z 4 are each independently an optionally modified ribonucleotide residue or deoxyribonucleotide residue; W 1 - W 6 are each independently an optionally modified ribonucleotide residue or deoxyribonucleotide residue; Q and T are each a guide strand or a passenger strand (when one is a guide strand, the other is a passenger strand); L is a linker; m and m' are each independently an integer of 1 - 12; n and n' are each independently an integer of 1 - 10; x1 and x2 are each independently 0 or 1; y1 and y2 are each independently 0 or 1; z1 - z4 are each independently 0, 1 or 2; and w1 - w6 are each independently 0, 1 or""]",False,"['1', '000', '006', '006', '000', '65']" 752,EP_3604605_A1 (5).png,EP3604605A1,"METAL MEMBER, METHOD FOR PRODUCING METAL MEMBER, METAL-RESIN BONDED BODY AND METHOD FOR PRODUCING METAL-RESIN BONDED BODY",['FIG8'],['FIG8 is a cross-sectional view of a metal-resin joined body according to an embodiment of the invention'],"['Next, a metal-resin joined body 20 of an embodiment of the invention will be explained on the basis of FIG8.', 'The synthetic resin substrate 22 is joined to the oxide film 14 formed on the surface of the metal substrate 12 by thermal compression, and constitutes the metal-resin joined body 20 shown in FIG8.', 'Next, a method for producing a metal-resin joined body 20 as shown in FIG8 will be explained.']",21,85,cross-sectional view,C,"[{'element_identifier': '12', 'terms': ['metal substrate']}, {'element_identifier': '20', 'terms': ['metal-resin joined body']}, {'element_identifier': '22', 'terms': ['synthetic resin substrate']}]","['1. A metal member, comprising a metal substrate formed from a metal; and an oxide film formed on a surface of the metal substrate by melting of the surface of the metal substrate, wherein a joining strength of the oxide film to the metal substrate is 45 MPa or higher as measured by the following method in which a specimen of type A as defined in ISO 19095-2 is produced by joining a PPS resin to the oxide film, and a tensile strength measured according to ISO 19095-3 for the specimen thus produced is designated as the joining strength of the oxide film to the metal substrate.', '10. A metal-resin joined body, comprising a metal substrate formed from a metal; the oxide film formed on a surface of the metal substrate; and a synthetic resin substrate formed from a synthetic resin, the synthetic resin substrate being joined to the oxide film, wherein the oxide film includes a plurality of molten parts formed by localized melting of the surface of the metal substrate and a plurality of peripheral parts formed around the molten parts by a metal scattered from the molten parts, the plurality of molten parts is provided on the surface of the metal substrate at shifted positions, and the peripheral parts formed around the adjacent molten parts overlap at least partially with one another.']",True,"['20', '22', '12', '12', '25']" 753,EP_3604649_A1 (1).png,EP3604649A1,FIBROUS STRUCTURE AND FIBER-REINFORCED COMPOSITE MATERIAL,"['FIG4A', ' FIG4B', ' FIG4C', ' FIG4D']","['FIG4D is a partial cross-sectional view showing a state in which the weft yarn is beaten with the reed to form the reinforced portion ', 'FIG4C is a partial cross-sectional view showing a moving distance of the woven fabric to form the reinforced portion ', 'FIG4A is a partial cross-sectional view showing a state before a weft yarn is beaten with a reed ', 'FIG4B is a partial cross-sectional view showing a state in which the weft yarn is beaten with the reed to form the non-reinforced portion']","['As shown in FIG4D, when the weft yarn 13 is inserted and beaten with the reed 62 at the beating point P, the weft yarn 13 is pressed with the reed 62 by the amount that the weft yarn 13 projects from the beating point P, as indicated with the double-dashed chain line L1 in FIG4D. As a result, the reinforced-portion weft yarn 13b is formed to have the same width as the width W2 that is the width of the reinforced-portion weft yarn 13b. When the predetermined number of the reinforced-portion weft yarn 13b to form the reinforced portion 51 is woven, a part of the reinforced portion 51 is complete. ', 'Subsequently, the reinforced portion 51 is formed. The moving distance of the woven fabric T in forming the reinforced portion 51 with the take-up roller 63 is made smaller than the first moving distance K1 of the woven fabric T in forming the non-reinforced portion 41, as shown in FIG4C. The distance of the woven fabric T moved to form the reinforced portion 51 is referred to as a second moving distance K2. The second moving distance K2 is smaller than the width W1 of the non-reinforced-portion weft yarn 13a in dimension. The second moving distance K2 corresponds to the width W2 of the reinforced-portion weft yarn 13b in dimension. When the woven fabric T is taken up, a space S1 corresponding to the width W2 in dimension is formed between the end G of the woven fabric T and the beating point P. ', 'In forming the fiber structure 11 with the loom 60, the weft yarn 13 is inserted and beaten with the reed 62. In the following description, all the weft yarns 13 to be inserted have a horizontally elongated flat shape having the same width as the width W1 of the non-reinforced-portion weft yarn 13a. A beating point P is located at a position indicated with a double-dashed chain line L1 shown in FIG4A. The beating point P is always located at the same position. The weft yarn 13 is inserted at a position away from the beating point P, i.e. the double-dashed chain line L1, on a side away from the woven fabric T. ', 'The weft yarn 13 is inserted and beaten with the reed 62 at the beating point P, as shown in FIG4B. In this case, the weft yarn 13 does not project from the beating point P. The weft yarn 13 maintains the width W1 without being pressed. In this way, the non-reinforced-portion weft yarn 13a forms a part of the non-reinforced portion 41.']",95,491,partial cross-sectional view,B,"[{'element_identifier': '14', 'terms': ['warp yarns', 'warp yarn']}, {'element_identifier': '2', 'terms': ['cost may be reduced.', 'second portion']}, {'element_identifier': '10', 'terms': ['fiber-reinforced composite']}, {'element_identifier': '62', 'terms': ['reed']}, {'element_identifier': '13', 'terms': ['weft yarns', 'weft yarn']}]","['1. A fiber structure used as a reinforcement base material of a fiber-reinforced composite, the fiber structure comprising: a multi-layered fabric including a warp layer and a weft layer, wherein when one direction refers to a direction in which warp yarns are adjacent to each other in the warp layer or weft yarns are adjacent to each other in the weft layer, the fiber structure comprises a first portion and a second portion, the first portion and the second portion being continuous with each other along the one direction, each of the warp yarns forming the second portion is thicker than each of the warp yarns forming the first portion, and/or each of the weft yarns forming the second portion is thicker than each of the weft yarns forming the first portion, and when a pitch between the yarns refers to a distance between main axes of the yarns adjacent to each other in the one direction, the pitch between the yarns in the second portion is smaller than the pitch between the yarns in the first portion.']",True,"['13', '13', '14', '29', '62', '10', '2', '62', '62', '13', '13', '62']" 754,EP_3604757_A1 (1).png,EP3604757A1,"APPARATUS, SYSTEM AND METHOD FOR MITIGATING DIESEL EXHAUST FLUID DEPOSITS AND ASSOCIATED CONDITIONS",['FIG2'],['FIG2 is a block diagram of a controller of the engine system of FIG1 according to one embodiment of the invention'],"['More specifically, as shown in the illustrated embodiment of FIG2, the controller 300 includes a diagnostic fault module 310, fault mitigation module 320, diagnostic interrupt module 330, and decomposition tube regeneration module 340. The controller 300 also receives an SCR inlet NOx signal 350 from the NOx sensor 160, an SCR outlet NOx signal 355 from the NOx sensor 162, a DPF outlet pressure signal 360 from the pressure sensor 164, and other diagnostic signals from any of various other sensors. The controller 300 is configured to issue OBD commands 370 to the OBD system user interface 500 when a diagnostic fault is set. In certain implementations, the OBD system user interface 500 includes an MIL, or other indicated, that is illuminated, or otherwise activated, in response to the receipt of an OBD command 370. Additionally, the controller 300 is configured to issue a decomposition tube regeneration command 375 when operating conditions warrant regeneration of the DEF decomposition tube 239.', 'Referring back to FIG2, in certain embodiments, the controller 300 includes a system override module 380. In certain instances, the initiation of a commanded regeneration of the DEF decomposition tube 375 as discussed above may be inhibited by the actions of a user or operator. In such instances, to prevent DEF deposits from growing too large for easy decomposition, the system override module 380 may light the DPF lamp to alert the user of the need for an active regeneration of the DEF decomposition tube 375. The alert can be communicated via a DPF lamp on the dashboard, as opposed to an OBD lamp, such as an MIL. In response to the alert, the user should change whatever action is preventing the initiation of the regeneration event. Operator actions that may prohibit a regeneration event on the DEF decomposition tube 375 can include a regeneration inhibit or disable switch in the ON position, tough duty cycles (e.g., frequent stops and starts) where an aftertreatment system cannot attain the requisite regeneration temperatures.']",21,370,block diagram,F,"[{'element_identifier': '310', 'terms': ['diagnostic fault module']}, {'element_identifier': '375', 'terms': ['regeneration command', 'DEF decomposition tube']}, {'element_identifier': '365', 'terms': ['other diagnostic signals']}, {'element_identifier': '325', 'terms': ['request']}, {'element_identifier': '335', 'terms': ['diagnostic interrupt command']}, {'element_identifier': '350', 'terms': ['SCR inlet NOx signal']}, {'element_identifier': '380', 'terms': ['system override module']}, {'element_identifier': '360', 'terms': ['DPF outlet pressure signal']}, {'element_identifier': '300', 'terms': ['controller']}, {'element_identifier': '355', 'terms': ['SCR outlet NOx signal']}, {'element_identifier': '320', 'terms': ['fault mitigation module']}, {'element_identifier': '370', 'terms': ['command', 'commands']}, {'element_identifier': '395', 'terms': ['regeneration frequency module']}, {'element_identifier': '340', 'terms': ['regeneration module']}, {'element_identifier': '390', 'terms': ['modified DEF rate command']}, {'element_identifier': '330', 'terms': ['diagnostic interrupt module']}]","['1. An apparatus (300) for mitigating on-board diagnostic, OBD, faults generated by an OBD system of an internal combustion engine, ICE, system (10) having a selective catalytic reduction system (230) with a diesel exhaust fluid, DEF, decomposition tube (239), characterized in that the apparatus comprises: a fault mitigation module (320) configured to monitor at least one OBD signal of the OBD system and issue a request (325) for regenerating the DEF decomposition tube (239) when a value of the at least one OBD signal (352) reaches a predetermined regeneration threshold (353) corresponding with the at least one OBD signal (352), the regeneration threshold (353) being reachable prior to an OBD fault threshold (354) corresponding with the at least one OBD signal (352); and a regeneration module (340) configured to regenerate the DEF decomposition tube (239) according to the issued request (325); characterized in that the at least one OBD signal comprises at least one of a first OBD signal corresponding with a NO x conversion efficiency of the selective catalytic reduction system and a second OBD signal corresponding with a particulate matter filter outlet high pressure.', '2. The apparatus of claim 1, further comprising a system override module (380) configured to alert a user of user actions preventing the initiation of a requested regeneration event and implement measures for mitigating consequences of the user actions if the user does not cease the user actions within a predetermined time period.', '3. The apparatus of claim 2, further comprising a diagnostic interrupt module (330) configured to suspend monitoring of the at least one OBD signal (352) in response to the issuance of a request (325) for regenerating the DEF decomposition tube (239), wherein the measures for mitigating consequences of the user actions comprise overriding the suspension of the monitoring of the at least one OBD signal (352) to re-enable the monitoring of the at least one OBD signal (352).']",False,"['300', '310', '320', '395', '370', '350', '335', '325', '330', '340', '355', '360', '365', '375', '390', '380', '17']" 755,EP_3604757_A1 (3).png,EP3604757A1,"APPARATUS, SYSTEM AND METHOD FOR MITIGATING DIESEL EXHAUST FLUID DEPOSITS AND ASSOCIATED CONDITIONS",['FIG5'],['FIG5 is a flow chart diagram of a method for mitigating diagnostic faults in an engine system according to one embodiment '],"['Referring to FIG5, a method 400 for mitigating diagnostic faults of diagnostics susceptible to DEF deposits includes monitoring diagnostics susceptible to DEF deposit formation at 405. Susceptible diagnostics can be any of various diagnostic signals that may be sensitive to DEF deposit changes. For example, in one implementation, the susceptible diagnostics include a SCR NOx conversion efficiency diagnostic (based partially on SCR inlet and outlet NOx sensor signals) and DPF outlet high pressure diagnostic (based partially on DPF filter outlet pressure sensor signals).']",21,93,flow chart diagram,F,"[{'element_identifier': '455', 'terms': ['DEF injection rate at']}, {'element_identifier': '420', 'terms': ['may be present at']}, {'element_identifier': '430', 'terms': ['action']}, {'element_identifier': '440', 'terms': ['at']}, {'element_identifier': '415', 'terms': ['predetermined time threshold at']}, {'element_identifier': '400', 'terms': ['method']}, {'element_identifier': '465', 'terms': ['DEF injection rates at']}, {'element_identifier': '405', 'terms': ['action']}, {'element_identifier': '425', 'terms': ['At']}, {'element_identifier': '435', 'terms': ['regeneration request at']}, {'element_identifier': '460', 'terms': ['DEF decomposition tube at']}, {'element_identifier': '410', 'terms': ['at']}, {'element_identifier': '450', 'terms': ['request at']}]","['1. An apparatus (300) for mitigating on-board diagnostic, OBD, faults generated by an OBD system of an internal combustion engine, ICE, system (10) having a selective catalytic reduction system (230) with a diesel exhaust fluid, DEF, decomposition tube (239), characterized in that the apparatus comprises: a fault mitigation module (320) configured to monitor at least one OBD signal of the OBD system and issue a request (325) for regenerating the DEF decomposition tube (239) when a value of the at least one OBD signal (352) reaches a predetermined regeneration threshold (353) corresponding with the at least one OBD signal (352), the regeneration threshold (353) being reachable prior to an OBD fault threshold (354) corresponding with the at least one OBD signal (352); and a regeneration module (340) configured to regenerate the DEF decomposition tube (239) according to the issued request (325); characterized in that the at least one OBD signal comprises at least one of a first OBD signal corresponding with a NO x conversion efficiency of the selective catalytic reduction system and a second OBD signal corresponding with a particulate matter filter outlet high pressure.', '12. A method for mitigating on-board diagnostic, OBD, faults in an internal combustion engine, ICE, system (10) having a selective catalytic reduction system (230) with a diesel exhaust fluid, DEF, decomposition tube (239), the method comprising monitoring a plurality of OBD signals and setting a diagnostic fault when one of the plurality of OBD signals (239) reaches a corresponding fault threshold (354), characterized in that the method further comprises: monitoring at least one OBD signal (352) of the plurality of OBD signals (352) that is susceptible to solid DEF deposits within the decomposition tube (239), the at least one OBD signal comprising at least one of a first OBD signal corresponding with a NO x conversion efficiency of the selective catalytic reduction system and a second OBD signal corresponding with a particulate matter filter outlet high pressure; requesting regeneration of the DEF decomposition tube (239) when the at least one OBD signal (352) susceptible to solid DEF deposits within the decomposition tube (239) reaches a corresponding regeneration threshold (353), the regeneration threshold (353) being reachable before the fault threshold (354) corresponding with the at least one susceptible OBD signal (352); regenerating the DEF decomposition tube (239) according to the regeneration request (325), and suspending monitoring of the at least one susceptible OBD signal (352) during regeneration of the DEF decomposition tube (239).']",False,"['400', '465', '405', '460', '410', '415', '455', '420', '425', '430', '435', '440', '450', '19']" 756,EP_3604772_A1 (1).png,EP3604772A1,COMBUSTION DEVICE AND GAS TURBINE ENGINE SYSTEM,['FIG2'],['FIG2 is a block diagram showing an overall constitution of a modified example of the gas turbine engine system according to the embodiment of the present disclosure'],"['For example, in the above-described embodiment, the constitution in which the intercooler 6 is installed outside the gas turbine engine 2 and the combustion air is cooled by the intercooler 6 has been described. However, the present disclosure is not limited thereto. For example, as shown in FIG2, a heat exchange unit 2f (a combustion air cooling unit) which cools the combustion air by heat exchange between the combustion air and the fuel ammonia during the compression process may be provided inside the low pressure compressor 2d. For example, a flow path through which the fuel ammonia flows may be formed inside a stationary blade of the low pressure compressor 2d, and a region in which the flow path is formed may be used as the heat exchange unit 2f. According to such a modified example, since it is not necessary to install the intercooler 6 outside the gas turbine engine 2, it is possible to miniaturize the gas turbine engine system 1.']",27,181,block diagram,B,"[{'element_identifier': '2', 'terms': ['gas turbine engine']}]",['7. A gas turbine engine system comprising the combustion device according to any one of claims 1 to'],False,['2'] 757,EP_3604772_A1.png,EP3604772A1,COMBUSTION DEVICE AND GAS TURBINE ENGINE SYSTEM,['FIG1'],['FIG1 is a block diagram showing an overall constitution of a gas turbine engine system according to an embodiment of the present disclosure'],"['FIG1 is a block diagram showing an overall constitution of a gas turbine engine system 1 according to the embodiment. As shown in the drawing, the gas turbine engine system 1 according to the embodiment includes a gas turbine engine 2, a fuel ammonia supply system 3, a natural gas supply system 4, a reduction catalyst chamber 5 (a denitration device), an intercooler 6 (a combustion air cooling unit), and a cooling water supply system 7. Further, in the embodiment, a compressor 2a of the gas turbine engine 2 which will be described later, the fuel ammonia supply system 3, the natural gas supply system 4, the intercooler 6 (the combustion air cooling unit), and the cooling water supply system 7 constitute a combustion device of the present disclosure. The gas turbine engine system 1 is a drive source of a generator G and generates rotational power by burning fuel ammonia using compressed combustion air.', 'As shown in FIG1, the pipe 3b of the fuel ammonia supply system 3 is connected to the ammonia supply unit 3a and the combustor 2b, and includes a first path which guides the fuel ammonia to the combustor 2b via the vaporizer 3d, and a second path which guides the fuel ammonia to the combustor 2b via the intercooler 6 without passing through the vaporizer 3d. Further, the pipe 3b also includes a third path which branches from the first path which guides the fuel ammonia to the combustor 2b via the vaporizer 3d, and guides the fuel ammonia to an exhaust gas pipe located on the upstream side of the reduction catalyst chamber 5.']",23,301,block diagram,B,"[{'element_identifier': '8', 'terms': ['heat exchanger']}, {'element_identifier': '3', 'terms': ['fuel ammonia supply system']}, {'element_identifier': '1', 'terms': ['gas turbine engine system']}]",['7. A gas turbine engine system comprising the combustion device according to any one of claims 1 to'],False,"['1', '31', '3', '8']" 758,EP_3604828_A1 (3).png,EP3604828A1,FASTENING STRUCTURE AND KEYBOARD DEVICE,"['FIG5', ' FIG6']","['FIG6 is a cross-sectional view showing an example of the fastening structure of the fourth embodiment ', 'FIG5 is a cross-sectional view showing an example of the fastening structure of the third embodiment']","['FIG6 schematically shows an example of the fastening structure of the fourth embodiment. In the above-described fastening structure, the effective thread 34 may be entangled with a dark ring 16 of the wood component 10. Wood grown in a temperate zone to a cool zone usually has dark rings 16 and light rings 17 alternately formed due to the difference in the growth rate of the cell wall depending on the season, resulting in annual rings. The dark rings 16 have a higher strength than the light rings 17, and variations due to characteristic differences between the dark rings 16 and the light rings 17 are large. Therefore, when the male screw portion 33 meshes with a portion including the dark ring 16, it is possible to enhance the viscoelastic reversible deformation characteristics. ', 'FIG5 schematically shows an example of the fastening structure of a third embodiment. In the present embodiment, a distance L2 between a to-be-pressed surface 23 of the to-be-fastened component 20 and the contact surface 12 of the wood component 10 with the to-be-fastened component 20 is 2 mm or less. Here, the to-be-pressed surface 23 is a portion where the to-be-fastened component 20 is pressed from the head portion 31 of the screw 30.']",36,244,cross-sectional view,F,"[{'element_identifier': '30', 'terms': ['screw']}, {'element_identifier': '12', 'terms': ['contact surface']}, {'element_identifier': '14', 'terms': ['pilot hole']}, {'element_identifier': '11', 'terms': ['surface']}, {'element_identifier': '20', 'terms': ['component']}, {'element_identifier': '34', 'terms': ['effective screw portion']}, {'element_identifier': '31', 'terms': ['head portion']}, {'element_identifier': '16', 'terms': ['dark rings', 'dark ring']}, {'element_identifier': '10', 'terms': ['wood component']}, {'element_identifier': '23', 'terms': ['surface']}, {'element_identifier': '32', 'terms': ['shaft portion']}]","['1. A fastening structure for fastening a to-be-fastened component to a wood component by using a screw, wherein the wood component is made of wood having a specific gravity of 0.08 g/cm 3 to 0.85 g/cm 3 inclusive; the screw has a nominal diameter of 0.8 mm to 3.5 mm inclusive; and the distance between an intermediate position in a longitudinal direction of an effective screw portion, which is the portion where the wood component and a male screw portion formed on a shaft portion of the screw mesh together, and a contact surface of the wood component with the to-be-fastened component is 1 mm to 15 mm inclusive.', '4. The fastening structure according to any one of claims 1 to 3, wherein a distance between a to-be-pressed surface where the to-be-fastened component is pressed from the head portion of the screw and the contact surface is 2 mm or less.', '5. The fastening structure according to any one of claims 1 to 4, wherein the effective screw portion is entangled with a dark ring of the wood component.']",True,"['20', '30', '32', '31', '23', '10', '11', '14', '12', '30', '32', '31', '16', '16', '20', '10', '34', '14', '11']" 759,EP_3604960_A2.png,EP3604960A2,FAN CONTROL APPARATUS AND FAN CONTROL METHOD,['FIG1'],['FIG1 is a diagram illustrating an example of the configuration of a fan control apparatus according to a first embodiment of the present disclosure'],"['FIG1 illustrates an example of the configuration of a fan control apparatus according to the embodiment.', 'As illustrated in FIG1, a fan control apparatus X according to the embodiment controls an RF fan 3 placed (at the boundary) between, for example, a first room such as a room A and a second room adjacent to the first room, such as a room B. The RF fan 3 can switch the direction of airflow between the room A side (AR1) and the room B side (AR2). Pressure sensors A5 and B7 are placed in the rooms A and B, respectively. A measured pressure value acquired by each pressure sensor is inputted into a controller 1. Moreover, an RF fan control signal SG1 and an RF fan rotation signal SG2 are exchanged between the controller 1 and the RF fan 3. In this example, the pressure sensor A5 measures the atmospheric pressure in the room A. The pressure sensor B7 measures the atmospheric pressure in the room B. The RF fan 3 is controlled automatically in such a manner that the atmospheric pressures in the two rooms are the same.', 'FIG1 illustrates the example where the pressure sensors perform sensing. However, it is also possible for the automatic control to adjust the temperatures with temperature sensors. Furthermore, it is also possible to adjust the humidities with humidity sensors.']",24,252,diagram,F,"[{'element_identifier': '1', 'terms': ['controller']}]","['1. A fan control apparatus comprising: a first sensor; a second sensor; an RF fan; and a controller, wherein the first sensor is provided in a first room, and is configured to acquire a measured value of at least one condition selected from conditions of atmospheric pressure, temperature, and humidity for the first room, the second sensor is provided in a second room adjacent to the first room, and is configured to acquire a measured value of the same condition as the at least one selected condition for the second room, the RF fan is placed at a boundary between the first and second rooms, and the controller is configured to control a rotational speed and rotational direction of the RF fan in such a manner that the measured values of the first and second sensors are the same.']",False,"['1', '12']" 760,EP_3604984_A1.png,EP3604984A1,ICE MACHINE,['FIG1'],['FIG1 is a front perspective view of an ice machine comprising an ice maker and a storage bin in accordance with one aspect of the present disclosure'],"['FIG1 is a front perspective view of an ice machine 100 in accordance with one aspect of the present disclosure. The ice machine 100 can comprise an ice maker 110 and a storage bin 190. The ice maker 110 can be configured to produce ice which can be fed by gravity downwards into the storage bin 190. The storage bin 190 can be insulated to maintain cold temperatures within the bit storage compartment to prevent the ice from melting. In some aspects, the storage bin 190 can be refrigerated, and in other aspects, the storage bin 190 can be unrefrigerated.']",27,108,front perspective view,F,"[{'element_identifier': '122', 'terms': ['front panel assembly']}, {'element_identifier': '1', 'terms': ['aforementioned']}, {'element_identifier': '100', 'terms': ['ice machine']}, {'element_identifier': '112', 'terms': ['top maker end']}, {'element_identifier': '190', 'terms': ['storage bin']}, {'element_identifier': '180', 'terms': ['air inlet opening']}, {'element_identifier': '192', 'terms': ['top bin end']}, {'element_identifier': '124', 'terms': ['air filter']}, {'element_identifier': '110', 'terms': ['ice maker']}, {'element_identifier': '114', 'terms': ['bottom maker end']}, {'element_identifier': '120', 'terms': ['outer casing']}]","['1. An ice maker comprising: a dry compartment; and a wet compartment adjacent to the dry compartment and comprising: an evaporator case sized to receive an evaporator, the evaporator case comprising: a plurality of interior panels joined to each other with snap-fit joints, each of the snap-fit joints comprising a tab and defining a slot, each of a plurality of seams formed between the interior panels defining a foam-tight seal and a water-tight seal; and a plurality of exterior panels, each of the plurality of exterior panels joined to a mating interior panel of the plurality of interior panels with slide joints, wherein the evaporator case is integrally insulated with blown foam insulation positioned inside an insulation cavity defined by and between the plurality of exterior panels and the plurality of interior panels.']",False,"['112', '124', '180', '100', '110', '120', '122', '192', '114', '190', '1', '24']" 761,EP_3605067_A1 (3).png,EP3605067A1,"OPTICAL SENSOR, LIGHT DETECTING DEVICE, PAPER SHEET PROCESSING DEVICE, LIGHT DETECTING METHOD, AND PHOSPHORESCENCE DETECTING DEVICE",['FIG9'],['FIG9 is a schematic diagram showing the structure of one embodiment of a light detection apparatus according to the present invention'],"['A light detection apparatus mounted with the optical sensor 10 will now be described. FIG9 is a block diagram schematically showing the structure of the light detection apparatus 100. The light detection apparatus 100 is an apparatus used to determine the authenticity of the detection target T attached to an object X to be conveyed. The light detection apparatus 100 includes a conveyor apparatus 80, an optical sensor 10 installed above the conveyor apparatus 80, and a control apparatus 90 that controls the conveyor apparatus 80 and the optical sensor 10. The light detection apparatus 100 can be used as a sheet processing apparatus, treating the object X to be conveyed as a sheet such as a banknote. Note that the light detection apparatus 100 functions as a phosphorescence detection apparatus when detecting phosphorescence as radiation light.']",21,146,schematic diagram,G,"[{'element_identifier': '30', 'terms': ['light source']}, {'element_identifier': '80', 'terms': ['conveyor apparatus']}, {'element_identifier': '92', 'terms': ['detection unit']}, {'element_identifier': '100', 'terms': ['detection apparatus']}, {'element_identifier': '94', 'terms': ['determination unit']}, {'element_identifier': '9', 'terms': ['Expression']}, {'element_identifier': '93', 'terms': ['correction unit']}, {'element_identifier': '20', 'terms': ['holder']}, {'element_identifier': '40', 'terms': ['photodetector', 'photodetectors']}, {'element_identifier': '90', 'terms': ['control apparatus']}, {'element_identifier': '91', 'terms': ['conveyor apparatus control unit']}, {'element_identifier': '53', 'terms': ['light incident/emission surface']}, {'element_identifier': '95', 'terms': ['storage unit']}, {'element_identifier': '10', 'terms': ['optical sensor', 'optical sensors']}, {'element_identifier': '50', 'terms': ['light guide']}]","['1. An optical sensor, comprising: a light source that irradiates excitation light; a photodetector that detects radiation light emitted from a detection target excited by the excitation light; and a single light guide unit that guides the excitation light to the detection target and guides the radiation light to the photodetector.', '8. A light detection apparatus, comprising: the optical sensor according to any one of claims 1 to 7; and a correction unit that corrects an intensity of the radiation light detected by the photodetector based on a relative position of the detection target with respect to the photodetector when the radiation light is detected.', '13. A phosphorescence detection apparatus, comprising the optical sensor according to claim 1, wherein: the light source is a light source that irradiates a detection target with the excitation light, the detection target containing a phosphorescent material, the photodetector is a photodetector that detects an intensity of phosphorescence emitted from the detection target, and the phosphorescence detection apparatus further comprises: a detection unit that controls the light source and the photodetector, and detects the intensity at least three times after stop of the irradiation with the excitation light while changing a detection time; and a determination unit that determines whether or not the phosphorescence results from multiple types of phosphorescence having different decay time constants, based on the at least three intensities detected by the detection unit and their detection times.']",False,"['100', '92', '90', '94', '95', '93', '30', '40', '10', '20', '91', '50', '53', '80', '9', '41']" 762,EP_3605067_A1 (4).png,EP3605067A1,"OPTICAL SENSOR, LIGHT DETECTING DEVICE, PAPER SHEET PROCESSING DEVICE, LIGHT DETECTING METHOD, AND PHOSPHORESCENCE DETECTING DEVICE",['FIG10'],['FIG10 is a flow chart showing the operation flow of a light detection apparatus according to the present invention'],"['An example of the operation flow of the light detection apparatus 100 with the structure described above will be described with reference to FIG10.', 'The operation of the phosphorescence detection apparatus 100 is as described above as the operation of the light detection apparatus 100 with reference to FIG10.', 'In Step S6 (FIG10), the phosphorescence detection apparatus 100 determines whether or not the phosphorescent material among the materials contained in the detection target T is a phosphorescent material that emits light within the same wavelength range and is composed of a plurality of types of dye having different decay time constants.', 'The operation of the phosphorescence detection apparatus 100 is as described above as the operation of the light detection apparatus 100 with reference to FIG10.', 'The phosphorescence detection apparatus 100 calculates the decay time constant of phosphorescence for each photodetector 40 (for each color of radiation light) in Step S6 (FIG10), and determines phosphorescence emitted from the phosphorescent material contained in the detection target T.']",19,182,flowchart,G,"[{'element_identifier': '30', 'terms': ['light source']}, {'element_identifier': '10', 'terms': ['optical sensor', 'optical sensors']}, {'element_identifier': '40', 'terms': ['photodetector', 'photodetectors']}]","['1. An optical sensor, comprising: a light source that irradiates excitation light; a photodetector that detects radiation light emitted from a detection target excited by the excitation light; and a single light guide unit that guides the excitation light to the detection target and guides the radiation light to the photodetector.']",False,"['30', '40', '30', '10', '42']" 763,EP_3605067_A1 (6).png,EP3605067A1,"OPTICAL SENSOR, LIGHT DETECTING DEVICE, PAPER SHEET PROCESSING DEVICE, LIGHT DETECTING METHOD, AND PHOSPHORESCENCE DETECTING DEVICE",['FIG12'],['FIG12 is a cross-sectional view showing the structure of still another embodiment of an optical sensor according to the present invention'],"['Further, in the optical sensor 10 to which the present invention is applied, the light guide 50 is not necessarily disposed in a position between the light source 30 and the photodetector 40 and the detection target T facing the optical sensor 10 as long as it can guide the excitation light from the light source 30 to the detection target T and can guide the radiation light from the detection target T to the photodetector 40. For example, as shown in FIG12, the light guide 50 may have an excitation light incident surface 51 and a radiation light emission surface 52 at the front and back, and a light incident/emission surface 53 at the lower side.']",23,126,cross-sectional view,G,"[{'element_identifier': '51', 'terms': ['excitation light incident surface']}, {'element_identifier': '30', 'terms': ['light source']}, {'element_identifier': '12', 'terms': ['following Expression', 'easily understood from Expressions']}, {'element_identifier': '20', 'terms': ['holder']}, {'element_identifier': '40', 'terms': ['photodetector', 'photodetectors']}, {'element_identifier': '52', 'terms': ['radiation light emission surface']}, {'element_identifier': '53', 'terms': ['light incident/emission surface']}, {'element_identifier': '10', 'terms': ['optical sensor', 'optical sensors']}, {'element_identifier': '50', 'terms': ['light guide']}, {'element_identifier': '21', 'terms': ['partition']}, {'element_identifier': '70', 'terms': ['optical filter', 'optical filters']}, {'element_identifier': '60', 'terms': ['board']}]","['6. The optical sensor according to any one of claims 1 to 5, further comprising an optical filter between the light source and the light guide unit and/or between the photodetector and the light guide unit.', '7. The optical sensor according to any one of claims 1 to 6, wherein the light source and the photodetector are disposed on a same board.']",False,"['10', '20', '21', '30', '70', '60', '51', '70', '40', '60', '52', '50', '53', '12', '44']" 764,EP_3605076_A1 (5).png,EP3605076A1,"ELECTROPHORETIC SEPARATION DATA ANALYZING APPARATUS, ELECTROPHORETIC SEPARATION DATA ANALYZING METHOD, AND COMPUTER PROGRAM FOR CAUSING A COMPUTER TO EXECUTE THE ANALYZING METHOD",['FIG8'],"['FIG8 is a diagram for describing a method of specifying an analysis target range, an analysis exclusion range, and a range of interest on a separation image ']","['In addition, as illustrated in FIG8, the analysis target peak identifying part 12 and the peak-of-interest identifying part 14 can require the user to specify each of the analysis target range, the analysis exclusion range, and the range of interest on the separation image.']",29,53,diagram,G,"[{'element_identifier': '8', 'terms': ['electropherogram creating part']}]","['5. The electrophoretic separation data analyzing apparatus according to claim 4, further comprising an electropherogram creating part that creates an electropherogram as the separation data, wherein the analysis target peak identifying part is configured to require the user to specify the analysis target range and the analysis exclusion range on the electropherogram, and the peak-of-interest identifying part is configured to require the user to specify the range of interest on the electropherogram.']",False,"['8', '13']" 765,EP_3605076_A1.png,EP3605076A1,"ELECTROPHORETIC SEPARATION DATA ANALYZING APPARATUS, ELECTROPHORETIC SEPARATION DATA ANALYZING METHOD, AND COMPUTER PROGRAM FOR CAUSING A COMPUTER TO EXECUTE THE ANALYZING METHOD",['FIG1'],['FIG1 is a block diagram schematically illustrating an embodiment of an electrophoretic separation data analyzing apparatus'],"['As illustrated in FIG1, an electrophoretic separation data analyzing apparatus 2 (hereinafter, analyzing apparatus 2) carries out data analysis processing by using separation data of a sample obtained by an electrophoresis apparatus 4 carrying out separation of a sample by electrophoresis, and displays an analysis result on a display device 6.', 'Returning to FIG1, when the analysis target peak identifying part 12 and the peak-of-interest identifying part 14 identify the analysis target peaks and the peak of interest, the abundance ratio calculating part 16 is configured to determine the abundance ratio of the peak of interest among the analysis target peaks. The timing of calculation of the abundance ratio of the peak of interest is not particularly limited, but it is preferable that the abundance ratio be calculated immediately after the analysis target peaks and the peak of interest are identified.']",16,157,block diagram,G,"[{'element_identifier': '8', 'terms': ['electropherogram creating part']}, {'element_identifier': '14', 'terms': ['identifying part']}, {'element_identifier': '12', 'terms': []}, {'element_identifier': '1', 'terms': ['peaks']}, {'element_identifier': '18', 'terms': ['abundance ratio display part']}, {'element_identifier': '4', 'terms': ['electrophoresis apparatus']}, {'element_identifier': '2', 'terms': ['analyzing apparatus']}, {'element_identifier': '6', 'terms': ['display device']}, {'element_identifier': '16', 'terms': ['abundance ratio calculating part']}, {'element_identifier': '10', 'terms': ['separation image creating part']}]","['1. An electrophoretic separation data analyzing apparatus for analyzing separation data obtained by electrophoretic separation, the analyzing apparatus comprising: an analysis target peak identifying part configured to require a user to input analysis target peak information on analysis target peaks to be added to an analysis target in the separation data, and to identify at least one of the analysis target peaks based on the analysis target peak information; a peak-of-interest identifying part configured to require the user to input peak-of-interest information on a peak of interest among the analysis target peaks, and identify the peak of interest based on the peak-of-interest information; and an abundance ratio calculating part configured to determine an abundance ratio of the peak of interest among all of the analysis target peaks based on a total value of peak areas of the analysis target peaks and a peak area value of the peak of interest.', '3. The electrophoretic separation data analyzing apparatus according to claim 1 or 2, further comprising an abundance ratio display part configured to display the abundance ratio of the peak of interest calculated by the abundance ratio calculating part on a display device.', '5. The electrophoretic separation data analyzing apparatus according to claim 4, further comprising an electropherogram creating part that creates an electropherogram as the separation data, wherein the analysis target peak identifying part is configured to require the user to specify the analysis target range and the analysis exclusion range on the electropherogram, and the peak-of-interest identifying part is configured to require the user to specify the range of interest on the electropherogram.', '6. The electrophoretic separation data analyzing apparatus according to claim 4, further comprising a separation image creating part that creates a separation image of a peak on an electrophoresis flow channel as the separation data, wherein the analysis target peak identifying part is configured to require the user to specify the analysis target range and the analysis exclusion range on the separation image.']",False,"['1', '4', '2', '10', '12', '14', '16', '18', '6', '8']" 766,EP_3605116_A1 (3).png,EP3605116A1,ELECTRICAL CONNECTION DEVICE,['FIG8'],['FIG8 is a schematic plan view illustrating another arrangement example of a guide hole group in the electric connection device according to the modification of the embodiment of the present invention '],"['Alternatively, as illustrated in FIG8, the spare guide holes (reference numerals thereof are not illustrated) may be arranged concentrically around the reference guide hole 150. The spare guide holes may be arranged around the reference guide hole 150 in multiple layers.']",31,47,schematic plan view,G,"[{'element_identifier': '150', 'terms': ['reference guide hole', 'reference guide holes']}, {'element_identifier': '13', 'terms': ['electrode substrate']}]","['1. An electric connection device, comprising: a probe; a probe head that holds the probe; and an electrode substrate on which an electrode pad to be connected to a proximal end of the probe is provided, wherein the probe head is provided with a guide pin for alignment of the probe head and the electrode substrate, and the electrode substrate is provided with a guide hole group composed of a plurality of guide holes corresponding to the guide pin.', '2. The electric connection device according to claim 1, wherein the probe head is provided with a plurality of the guide pins, the guide hole group is provided in the electrode substrate corresponding to each of the guide pins, the guide hole group is composed of a reference guide hole located at a design reference position and a spare guide hole located in the vicinity the reference guide hole.']",True,"['7', '13', '150', '00', '8', '13', '150']" 767,EP_3605116_A1.png,EP3605116A1,ELECTRICAL CONNECTION DEVICE,"['FIG1', ' FIG2']","['FIG2 is a schematic cross-sectional view illustrating the configuration of a guide pin and guide holes in the electric connection device according to the embodiment of the present invention ', 'FIG1 is a schematic view illustrating the configuration of an electric connection device according to an embodiment of the present invention']","['The probe head 12 is provided with guide pins 14 for alignment of the probe head 12 and electrode substrate 13. The electrode substrate 13 includes a guide hole group composed of plural guide holes corresponding to each guide pin 14. In the electric connection device 10, each guide pin 14 corresponds to a guide hole group including a reference guide hole 150, which is located at a design reference position, and spare guide holes 151 and 152, which are located in the vicinity of the reference guide hole 150, as illustrated in FIG2. FIG2 illustrates a state where the guide pin 14 is fitted in the reference guide hole 150. ', 'As illustrated in FIG1, an electric connection device 10 according to an embodiment of the present invention includes: a probe head 12, which holds probes 11; and an electrode substrate 13, on which electrode pads 131 are provided. FIG1 illustrates the probes 11 through the side surface of the probe head 12.', 'The probe head 12 is laid on and attached to the electrode substrate 13, and proximal ends of the probes 11 are electrically connected to the respective electrode pads 131. As illustrated in FIG1, the proximal ends of the probes 11 protruding from the upper surface of the probe head 12, that faces the electrode substrate 13, are connected to the respective electrode pads 131, which are provided on the lower surface of the electrode substrate 13, that faces the probe head 12.', 'The electric connection device 10 illustrated in FIG1 is a vertically-moving probe card, and the distal ends of the probes 11 exposed from the lower surface of the probe head 12 are brought into contact with inspection pads (not illustrated) of an inspection object 20 that is placed under the electric connection device 10. In the state illustrated in FIG1, the probes 11 are not in contact with the inspection object 20. When a chuck 30 with the inspection object 20 placed thereon is elevated, the distal ends of the probes 11 come into contact with the inspection object 20, for example.', 'As described above, the electric connection device 10 according to the embodiment of the present invention is equipped with a guide hole group, that is composed of the reference guide hole 150 and spare guide holes provided around the same. The guide holes to be fitted to the guide pins 14 can be selected from the spare guide holes in addition to the reference guide holes 150 so that the probes 11 can come into proper contact with the respective electrode pads 131 of the electrode substrate 13. According to the electric connection device 10 illustrated in FIG1, it is possible to easily resolve misalignment of the probes 11 and electrode pads 131.']",52,505,"schematic cross-sectional view, schematic view",G,"[{'element_identifier': '30', 'terms': ['chuck']}, {'element_identifier': '14', 'terms': ['guide pins', 'guide pin']}, {'element_identifier': '151', 'terms': ['spare guide holes']}, {'element_identifier': '133', 'terms': ['connection pads']}, {'element_identifier': '20', 'terms': ['inspection object']}, {'element_identifier': '152', 'terms': ['spare guide holes']}, {'element_identifier': '131', 'terms': ['electrode pads', 'electrode pad']}, {'element_identifier': '132', 'terms': ['through respective electrode interconnections']}, {'element_identifier': '150', 'terms': ['reference guide hole', 'reference guide holes']}, {'element_identifier': '13', 'terms': ['electrode substrate']}]","['1. An electric connection device, comprising: a probe; a probe head that holds the probe; and an electrode substrate on which an electrode pad to be connected to a proximal end of the probe is provided, wherein the probe head is provided with a guide pin for alignment of the probe head and the electrode substrate, and the electrode substrate is provided with a guide hole group composed of a plurality of guide holes corresponding to the guide pin.', '2. The electric connection device according to claim 1, wherein the probe head is provided with a plurality of the guide pins, the guide hole group is provided in the electrode substrate corresponding to each of the guide pins, the guide hole group is composed of a reference guide hole located at a design reference position and a spare guide hole located in the vicinity the reference guide hole.', '4. The electric connection device according to claim 2, wherein a plurality of the spare guide holes are located around the reference guide hole.']",True,"['1', '133', '131', '132', '14', '133', '13', '132', '20', '30', '2', '151', '150', '152', '13', '14']" 768,EP_3605124_A1 (1).png,EP3605124A1,"DEGRADATION ESTIMATING DEVICE, DEGRADATION ESTIMATING METHOD, AND COMPUTER PROGRAM",['FIG2'],['FIG2 is a diagram illustrating a configuration of a degradation estimating device'],"['FIG2 is a diagram illustrating a configuration of the degradation estimating device.', 'Referring to FIG2, the degradation estimating device 101 includes a control unit 20, a storage unit 23, an interface unit 24. The interface unit 24 is composed, for example, of a LAN interface, a USB interface or the like, and performs communication with another device, for example, such as the monitoring device 151 by wire or wirelessly.', 'Referring to FIG2 again, the estimating unit 22 estimates the degradation of the battery based on the fluctuation magnitude of the SOC in the time-series data of the SOC, which is acquired by the acquiring unit 21.']",12,125,diagram,G,"[{'element_identifier': '24', 'terms': ['interface unit']}, {'element_identifier': '22', 'terms': ['estimating unit']}, {'element_identifier': '2', 'terms': ['Equation']}, {'element_identifier': '20', 'terms': ['control unit']}, {'element_identifier': '57', 'terms': ['communication unit']}, {'element_identifier': '56', 'terms': ['storage unit']}, {'element_identifier': '101', 'terms': ['degradation estimating device', 'degradation estimating devices']}, {'element_identifier': '231', 'terms': ['degradation estimating program']}, {'element_identifier': '21', 'terms': ['acquiring unit']}, {'element_identifier': '23', 'terms': ['storage unit']}, {'element_identifier': '60', 'terms': ['computer-readable recording medium']}]",['1. A degradation estimating device comprising: an acquiring unit that acquires time-series data of an SOC in an energy storage device; and an estimating unit that estimates degradation of the energy storage device based on a fluctuation magnitude of the SOC in the time-series data acquired by the acquiring unit.'],False,"['2', '101', '20', '21', '23', '231', '22', '24', '60', '56', '57', '21']" 769,EP_3605133_B1.png,EP3605133B1,LASER SCANNER SYSTEM,['FIG1'],['FIG1 is a front cross-sectional view to show a laser scanner according to a first embodiment of the present invention'],"['First, in FIG1, a description will be given on a laser scanner according to a first embodiment of the present invention.', 'According to the second embodiment, in a state where the positions of the mobile station 19 and the second fixed station 25 are unknown, a positioning of the mobile station 19 is performed at every predetermined angle while horizontally rotating a frame unit 6 (see FIG1) by 360° around an axis 7a (see FIG1).']",22,87,front cross-sectional view,G,"[{'element_identifier': '7', 'terms': ['horizontal rotation shaft']}, {'element_identifier': '14', 'terms': ['vertical rotation motor']}, {'element_identifier': '12', 'terms': ['vertical rotation shaft']}, {'element_identifier': '17', 'terms': ['operation panel']}, {'element_identifier': '11', 'terms': ['horizontal angle encoder']}, {'element_identifier': '19', 'terms': ['station']}, {'element_identifier': '18', 'terms': ['antenna']}, {'element_identifier': '22', 'terms': ['storage module']}, {'element_identifier': '23', 'terms': ['distance measuring module']}, {'element_identifier': '20', 'terms': ['recessed part']}, {'element_identifier': '21', 'terms': ['arithmetic control module']}, {'element_identifier': '16', 'terms': ['scanning mirror']}, {'element_identifier': '15', 'terms': ['vertical angle encoder']}, {'element_identifier': '3', 'terms': ['scanner main body']}, {'element_identifier': '13', 'terms': ['vertical rotation bearing']}]","['1. A laser scanner system comprising a laser scanner (1) which has a mobile station (19) and for acquiring three-dimensional point cloud data, and at least three fixed stations (24, 25, 26), wherein said laser scanner comprises a mobile station (19) which is offset to a known position from a mechanical point on a horizontal rotation axis (7a) of said laser scanner, a horizontal angle detecting module (11) for detecting a relative horizontal angle of said laser scanner and an arithmetic control module (21) for controlling a horizontal rotation of said laser scanner, wherein said fixed stations are configured to emit pulses to said mobile station and to measure distances to said mobile station by receiving the pulses from said mobile station, and wherein said arithmetic control module is configured to calculate a two-dimensional fixed station coordinate system formed each of said fixed stations, to calculate coordinates of intersections of at least three circles, which have said fixed stations as their centers and the distances between each of said fixed stations and said mobile station as their radii, at every predetermined angle as each positioning result of said mobile station while horizontally rotating said laser scanner by 360° around said mechanical point, to average each of the positioning results corresponding to 360° and to calculate approximate mechanical point coordinates in said fixed station coordinate system.']",False,"['18', '20', '14', '16', '13', '15', '23', '3', '19', '12', '11', '7', '21', '22', '17']" 770,EP_3605136_A1 (2).png,EP3605136A1,"SENSOR MODULE, SENSOR SYSTEM, AND METHOD FOR INSTALLING SENSOR SYSTEM IN VEHICLE",['FIG3'],['FIG3 illustrates a configuration of a sensor system according to a second embodiment'],"['FIG3 schematically illustrates a configuration of a left front sensor system 2LF according to a second embodiment. Components that are the same as or equivalent to those of the left front sensor system 1LF according to the first embodiment are assigned with the same reference numerals, and repetitive descriptions for those will be omitted.']",13,57,schematic,B,"[{'element_identifier': '24', 'terms': ['first sensor module']}, {'element_identifier': '191', 'terms': []}, {'element_identifier': '12', 'terms': ['translucent member']}, {'element_identifier': '19', 'terms': ['third screw mechanism']}, {'element_identifier': '18', 'terms': ['lamp unit']}, {'element_identifier': '541', 'terms': []}, {'element_identifier': '42', 'terms': ['first acceleration sensor']}, {'element_identifier': '52', 'terms': ['second acceleration sensor']}, {'element_identifier': '53', 'terms': ['member']}, {'element_identifier': '192', 'terms': ['third vertical adjusting screw']}, {'element_identifier': '26', 'terms': ['processor']}, {'element_identifier': '13', 'terms': ['lamp chamber']}]","['2. A sensor system adapted to be installed in a vehicle, comprising: a sensor configured to sense external information of the vehicle; a support member supporting the sensor; an acceleration sensor supported on the support member; a memory configured to store a first output value of the acceleration sensor at a first time point; and a processor configured to acquire a difference between the first output value and a second output value of the acceleration sensor at a second time point.']",False,"['3', '12', '18', '13', '24', '42', '191', '192', '19', '26', '52', '541', '53', '22']" 771,EP_3605136_A1 (3).png,EP3605136A1,"SENSOR MODULE, SENSOR SYSTEM, AND METHOD FOR INSTALLING SENSOR SYSTEM IN VEHICLE",['FIG4'],['FIG4 illustrates a configuration of a sensor system according to a third embodiment'],"['FIG4 schematically illustrates a configuration of a left front sensor system 3LF according to a third embodiment. Components that are the same as or equivalent to those of the left front sensor system 1LF according to the first embodiment are assigned with the same reference numerals, and repetitive descriptions for those will be omitted.']",13,57,schematic,B,"[{'element_identifier': '51', 'terms': ['second LiDAR sensor', 'second LiDAR sensors']}, {'element_identifier': '191', 'terms': []}, {'element_identifier': '35', 'terms': ['second sensor module']}, {'element_identifier': '12', 'terms': ['translucent member']}, {'element_identifier': '19', 'terms': ['third screw mechanism']}, {'element_identifier': '48', 'terms': ['actuator']}, {'element_identifier': '18', 'terms': ['lamp unit']}, {'element_identifier': '36', 'terms': ['processor']}, {'element_identifier': '541', 'terms': []}, {'element_identifier': '56', 'terms': ['second camera']}, {'element_identifier': '42', 'terms': ['first acceleration sensor']}, {'element_identifier': '53', 'terms': ['member']}, {'element_identifier': '192', 'terms': ['third vertical adjusting screw']}, {'element_identifier': '43', 'terms': ['first support member']}, {'element_identifier': '44', 'terms': ['first screw mechanism']}, {'element_identifier': '46', 'terms': ['first camera']}, {'element_identifier': '13', 'terms': ['lamp chamber']}]","['2. A sensor system adapted to be installed in a vehicle, comprising: a sensor configured to sense external information of the vehicle; a support member supporting the sensor; an acceleration sensor supported on the support member; a memory configured to store a first output value of the acceleration sensor at a first time point; and a processor configured to acquire a difference between the first output value and a second output value of the acceleration sensor at a second time point.']",False,"['4', '12', '18', '13', '4', '42', '46', '48', '43', '56', '44', '35', '51', '191', '192', '19', '36', '541', '53', '23']" 772,EP_3605136_A1 (4).png,EP3605136A1,"SENSOR MODULE, SENSOR SYSTEM, AND METHOD FOR INSTALLING SENSOR SYSTEM IN VEHICLE",['FIG5'],['FIG5 illustrates a configuration of a sensor system according to a fourth embodiment'],"['FIG5 schematically illustrates a configuration of the left front sensor system 4LF according to a fourth embodiment. Components that are the same as or equivalent to those of the left front sensor system 3LF according to the third embodiment are assigned with the same reference numerals, and repetitive descriptions for those will be omitted.', 'As illustrated in FIG5, the second information processing device 59 has a single housing or substrate. The second information processing device 59 is supported by the second supporting member 53 together with the second LiDAR sensor 51, the second acceleration sensor 52, and the second camera 56.']",13,110,schematic,B,"[{'element_identifier': '24', 'terms': ['first sensor module']}, {'element_identifier': '51', 'terms': ['second LiDAR sensor', 'second LiDAR sensors']}, {'element_identifier': '191', 'terms': []}, {'element_identifier': '12', 'terms': ['translucent member']}, {'element_identifier': '19', 'terms': ['third screw mechanism']}, {'element_identifier': '48', 'terms': ['actuator']}, {'element_identifier': '18', 'terms': ['lamp unit']}, {'element_identifier': '56', 'terms': ['second camera']}, {'element_identifier': '53', 'terms': ['member']}, {'element_identifier': '192', 'terms': ['third vertical adjusting screw']}, {'element_identifier': '43', 'terms': ['first support member']}, {'element_identifier': '41', 'terms': ['LiDAR sensor']}, {'element_identifier': '49', 'terms': []}, {'element_identifier': '65', 'terms': ['second sensor module']}, {'element_identifier': '59', 'terms': []}, {'element_identifier': '55', 'terms': ['second actuator']}, {'element_identifier': '442', 'terms': ['first vertical adjusting screw']}, {'element_identifier': '13', 'terms': ['lamp chamber']}]","['1. A sensor module adapted to be installed in a vehicle, comprising: a sensor configured to sense external information of the vehicle; a support member supporting the sensor; and an acceleration sensor supported on the support member.', '8. The sensor system according to any one of claims 2 to 7, wherein the sensor includes at least one of a LiDAR sensor, an ultrasonic wave sensor, a millimeter wave radar, and a camera.']",False,"['5', '12', '18', '41', '13', '41', '49', '43', '65', '56', '59', '51', '48', '442', '191', '192', '19', '552', '55', '551', '53', '24']" 773,EP_3605136_A1 (6).png,EP3605136A1,"SENSOR MODULE, SENSOR SYSTEM, AND METHOD FOR INSTALLING SENSOR SYSTEM IN VEHICLE",['FIG7'],['FIG7 illustrates a configuration of a sensor system according to a fifth embodiment'],"['FIG7 schematically illustrates a configuration of the left front sensor system 5LF according to a fifth embodiment. Components that are the same as or equivalent to those of the left front sensor system 3LF according to the third embodiment are assigned with the same reference numerals, and repetitive descriptions for those will be omitted.']",13,57,schematic,B,"[{'element_identifier': '191', 'terms': []}, {'element_identifier': '12', 'terms': ['translucent member']}, {'element_identifier': '19', 'terms': ['third screw mechanism']}, {'element_identifier': '750', 'terms': ['second support member']}, {'element_identifier': '18', 'terms': ['lamp unit']}, {'element_identifier': '740', 'terms': ['first support member']}, {'element_identifier': '541', 'terms': []}, {'element_identifier': '56', 'terms': ['second camera']}, {'element_identifier': '42', 'terms': ['first acceleration sensor']}, {'element_identifier': '192', 'terms': ['third vertical adjusting screw']}, {'element_identifier': '26', 'terms': ['processor']}, {'element_identifier': '46', 'terms': ['first camera']}, {'element_identifier': '442', 'terms': ['first vertical adjusting screw']}]","['2. A sensor system adapted to be installed in a vehicle, comprising: a sensor configured to sense external information of the vehicle; a support member supporting the sensor; an acceleration sensor supported on the support member; a memory configured to store a first output value of the acceleration sensor at a first time point; and a processor configured to acquire a difference between the first output value and a second output value of the acceleration sensor at a second time point.']",False,"['12', '18', '46', '42', '740', '750', '56', '442', '191', '192', '19', '541', '26']" 774,EP_3605137_A1 (4).png,EP3605137A1,OBJECT DETECTION BASED ON LIDAR INTENSITY,['FIG7'],"['FIG7 is a flowchart illustrating example operations performed as part of a method for performing vehicle localization based on one or more reflectance values inferred based on raw Lidar intensity values, according to some embodiments']","['FIG7 is a flowchart illustrating example operations performed as part of a method 700 for performing vehicle localization based on one or more reflectance values inferred based on raw Lidar intensity values, according to some embodiments. The method 700 may be embodied in computer-readable instructions for execution by a hardware component (e.g., a processor) such that the operations of the method 700 may be performed by one or more components of the AV system 100. Accordingly, the method 700 is described below, by way of example, with reference thereto. However, it shall be appreciated that the method 700 may be deployed on various other hardware configurations and is not intended to be limited to deployment on the AV system 100.']",36,134,flowchart,G,"[{'element_identifier': '7', 'terms': ['at power level']}, {'element_identifier': '710', 'terms': ['described herein. At operation']}, {'element_identifier': '705', 'terms': ['At operation']}, {'element_identifier': '715', 'terms': ['computing systems. At operation']}, {'element_identifier': '700', 'terms': ['method', 'methods']}]","['9. A method comprising: collecting a data set comprising a plurality of data points output by a light detection and ranging (Lidar) unit of an autonomous vehicle, each of the data points corresponding to one of multiple targets, each target having a known reflectance value; generating a reflectance inference model for the Lidar unit based on the data set, the generating of the reflectance inference model comprising mapping the plurality of data points to a coordinate system using range and raw intensity values of each data point as coordinates; accessing, by a vehicle computing system of the autonomous vehicle, an incoming data point output by the Lidar unit during operation of the autonomous vehicle; inferring, using the reflectance inference model, a reflectance value of an object based on the incoming data point, the reflectance value being interpolated from at least two data points mapped to the coordinate system; and determining, by the vehicle computing system, a motion plan for the autonomous vehicle based on the inferred reflectance value, the motion plan of the autonomous vehicle being used to control motion of the autonomous vehicle.']",False,"['700', '705', '710', '715', '7', '22']" 775,EP_3605137_A1.png,EP3605137A1,OBJECT DETECTION BASED ON LIDAR INTENSITY,['FIG1'],"['FIG1 is a block diagram illustrating an example autonomous vehicle (AV) system, according to some embodiments']","['With reference to FIG1, an example autonomous vehicle (AV) system 100 is illustrated, according to some embodiments. To avoid obscuring the inventive subject matter with unnecessary detail, various functional components that are not germane to conveying an understanding of the inventive subject matter have been omitted from FIG1. However, a skilled artisan will readily recognize that various additional functional components may be included as part of the AV system 100 to facilitate additional functionality that is not specifically described herein.', 'As illustrated in FIG1, the vehicle computing system 102 can include one or more computing devices that assist in controlling the AV system 100. The vehicle computing system 102 can include a localizer system 106, a perception system 108, a prediction system 110, a motion planning system 112, and a reflectance inference system 120 that cooperate to perceive the dynamic surrounding environment of the AV system 100 and determine a trajectory describing a proposed motion path for the AV system 100. The vehicle computing system 102 can additionally include a vehicle controller 114 configured to control the one or more vehicle controls 116 (e.g., actuators that control gas flow (propulsion), steering, braking, etc.) to execute the motion of the AV system 100 to follow the trajectory.']",19,233,block diagram,G,"[{'element_identifier': '122', 'terms': ['map data']}, {'element_identifier': '124', 'terms': ['positioning system']}, {'element_identifier': '1', 'terms': ['into two phases -']}, {'element_identifier': '100', 'terms': ['system']}, {'element_identifier': '104', 'terms': ['sensors']}, {'element_identifier': '118', 'terms': ['Lidar unit']}, {'element_identifier': '102', 'terms': ['vehicle computing system']}, {'element_identifier': '108', 'terms': ['perception system']}, {'element_identifier': '106', 'terms': ['localizer system']}, {'element_identifier': '110', 'terms': ['prediction system']}, {'element_identifier': '114', 'terms': ['vehicle controller']}, {'element_identifier': '120', 'terms': ['system']}]","['1. An autonomous vehicle ""AV"" system comprising: one or more processors of a machine; and a machine-storage medium storing instructions that, when executed by the one or more processors, cause the machine to perform operations comprising: accessing an incoming data point output by a light detection and ranging (Lidar) unit during operation of the AV system; inferring, using a reflectance inference model, a reflectance value of an object based on the incoming data point, the reflectance inference model comprising a mapping of a set of previously collected data points to a coordinate system using range and raw intensity values of the previously collected data points as coordinates, the reflectance value being interpolated from at least two previously collected data points of the set of previously collected data points mapped to the coordinate system, each of the two previously collected data points corresponding to one of multiple known reflectance values; and determining one or more characteristics of the object based on the inferred reflectance value.', '3. The AV system of claim 1 or claim 2, wherein: the reflectance inference model comprises a look-up table comprising a plurality of reflectance values interpolated from the set of previously collected data points mapped to the coordinate system, each reflectance value corresponding to a particular combination of range and raw intensity values; and the inferring of the reflectance value of the object comprises: accessing the look-up table; and determining the reflectance value from the look-up table based on a raw intensity value and a range value of the incoming data point; and/or the Lidar unit comprises a plurality of channels, each channel being capable of operating at a plurality of power levels; the reflectance inference model comprises multiple mappings of the previously collected data points to the coordinate system, each of the mappings corresponding to a particular power level of a particular channel of the Lidar unit; and the inferring of the reflectance value of the object comprises selecting the mapping of the set of previously collected data points from the multiple mappings based on a channel of the Lidar unit that output the incoming data point and a power level of the channel; and/or wherein the operations further comprise generating state data that describes the object, the state data comprising at least the inferred reflectance value; and/or wherein the operations further comprise: generating a reflectance map that includes an indication of the inferred reflectance value of the object; and performing vehicle localization based on the reflectance map. and/or wherein the operations further comprise: collecting a data set comprising data points output by the Lidar unit, each of the data points corresponding to one of multiple targets, each target having one of the multiple known reflectance values, the data set corresponding to the set of previously collected data points; and generating the reflectance inference model for the Lidar unit based on the data set, the generating of the reflectance inference model comprising mapping the set of previously collected data points to the coordinate system.', '6. The Lidar calibration system of claim 5, wherein the operations further comprise: compressing the look-up table to generate a compressed look-up table; and storing the compressed look-up table in a memory device of a vehicle computing system.']",False,"['100', '102', '122', '108', '104', '124', '120', '106', '110', '114', '118', '16', '1']" 776,EP_3605152_A1 (1).png,EP3605152A1,GROUND PENETRATING RADAR AND ELECTROMAGNETIC SOIL ANALYSIS METHOD,['FIG2'],['FIG2 shows a schematic view of a radar soil analysis system according to the invention'],"['FIG2 shows a soil analysis radar system, which comprises the radar 100 as previously described. The soil analysis radar system further comprises a first antenna 101 and a second antenna 102: the first antenna 101 is in use detachably connected to the RF output 109 and the second antenna 102 is detachably connected to the RF input 110. A first cable 117 of appropriate length connects the first antenna 101 to the RF output 109 and a second cable 117 of appropriate length connects the second antenna 102 to the RF input 110. Cables 117 are standard RF cables which the technician may choose for the particular frequency of the signal generated by the radar. Cables 117 may for example be RG58, RG8, H155, RG213, or other type of coaxial cables.', 'FIG2 further depicts the typical installation of the system 200 in the field, wherein the first antenna 101 and the second antenna 102 are arranged with their waterproof cases 116 introduced in a respective first borehole 10 and second borehole 20 pre-emptively practiced in the soil. Preferably such boreholes 10, 20 axially extend along a direction substantially coinciding with the vertical direction, although other directions may be used for performing different analysis of soils. The applicant recommends, although in a non-limiting extent, the preferred use of boreholes within 50mm and 80mm in diameter, although other diameters may be used. The first and the second borehole 10, 20 are arranged at a predetermined distance d, which in use may be some meters long, e.g. 5m. Optionally, albeit preferably, to the first and second antennas 101, 102 may be attached weights to provide tensioning, which are especially useful in case the boreholes are performed along a vertical direction.']",15,323,schematic view,E,"[{'element_identifier': '20', 'terms': ['second borehole']}, {'element_identifier': '104', 'terms': ['receiver']}, {'element_identifier': '112', 'terms': ['display']}, {'element_identifier': '115', 'terms': ['wireless interface']}, {'element_identifier': '108', 'terms': ['amplification stage']}, {'element_identifier': '31', 'terms': ['portion', 'portions']}, {'element_identifier': '109', 'terms': ['RF output']}, {'element_identifier': '103', 'terms': ['transmitter']}, {'element_identifier': '30', 'terms': ['soil', 'soils']}, {'element_identifier': '116', 'terms': ['waterproof case', 'waterproof cases']}, {'element_identifier': '113', 'terms': ['keyboard']}, {'element_identifier': '10', 'terms': ['borehole', 'boreholes']}, {'element_identifier': '117', 'terms': ['cable', 'Cables']}, {'element_identifier': '110', 'terms': ['first antenna']}, {'element_identifier': '107', 'terms': ['mains input']}, {'element_identifier': '100', 'terms': ['radar']}, {'element_identifier': '105', 'terms': ['power management unit']}, {'element_identifier': '111', 'terms': ['data processing unit']}, {'element_identifier': '102', 'terms': ['antenna']}, {'element_identifier': '101', 'terms': ['antenna', 'antennas']}, {'element_identifier': '106', 'terms': ['battery']}, {'element_identifier': '114', 'terms': ['USB port']}]","[""1. Electromagnetic soil analysis method, the method being characterized in that it comprises: - a step of making a first borehole (10) in an initial or first predetermined position in the soil (30); - a step of making a second borehole (20) in a second predetermined position in the soil (30), said second position being different from the first position; - a step of introducing a first antenna (101) in the first borehole (10) and a second antenna (102) in the second borehole (20); - a step of feeding a predetermined radio signal (s1(t)) to said first antenna (101), so that the first antenna (101) radiates said predetermined radio signal according to a predefined radiation pattern across a portion (31) of said soil (30) so that said predetermined radio signal (s1(t)) may be received by said second antenna (102); - a step of soil compactness analysis, by determining or calculating the amount of water ( x water ) and/or humidity and/or dielectric constant ( ε ') of a portion (31) of soil (30) interested by the radiation of the first antenna, said portion (31) of soil (30) being positioned between the first antenna (101) and the second antenna (102), - wherein the step of determining or calculating the amount of water ( x water ) and/or humidity and/or dielectric constant ( ε ') of the portion (31) of soil (30) is performed by electronically measuring the speed of propagation of said predetermined radio signal (s1(t)) between said first antenna (101) and said second antenna (102) or the delay with which the predetermined radio signal (s1(t))transmitted by said first antenna (101) or through a transmitter (103) connected to said first antenna (110) reaches said second antenna (102) or a receiver (104) connected to said second antenna (102)."", ""11. An electromagnetic soil analysis device (100) comprising: - a transmitter (103) configured to transmit a predetermined radio signal (s1(t)) and configured to be connected - in use - with a first antenna (101); - a receiver (104) configured to receive at least a part of said predetermined radio signal (s1(t)) after a propagation into a portion (31) of soil (30) and configured to be connected - in use - with a second antenna (102), and - a data processing unit (111) configured to calculate an amount of water ( x water ) and/or humidity and/or dielectric constant ( ε ') of the portion (31) of soil (30) by automatically and electronically calculating the speed of propagation of said predetermined radio signal (s1(t)) between said transmitter (103) and said receiver (104) or by calculating the delay with which the predetermined radio signal (s1(t)) transmitted by said transmitter (103) reaches said second antenna (102) or a receiver (104) connected to said second antenna (102)."", '15. A radar soil analysis system (200), said system (200) comprising an electromagnetic soil analysis device (100) according to one or more of claims 11-14 and: - a first antenna (101), electrically connected to said transmitter (103); and - a second antenna (102), electrically connected to said receiver (104); wherein the first and/or second antenna (101, 102) are dipole antennas or wherein the first and/or second antenna (101, 102) are broadband antennas, optionally dipole broadband antennas, optionally conical antennas.']",False,"['100', '112', '113', '111', '114', '103', '104', '108', '109', '106', '105', '110', '115', '107', '117', '101', '116', '10', '102', '31', '20', '30', '30', '19']" 777,EP_3605165_A1 (1).png,EP3605165A1,LIGHT-TRANSMISSIVE SUBSTRATE FOR SUPPRESSING HEAT-RAY TRANSMISSION AND LIGHT-TRANSMISSIVE SUBSTRATE UNIT,"['FIG3', ' FIG4']","['FIG4 is a cross-sectional view of a light-transmissive base material unit in one configuration example according to an embodiment of the present invention ', 'FIG3 is a cross-sectional view of a heat-ray-transmission-controllable, light-transmissive base material in yet another configuration example according to an embodiment of the present invention']","['Next, a configuration example of a light-transmissive base material unit of the present embodiment will be described. As illustrated in FIG4, a light-transmissive base material unit 40 of the present embodiment includes a light-transmissive base material 41 for windows and a heat-ray-transmission-controllable, light-transmissive base material 42 described above disposed over one surface 41a of the light-transmissive base material 41 for windows.', 'Normally, the heat-ray-transmission-controllable, light-transmissive base material 42 is disposed on the side of a room interior relative to the light-transmissive base material 41 for windows. Therefore, in the example illustrated in FIG4, it is favorable to fix the heat-ray-transmission-controllable, light-transmissive base material 42 such that the transparent conductive oxide layer is positioned on the side of the other surface 42a opposite to the one surface 42b facing the light-transmissive base material 41 for windows. Also, it is favorable to carry out the fixation such that the light-transmissive insolation-cutting unit is positioned on the side of the one surface 42b facing the light-transmissive base material 41 for windows, among the sides of the heat-ray-transmission-controllable, light-transmissive base material 42. ', 'A heat-ray-transmission-controllable, light-transmissive base material of the present embodiment may include, in addition to a light-transmissive insolation-cutting unit 11 and a transparent conductive oxide layer 12 as in a heat-ray-transmission-controllable, light-transmissive base material 30 illustrated in FIG3, for example, an optical interference layer 31.']",62,315,cross-sectional view,B,"[{'element_identifier': '30', 'terms': ['light-transmissive base material', 'No.']}, {'element_identifier': '12', 'terms': ['transparent conductive oxide layer']}, {'element_identifier': '40', 'terms': ['light-transmissive base material unit']}]","['1. A heat-ray-transmission-controllable, light-transmissive base material comprising: a light-transmissive insolation-cutting unit configured to control transmission of light in at least a part of wavelength regions among wavelength regions of visible light and near-infrared light; and a transparent conductive oxide layer disposed over the light-transmissive insolation-cutting unit, containing a transparent conductive oxide.', '8. 8. A light-transmissive base material unit comprising: a light-transmissive base material for a window; and the heat-ray-transmission-controllable, light-transmissive base material as claimed in any one of claims 1 to 7, disposed on one surface of the light-transmissive base material for the window.']",True,"['30', '40', '12', '28']" 778,EP_3605165_A1.png,EP3605165A1,LIGHT-TRANSMISSIVE SUBSTRATE FOR SUPPRESSING HEAT-RAY TRANSMISSION AND LIGHT-TRANSMISSIVE SUBSTRATE UNIT,"['FIG1', ' FIG2']","['FIG1 is a cross-sectional view of a heat-ray-transmission-controllable, light-transmissive base material in one configuration example according to an embodiment of the present invention ', 'FIG2 is a cross-sectional view of a heat-ray-transmission-controllable, light-transmissive base material in another configuration example according to an embodiment of the present invention']","['Here, a configuration example of a heat-ray-transmission-controllable, light-transmissive base material of the present embodiment is illustrated in FIG1. FIG1 schematically illustrates a cross-sectional view of a heat-ray-transmission-controllable, light-transmissive base material of the present embodiment on a plane parallel to the laminating direction of a light-transmissive insolation-cutting unit and a transparent conductive oxide layer.', 'As illustrated in FIG1, a heat-ray-transmission-controllable, light-transmissive base material 10 of the present embodiment may have a structure in which a transparent conductive oxide layer 12 is laminated over one surface of a light-transmissive insolation-cutting unit 11. In the following, each of the members will be described. ', 'Further, like a heat-ray-transmission-controllable, light-transmissive base material 20 illustrated in FIG2, a heat-ray-transmission-controllable, light-transmissive base material of the present embodiment may have a structure in which a light-transmissive insolation-cutting unit 11 includes a hard-coat layer 111, a light-transmissive base material 112, and an adhesive layer 113, in this order starting from the side of a surface 11a facing the transparent conductive oxide layer 12. In this case, one or more layers selected from among the hard-coat layer 111, the light-transmissive base material 112, and the adhesive layer 113 may have a function of controlling transmission of light in at least a part of wavelength regions among wavelength regions of visible light and near-infrared light. In other words, one or more layers selected from among the hard-coat layer 111, the light-transmissive base material 112, and the adhesive layer 113 may also serve as heat-shielding function layers.']",68,342,cross-sectional view,B,"[{'element_identifier': '12', 'terms': ['transparent conductive oxide layer']}, {'element_identifier': '11', 'terms': ['light-transmissive insolation-cutting unit']}, {'element_identifier': '1', 'terms': ['Example', 'Examples']}, {'element_identifier': '20', 'terms': ['light-transmissive base material']}, {'element_identifier': '10', 'terms': ['after']}, {'element_identifier': '13', 'terms': ['Note that in Examples']}]","['1. A heat-ray-transmission-controllable, light-transmissive base material comprising: a light-transmissive insolation-cutting unit configured to control transmission of light in at least a part of wavelength regions among wavelength regions of visible light and near-infrared light; and a transparent conductive oxide layer disposed over the light-transmissive insolation-cutting unit, containing a transparent conductive oxide.']",True,"['10', '12', '1', '20', '12', '11', '13', '27']" 779,EP_3605182_A1 (3).png,EP3605182A1,"PROJECTION OPTICAL SYSTEM, IMAGE PROJECTION DEVICE AND IMAGE PROJECTION SYSTEM",['FIG5'],['FIG5 is a configuration view of an image projection system in a first numerical example'],"['Table 7 to Table 11 below show specific data of transmissive optical system 110 of a first numerical example. Note that a slow ratio of the first numerical example is 0.147. Projection magnification of the first numerical example is 178.75. Sizes of image display element 130 to be used are 9.856 mm in a long-side direction and 6.162 mm in a short-side direction. FIG5 is a configuration view of image projection device 10 and screen SC in the first numerical example. When viewed in an X direction perpendicular to the paper plane, screen SC is disposed to be parallel to optical axis AZ of the transmissive optical system.']",15,119,view,G,"[{'element_identifier': '5', 'terms': ['conditional expression']}, {'element_identifier': '10', 'terms': ['image projection device']}]","['2. The projection optical system according to claim 1, wherein the projection optical system satisfies a conditional expression (3) shown below, θ \u2062 m 2 < θ \u2062 m 1 where θm1 is an angle formed by a normal line of the first reflecting surface at a position where the principal ray of the reference rays enters the first reflecting surface, and the principal ray of the reference rays.', '12. An image projection device comprising: the projection optical system according to any one of claims 1 to 11; and the image display element.']",False,"['5', '10', '55']" 780,EP_3605182_A1 (5).png,EP3605182A1,"PROJECTION OPTICAL SYSTEM, IMAGE PROJECTION DEVICE AND IMAGE PROJECTION SYSTEM",['FIG7'],['FIG7 is a configuration view of an image projection system in a third numerical example'],"['Table 17 to Table 21 below show specific data of transmissive optical system 110 of a third numerical example. Note that a slow ratio of the third numerical example is 0.170. Projection magnification of the third numerical example is 178.73. Sizes of image display element 130 to be used are 9.856 mm in a long-side direction and 6.162 mm in a short-side direction. FIG7 is a configuration view of image projection device 10 and screen SC in the third numerical example. When viewed in an X direction perpendicular to the paper plane, screen SC is disposed to be inclined at 15 degrees to optical axis AZ of the transmissive optical system.']",15,122,view,G,"[{'element_identifier': '7', 'terms': ['Table']}, {'element_identifier': '10', 'terms': ['image projection device']}]",['12. An image projection device comprising: the projection optical system according to any one of claims 1 to 11; and the image display element.'],False,"['7', '10', '57']" 781,EP_3605182_A1 (6).png,EP3605182A1,"PROJECTION OPTICAL SYSTEM, IMAGE PROJECTION DEVICE AND IMAGE PROJECTION SYSTEM",['FIG8'],['FIG8 is a configuration view of an image projection system in a fourth numerical example'],"['Table 22 to Table 26 below show specific data of transmissive optical system 110 of a fourth numerical example. Note that a slow ratio of the fourth numerical example is 0.175. Projection magnification of the fourth numerical example is 178.93. Sizes of image display element 130 to be used are 9.856 mm in a long-side direction and 6.162 mm in a short-side direction. FIG8 is a configuration view of image projection device 10 and screen SC in the fourth numerical example. When viewed in an X direction perpendicular to the paper plane, screen SC is disposed to be inclined at 25 degrees to optical axis AZ of the transmissive optical system.']",15,122,view,G,"[{'element_identifier': '8', 'terms': ['shown below in Table']}, {'element_identifier': '10', 'terms': ['image projection device']}]",['12. An image projection device comprising: the projection optical system according to any one of claims 1 to 11; and the image display element.'],False,"['8', '10', '58', '74']" 782,EP_3605207_A1 (6).png,EP3605207A1,"ARRAY SUBSTRATE, DISPLAY SCREEN, AND ELECTRONIC DEVICE",['FIG14'],['FIG14 is a schematic structural diagram illustrating partial structure of the array substrate of FIG13'],"['The display circuit layer 32 includes the gate 3231 of the TFT 323, the gate insulation layer 326, the semiconductor layer 3234 of the TFT 323, the first end 3232 of the TFT 323, the second end 3233 of the TFT 323, and the first planarization layer 325. The display circuit layer 32 further includes the data line 322 coupled with the first end 3232 of the TFT 323 and the gate line 321 (not illustrated in FIG14) coupled with the gate 3231 of the TFT 323.', 'The recognition circuit layer 33 includes the cathode 3312 of the photoelectric sensor 331, the photosensitive layer 3313 of the photoelectric sensor 331, and the anode 3311 of the photoelectric sensor 331. The recognition circuit layer 33 further includes the multiple output wires 333. The multiple output wires 333 are coupled with the cathodes 3312 of the multiple photoelectric sensors 331 respectively. The display circuit layer 32 further includes the multiple input wires 332 (not illustrated in FIG14). The multiple input wires 332 are coupled with the anodes 3311 of the multiple photoelectric sensors 331 respectively.']",15,202,schematic structural diagram,G,"[{'element_identifier': '331', 'terms': ['photoelectric sensors', 'photoelectric sensor']}, {'element_identifier': '3234', 'terms': ['semiconductor layer']}, {'element_identifier': '3231', 'terms': ['gate']}, {'element_identifier': '3232', 'terms': ['first end']}, {'element_identifier': '3312', 'terms': ['cathodes', 'cathode']}, {'element_identifier': '325', 'terms': ['first planarization layer']}, {'element_identifier': '323', 'terms': ['TFT']}, {'element_identifier': '3313', 'terms': ['photosensitive layer', 'photosensitive layers']}, {'element_identifier': '334', 'terms': ['insulation layer']}, {'element_identifier': '326', 'terms': ['gate insulation layer']}, {'element_identifier': '31', 'terms': ['first base material']}, {'element_identifier': '3233', 'terms': ['second end', 'second ends']}, {'element_identifier': '3311', 'terms': ['anodes', 'anode']}, {'element_identifier': '33', 'terms': ['recognition circuit layer']}, {'element_identifier': '3', 'terms': ['array substrate']}, {'element_identifier': '322', 'terms': ['multiple data lines']}, {'element_identifier': '333', 'terms': ['multiple output wires']}, {'element_identifier': '32', 'terms': ['display circuit layer']}]","['1. An array substrate (3), comprising a first base material (31), and a display circuit layer (32) and a recognition circuit layer (33) laminated on the first base material; the display circuit layer comprising a plurality of gate lines (321), a plurality of data lines (322), and a plurality of thin-film transistors, TFT (323), projections of the plurality of gate lines on the first base material and projections of the plurality of data lines on the first base material defining a plurality of sub-pixel projection areas (320), and each of projections of the plurality of TFTs on the first base material falling into a corresponding area of the plurality of sub-pixel projection areas; and the recognition circuit layer comprising a plurality of photoelectric sensors (331), projections of the plurality of photoelectric sensors on the first base material falling into a corresponding area of the sub-pixel projection areas, and the photoelectric sensor being configured to sense target lights carrying user fingerprint information.', '3. The array substrate of claim 2, wherein each of the plurality of photoelectric sensors comprises a cathode (3312), a photosensitive layer (3313), and an anode (3311) sequentially laminated, and wherein the cathode is located on one side of the photosensitive layer towards the first base material; and the anode is located on one side of the photosensitive layer away from the cathode, and the anode is made of a transparent conductive material.', '7. The array substrate of claim 6, wherein the cathodes of the plurality of photoelectric sensors are located on one side of the first planarization layer away from the first base material, and wherein the recognition circuit layer further comprises an insulation layer (326), the insulation layer is located on the one side of the first planarization layer away from the first base material and covers the cathodes of the plurality of photoelectric sensors, the insulation layer has a plurality of second through-holes (3341) and a plurality of third through-holes (3342), the plurality of second through-holes are aligned with the cathodes of the plurality of photoelectric sensors respectively, and the plurality of third through-holes communicate with the plurality of first through-holes respectively; the photosensitive layers of the plurality of photoelectric sensors are partially or wholly filled in the plurality of second through-holes respectively and are in contact with the cathodes of the plurality of photoelectric sensors; the anodes of the plurality of photoelectric sensors are located on one side of the insulation layer away from the first planarization layer and covers the photosensitive layers of the plurality of photoelectric sensors respectively; and the plurality of pixel electrodes are located on the one side of the insulation layer away from the first planarization layer and are coupled to the plurality of TFTs via the plurality of third through-holes and the plurality of first through-holes respectively.']",True,"['3313', '323', '331', '22', '33', '32', '3', '31', '13', '334', '3311', '3313', '331', '3312', '333', '334', '33', '325', '32', '31', '322', '3232', '3234', '323', '14', '3231', '3233', '326', '20']" 783,EP_3605217_A1 (1).png,EP3605217A1,"ARRAY SUBSTRATE, DISPLAY PANEL, AND DISPLAY DEVICE",['FIG2'],['FIG2 is an exemplary block diagram illustrating a display panel provided by another embodiment of the present disclosure and a display device provided by yet another embodiment of the present disclosure'],"['For example, FIG2 is an exemplary block diagram illustrating a display panel provided by another embodiment of the present disclosure and a display device provided by yet another embodiment of the present disclosure.', 'For example, as illustrated in FIG2, the display panel can include an array substrate. It should be understood that, for other indispensible components (e.g., opposed substrate, a LC layer and the like) for the display panel, conventional components can be adopted, which should be appreciated by those skilled art in the art, no further descriptions will be given herein and it shall not be constructed as limitations to the embodiments of the present disclosure. The display panel achieves an improvement in the aperture ratio.', 'For example, as illustrated in FIG2, the display device can include the display panel or the array substrate described above. It should be understood that, other indispensible components (e.g., a controlling device, an image data encoding/decoding device, a row scanning driver, a column scanning driver, a clock circuit and the like) for the display device are also included in the display device, which should be appreciated by those skilled art in the art, no further descriptions will be given herein and it shall not be constructed as limitations to the embodiments of the present disclosure. The display device achieves an improvement in the aperture ratio.']",31,256,exemplary block diagram,G,"[{'element_identifier': '210', 'terms': ['data line']}, {'element_identifier': '100', 'terms': ['array substrate']}, {'element_identifier': '260', 'terms': ['common electrode line']}, {'element_identifier': '232', 'terms': ['second sub-pixel']}, {'element_identifier': '255', 'terms': ['second electrode portion']}, {'element_identifier': '3', 'terms': ['andFig.']}, {'element_identifier': '200', 'terms': ['array substrate']}]","['3. The array substrate according to claim 2, wherein the three sub-pixels comprise a first sub-pixel adjacent to the first gate line, a third sub-pixel adjacent to the second gate line, and a second sub-pixel located between the first sub-pixel and the second sub-pixel, the first sub-pixel is electrically connected to the first gate line and the first data line, the third sub-pixel is electrically connected to the second gate line and the first data line, and the second sub-pixel is electrically connected to the first gate line and the second data line, or is electrically connected to the second gate line and the second data line.', '11. The array substrate according to claim 10, wherein the first driving sub-electrode comprises a first electrode portion and a second electrode portion which extend along different directions, and the first electrode portion and the second electrode portion are intersected with the rubbing alignment direction, respectively.', '14. The array substrate according to claim 11, further comprising a common electrode line, wherein the common electrode line is non-transparent and is disposed between adjacent two of the sub-pixels.']",True,"['20', '10', '100', '2', '200', '255', '23', '232', '260', '210', '3', '13']" 784,EP_3605221_A1 (4).png,EP3605221A1,LENS DRIVING DEVICE AND CAMERA MODULE,['FIG9'],['FIG9 is a cross-sectional view of the first lens driving device according to the present embodiment'],"['In the present embodiment, the center axis (refer to C1 in FIG9) of the lens coupled to the bobbin 1210 may be eccentrically disposed toward the direction of the dummy member 1330 from the center axis of the first lens driving device 1000. The center axis C1 of the bobbin 1210 may be disposed eccentrically toward the direction of the dummy member 1330 from the center axis C2 of the housing 1310. At this time, the center axis C1 of the lens can coincide with the center axis C1 of the bobbin 1210 or the center axis of the hole 1311 of the housing 1310. The center axis C2 of the first lens driving device 1000 and the center axis C2 of the housing 1310 may coincide with each other. At this time, the center axis C2 of the housing 1310 may be a center axis viewed with reference to the outer periphery of the housing 1310, not the center axis of the hole 1311 of the housing 1310. Further, the hole 1411a may be disposed eccentrically to the first surface side of the first lens driving device 1000. Through the above-mentioned structure of the present embodiment, a space can be secured so that the length L1 of the first coil unit 1422a in the lengthwise direction can be formed to be longer than the length L2 of each of the second and third coil units 1422b and 1422c in the lengthwise direction.']",18,260,cross-sectional view,G,"[{'element_identifier': '1521', 'terms': ['outer side portion']}, {'element_identifier': '1522', 'terms': []}, {'element_identifier': '1430', 'terms': ['base', 'bases']}, {'element_identifier': '1520', 'terms': ['lower elastic member']}, {'element_identifier': '1000', 'terms': ['first lens driving device']}, {'element_identifier': '1410', 'terms': ['substrate']}, {'element_identifier': '1523', 'terms': ['connecting portion']}, {'element_identifier': '1500', 'terms': ['elastic member']}, {'element_identifier': '1330', 'terms': ['dummy member']}, {'element_identifier': '1512', 'terms': []}, {'element_identifier': '1422', 'terms': ['coil', 'coils']}, {'element_identifier': '1510', 'terms': ['upper elastic member']}, {'element_identifier': '1514', 'terms': ['coupling portion']}, {'element_identifier': '1100', 'terms': ['cover']}, {'element_identifier': '1321', 'terms': ['first magnet unit']}, {'element_identifier': '1310', 'terms': ['housing']}, {'element_identifier': '1210', 'terms': ['bobbin']}, {'element_identifier': '1513', 'terms': ['connecting portion']}, {'element_identifier': '1511', 'terms': ['outer side portion']}]","['1. A lens driving device comprising: a housing; a bobbin disposed in the housing; a magnet and a dummy member, disposed on the housing; a first coil disposed on the bobbin; and a substrate comprising a second coil facing the magnet, wherein the housing comprises a first and a second side part facing each other, and a third and a fourth side part facing each other, wherein the magnet comprises a first magnet unit disposed on the first side part, a second magnet unit disposed on the third side part, and a third magnet unit disposed on the fourth side part, and wherein the dummy member is disposed on the second side part.', '4. The lens driving device according to claim 3, wherein the first coil comprises a connecting portion connecting the first coil unit and the second coil unit, and wherein the connecting portion of the first coil is disposed between the first magnet unit and the bobbin or disposed between the dummy member and the bobbin.', '10. A camera module comprising: a first lens driving device according to any one of claims 1 to 3 and 5; and a second lens driving device adjacent to the first lens driving device, wherein the second lens driving device is disposed adjacent to the fourth side part of the housing of the first lens driving device, wherein the second lens driving device comprises: a housing; a bobbin disposed in the housing of the second lens driving device; a third coil disposed on an outer circumferential surface of the bobbin of the second lens driving device; a magnet disposed in the housing of the second lens driving device and facing the third coil; and a fourth coil facing the magnet of the second lens driving device, wherein the magnet of the second lens driving device comprises four magnet units disposed at the corners of the housing of the second lens driving device.']",True,"['8', '1500', '1511', '1514', '1510', '1512', '1513', '1520', '1523', '1521', '1522', '1000', '1330', '1100', '1210', '1510', '1310', '1321', '1422', '1410', '1520', '1430', '26']" 785,EP_3605233_A1 (4).png,EP3605233A1,IMAGE FORMING APPARATUS AND IMAGE FORMING METHOD,['FIG10'],"['FIG10 is a graph representation illustrating a relationship between volume median diameter of toner, number average roundness of toner, and linear pressure of a cleaning blade']","['The minimum linear pressure necessary for cleaning was measured with respect to each of 15 toners having a D50 of 4.0 µm, 6.0 µm, or 8.0 µm and a number average roundness of 0.960, 0.965, 0.970, 0.975, or 0.980. Table 10 shows measurement results. In FIG10, the vertical axis represents minimum linear pressure necessary for cleaning (unit: N/m), and the horizontal axis represents number average roundness of toner. In FIG10, circles on the plot indicate measurement results of the toners having D50 of 4.0 µm, diamonds on the plot indicate measurement results of the toners having a D50 of 6.0 µm, and crosses on the plot indicate measurement results of the toners having a D50 of 8.0 µm.', 'FIG10 demonstrates that the smaller D50 of toner is, the higher the minimum linear pressure necessary for cleaning is. FIG10 also demonstrates that the higher the number average roundness of toner is, the higher the minimum linear pressure necessary for cleaning is. FIG10 also indicates that a linear pressure of at least 10 N/m is necessary for the use of the toner having a D50 of 6.0 µm and a number average roundness of 0.960. FIG10 also indicates that a linear pressure of approximately 40 N/m is preferable for the use of the toner having a D50 of 4.0 µm and a number average roundness of 0.980. The above-described tendency of the photosensitive member (P-B1), which has a chargeability ratio of lower than 0.60, indicated in FIG10 is expected to be true for photosensitive members having a chargeability ratio of at least 0.60. Therefore, study was made as follows on photosensitive members that can inhibit occurrence of a ghost image even if the linear pressure of the cleaning blade is at least 10 N/m and no greater than 40 N/m.']",28,343,graph,G,"[{'element_identifier': '35', 'terms': ['fixing device', 'no greater than']}, {'element_identifier': '5', 'terms': ['expression']}, {'element_identifier': '30', 'terms': ['image forming section', 'no greater than']}, {'element_identifier': '20', 'terms': ['polyarylate resin', 'polyarylate resins']}, {'element_identifier': '40', 'terms': ['no greater than']}, {'element_identifier': '10', 'terms': ['than']}, {'element_identifier': '15', 'terms': ['greater than']}]","['1. An image forming apparatus (1) comprising: an image bearing member (50); a charger (51) configured to charge a circumferential surface (50a) of the image bearing member to a positive polarity; and a cleaning member (81) pressed against the circumferential surface of the image bearing member and configured to collect a toner (T) remaining on the circumferential surface of the image bearing member, wherein a linear pressure of the cleaning member on the circumferential surface of the image bearing member is at least 10 N/m and no greater than 40 N/m, the image bearing member includes a conductive substrate (501) and a single-layer photosensitive layer (502), the single-layer photosensitive layer contains a charge generating material, a hole transport material, an electron transport material, and a binder resin, and the image bearing member satisfies formula (1), 0.60 ≦ V Q / S × d / ε r ⋅ ε 0 where in formula (1), Q represents a charge amount of the image bearing member, S represents a charge area of the image bearing member, d represents a film thickness of the single-layer photosensitive layer, ε r represents a specific permittivity of the binder resin contained in the single-layer photosensitive layer, ε 0 represents a vacuum permittivity, V is a value calculated in accordance with the following expression: V = V 0 - V r , V r represents a first potential of the circumferential surface of the image bearing member yet to be charged by the charger, and V 0 represents a second potential of the circumferential surface of the image bearing member charged by the charger.', '4. The image forming apparatus according to any one of claims 1 to 3, wherein the binder resin includes a polyarylate resin including a repeating unit represented by general formula (20), where in general formula (20), R 20 and R 21 each represent, independently of one another, a hydrogen atom or an alkyl group having a carbon number of at least 1 and no greater than 4, R 22 and R 23 each represent, independently of one another, a hydrogen atom, a phenyl group, or an alkyl group having a carbon number of at least 1 and no greater than 4, R 22 and R 23 may be bonded to one another to form a divalent group represented by general formula (W), and Y represents a divalent group represented by chemical formula (Y1), (Y2), (Y3), (Y4), (Y5), or (Y6), and in general formula (W), t represents an integer of at least 1 and no greater than 3, and asterisks each represent a bond']",False,"['45', '40', '35', '30', '25', '20', '15', '10', '5', '01', '960', '965', '980', '985', '10', '49']" 786,EP_3605234_A1 (4).png,EP3605234A1,"TONER, TONER SET, TONER ACCOMMODATING UNIT, IMAGE FORMING METHOD, AND IMAGE FORMING APPARATUS",['FIG8'],"['FIG8 is a cross-sectional view of an image forming apparatus according to an embodiment of the present invention, at an upstream portion of a supplying conveyance path with respect to the direction of conveyance of developer']","['FIG8 is a cross-sectional view of the developing unit 4 at an upstream portion with respect to the direction of conveyance of developer by the supplying screw 5. The third partition 3C has an opening 2e communicating the stirring conveyance path 2c and the supplying conveyance path 2a.', 'At an upstream portion in the supplying conveyance path 2a with respect to the direction of conveyance of developer, as illustrated in FIG8, the developer is supplied from the stirring conveyance path 2c, disposed obliquely below the supplying conveyance path 2a, to the supplying conveyance path 2a. Specifically, the stirring screw 7 rotates to push the developer into the opening 2e to cause the developer to overflow from the opening 2e, thereby supplying the developer to the supplying conveyance path 2a. Such a movement of the developer gives stress to the developer and reduces the lifespan of the developer.']",39,161,cross-sectional view,G,"[{'element_identifier': '8', 'terms': ['is', 'less than']}, {'element_identifier': '9', 'terms': ['Production Example']}, {'element_identifier': '37', 'terms': ['with']}, {'element_identifier': '5', 'terms': ['supplying screw']}]","['2. The toner according to claim 1, wherein a solid image formed of the toner with a deposition amount of 0.6 mg/cm 2 has: a chroma C* of 20 or less in the L*C*h color space; a hue angle h of from 50 to 90 degrees in the L*C*h color space; and a spectral reflectance of 40% or less at a wavelength of from 800 to 900 nm.', '9. The image forming method according to any one of claims 6 to 8, wherein a difference in 60-degree gloss value between the recording medium and the solid image portion of the invisible toner image fixed on the recording medium is 10 or less.']",True,"['8', '9', '5', '37']" 787,EP_3605234_A1.png,EP3605234A1,"TONER, TONER SET, TONER ACCOMMODATING UNIT, IMAGE FORMING METHOD, AND IMAGE FORMING APPARATUS","['FIG1', ' FIG2']","['FIG2 is a graph showing the L*a*b* color space for solid images formed of respective toners of Example 1 and Comparative Example 3 with a toner deposition amount of 0 6 mg/cm2 ', 'FIG1 is a graph showing spectral reflectance curves of solid images formed of respective toners of Example 1 and Comparative Example 3 with a toner deposition amount of 0 6 mg/cm2']","['As near-infrared light absorbing materials, phthalocyanines such as naphthalocyanine have been mainstream so far. A phthalocyanine-based near-infrared light absorbing material has a greenish or bluish color in the L*a*b* color space, as indicated by toner of Comparative Example 3 in FIG2.', 'When the conventional invisible toner is recorded on a recording medium such as paper and stored for a long time, the recording medium gets deteriorated and discolored to be reddish over time as illustrated in FIG2, thus lowering invisibility of the invisible toner that has a greenish or bluish color on the recording medium.', 'Here, FIG2 illustrates the L*a*b* color space for solid images formed of respective toners of Example 1 and Comparative Example 3 with a toner deposition amount of 0.6 mg/cm2. ', 'That is, an invisible toner is required to absorb near-infrared light having a wavelength of 700 to 900 nm and to reflect visible light having a wavelength of 400 nm to 700 nm for their invisibility under visible light, as indicated by a spectral reflectance curve of a solid image formed of toner of Example 1, with a toner deposition amount of 0.6 mg/cm2, illustrated in FIG1.']",68,221,graph,G,"[{'element_identifier': '80', 'terms': ['fixing device']}, {'element_identifier': '1', 'terms': ['Example', 'Examples']}, {'element_identifier': '100', 'terms': ['in', 'process cartridge']}, {'element_identifier': '2', 'terms': ['developer container', 'Example']}, {'element_identifier': '600', 'terms': ['minute dots with']}, {'element_identifier': '20', 'terms': ['is', 'from', 'less than']}, {'element_identifier': '40', 'terms': ['less than']}, {'element_identifier': '500', 'terms': ['1H']}, {'element_identifier': '10', 'terms': ['less than', 'regulation blade']}, {'element_identifier': '3', 'terms': ['Example']}, {'element_identifier': '800', 'terms': ['from']}, {'element_identifier': '32', 'terms': ['less than']}]","['1. A toner comprising: a binder resin; and a near-infrared light absorbing material, wherein the toner in the form of a pellet has: a chroma C* of 20 or less in the L*C*h color space; a hue angle h of from 50 to 90 degrees in the L*C*h color space; and a spectral reflectance of 5% or less at a wavelength of from 800 to 900 nm.', '11. An image forming apparatus (A; B; C) comprising: an electrostatic latent image bearer (21; 1; 20); an electrostatic latent image forming device (15; 51; 132) configured to form an electrostatic latent image on the electrostatic latent image bearer (21; 1; 20); a developing device (31; 4; 140) containing the toner according to any one of claims 1 to 3, configured to develop the electrostatic latent image formed on the electrostatic latent image bearer (21; 1; 20) with the toner to form an invisible toner image; a transfer device (61; 66) configured to transfer the invisible toner image formed on the electrostatic latent image bearer (21; 1; 20) onto a surface of a recording medium; and a fixing device (80) configured to fix the invisible toner image on the surface of the recording medium.']",True,"['1', '100', '80', '60', '40', '20', '1', '3', '400', '2', '500', '600', '700', '800', '900', '30', '10', '10', '20', '30', '10', '1', '3', '32']" 788,EP_3605255_A1 (2).png,EP3605255A1,NORMALIZED PROCESS DYNAMICS,['FIG4'],['FIG4 provides graphs of standard deviation as a function of frequency for various temperatures of a differential pressure sensor'],"['FIG4 provides a graph of the frequency response of the standard deviation of a differential pressure sensor at a collection of temperatures. In FIG4, frequency is shown along horizontal axis 400 and the standard deviation of the differential pressure is shown along vertical axis 402. Frequency response curves 404, 406, 408, 410 and 412 represent the standard deviation frequency response for a differential pressure sensor at 185°F, 130°F, 75°F, 20°F, and -40°F, respectively. FIG4 also shows an ideal standard deviation 414, which represents the standard deviation of a sine wave of magnitude 1. This ideal standard deviation has a value of 0.71 for all frequencies and temperatures.']",19,132,graphs,G,"[{'element_identifier': '8', 'terms': ['embodiment']}, {'element_identifier': '5', 'terms': ['order']}, {'element_identifier': '502', 'terms': ['shown along vertical axis']}, {'element_identifier': '400', 'terms': ['shown along horizontal axis']}, {'element_identifier': '414', 'terms': ['ideal standard deviation']}, {'element_identifier': '2', 'terms': ['transmitters', 'range']}, {'element_identifier': '4', 'terms': ['uses EQ.']}, {'element_identifier': '20', 'terms': ['embodiment']}, {'element_identifier': '40', 'terms': ['interface application']}, {'element_identifier': '402', 'terms': ['shown along vertical axis']}, {'element_identifier': '500', 'terms': ['shown along horizontal axis']}, {'element_identifier': '10', 'terms': ['process plant']}, {'element_identifier': '504', 'terms': ['graphs']}, {'element_identifier': '185', 'terms': ['sensor operating at']}, {'element_identifier': '404', 'terms': ['Frequency response curves']}]",['4. The computer readable medium of claim 3 wherein the target frequency response comprises a frequency response of a standard deviation of a filtered sensor signal wherein the sensor signal is produced by a model sensor operating at a same range as the sensor and at a selected temperature.'],False,"['185', '130', '75', '20', '414', '402', '404', '406', '408', '30', '75', '502', '40', '504', '506', '508', '510', '512', '8', '10', '500', '5', '15', '412', '2', '4', '8', '10', '400', '4']" 789,EP_3605255_A1 (6).png,EP3605255A1,NORMALIZED PROCESS DYNAMICS,['FIG11'],['FIG11 is a graph of a target frequency response for a standard deviation of a differential pressure signal'],"['At step 1002, a target standard deviation frequency response 918 is retrieved or computed by microprocessor 264. In accordance with one embodiment, the target frequency response is the standard deviation frequency response of a filtered sensor signal produced by a model sensor operating at a selected temperature and at the same range as the sensor in the field device and filtered by a high pass difference filter. An example of such a target frequency response is shown in FIG11 where frequency is shown along horizontal axis 1100 and the standard deviation of the filtered sensor signal produced by a model sensor at a selected temperature is shown on vertical axis 1102. In accordance with one embodiment, the selected temperature is room temperature. By constructing the filter so that the standard deviation frequency response matches the target frequency response of FIG11, it is possible to filter the sensor measurements taken at different temperatures so as to normalize the frequency response of the standard deviation across temperatures. This is accomplished by dynamically changing the filter as the temperature changes so that regardless of the sensor temperature, the same standard deviation frequency response is achieved.']",18,203,graph,G,"[{'element_identifier': '1100', 'terms': ['shown along horizontal axis']}, {'element_identifier': '2', 'terms': ['transmitters', 'range']}, {'element_identifier': '4', 'terms': ['uses EQ.']}, {'element_identifier': '20', 'terms': ['embodiment']}, {'element_identifier': '6', 'terms': ['EQ.']}, {'element_identifier': '10', 'terms': ['process plant']}, {'element_identifier': '1102', 'terms': ['vertical axis']}]",['4. The computer readable medium of claim 3 wherein the target frequency response comprises a frequency response of a standard deviation of a filtered sensor signal wherein the sensor signal is produced by a model sensor operating at a same range as the sensor and at a selected temperature.'],False,"['1102', '2', '4', '6', '11', '10', '1100', '20']" 790,EP_3605274_A1 (2).png,EP3605274A1,FOLDABLE DISPLAY,['FIG4'],['FIG4 is an enlarged view illustrating a connected portion of a printed circuit board of the foldable display shown in FIG2'],"['The second connectors 162 are configured on the FPC 161 so as to compensate for change in length during folding of the folding region FR. As illustrated in FIG4, the second connectors 162 are configured such that they have the folded structure when the display panel 110 is in the unfolded state but they are unfolded when the display panel 110 is folded. Other embodiments include the FPC 161 configured with a different structure for compensating for change in length upon folding of the display panel 110.', 'The case segments 121 are coupled to upper surfaces 137, 139 of the hinge bodies 131 and 135, respectively, and the upper surfaces 137, 139 of the hinge bodies 131 and 135 are provided therein with guide grooves 131a so as not to interfere with the second connectors 162 (see FIG4) or the FPCs 161 (see FIG4) such that the second connectors 162 are connected to the first connection holes 122 between the rear surfaces of the case segments 121 and the upper surfaces 137, 139 of the hinge bodies 131, 135.']",21,195,enlarged view,G,"[{'element_identifier': '13', 'terms': ['andFIG.']}, {'element_identifier': '160', 'terms': ['printed circuit board', 'PCB']}, {'element_identifier': '112', 'terms': ['first connector', 'first connectors']}, {'element_identifier': '111', 'terms': ['arrays', 'array']}, {'element_identifier': '162', 'terms': ['second connectors', 'second connector']}, {'element_identifier': '110', 'terms': ['display panel', 'display panels']}, {'element_identifier': '161', 'terms': ['FPC']}]","['1. A foldable display (100) comprising: a display panel (110) including a plurality of LED arrays (111), which extend in one direction; a lower plate (120) including at least one folding region (FR) and unfolding regions (UFR) connected to both sides of the folding region (FR), the display panel (110) being coupled to upper surfaces of the folding region (FR) and the unfolding regions (UFR); a printed circuit board (160) coupled to a rear surface of the lower plate (120) so as to control an operation of the display panel (110); and a hinge part (130) coupled to a lower portion of the folding region (FR) so as to form and maintain a folded state of the folding region (FR).', '3. The foldable display (100) according to claim 2, wherein each of the plurality of case segments (121) includes a first connection hole (122) formed therethrough, which allows a first connector (112) provided on a rear surface of a corresponding one of the plurality of LED arrays (111) to be connected to a second connector (162) provided at a flexible printed circuit (161) coupled to the printed circuit board (160).']",False,"['4', '162', '161', '160', '160', '0', '6', '110', '112', '111', '13']" 791,EP_3605274_A1 (5).png,EP3605274A1,FOLDABLE DISPLAY,['FIG6B'],"['FIG6B is a perspective view illustrating the hinge part of the foldable display shown in FIG5B, which is in the folded state']","['The hinge bodies 131 and 135, which are coupled to the rear surfaces 104FR of the case segments 121, include first hinge bodies 131 and second hinge bodies 135 connected to adjacent first hinge bodies 131. Since the first unit hinges 132 and the second unit hinges 133 are coupled to each other, the hinge bodies may be folded as illustrated in FIG6B.']",23,67,perspective view,G,"[{'element_identifier': '141', 'terms': ['rear surface', 'rear surfaces']}, {'element_identifier': '130', 'terms': ['hinge part']}, {'element_identifier': '137', 'terms': ['upper surfaces']}, {'element_identifier': '133', 'terms': ['second unit hinge', 'second unit hinges']}, {'element_identifier': '131', 'terms': ['bodies', 'body']}, {'element_identifier': '132', 'terms': ['first unit hinge', 'first unit hinges']}, {'element_identifier': '143', 'terms': ['rear surface']}, {'element_identifier': '135', 'terms': ['second hinge body', 'second hinge bodies']}]","['1. A foldable display (100) comprising: a display panel (110) including a plurality of LED arrays (111), which extend in one direction; a lower plate (120) including at least one folding region (FR) and unfolding regions (UFR) connected to both sides of the folding region (FR), the display panel (110) being coupled to upper surfaces of the folding region (FR) and the unfolding regions (UFR); a printed circuit board (160) coupled to a rear surface of the lower plate (120) so as to control an operation of the display panel (110); and a hinge part (130) coupled to a lower portion of the folding region (FR) so as to form and maintain a folded state of the folding region (FR).', '5. The foldable display (100) according to any one of claims 2 to 4, wherein the hinge part (130) comprises: a plurality of hinge bodies (131, 135) respectively coupled to rear surfaces of the plurality of case segments (121) ; a plurality of first unit hinges (132) coupled to a rear surface of the first hinge body (131) of the hinge bodies (131) at predetermined intervals; a plurality of second unit hinges (133) coupled to a rear surface of the second hinge body (135) that is adjacent to the first hinge body (131) and alternately coupled to the plurality of first unit hinges (132).']",False,"['130', '132', '133', '141', '143', '131', '135', '132', '133', '137', '139', '18']" 792,EP_3605280_A1 (4).png,EP3605280A1,A TOUCH INTERFACE DEVICE HAVING AN ELECTROSTATIC MULTITOUCH SURFACE AND METHOD FOR CONTROLLING THE DEVICE,['FIG13'],['FIG13 illustrates a cross-sectional view of a portion of an example touch surface having multiple electrodes and insulating layers'],"['FIG13 illustrates a cross-sectional view of a portion of an example touch surface 1300 having multiple electrodes 1302, 1304 and insulating layers 1306, 1308. The surface 1300 may be similar to the touch surface 12 of the device 10 described above. For example, the surface 1300 may be capable of perceiving touch from an operator and of generating haptic effects that are perceived by the operator. The device 1300 includes the multiple electrodes 1302, 1304 and insulating layers 1306, 1308 stacked on top one another and coupled with a screen 1310, such as a display screen or other surface of the device 10.', 'The electrodes 1302, 1304 may be used for sensing touch of the device 10 that includes the surface 1300 and/or for generating haptic effects, as described herein. As shown in FIG13, the electrodes and insulating layers are disposed on a side of the device that an operator acts to touch. As described herein, the operator touching or acting to touch the surface 1300 may involve the operator touching the insulating layer 1308 instead of actually engaging the underlying screen 1310. The electrodes and insulating layers may be at least partially transparent, or light transmissive, so that a visual display can be seen through the touch screen 1300 by the operator, as described above. One transparent and electrically conductive material that can used for such layers is Indium Tin Oxide, ITO.']",21,259,cross-sectional view,G,"[{'element_identifier': '1300', 'terms': ['surface']}, {'element_identifier': '12', 'terms': ['surface']}, {'element_identifier': '1302', 'terms': ['electrodes']}, {'element_identifier': '1306', 'terms': ['insulating layers']}, {'element_identifier': '1310', 'terms': ['screen']}, {'element_identifier': '1308', 'terms': ['insulating layer']}, {'element_identifier': '1102', 'terms': ['switches', 'switch']}]","['1. A touch interface device comprising: a touch surface; and elongated electrodes coupled with the touch surface, the electrodes including a first electrode oriented along a first direction and a second electrode oriented along a second direction that is substantially parallel to the first direction, wherein the first and second electrodes are configured to receive haptic actuation electric potentials of opposite polarities to generate an electrostatic force that is imparted on the one or more appendages of the operator that touch the touch surface above the first and second electrodes.']",True,"['1102', '104', '12', '1300', '1302', '1310', '1308', '1306', '13', '32']" 793,EP_3605292_A1 (1).png,EP3605292A1,FORCE SENSOR AND DISPLAY DEVICE INCLUDING THE SAME,['FIG2'],['FIG2 is an exploded perspective view of the display device according to the embodiment'],"['The force sensors 100 and 200 may be disposed to overlap at least one edge of the display panel 30. A plurality of force sensors 100 and 200 may be provided. As illustrated in the drawings, the force sensors 100 and 200 include a first force sensor 100 overlapping a first long edge (first long side LSi) of the display panel 30 and a second force sensor 200 overlapping a second long edge (second long side LS2) of the display panel 30. In FIG2, the force sensors 100 and 200 are disposed in the second area DR2 (i.e., the curved portion) of the display device 1. For example, when the second area DR2 is divided into first and second subareas, the first sensor 100 may be disposed in the first subarea, the second force sensor 200 may be disposed in the second subarea, and the first area DR1 is disposed between the subareas. However, the force sensors 100 and 200 are disposed in the second area DR2 in alternate embodiments. In an exemplary embodiment, any one of the force sensor 100 and 200 is omitted. For example, in some embodiments only one of the force sensor 100 or force sensor 200 is present.', 'The position where the force has been applied may be identified through the touch member 20 (see FIG2). That is, a touch electrode may be disposed in regions of the touch member 20 which overlap the force sensors 100_4 and 200_4 to detect the presence or absence of a touch and the position of the touch, and the presence or absence of a force and the magnitude of the force may be measured by the force sensors 100_4 and 200_4 and used as an input signal.']",14,320,exploded perspective view,G,"[{'element_identifier': '51', 'terms': ['bottom portion']}, {'element_identifier': '30', 'terms': ['display panel']}, {'element_identifier': '100', 'terms': ['sensor', 'sensors']}, {'element_identifier': '20', 'terms': ['touch member']}, {'element_identifier': '25', 'terms': ['is']}, {'element_identifier': '52', 'terms': ['sidewalls']}, {'element_identifier': '53', 'terms': ['hole']}, {'element_identifier': '10', 'terms': ['window']}, {'element_identifier': '50', 'terms': ['bracket']}, {'element_identifier': '21', 'terms': ['touch flexible circuit board']}, {'element_identifier': '31', 'terms': ['display flexible circuit board']}, {'element_identifier': '200', 'terms': ['force sensors', 'force sensor']}]","['1. A display device comprising: a display panel; and a first force sensor disposed adjacent to a first edge of the display panel, the first force sensor extending along the first edge, wherein the first force sensor comprises: a first sensing region; a second sensing region located adjacent the first sensing region and having a larger area than the first sensing region; a first force concentration bump overlapping the first sensing region; and a second force concentration bump overlapping the second sensing region and spaced apart from the first force concentration bump.', '18. The display device of any one of claims 1 to 16, comprising a recess disposed at an inner side of the first force sensor, wherein the first sensing region is disposed on a first side of the recess and the second sensing region is disposed on a second side of the recess; optionally wherein the recess is notch-shaped; optionally further comprising a bracket which houses the display panel and the first force sensor, the bracket comprising a connect hole through which a connector passes, wherein the recess bypasses the connect hole in an outward direction.']",False,"['10', '20', '21', '30', '100', '200', '31', '52', '53', '51', '50', '25']" 794,EP_3605292_A1 (4).png,EP3605292A1,FORCE SENSOR AND DISPLAY DEVICE INCLUDING THE SAME,['FIG17'],['FIG17 is a layout view of the first force sensor of FIG16'],"['In FIG17, the first electrode 113 is a separate sensing electrode disposed in each sensing region, and the second electrode 123 is a driving electrode formed as a whole-plate electrode. However, the first electrode 113 may also be formed as a whole-plate electrode, and the second electrode 123 may also be formed as a sensing electrode.']",12,66,layout view,G,"[{'element_identifier': '122', 'terms': ['force sensing layer']}, {'element_identifier': '113', 'terms': ['first electrode']}, {'element_identifier': '123', 'terms': ['second electrode', 'second electrodes']}]","['5. The display device of any one of claims 1 to 3, wherein the first force sensor comprises a first electrode and a plurality of second electrodes separated from the first electrode, wherein the first electrode is disposed in the first sensing region and the second sensing region, and the plurality of second electrodes are disposed separately in each of the first sensing region and the second sensing region.', '6. The display device of claim 4, wherein the first force sensor further comprises a force sensing layer comprising a force sensitive material having a resistance that varies according to a force, wherein the force sensing layer overlaps the first force concentration bump, the first electrode and the second electrode in the first sensing region and wherein the force sensing layer overlaps the second force concentration bump, the first electrode and the second electrode in the second sensing region.']",False,"['17', '113', '122', '123', '1205', '43']" 795,EP_3605306_A1 (2).png,EP3605306A1,UNLOCKING METHOD AND MOBILE TERMINAL,"['FIG3', ' FIG4']","['FIG3 is a first schematic view of a mobile terminal in some embodiments of the present disclosure ', 'FIG4 is a second schematic view of a mobile terminal in some embodiments of the present disclosure']","['Referring to FIG3, FIG3 is a schematic view of a mobile terminal in the embodiments of the present disclosure. As shown in FIG3, a mobile terminal 300 includes a touch chip 301, a fingerprint driving chip 302, a central processor 303, the touch chip 301 is connected to the fingerprint driving chip 302, the touch chip 301 is connected to the central processor 303, the central processor 303 is connected to the fingerprint driving chip 302. ', 'Optionally, as shown in FIG4, the touch chip 301 is connected to a display module 304 of the mobile terminal 300, the central processor 303 is connected to the display module 304, the mobile terminal 300 includes:the touch chip 301, further configured to send a third control signal to the display module ; andthe display module 304, configured to emit light in response to the third control signal sent by the touch chip 301, to enable the fingerprint sensor to collect the fingerprint information of the fingerprint verification operation in an illumination environment.']",34,188,schematic view,G,"[{'element_identifier': '304', 'terms': ['display module']}, {'element_identifier': '303', 'terms': ['central processor']}, {'element_identifier': '302', 'terms': ['fingerprint driving chip']}, {'element_identifier': '301', 'terms': ['touch chip']}, {'element_identifier': '300', 'terms': ['mobile terminal']}]","['2. The method according to claim 1, wherein the touch chip is connected to a display module of the mobile terminal, the central processor is connected to the display module, the method further comprises: while sending, by the touch chip, the first control signal to the fingerprint driving chip and the second control signal to the central processor, sending, by the touch chip, a third control signal to the display module; and emitting light by the display module in response to the third control signal, to enable the fingerprint sensor to collect the fingerprint information of the fingerprint verification operation in an illumination environment.']",True,"['300', '3', '301', '302', '303', '302', '300', '301', '304', '303', '4', '15']" 796,EP_3605306_A1 (3).png,EP3605306A1,UNLOCKING METHOD AND MOBILE TERMINAL,['FIG6'],['FIG6 is a fourth schematic view of a mobile terminal in some embodiments of the present disclosure'],"['Referring to FIG6, FIG6 is a schematic view of a structure of a mobile terminal in the embodiments of the present disclosure. As shown in FIG6, a mobile terminal 600 includes: at least one processor 601, a storage 602, at least one network interface 604 and a user interface 603. Each component of the mobile terminal 600 is coupled together through a bus system 605. It is understandable that, the bus system 605 is to realize connection communication between these components. The bus system 605 includes not only a data bus, but also a power bus, a control bus and a state signal bus. But for the sake of clarity, in FIG6, all kinds of buses are marked as the bus system 605. The mobile terminal 600 also includes an acquisition component 606 of characteristics of human body. The acquisition component 606 of characteristics of human body is connected to each component of the mobile terminal through the bus system 605.']",17,179,schematic view,G,"[{'element_identifier': '601', 'terms': ['processor']}, {'element_identifier': '3012', 'terms': ['obtaining module']}, {'element_identifier': '6022', 'terms': ['application']}, {'element_identifier': '605', 'terms': ['bus system']}, {'element_identifier': '6021', 'terms': ['operating system']}, {'element_identifier': '303', 'terms': ['central processor']}, {'element_identifier': '3013', 'terms': ['judging module']}, {'element_identifier': '600', 'terms': ['mobile terminal']}, {'element_identifier': '302', 'terms': ['fingerprint driving chip']}, {'element_identifier': '301', 'terms': ['touch chip']}, {'element_identifier': '300', 'terms': ['mobile terminal']}, {'element_identifier': '604', 'terms': []}, {'element_identifier': '602', 'terms': ['storage']}, {'element_identifier': '3014', 'terms': ['anda determining module']}, {'element_identifier': '3011', 'terms': ['detecting module']}, {'element_identifier': '603', 'terms': ['user interface']}]","['1. An unlocking method, applied to a mobile terminal, wherein a touch chip of the mobile terminal is connected to a central processor of the mobile terminal and a fingerprint driving chip of the mobile terminal, the central processor is connected to the fingerprint driving chip, the method comprises: determining, by the touch chip, whether a fingerprint verification operation is detected in the case that the mobile terminal is locked; sending, by the touch chip, a first control signal to the fingerprint driving chip and a second control signal to the central processor in the case that the fingerprint verification operation is detected; driving, by the fingerprint driving chip, in response to the first control signal, a fingerprint sensor to collect fingerprint information of the fingerprint verification operation, and determining whether the collected fingerprint information matches preset fingerprint information; and unlocking the mobile terminal by the central processor in response to the second control signal and a determination result from the fingerprint driving chip in the case that the fingerprint driving chip determines that the collected fingerprint information matches the preset fingerprint information.', '9. The mobile terminal according to claim 6, wherein the touch chip comprises: a detecting module, configured to detect a touch operation of a user on the mobile terminal; an obtaining module, configured to obtain a touch parameter of the touch operation detected by the detecting module; a judging module, configured to determine whether the touch parameter obtained by the obtaining module matches a preset touch parameter; and a determining module, configured to determine the touch operation is the fingerprint verification operation in the case that the judging module determines that the touch parameter of the touch operation matches the preset touch parameter.']",True,"['300', '301', '3011', '3012', '3013', '3014', '302', '303', '601', '600', '602', '6021', '6022', '605', '603', '604', '6', '16']" 797,EP_3605316_A1 (2).png,EP3605316A1,"INFORMATION PROCESSING DEVICE, INFORMATION PROCESSING METHOD AND PROGRAM",['FIG4'],['FIG4 is a diagram for describing an operation of the information processing system'],"['In a case where the messenger 33 has been found at time T3, the messenger 33 is notified of a message state at time T4. Then, at time T5 (FIG4), the information processing unit 12 sends a message such as ""there is something to be conveyed to ""mother"""" to the messenger 33. Whether or not the messenger 33 (the child in this case) has taken any reaction, for example, has raised a hand or has replied to the message is determined.', 'For example, as the message call request template for infants, templates such as ""(name info), please listen"", ""(name info), can you come here"", and ""there is something to ask you to convey to (target user)"" are prepared. For example, as illustrated at the time T5 in FIG4, in a case where the messenger 33 is a child (infant), an appropriate template at the point of time is selected from the templates prepared as the message call request templates for infants.', 'It is determined that the messenger 33 has responded to the message from these detection results. In a case where it is determined that there has been a response from the messenger 33, the request type in the message mode is selected (time T6 (FIG4)).']",13,256,diagram,G,"[{'element_identifier': '33', 'terms': ['messenger']}, {'element_identifier': '4', 'terms': ['second user.']}, {'element_identifier': '12', 'terms': ['processing unit', 'processing units']}, {'element_identifier': '22', 'terms': ['network']}]",['1. An information processing apparatus comprising: a presentation unit configured to present information to a first user; a detection unit configured to detect a reaction indicating that the first user has received the information; a search unit configured to search for a second user in a case where the detection unit has not been able to detect the reaction; and a request unit configured to request the second user found by the search unit to convey a message to the first user.'],False,"['4', '22', '33', '12', '33', '12', '33', '12']" 798,EP_3605316_A1 (4).png,EP3605316A1,"INFORMATION PROCESSING DEVICE, INFORMATION PROCESSING METHOD AND PROGRAM",['FIG19'],['FIG19 is a diagram for describing an update of a database'],"['In a case where the recipient 32 has been performing an action of ""shaking a pod"" and has uttered to the child that ""YYY, take a bath soon"" when the information processing unit 12 has detected the utterance and the action of the recipient 32 at the time T2, this detection result is written in the detection information database 110b and the database illustrated in FIG19 is created.', 'In the example described here, the search information database 110b as illustrated in FIG19 is created at the time T3. Therefore, it is determined that there has been no response from the recipient 32. Then, the information processing unit 12 transitions to the message mode.']",11,127,diagram,G,"[{'element_identifier': '40', 'terms': ['age']}]","['8. The information processing apparatus according to claim 1, wherein the request unit generates and outputs a message according to an age of the second user.']",False,"['19', '40', '34']" 799,EP_3605318_A1 (1).png,EP3605318A1,APPLICATION COMPONENT DEPLOYMENT SEQUENCES,['FIG2'],['FIG2 is a block diagram of an example of a memory resource for generating deployment sequences consistent with the disclosure'],"['FIG2 is a block diagram of an example of a memory resource 220 for generating deployment sequences consistent with the disclosure. In some examples, the memory resource 220 can be utilized to store instructions 224, 226 that can be executed by a processing resource to perform functions described herein. In some examples, the processing resource can be coupled to the memory resource 220 via a connection. A processing resource may be a central processing unit (CPU), microprocessor, and/or other hardware device suitable for retrieval and execution of instructions stored in memory resource 220.', 'Memory resource 320 may be any electronic, magnetic, optical, or other physical storage device that stores executable instructions 338, 340, 342, 344. In some examples, the memory resource 320 can be the same or similar as memory resource 220 as referenced in FIG2.']",20,157,block diagram,G,"[{'element_identifier': '220', 'terms': ['memory resource']}, {'element_identifier': '224', 'terms': ['instructions']}]","['1. A non-transitory machine-readable storage medium having stored thereon machine-readable instructions to cause a computer processor to: determine dependencies between a plurality of application components of an application solution to be deployed on a plurality of hardware components of a computing system; and generate a deployment sequence for the plurality of application components based on the determined dependencies between the plurality of application components, wherein the deployment sequence includes a portion of the plurality of applications to be deployed on each of the plurality of hardware components and a sequence to deploy the portion of the plurality of application components based on the determined dependencies.', '7. A system comprising: a processing resource; and a memory resource storing machine readable instructions to cause the processing resource to: identify application components of an application solution to be applied to a hardware component of a hardware topology; determine dependencies between the identified application components to be applied to the hardware component; determine an order of deployment based on the determined dependencies between the identified application components; and deploy the identified application components on the hardware component based on the determined order of deployment.']",False,"['220', '224', '12', '2']" 800,EP_3605318_A1 (2).png,EP3605318A1,APPLICATION COMPONENT DEPLOYMENT SEQUENCES,['FIG3'],['FIG3 is a block diagram of an example of a system for generating deployment sequences consistent with the disclosure'],"['FIG3 is a block diagram of an example of a system 330 for generating deployment sequences consistent with the disclosure. In some examples, the system 330 can include a memory resource 320 that can be utilized to store instructions 338, 340, 342, 344 that can be executed by a processing resource 332 to perform functions described herein. In some examples, the processing resource 332 can be coupled to the memory resource 320 via a connection 334. Connection 334 can be a physical or wireless communication connection that can be utilized to transfer data signals between the processing resource 332 and the memory resource 320.', 'A processing resource 332 may be a central processing unit (CPU), microprocessor, and/or other hardware device suitable for retrieval and execution of instructions stored in memory resource 320. In the particular example shown in FIG3, processing resource 332 may receive, determine, and send instructions 338, 340, 342, 344. As an alternative or in addition to retrieving and executing instructions 338, 340, 342, 344, processing resource 332 may include an electronic circuit comprising a number of electronic components for performing the operations of the instructions 338, 340, 342, 344 in the memory resource 320. With respect to the executable instruction representations or boxes described and shown herein, it should be understood that part or all of the executable instructions 338, 340, 342, 344 and/or electronic circuits included within one box may be included in a different box shown in the figures or in a different box not shown.']",19,286,block diagram,G,"[{'element_identifier': '338', 'terms': ['instructions']}, {'element_identifier': '334', 'terms': ['connection']}, {'element_identifier': '342', 'terms': ['can include instructions']}, {'element_identifier': '344', 'terms': ['can include instructions']}, {'element_identifier': '320', 'terms': ['memory resource']}, {'element_identifier': '340', 'terms': ['can include instructions']}]","['1. A non-transitory machine-readable storage medium having stored thereon machine-readable instructions to cause a computer processor to: determine dependencies between a plurality of application components of an application solution to be deployed on a plurality of hardware components of a computing system; and generate a deployment sequence for the plurality of application components based on the determined dependencies between the plurality of application components, wherein the deployment sequence includes a portion of the plurality of applications to be deployed on each of the plurality of hardware components and a sequence to deploy the portion of the plurality of application components based on the determined dependencies.', '7. A system comprising: a processing resource; and a memory resource storing machine readable instructions to cause the processing resource to: identify application components of an application solution to be applied to a hardware component of a hardware topology; determine dependencies between the identified application components to be applied to the hardware component; determine an order of deployment based on the determined dependencies between the identified application components; and deploy the identified application components on the hardware component based on the determined order of deployment.']",False,"['334', '320', '338', '340', '342', '344', '13', '3']" 801,EP_3605327_A1 (3).png,EP3605327A1,METHOD AND APPARATUS FOR CAPTURING SCREENSHOTS OF GUEST OPERATING SYSTEM IN COMPUTER DEVICE,"['FIG6', ' FIG7']","['FIG6 is a block diagram of a guest operating system screen-shooting device in the computer apparatus according to an embodiment of the present disclosure ', 'FIG7 is a hardware structural diagram of the computer apparatus according to an embodiment of the present disclosure ']","['As shown in FIG6, according to an embodiment of the present disclosure, there is also provided a screen-shooting device for guest operating system in a computer apparatus, the computer apparatus having a host operating system, and a guest operating system being displayed through a display window on the host operating system and assigned to the guest operating system, the device comprising: ', 'A computer apparatus 800 according to an embodiment of the present disclosure is described below with reference to FIG7. The computer apparatus 800 shown in FIG7 is merely an example and should not impose any limitation on the function and use range of embodiments of the present invention.', 'As shown in FIG7, the computer apparatus 800 is embodied in the form of a general purpose computing apparatus. Components of the computer apparatus 800 may include, but are not limited to, at least one processing unit 810, at least one storage unit 820, and a bus 830 that connects different system components (including the storage unit 820 and the processing unit 810).']",44,192,"block diagram, structural diagram",G,"[{'element_identifier': '620', 'terms': ['lookup unit']}, {'element_identifier': '830', 'terms': ['bus']}, {'element_identifier': '8202', 'terms': ['cache storage unit']}, {'element_identifier': '860', 'terms': ['network adapter']}, {'element_identifier': '810', 'terms': ['processing unit']}, {'element_identifier': '8205', 'terms': ['program modules']}, {'element_identifier': '820', 'terms': ['storage unit']}, {'element_identifier': '8204', 'terms': ['program/utility']}, {'element_identifier': '630', 'terms': ['transmitting unit']}, {'element_identifier': '15', 'terms': ['address translator']}, {'element_identifier': '610', 'terms': ['receiving unit']}, {'element_identifier': '800', 'terms': ['computer apparatus']}, {'element_identifier': '700', 'terms': ['external apparatuses']}]","['9. A screen-shooting device for a guest operating system in a computer apparatus, wherein, the computer apparatus comprises a host operating system, and a guest operating system is displayed through a display window on the host operating system and assigned to the guest operating system, the device comprising: a receiving unit configured for receiving a screen-shooting request from the guest operating system; a looking-up unit configured for looking up a layer corresponding to the display window on the host operating system and assigned to the guest operating system; and a transmitting unit configured for transmitting the layer to the guest operating system as a displayed guest operating system screenshot.']",True,"['610', '620', '630', '6', '800', '820', '8201', '8203', '810', '8202', '8204', '8205', '830', '700', '860', '7', '15']" 802,EP_3605388_A1 (4).png,EP3605388A1,"FACE DETECTION METHOD AND APPARATUS, COMPUTER DEVICE, AND STORAGE MEDIUM",['FIG9'],['FIG9 is a flowchart of dividing sample images in a sample image set to split to generate each of nodes of a regression tree according to an embodiment'],"['As shown in FIG9, in an embodiment, the dividing sample images in the sample image set according to the first pixel pair collection, splitting to generate each of nodes of a regression tree includes:performing the following processing on a root node and each of the nodes that are generated by splitting by beginning from the root node of the regression tree:S902: Select a second pixel pair collection randomly from the first pixel pair collection.']",28,83,flowchart,G,"[{'element_identifier': '4', 'terms': ['node', 'nodes']}]","['1. A face detection method for a computer device, comprising: obtaining a to-be-detected image; obtaining an initial shape of a current regression tree in a pre-constructed probability regression model; extracting image features from the to-be-detected image and respectively calculating a probability of each of leaf nodes of the current regression tree according to the image features; extracting an error of each of the leaf nodes from the current regression tree; determining a shape error of the current regression tree according to the probability and the error of each of the leaf nodes; calculating, by the compute device, an estimated shape of the current regression tree according to the initial shape and the shape error; and performing iterative calculation by using the estimated shape as an initial shape of a neighboring next regression tree until a last regression tree in the probability regression model, to obtain an estimated shape of the last regression tree as a detected face shape.']",True,"['4', '4', '00', '9', '31']" 803,EP_3605388_A1 (5).png,EP3605388A1,"FACE DETECTION METHOD AND APPARATUS, COMPUTER DEVICE, AND STORAGE MEDIUM","['FIG10', ' FIG11']","['FIG11 is a flowchart of calculating an error of a divided sample image at a node according to an embodiment ', 'FIG10 is a flowchart of determining a division pixel pair of each of nodes according to an embodiment']","['As shown in FIG11, in an embodiment, S1002, that is, repeating for the first preset number of times randomly selecting a pixel pair from the second pixel pair collection to divide the sample images allocated to the node, split the node into new branch nodes, determine branch nodes where the divided sample images are located, and calculate errors of the divided sample images at the node, includes the followings:S 1102: Obtain coordinate information of a pixel pair selected randomly from the second pixel pair collection. ', 'As shown in FIG10, in an embodiment, S904 includes the followings:S1002: Looping or iterating for a first preset number of times: randomly selecting a pixel pair from the second pixel pair collection to divide the sample images allocated to the node, split the node into new branch nodes, determine branch nodes where the divided sample images are located, and calculate errors of the divided sample images at the node.']",38,176,flowchart,G,"[{'element_identifier': '4', 'terms': ['node', 'nodes']}, {'element_identifier': '10', 'terms': ['such as']}]","['1. A face detection method for a computer device, comprising: obtaining a to-be-detected image; obtaining an initial shape of a current regression tree in a pre-constructed probability regression model; extracting image features from the to-be-detected image and respectively calculating a probability of each of leaf nodes of the current regression tree according to the image features; extracting an error of each of the leaf nodes from the current regression tree; determining a shape error of the current regression tree according to the probability and the error of each of the leaf nodes; calculating, by the compute device, an estimated shape of the current regression tree according to the initial shape and the shape error; and performing iterative calculation by using the estimated shape as an initial shape of a neighboring next regression tree until a last regression tree in the probability regression model, to obtain an estimated shape of the last regression tree as a detected face shape.']",True,"['10', '4', '4', '4', '11', '32']" 804,EP_3605407_A1 (3).png,EP3605407A1,"INFORMATION PROCESSING DEVICE, INFORMATION PROCESSING METHOD, AND COMPUTER-READABLE STORAGE MEDIUM",['FIG4'],['FIG4 is a diagram showing the numbers of pieces of training data included in original learning data and subsets according to an embodiment'],"['FIG4 is a diagram showing the numbers of pieces of training data in original learning data and subsets, in a table format. As shown in FIG4, the number of pieces of original first data D1 (data for target task learning) is 1,000,000, and the number of pieces of original second data D2 (data for watermark detection) is 100. On the other hand, in each subset, the number of pieces of first data D1 is 10,000, and the number of pieces of second data D2 is 5,000. Accordingly, in the process of machine learning, it is possible to increase the contribution rate of the second data D2 related to generation of the model parameter P.']",23,129,diagram,G,"[{'element_identifier': '100', 'terms': ['is']}, {'element_identifier': '5000', 'terms': ['G2 is defined as']}]","['2. The information processing apparatus according to claim 1, wherein the acquisition means acquires, as data for the second training data, data whose degree of similarity to a plurality of pieces of data included in the first training data is smaller than a degree of similarity between a plurality of pieces of data included in the first training data.']",False,"['4', '1000000', '100', '10000', '5000', '10000', '5000', '10000', '5000', '13']" 805,EP_3605407_A1 (4).png,EP3605407A1,"INFORMATION PROCESSING DEVICE, INFORMATION PROCESSING METHOD, AND COMPUTER-READABLE STORAGE MEDIUM",['FIG5'],['FIG5 is a flowchart of information processing that is executed by an information processing apparatus according to an embodiment'],"['FIG5 is a flowchart illustrating a flow of information processing that is executed by the information processing apparatus 1 according to an embodiment of the present invention. The processing in this flowchart is started, for example, when the information processing apparatus 1 is started.']",19,48,flowchart,G,"[{'element_identifier': '5', 'terms': ['is']}, {'element_identifier': '2', 'terms': ['storage unit']}]","['2. The information processing apparatus according to claim 1, wherein the acquisition means acquires, as data for the second training data, data whose degree of similarity to a plurality of pieces of data included in the first training data is smaller than a degree of similarity between a plurality of pieces of data included in the first training data.']",False,"['5', '2', '14']" 806,EP_3605422_A1 (3).png,EP3605422A1,"TRANSACTION CONTROL DEVICE, TRANSACTION CONTROL METHOD",['FIG8'],['FIG8 is a diagram illustrating another example of the BC order determination according to the embodiment'],"['FIG8 is a diagram illustrating another example of BC order determination according to the embodiment. As depicted in FIG8, for a plurality of BCs targeted of the transaction, that is, BC-A and BC-B, respective BC information is stored in the BC information table 261. For BC-A, the TX queue size 261b is 2 MB. The block size 261c is 1 MB. For BC-B, the TX queue size 261b is 50 MB. The block size 261c is 10 MB.']",16,98,diagram,G,"[{'element_identifier': '30', 'terms': ['communication unit']}, {'element_identifier': '261', 'terms': ['BC information table']}, {'element_identifier': '20', 'terms': ['library unit']}, {'element_identifier': '10', 'terms': ['application']}, {'element_identifier': '60', 'terms': ['every']}]","['1. A transaction control device comprising: a library unit configured to: perform prediction of a first confirmation time at which first one or more transactions are confirmed in a first blockchain, and prediction of a second confirmation time at which second one or more transactions are confirmed in a second blockchain, perform, based on the predicted first confirmation time and the predicted second confirmation time, determination of an execution order of a plurality of transactions to be executed in the first blockchain and the second blockchain, and execute, based on the determined execution order, the plurality of transactions in the first blockchain and the second blockchain.']",False,"['8', '261', '60', '20', '30', '10', '20']" 807,EP_3605431_A1 (5).png,EP3605431A1,"GOODS ORDER PROCESSING METHOD AND APPARATUS, SERVER, SHOPPING TERMINAL, AND SYSTEM",['FIG15'],"['FIG15 is a schematic structural diagram illustrating modules of another implementation of the apparatus, according to one implementation of the present specification']","['FIG15 is a schematic structural diagram illustrating modules of another implementation of the apparatus, according to one implementation of the present specification. As shown in FIG15, the apparatus can further include the following: a manual scheduling module 106, configured to, if a goods identifier in the associated image fails to be detected, or fails to be detected by using the goods detection model, generate an operation task for the detection failure of the associated image, and place the operation task in a task scheduling queue; and push, based on an obtained network cashier list, the operation task in the task scheduling queue to cashier nodes that satisfy an operation condition, where the network cashier list records processing task operation statuses of cashier nodes.']",23,137,schematic structural diagram,G,"[{'element_identifier': '103', 'terms': []}, {'element_identifier': '104', 'terms': ['order update module']}, {'element_identifier': '105', 'terms': ['information feedback module']}, {'element_identifier': '102', 'terms': ['image recognition module']}, {'element_identifier': '101', 'terms': ['in']}, {'element_identifier': '106', 'terms': ['manual scheduling module']}]","['1. A goods order processing method, wherein the method comprises: detecting, by a client based on an image recognition method, whether a change of the goods occurs in a storage container; if a change of the goods is detected, sending, by the client, an associated image of the change of the goods in the storage container to a server; identifying, by the server, information about the goods difference in the storage container based on the associated image; generating, by the server, corresponding goods order change information by using the difference information; updating, by the server, user order information corresponding to the client based on the goods order change information; sending, by the server, updated user order information to the client; and displaying, by the client, the updated user order information.', '18. A goods order processing apparatus, wherein the apparatus comprises: an image receiving module, configured to receive an associated image uploaded by a client, wherein the associated image comprises an image obtained when the client detects, based on an image recognition method, that a change of the goods occurs in a storage container; an image recognition module, configured to identify information about the goods difference in the storage container based on the associated image; an order generation module, configured to generate corresponding goods order change information by using the difference information; an order update module, configured to update user order information corresponding to the client based on the goods order change information; and an information feedback module, configured to send updated user order information to the client.', '23. The goods order processing apparatus according to claim 22, wherein the apparatus further comprises: a manual scheduling module, configured to, when a goods in the associated image fails to be detected, generate an operation task for the detection failure of the associated image, and place the operation task in a task scheduling queue; and push, based on an obtained network cashier list, the operation task in the task scheduling queue to cashier nodes that satisfy an operation condition, wherein the network cashier list records processing task operation statuses of cashier nodes.']",False,"['101', '102', '103', '106', '104', '105', '15', '38']" 808,EP_3605431_A1 (6).png,EP3605431A1,"GOODS ORDER PROCESSING METHOD AND APPARATUS, SERVER, SHOPPING TERMINAL, AND SYSTEM",['FIG16'],"['FIG16 is a schematic structural diagram illustrating modules of another implementation of the apparatus, according to one implementation of the present specification']","['FIG16 is a schematic structural diagram illustrating modules of another implementation of the apparatus, according to one implementation of the present specification. As shown in FIG16, in another implementation of the apparatus, the apparatus can further include the following: a cashier control module 107, configured to query whether a network cashier in the network cashier list is bound to the operation task; and if yes, send the corresponding operation task to a cashier node of the corresponding bound network cashier for processing.']",23,91,schematic structural diagram,G,"[{'element_identifier': '103', 'terms': []}, {'element_identifier': '104', 'terms': ['order update module']}, {'element_identifier': '105', 'terms': ['information feedback module']}, {'element_identifier': '102', 'terms': ['image recognition module']}, {'element_identifier': '101', 'terms': ['in']}, {'element_identifier': '106', 'terms': ['manual scheduling module']}, {'element_identifier': '107', 'terms': ['cashier control module']}]","['1. A goods order processing method, wherein the method comprises: detecting, by a client based on an image recognition method, whether a change of the goods occurs in a storage container; if a change of the goods is detected, sending, by the client, an associated image of the change of the goods in the storage container to a server; identifying, by the server, information about the goods difference in the storage container based on the associated image; generating, by the server, corresponding goods order change information by using the difference information; updating, by the server, user order information corresponding to the client based on the goods order change information; sending, by the server, updated user order information to the client; and displaying, by the client, the updated user order information.', '18. A goods order processing apparatus, wherein the apparatus comprises: an image receiving module, configured to receive an associated image uploaded by a client, wherein the associated image comprises an image obtained when the client detects, based on an image recognition method, that a change of the goods occurs in a storage container; an image recognition module, configured to identify information about the goods difference in the storage container based on the associated image; an order generation module, configured to generate corresponding goods order change information by using the difference information; an order update module, configured to update user order information corresponding to the client based on the goods order change information; and an information feedback module, configured to send updated user order information to the client.', '23. The goods order processing apparatus according to claim 22, wherein the apparatus further comprises: a manual scheduling module, configured to, when a goods in the associated image fails to be detected, generate an operation task for the detection failure of the associated image, and place the operation task in a task scheduling queue; and push, based on an obtained network cashier list, the operation task in the task scheduling queue to cashier nodes that satisfy an operation condition, wherein the network cashier list records processing task operation statuses of cashier nodes.', '24. The goods order processing apparatus according to claim 23, wherein the apparatus further comprises: a cashier control module, configured to query whether a network cashier in the network cashier list is bound to the operation task; and if a network cashier in the network cashier list is bound to the operation task, send the corresponding operation task to a cashier node of the corresponding bound network cashier for processing.']",False,"['101', '102', '103', '106', '104', '107', '105', '16', '39']" 809,EP_3605467_A1 (1).png,EP3605467A1,"COATING COLOR IDENTIFYING DEVICE, COATING COLOR IDENTIFYING METHOD, COATING COLOR IDENTIFYING PROGRAM, AND COMPUTER-READABLE MEDIUM CONTAINING COATING COLOR IDENTIFYING PROGRAM",['FIG2'],['FIG2 is a flowchart showing an example of an operation of the paint color specifying apparatus in an embodiment'],"['Next, the operation of the paint color specifying apparatus 1 will be described using FIG2. FIG2 is a flowchart showing an example of the operation of the paint color specifying apparatus in an embodiment. The operation of the paint color specifying apparatus 1 shown in the flowchart can be realized by executing the above-described paint color specifying program. A subject of the operation is the paint color specifying apparatus 1 in the following description.', 'In FIG2, the paint color specifying apparatus 1 determines whether a digital image has been acquired (step S11). Determination of whether a digital image has been acquired can be performed, for example, by the image acquiring device 11 determining whether scan data has been acquired from the scanner 31. If it is determined that a digital image has not been acquired (NO in step S11), the paint color specifying apparatus 1 repeats the process of step S11 and waits for acquisition of a digital image.']",19,178,flowchart,G,"[{'element_identifier': '16', 'terms': ['texture information acquiring device']}, {'element_identifier': '4', 'terms': ['server']}]",['1. A paint color specifying apparatus comprising: an image display which causes a display device to display a digital image such that a highlighted portion and a shaded portion of the digital image are able to be designated; a color information acquiring device which acquires color information of the designated highlighted portion and shaded portion; a texture information selection display which causes the display device to display texture information of paint colors such that texture information of a paint color is selectable; a texture information acquiring device which acquires the selected texture information; a color characteristic calculating device which uses a correction coefficient corresponding to the acquired texture information in accordance with the acquired color information and thereby calculates color characteristics of a paint color represented by change in brightness of reflected light according to a reflection angle with respect to incident light; and a paint color specifying device which specifies a paint color in accordance with the calculated color characteristics.'],False,"['4', '16']" 810,EP_3605467_A1 (2).png,EP3605467A1,"COATING COLOR IDENTIFYING DEVICE, COATING COLOR IDENTIFYING METHOD, COATING COLOR IDENTIFYING PROGRAM, AND COMPUTER-READABLE MEDIUM CONTAINING COATING COLOR IDENTIFYING PROGRAM",['FIG3'],['FIG3 is a diagram showing an example of a relationship between incident light and reflection angles of reflected light in the paint color specifying apparatus in an embodiment'],"['The spectrophotometer measures a spectral reflectance by measuring the intensity of reflected light from a painted surface in radiated light through a photodiode using monochromatic light every 10 nm in wavelengths of 400 to 700 nm, of a light source. The spectrophotometer measures intensity according to a light-receiving angle (reflection angle) of reflected light for incident light. Note that, a light-receiving angle in the spectrophotometer will be described in detail later using FIG3.', 'Next, a relationship between incident light and reflection angles of reflected light will be described using FIG3. FIG3 is a diagram showing an example of a relationship between incident light and reflection angles of reflected light in the paint color specifying apparatus in an embodiment.', 'In FIG3, when the direction perpendicular to a painted surface is assumed to be 0°, incident light enters in a direction of -45° with respect to the perpendicular direction. The incident light is reflected on the painted surface to become reflected light. FIG3 shows that a paint contains a metallic flake pigment and a clear layer is provided on the painted surface. The paint containing the metallic flake pigment is a paint color having a strong impression of shade (a large FF value) in general.']",28,229,diagram,G,"[{'element_identifier': '15', 'terms': ['texture information selection display']}, {'element_identifier': '17', 'terms': []}, {'element_identifier': '0', 'terms': ['tone as FF68 approaches']}]",['1. A paint color specifying apparatus comprising: an image display which causes a display device to display a digital image such that a highlighted portion and a shaded portion of the digital image are able to be designated; a color information acquiring device which acquires color information of the designated highlighted portion and shaded portion; a texture information selection display which causes the display device to display texture information of paint colors such that texture information of a paint color is selectable; a texture information acquiring device which acquires the selected texture information; a color characteristic calculating device which uses a correction coefficient corresponding to the acquired texture information in accordance with the acquired color information and thereby calculates color characteristics of a paint color represented by change in brightness of reflected light according to a reflection angle with respect to incident light; and a paint color specifying device which specifies a paint color in accordance with the calculated color characteristics.'],False,"['0', '25', '15', '75', '110', '17']" 811,EP_3605467_A1 (5).png,EP3605467A1,"COATING COLOR IDENTIFYING DEVICE, COATING COLOR IDENTIFYING METHOD, COATING COLOR IDENTIFYING PROGRAM, AND COMPUTER-READABLE MEDIUM CONTAINING COATING COLOR IDENTIFYING PROGRAM",['FIG8'],['FIG8 is a diagram showing an example of the method of calculating a correction coefficient used in the paint color specifying apparatus in an embodiment'],"['FIG8 has data items of ""name,"" ""FF68,"" ""r(Y15-Y75),"" ""ar(Y15-Y25),"" ""br(Y25-Y45)."" ""cr(Y45-Y75)"" and ""d(Y110/Y75)."" In FIG8, ""r(Y15-Y75)"" becomes ""1"" in each piece of texture information and values of each data item are modified in proportion to this. Accordingly, a Y value difference in each piece of texture information is normalized. The data item of ""d(Y1J0/Y75)"" represents Y110 and Y75, that is, a magnitude of brightness change in a shaded portion.', 'The normalized widths of the Y values shown in FIG8 are stored in the correction coefficient storage 17 as correction coefficients, read by the color characteristic calculating device 18 and used to calculate color characteristics.', 'In formulas 3 to 5, Y15 and Y75 are known values because they are numerical values designated from a digital image. Y110 is calculated from Y75 that is known. ar, br and d are correction coefficients ""ar(Y15-Y25),"" ""br(Y25-Y45)"" and ""d(Y110/Y75)"" described in FIG8. Y45 is calculated when Y110 is calculated and Y25 is calculated when Y45 is calculated. The data item of ""calculation order"" indicates a calculation order of these Y values.']",25,259,diagram,G,"[{'element_identifier': '20', 'terms': ['paint color specifying device']}]",['1. A paint color specifying apparatus comprising: an image display which causes a display device to display a digital image such that a highlighted portion and a shaded portion of the digital image are able to be designated; a color information acquiring device which acquires color information of the designated highlighted portion and shaded portion; a texture information selection display which causes the display device to display texture information of paint colors such that texture information of a paint color is selectable; a texture information acquiring device which acquires the selected texture information; a color characteristic calculating device which uses a correction coefficient corresponding to the acquired texture information in accordance with the acquired color information and thereby calculates color characteristics of a paint color represented by change in brightness of reflected light according to a reflection angle with respect to incident light; and a paint color specifying device which specifies a paint color in accordance with the calculated color characteristics.'],False,['20'] 812,EP_3605473_A1 (2).png,EP3605473A1,"FACIAL RECOGNITION SYSTEM, DEVICE, METHOD AND PROGRAM",['FIG2B'],['FIG2B is a diagram illustrating a gate using a wireless tag (remote IC card)'],"['When the wireless tag 20A of the user A enters into a wireless area of the reader 102 provided at the other side (exit side) of the longitudinal direction of the gate apparatus 100, communicates with the reader 102 and replies the ID of the wireless tag 20A, and the reader 102 receives the ID, collation whether or not the facial feature value of the users A and B acquired in advance match the facial feature value extracted from image data captured by the camera 103 (for instance the facial feature value of the user A extracted from the image data) is performed. When the extracted facial feature value match one of the acquired facial feature values (the facial feature values corresponding to the IDs received by the reader 101) as a result of the collation, a gate (for instance refer to the flapper gate in FIG2B) of the gate apparatus 100 remains open.']",16,168,diagram,G,"[{'element_identifier': '28', 'terms': ['Note']}, {'element_identifier': '3', 'terms': ['lane']}, {'element_identifier': '2', 'terms': ['feature value', 'feature values']}, {'element_identifier': '1', 'terms': ['Supplementary Notes', 'Supplementary Note']}]","['1. A gate apparatus comprising: a reader part that receives one or more identifiers transmitted by one or more wireless tags of one or more users entering a wireless area located outside one end of a longitudinal direction of a gate; an acquisition part that acquires one or more individual facial feature values registered in association with the one or more identifiers received from the one or more wireless tags; an imaging part that captures image of the user; an extraction part that extracts a facial feature value from image data captured by the imaging part; and a face collation part that receives the facial feature value extracted by the extraction part and performs collation to check whether or not the feature value extracted matches any one of one or more facial feature values acquired by the acquisition part.', '12. The gate apparatus according to any one of claims 1 to 11, wherein the imaging part captures image of the user, when a sensor that monitors progress of the user in a lane inside the gate detects the user.']",False,"['1', '2', '3', '28']" 813,EP_3605473_A1 (3).png,EP3605473A1,"FACIAL RECOGNITION SYSTEM, DEVICE, METHOD AND PROGRAM",['FIG11'],['FIG11 is a diagram illustrating an example of a reader according to the second example embodiment of the present invention'],"['FIG11 is a diagram illustrating a configuration example of the reader 101 (or 102) of the second example embodiment. The reader 101 includes directional antennas 1011A and 1011B, RF (Radio Frequency) circuits 1012A and 1012B including a transmitter that converts a frequency of a transmission signal to a RF (Radio Frequency), power-amplifies the RF transmission signal and transmits the signal from the antennas 1011A and 1011B, and a receiver that amplifies a RF signal received by the antennas 1011A and 1011B and converts a frequency of the reception signal into an intermediate frequency, a control circuit 1013 that transmits/receives a transmission/reception signal to/from the RF circuits 1012A and 1012B, and a communication interface 1014. The readers 101A and 101B are constituted by the antennas 1011A and 1011B, and the RF circuit 1012A and 1012B.', 'The control circuit 1013 of the reader 101 in FIG11 adds, to an ID signal received from the RF circuits 1012A and 1012B, an identification code indicating from which antenna the ID signal is received and notifies the communication interface 105. The direction control part 120 is able to identify which antenna (1011A or 1011B) has received the ID signal. Similarly, regarding the reader 102, the direction control part 120 is able to identify which reader (102A or 102B) has received an ID signal.']",20,252,diagram,G,"[{'element_identifier': '11', 'terms': ['user']}, {'element_identifier': '1013', 'terms': ['control circuit']}, {'element_identifier': '40', 'terms': ['data server']}, {'element_identifier': '105', 'terms': ['interfaces', 'interface']}, {'element_identifier': '101', 'terms': ['reader', 'readers']}, {'element_identifier': '1014', 'terms': ['communication interface']}]","['1. A gate apparatus comprising: a reader part that receives one or more identifiers transmitted by one or more wireless tags of one or more users entering a wireless area located outside one end of a longitudinal direction of a gate; an acquisition part that acquires one or more individual facial feature values registered in association with the one or more identifiers received from the one or more wireless tags; an imaging part that captures image of the user; an extraction part that extracts a facial feature value from image data captured by the imaging part; and a face collation part that receives the facial feature value extracted by the extraction part and performs collation to check whether or not the feature value extracted matches any one of one or more facial feature values acquired by the acquisition part.', '16. The facial authentication system according to claim 15, comprising a data server that stores in advance a facial feature value of the user in association with an identifier stored in a wireless tag of the user, wherein the acquisition part transmits a search request including an identifier of a wireless tag received by the reader part to the data server before an image of the user entering the gate is captured, and acquires a facial feature value corresponding to the identifier from the data server.']",False,"['11', '101', '1013', '1014', '105', '40']" 814,EP_3605480_A1 (1).png,EP3605480A1,PAPER SHEET PROCESSING DEVICE,['FIG2'],['FIG2 is a schematic configuration view from the front side showing the state of the receiving part of the paper sheet processing device pulled out and the conveyance unit opened up'],"['In the paper sheet processing device 1, the receiving part 11 and the identification main body unit 24 are disposed so that the positions thereof overlap in the vertical direction and the front-rear direction. Furthermore, the receiving part 11 and the identification main body unit 24 are provided side by side in the left-right direction of the lateral direction. As shown in FIG2, the receiving part 11 is removable to the right side, which is one side in the left-right direction, that is, the opposite side to the identification main body unit 24 (the in-sorting-accumulating unit conveyance constituent unit 27), with respect to a device main body 81 excluding the receiving part 11 of the paper sheet processing device 1. Further, the receiving part 11 can be pushed to the left side, which is the other side in the left-right direction, that is, the identification main body unit 24 side, with respect to the device main body 81 excluding the receiving part 11 of the paper sheet processing device 1. With this configuration, a jammed paper sheet in the leftward extension part 21a can be easily removed by pulling the receiving part 11 to the right to open the leftward extension part 21a.']",31,235,schematic view,B,"[{'element_identifier': '23', 'terms': ['detection unit']}, {'element_identifier': '30', 'terms': ['conveyance unit']}, {'element_identifier': '12', 'terms': ['lower reject accumulating part']}, {'element_identifier': '14', 'terms': ['post-count accumulating part', 'post-count accumulating parts']}, {'element_identifier': '2', 'terms': ['base unit']}, {'element_identifier': '81', 'terms': ['device main body']}, {'element_identifier': '21', 'terms': []}, {'element_identifier': '82', 'terms': ['constituent part']}, {'element_identifier': '3', 'terms': ['sorting-accumulating unit', 'sorting-accumulating units']}, {'element_identifier': '83', 'terms': ['constituent part']}, {'element_identifier': '13', 'terms': []}]","['1. A paper sheet processing device comprising: a receiving part which opens to an exterior of the device, in which paper sheets from the exterior of the device are set, and which dispenses the set paper sheets in a stacked state, one by one; a conveyance unit which conveys the paper sheets dispensed from the receiving part; an identification unit which identifies whether the paper sheets that are being conveyed by the conveyance unit are a to-be-counted paper sheet or a reject paper sheet, and which counts a paper sheet identified as the to-be-counted paper sheet; a post-count accumulating part which accumulates the counted paper sheet; and a plurality of reject accumulating parts which accumulate, in a state sorted by reason for rejection, a paper sheet identified as the reject paper sheet.', '7. The paper sheet processing device according to any one of claims 1 to 6, wherein the receiving part and the identification unit are aligned in a lateral direction, the receiving part is configured to be capable to being pulled out from a device main body in the lateral direction to an opposite side of the identification unit, and the identification unit and the conveyance unit are opened in a state in which the receiving part is pulled out in the lateral direction from the device main body.', '8. The paper sheet processing device according to any one of claims 1 to 7, further comprising: a base unit which comprises an in-base unit conveyance constituent unit, the receiving part, the identification unit, and the reject accumulating part, the in-base unit conveyance constituent unit constituting the conveyance unit; a first processing unit which comprises a first in-processing unit conveyance constituent unit and the post-count accumulating part, the first in-processing unit conveyance constituent unit constituting the conveyance unit; and a second processing unit which comprises a second in-processing unit conveyance constituent unit which constitutes the conveyance unit, wherein the first processing unit is adjacent to the second processing unit, and placed between the base unit and the second processing unit, the first in-processing unit conveyance constituent unit comprises: a coupling conveyance constituent unit which connects the in-base unit conveyance constituent unit and the second in-processing unit conveyance constituent unit; and a branching conveyance constituent unit which branches from the coupling conveyance constituent unit and is connected to the post-count accumulating part, and the coupling conveyance constituent unit and the branching conveyance constituent unit are independently driven.']",False,"['2', '3', '14', '13', '14', '82', '14', '12', '83', '14', '30', '21', '81', '23']" 815,EP_3605480_A1 (3).png,EP3605480A1,PAPER SHEET PROCESSING DEVICE,['FIG5'],['FIG5 is a flowchart of the sorting process of the first operation mode of the paper sheet processing device shown in FIG1'],"['As described above, the first operation mode is executed in a state in which the type of the paper sheet S serving as the to-be-counted paper sheet to be accumulated in each post-count accumulating part 14 has been set. In the first operation mode, in a state in which such a setting has been performed, when the paper sheets S are set in a stacked state in the receiving part 11 and the start operation of one sorting process is input to the operation display unit 31, the control unit 32 performs control following to the flowchart shown in FIG5 with regard to the paper sheets S placed in the receiving part 11.', 'By such notification, the operator sets the paper sheet S accumulated in the lower reject accumulating part 12 in the receiving part 11, and inputs the restart operation for one sorting process to the operation display unit 31. Then, the control unit 32 again performs control according to the flowchart shown in FIG5 with regard to paper sheets S placed again in the receiving part 11. As a result, the paper sheet S accumulated in the lower reject accumulating part 12 is again identified by the identification unit 22. For the paper sheet S that has been identified as having no conveyance abnormality (Step Sa3: NO), no identification abnormality (Step Sa6: NO), a destination (Step Sa8: YES), and a destination that is not full (Step Sa9: NO), the control unit 32 adds one to the count value of that type, that is, that denomination. Further, the control unit 32 controls the conveyance unit 30 to convey the paper sheet S to the corresponding post-count accumulating part 14 to be accumulated.']",22,326,flowchart,B,"[{'element_identifier': '5', 'terms': ['accumulate']}]","['1. A paper sheet processing device comprising: a receiving part which opens to an exterior of the device, in which paper sheets from the exterior of the device are set, and which dispenses the set paper sheets in a stacked state, one by one; a conveyance unit which conveys the paper sheets dispensed from the receiving part; an identification unit which identifies whether the paper sheets that are being conveyed by the conveyance unit are a to-be-counted paper sheet or a reject paper sheet, and which counts a paper sheet identified as the to-be-counted paper sheet; a post-count accumulating part which accumulates the counted paper sheet; and a plurality of reject accumulating parts which accumulate, in a state sorted by reason for rejection, a paper sheet identified as the reject paper sheet.']",False,"['5', '26']" 816,EP_3605494_A1 (2).png,EP3605494A1,LASER LIGHT SOURCE DEVICE AND PARKING INDICATOR LIGHT SYSTEM INCLUDING SAME,['FIG3'],['FIG3 is a block diagram of a laser light source device according to an embodiment of the present invention'],"['FIG3 is a block diagram of the laser light source device 100 according to an embodiment of the present invention.', 'Referring to FIG3, the laser light source device 100 may include the light source unit 110, the optical unit 120, and the controller 130, wherein the light source unit 110 outputs a laser beam of the first light path L1 traveling straight to the front in a point shape, the optical unit 120 is disposed on the first light path L1 and includes a lens having at least one prism pattern formed thereon that deflects the light of the first light path L1 into the light of the second light path L2 in a line shape, and the controller 130 controls an incident angle of the light of the first light path L1 with respect to the optical unit 120 so as for the line shape to have a curvature.']",19,159,block diagram,G,"[{'element_identifier': '121', 'terms': ['prism pattern lens']}, {'element_identifier': '130', 'terms': ['controller']}, {'element_identifier': '100', 'terms': ['laser light source device']}, {'element_identifier': '10', 'terms': ['vehicle']}, {'element_identifier': '131', 'terms': ['actuator']}, {'element_identifier': '132', 'terms': ['control signal receiver']}, {'element_identifier': '110', 'terms': ['light source unit']}, {'element_identifier': '120', 'terms': ['optical unit']}]","['1. A laser light source device comprising: a light source unit for outputting a laser beam of a first light path traveling straight to the front in a point form; an optical unit being disposed on the first light path and comprising a lens having at least one prism pattern formed thereon that deflects the light of the first light path into light of a second light path in a line shape; and a controller for controlling an incident angle of the light of the first light path with respect to the optical unit 120 so as for the line shape to have a curvature.', '6. The laser light source device of claim 5, wherein the controller comprises: a control signal receiver connected with a control device by an 12C method; and an actuator for changing an angle of the incident surface according to a control signal received through the control signal receiver.', '7. The laser light source device of claim 6, wherein the controller turns on or off the light source unit in response to the control signal included an approach or entry of a vehicle sensed by the sensor.']",False,"['3', '100', '110', '120', '121', '131', '130', '132', '10']" 817,EP_3605515_A1 (3).png,EP3605515A1,BACKLIGHT ADJUSTING METHOD AND BACKLIGHT ADJUSTING DEVICE,['FIG6'],['FIG6 is a block diagram illustrating a device 800 for adjusting backlight according to an embodiment of the present disclosure '],"['FIG6 is a block diagram illustrating a device 800 for adjusting backlight according to an embodiment of the present disclosure. For example, the device 800 may be a mobile phone, a computer, a digital broadcast device, a messaging transeivor device, a game console, a tablet device, a medical device, a fitness device, a personal digital assistant, and the like.', 'As illustrated in FIG6, the device 800 may include one or more components as follows: a processor component 802, a memory 804, an electric power source assembly 806, a multimedia component 808, an audio component 810, an input/output (I/O) interface 812, a sensor assembly 814 and communication operation 816.']",20,136,block diagram,G,"[{'element_identifier': '812', 'terms': ['interface']}, {'element_identifier': '804', 'terms': ['memory']}, {'element_identifier': '820', 'terms': []}, {'element_identifier': '816', 'terms': ['communication component']}, {'element_identifier': '802', 'terms': ['component']}, {'element_identifier': '814', 'terms': ['sensor component']}, {'element_identifier': '800', 'terms': ['device']}, {'element_identifier': '808', 'terms': ['multimedia component']}, {'element_identifier': '806', 'terms': ['power component']}]","['1. A method for adjusting backlight of a device, comprising: obtaining (S11) an ambient illuminance; adjusting (S12) a screen backlight brightness value of the device to be greater than a preset maximum brightness value when the obtained ambient illuminance is greater than an illuminance threshold; detecting (S13) a temperature value of the device through a first temperature sensor installed in the device; and adjusting (S14) the screen backlight brightness value of the device to be lower than or equal to the preset maximum brightness value when the temperature value of the device detected by the first temperature sensor is greater than a termperature threshold.']",False,"['802', '800', '804', '816', '806', '808', '820', '814', '812', '6', '14']" 818,EP_3605530_A1 (2).png,EP3605530A1,METHOD AND APPARATUS FOR RESPONDING TO A VOICE COMMAND,['FIG3'],['FIG3 shows schematically the user being presented with a response that contains a small number of options'],"['Referring to FIG3, in this example a user 301 issues a voice command 302 which is received at the apparatus (not shown in FIG3) either directly or indirectly via a user device (not shown in FIG3). The apparatus formulates a response 303 to the voice command 302. In this example, the response 303 contains a small number of options 303A, 303B (here, two options), which does not exceed the threshold for the number of options (here, two options). Accordingly, the apparatus causes the response 303, specifically the options 303A, 303B, to be presented audibly to the user 301. The user 301 selects 304 one of the options. In an example, the user 301 may select an option using a voice command. Upon selection of the option, the apparatus responds 305 by taking some action in response to the selection of the option by the user 301.']",17,173,schematic,G,"[{'element_identifier': '304', 'terms': ['selects']}, {'element_identifier': '303', 'terms': ['response']}, {'element_identifier': '302', 'terms': ['voice command']}, {'element_identifier': '301', 'terms': ['user']}, {'element_identifier': '10', 'terms': ['may be say']}, {'element_identifier': '3', 'terms': ['may be say']}, {'element_identifier': '305', 'terms': ['apparatus responds']}]","['1. A computer-implemented method of responding to a voice command received from a user, the method comprising: receiving a voice command from a user; processing the received voice command to formulate a response for the user; and providing the response to the user; wherein the response is selectively provided to the user in an audio format or in a visual format depending on one or more characteristics of the response.']",False,"['301', '302', '301', '304', '303', '305', '3', '10']" 819,EP_3605530_A1.png,EP3605530A1,METHOD AND APPARATUS FOR RESPONDING TO A VOICE COMMAND,['FIG1'],['FIG1 shows schematically an example of a user interacting with apparatus for responding to a voice command'],"['FIG1 shows schematically an example of a user 101 interacting with apparatus 102 for responding to a voice command 103 from the user 101 according to the present disclosure.', 'Also shown schematically in FIG1 is a display screen 107. The display screen 107 is in communication with the apparatus 102 and is capable of displaying visually at least responses that are provided by the apparatus 102 for the user 101.']",17,74,schematic,G,"[{'element_identifier': '103', 'terms': ['command', 'commands']}, {'element_identifier': '104', 'terms': ['microphone']}, {'element_identifier': '105', 'terms': ['user device']}, {'element_identifier': '102', 'terms': ['apparatus']}, {'element_identifier': '101', 'terms': ['user']}, {'element_identifier': '106', 'terms': ['microphone']}, {'element_identifier': '107', 'terms': ['display screen']}]","['1. A computer-implemented method of responding to a voice command received from a user, the method comprising: receiving a voice command from a user; processing the received voice command to formulate a response for the user; and providing the response to the user; wherein the response is selectively provided to the user in an audio format or in a visual format depending on one or more characteristics of the response.', '6. A method according to any of claims 1 to 5, wherein the method is performed by an apparatus which comprises a display screen for display of a response in a visual format.']",False,"['103', '107', '101', '104', '106', '102', '105', '1', '8']" 820,EP_3605532_A1 (2).png,EP3605532A1,AUDIO ENCODER AND DECODER,['FIG5'],['FIG5 is a generalized block diagram of an audio decoding system in accordance with an example embodiment'],"['FIG5 is a generalized block diagram of an audio decoding system 500 for recreating encoded audio objects from a coded downmix signal 510 and a coded upmix matrix 512. The coded downmix signal 510 is received by a downmix receiving component 506 where the signal is decoded and, if not already in a suitable frequency domain, transformed to a suitable frequency domain. The decoded downmix signal 516 is then sent to the upmix component 508. In the upmix component 508, the encoded audio objects are recreated using the decoded downmix signal 516 and a decoded upmix matrix 504. More specifically, the upmix component 508 may perform a matrix operation in which the decoded upmix matrix 504 is multiplied by a vector comprising the decoded downmix signals 516. The decoding process of the upmix matrix is described below. The audio decoding system 500 further comprises a rendering component 514 which output an audio signal based on the reconstructed audio objects 518 depending on what type of playback unit that is connected to the audio decoding system 500.']",17,187,block diagram,G,"[{'element_identifier': '5', 'terms': ['e.g.']}, {'element_identifier': '502', 'terms': ['decoder']}, {'element_identifier': '606', 'terms': ['component']}, {'element_identifier': '9', 'terms': ['max value is']}, {'element_identifier': '506', 'terms': ['downmix receiving component']}, {'element_identifier': '508', 'terms': ['upmix component']}, {'element_identifier': '514', 'terms': ['rendering component']}, {'element_identifier': '500', 'terms': ['audio decoding system']}, {'element_identifier': '516', 'terms': ['decoded downmix signal', 'decoded downmix signals']}, {'element_identifier': '504', 'terms': ['decoded upmix matrix']}, {'element_identifier': '602', 'terms': ['receiving component']}, {'element_identifier': '518', 'terms': ['reconstructed audio objects']}, {'element_identifier': '604', 'terms': ['indexing component']}, {'element_identifier': '510', 'terms': ['coded downmix signal']}, {'element_identifier': '23', 'terms': ['filed']}, {'element_identifier': '512', 'terms': ['coded upmix matrix']}, {'element_identifier': '608', 'terms': ['decoding component']}]","['4. An encoder (100) for encoding an upmix matrix in an audio encoding system (100), each row of the upmix matrix comprising M elements allowing reconstruction of a time/frequency tile of an audio object from a downmix signal comprising M channels, the encoder comprising: a receiving component adapted to receive each row in the upmix matrix; a selection component adapted to select a subset of elements from the M elements of the row in the upmix matrix, wherein the selected subset of elements comprises the same number of elements for each row of the upmix matrix; an encoding component adapted to represent each element in the selected subset of elements by a value and a position in the upmix matrix, the encoding component further adapted to encode the value and the position in the upmix matrix of each element in the selected subset of elements wherein, for each row in the upmix matrix and for a plurality of frequency bands or a plurality of time frames, the values of the elements and/or the positions of the elements of the selected subsets of elements form one or more vectors (114, 902, 1002) of parameters, each parameter in the vector of parameters corresponding to one of the plurality of frequency bands or the plurality of time frames, the vector of parameters having a first element (1002) and at least one second element (902), wherein the encoding component is adapted to encode the one or more vectors of parameters by for each vector: representing (S702, S802) each parameter in the vector by an index value which takes one of N possible values; associating each of the at least one second element with a symbol, the symbol being calculated by: calculating (S704) a difference between the index value of the second element and the index value of its preceding element in the vector; applying (S706) modulo N to the difference; encoding (S708) each of the at least one second element by entropy coding of the symbol associated with the at least one second element based on a probability table comprising probabilities of the symbols associating the first element in the vector with a symbol, the symbol being calculated by: shifting (S804) the index value representing the first element in the vector by subtracting an off-set value from the index value; applying (S806) modulo N to the shifted index value; encoding the first element by entropy coding of the symbol associated with the first element using the same probability table that is used to encode the at least one second element.', '5. A method for reconstructing a time/frequency tile of an audio object in an audio decoding system (1200), comprising: receiving a downmix signal (1210) comprising M channels; receiving at least one encoded element (1204) representing a subset of M elements of a row in an upmix matrix, each encoded element comprising a value and a position in the row in the upmix matrix, the position indicating one of the M channels of the downmix signal to which the encoded element corresponds; and reconstructing (1208) the time/frequency tile of the audio object from the downmix signal by forming a linear combination of the downmix channels that correspond to the at least one encoded element, wherein in said linear combination each downmix channel is multiplied by the value of its corresponding encoded element wherein, for a plurality of frequency bands or a plurality of time frames, the values and/or the positions of the at least one encoded element form one or more vectors (1214), wherein the positions of the at least one encoded element vary across a plurality of frequency bands and/or across a plurality of time frames, wherein each position is represented by an entropy coded symbol, wherein each symbol in each vector of entropy coded symbols corresponds to one of the plurality of frequency bands or the plurality of time frames, and wherein the one or more vectors of entropy coded symbols are decoded into one or more vectors of parameters, wherein each vector of entropy coded symbols comprises a first entropy coded symbol and at least one second entropy coded symbol and wherein each vector of parameters comprises a first element and at least one second element, wherein the decoding of each of the one or more vectors of entropy coded symbols comprises: representing each entropy coded symbol in the vector of entropy coded symbols by a symbol which may take N integer values by using a probability table; associating the first entropy coded symbol with an index value; associating each of the at least one second entropy coded symbol with an index value, the index value of the at least one second entropy coded symbol being calculated by: calculating the sum of the index value associated with the of entropy coded symbol preceding the second entropy coded symbol in the vector of entropy coded symbols and the symbol representing the second entropy coded symbol; and applying modulo N to the sum; and representing the at least one second element of the vector of parameters by a parameter value corresponding to the index value associated with the at least one second entropy coded symbol, wherein the step of representing each entropy coded symbol in the vector of entropy coded symbols by a symbol is performed using the same probability table for all entropy coded symbols in the vector of entropy coded symbols, wherein the index value associated with the first entropy coded symbol is calculated by: shifting the symbol representing the first entropy coded symbol in the vector of entropy coded symbols by adding an off-set value to the symbol; and applying modulo N to the shifted symbol, wherein the method further comprises the step of: representing the first element of the vector of parameters by a parameter value corresponding to the index value associated with the first entropy coded symbol.', '7. A decoder (1200) for reconstructing a time/frequency tile of an audio object, comprising: a receiving component (1206) configured to receive a downmix signal (1210) comprising M channels and at least one encoded element (1204) representing a subset of M elements of a row in an upmix matrix, each encoded element comprising a value and a position in the row in the upmix matrix, the position indicating one of the M channels of the downmix signal to which the encoded element corresponds; and a reconstructing component (1208) configured to reconstruct the time/frequency tile of the audio object from the downmix signal by forming a linear combination of the downmix channels that correspond to the at least one encoded element, wherein in said linear combination each downmix channel is multiplied by the value of its corresponding encoded element, wherein, for a plurality of frequency bands or a plurality of time frames, the values and/or the positions of the at least one encoded element form one or more vectors (1214), wherein the positions of the at least one encoded element vary across a plurality of frequency bands and/or across a plurality of time frames, wherein each position is represented by an entropy coded symbol, wherein each symbol in each vector of entropy coded symbols corresponds to one of the plurality of frequency bands or the plurality of time frames, and wherein the decoder further comprises a decoding component (1202) configured to decode the one or more vectors of entropy coded symbols into one or more vectors of parameters, wherein each vector of entropy coded symbols comprises a first entropy coded symbol and at least one second entropy coded symbol and wherein each vector of parameters comprises a first element and at least one second element, wherein the decoding component is configured to decode each of the one or more vectors of entropy coded symbols by: representing each entropy coded symbol in the vector of entropy coded symbols by a symbol which may take N integer values by using a probability table; associating the first entropy coded symbol with an index value; associating each of the at least one second entropy coded symbol with an index value, the index value of the at least one second entropy coded symbol being calculated by: calculating the sum of the index value associated with the of entropy coded symbol preceding the second entropy coded symbol in the vector of entropy coded symbols and the symbol representing the second entropy coded symbol; applying modulo N to the sum; representing the at least one second element of the vector of parameters by a parameter value corresponding to the index value associated with the at least one second entropy coded symbol, wherein the step of representing each entropy coded symbol in the vector of entropy coded symbols by a symbol is performed using the same probability table for all entropy coded symbols in the vector of entropy coded symbols, wherein the index value associated with the first entropy coded symbol is calculated by: shifting the symbol representing the first entropy coded symbol in the vector of entropy coded symbols by adding an off-set value to the symbol; applying modulo N to the shifted symbol; and representing the first element of the vector of parameters by a parameter value corresponding to the index value associated with the first entropy coded symbol.']",True,"['500', '510', '506', '508', '514', '516', '518', '502', '512', '504', '5', '502', '602', '604', '606', '9', '608', '23']" 821,EP_3605532_A1 (5).png,EP3605532A1,AUDIO ENCODER AND DECODER,['FIG12'],['FIG12 is a generalized block diagram of an audio decoding system in accordance with an example embodiment'],"['FIG12 is a generalized block diagram of an audio decoding system 1200 in accordance with an example embodiment. The decoder 1200 comprises a receiving component 1206 configured to receive a downmix signal 1210 comprising M channels and at least one encoded element 1204 representing a subset of M elements of a row in an upmix matrix. Each of the encoded elements comprises a value and a position in the row in the upmix matrix, the position indicating one of the M channels of the downmix signal 1210 to which the encoded element corresponds. The at least one encoded element 1204 is decoded by an upmix matrix element decoding component 1202. The upmix matrix element decoding component 1202 is configured to decode the at least one encoded element 1204 according to the encoding strategy used for encoding the at least one encoded element 1204. Examples on such encoding strategies are disclosed above. The at least one decoded element 1214 is then sent to the reconstructing component 1208 which is configured to reconstruct a time/frequency tile of the audio object from the downmix signal 1210 by forming a linear combination of the downmix channels that correspond to the at least one encoded element 1204. When forming the linear combination each downmix channel is multiplied by the value of its corresponding encoded element 1204.']",17,232,block diagram,G,"[{'element_identifier': '1104', 'terms': ['selection component']}, {'element_identifier': '1204', 'terms': ['encoded element']}, {'element_identifier': '12', 'terms': ['frequency bands are']}, {'element_identifier': '1216', 'terms': ['rendering component']}, {'element_identifier': '11', 'terms': ['decoder side is', 'EEE']}, {'element_identifier': '1210', 'terms': ['downmix signal']}, {'element_identifier': '1218', 'terms': ['reconstructed audio object']}, {'element_identifier': '1214', 'terms': ['decoded element']}, {'element_identifier': '1208', 'terms': ['reconstructing component']}, {'element_identifier': '1202', 'terms': ['matrix element decoding component']}, {'element_identifier': '1106', 'terms': ['encoding component']}, {'element_identifier': '1102', 'terms': ['receiving component']}, {'element_identifier': '1206', 'terms': ['receiving component']}, {'element_identifier': '1200', 'terms': ['audio decoding system']}]","['1. A method for encoding an upmix matrix in an audio encoding system (100), each row of the upmix matrix comprising M elements allowing reconstruction of a time/frequency tile of an audio object from a downmix signal comprising M channels, the method comprising: for each row in the upmix matrix: selecting a subset of elements from the M elements of the row in the upmix matrix, wherein the selected subset of elements comprises the same number of elements for each row of the upmix matrix; representing each element in the selected subset of elements by a value and a position in the upmix matrix; encoding the value and the position in the upmix matrix of each element in the selected subset of elements, wherein, for each row in the upmix matrix and for a plurality of frequency bands or a plurality of time frames, the values of the elements and/or the positions of the elements of the selected subsets of elements form one or more vectors (114, 902, 1002) of parameters, each parameter in the vector of parameters corresponding to one of the plurality of frequency bands or the plurality of time frames, wherein each vector of the one or more vectors of parameters has a first element (1002) and at least one second element (902), and wherein the one or more vectors of parameters are encoded by: representing (S702, S802) each parameter in the vector by an index value which takes one of N possible values; associating each of the at least one second element with a symbol, the symbol being calculated by: calculating (S704) a difference between the index value of the second element and the index value of its preceding element in the vector; and applying (S706) modulo N to the difference; encoding (S708) each of the at least one second element by entropy coding of the symbol associated with the at least one second element based on a probability table comprising probabilities of the symbols; associating the first element in the vector with a symbol, the symbol being calculated by: shifting (S804) the index value representing the first element in the vector by subtracting an off-set value from the index value; and applying (S806) modulo N to the shifted index value; and encoding the first element by entropy coding of the symbol associated with the first element using the same probability table that is used to encode the at least one second element.', '4. An encoder (100) for encoding an upmix matrix in an audio encoding system (100), each row of the upmix matrix comprising M elements allowing reconstruction of a time/frequency tile of an audio object from a downmix signal comprising M channels, the encoder comprising: a receiving component adapted to receive each row in the upmix matrix; a selection component adapted to select a subset of elements from the M elements of the row in the upmix matrix, wherein the selected subset of elements comprises the same number of elements for each row of the upmix matrix; an encoding component adapted to represent each element in the selected subset of elements by a value and a position in the upmix matrix, the encoding component further adapted to encode the value and the position in the upmix matrix of each element in the selected subset of elements wherein, for each row in the upmix matrix and for a plurality of frequency bands or a plurality of time frames, the values of the elements and/or the positions of the elements of the selected subsets of elements form one or more vectors (114, 902, 1002) of parameters, each parameter in the vector of parameters corresponding to one of the plurality of frequency bands or the plurality of time frames, the vector of parameters having a first element (1002) and at least one second element (902), wherein the encoding component is adapted to encode the one or more vectors of parameters by for each vector: representing (S702, S802) each parameter in the vector by an index value which takes one of N possible values; associating each of the at least one second element with a symbol, the symbol being calculated by: calculating (S704) a difference between the index value of the second element and the index value of its preceding element in the vector; applying (S706) modulo N to the difference; encoding (S708) each of the at least one second element by entropy coding of the symbol associated with the at least one second element based on a probability table comprising probabilities of the symbols associating the first element in the vector with a symbol, the symbol being calculated by: shifting (S804) the index value representing the first element in the vector by subtracting an off-set value from the index value; applying (S806) modulo N to the shifted index value; encoding the first element by entropy coding of the symbol associated with the first element using the same probability table that is used to encode the at least one second element.', '5. A method for reconstructing a time/frequency tile of an audio object in an audio decoding system (1200), comprising: receiving a downmix signal (1210) comprising M channels; receiving at least one encoded element (1204) representing a subset of M elements of a row in an upmix matrix, each encoded element comprising a value and a position in the row in the upmix matrix, the position indicating one of the M channels of the downmix signal to which the encoded element corresponds; and reconstructing (1208) the time/frequency tile of the audio object from the downmix signal by forming a linear combination of the downmix channels that correspond to the at least one encoded element, wherein in said linear combination each downmix channel is multiplied by the value of its corresponding encoded element wherein, for a plurality of frequency bands or a plurality of time frames, the values and/or the positions of the at least one encoded element form one or more vectors (1214), wherein the positions of the at least one encoded element vary across a plurality of frequency bands and/or across a plurality of time frames, wherein each position is represented by an entropy coded symbol, wherein each symbol in each vector of entropy coded symbols corresponds to one of the plurality of frequency bands or the plurality of time frames, and wherein the one or more vectors of entropy coded symbols are decoded into one or more vectors of parameters, wherein each vector of entropy coded symbols comprises a first entropy coded symbol and at least one second entropy coded symbol and wherein each vector of parameters comprises a first element and at least one second element, wherein the decoding of each of the one or more vectors of entropy coded symbols comprises: representing each entropy coded symbol in the vector of entropy coded symbols by a symbol which may take N integer values by using a probability table; associating the first entropy coded symbol with an index value; associating each of the at least one second entropy coded symbol with an index value, the index value of the at least one second entropy coded symbol being calculated by: calculating the sum of the index value associated with the of entropy coded symbol preceding the second entropy coded symbol in the vector of entropy coded symbols and the symbol representing the second entropy coded symbol; and applying modulo N to the sum; and representing the at least one second element of the vector of parameters by a parameter value corresponding to the index value associated with the at least one second entropy coded symbol, wherein the step of representing each entropy coded symbol in the vector of entropy coded symbols by a symbol is performed using the same probability table for all entropy coded symbols in the vector of entropy coded symbols, wherein the index value associated with the first entropy coded symbol is calculated by: shifting the symbol representing the first entropy coded symbol in the vector of entropy coded symbols by adding an off-set value to the symbol; and applying modulo N to the shifted symbol, wherein the method further comprises the step of: representing the first element of the vector of parameters by a parameter value corresponding to the index value associated with the first entropy coded symbol.', '7. A decoder (1200) for reconstructing a time/frequency tile of an audio object, comprising: a receiving component (1206) configured to receive a downmix signal (1210) comprising M channels and at least one encoded element (1204) representing a subset of M elements of a row in an upmix matrix, each encoded element comprising a value and a position in the row in the upmix matrix, the position indicating one of the M channels of the downmix signal to which the encoded element corresponds; and a reconstructing component (1208) configured to reconstruct the time/frequency tile of the audio object from the downmix signal by forming a linear combination of the downmix channels that correspond to the at least one encoded element, wherein in said linear combination each downmix channel is multiplied by the value of its corresponding encoded element, wherein, for a plurality of frequency bands or a plurality of time frames, the values and/or the positions of the at least one encoded element form one or more vectors (1214), wherein the positions of the at least one encoded element vary across a plurality of frequency bands and/or across a plurality of time frames, wherein each position is represented by an entropy coded symbol, wherein each symbol in each vector of entropy coded symbols corresponds to one of the plurality of frequency bands or the plurality of time frames, and wherein the decoder further comprises a decoding component (1202) configured to decode the one or more vectors of entropy coded symbols into one or more vectors of parameters, wherein each vector of entropy coded symbols comprises a first entropy coded symbol and at least one second entropy coded symbol and wherein each vector of parameters comprises a first element and at least one second element, wherein the decoding component is configured to decode each of the one or more vectors of entropy coded symbols by: representing each entropy coded symbol in the vector of entropy coded symbols by a symbol which may take N integer values by using a probability table; associating the first entropy coded symbol with an index value; associating each of the at least one second entropy coded symbol with an index value, the index value of the at least one second entropy coded symbol being calculated by: calculating the sum of the index value associated with the of entropy coded symbol preceding the second entropy coded symbol in the vector of entropy coded symbols and the symbol representing the second entropy coded symbol; applying modulo N to the sum; representing the at least one second element of the vector of parameters by a parameter value corresponding to the index value associated with the at least one second entropy coded symbol, wherein the step of representing each entropy coded symbol in the vector of entropy coded symbols by a symbol is performed using the same probability table for all entropy coded symbols in the vector of entropy coded symbols, wherein the index value associated with the first entropy coded symbol is calculated by: shifting the symbol representing the first entropy coded symbol in the vector of entropy coded symbols by adding an off-set value to the symbol; applying modulo N to the shifted symbol; and representing the first element of the vector of parameters by a parameter value corresponding to the index value associated with the first entropy coded symbol.']",True,"['1102', '1104', '11', '1106', '1200', '1206', '1208', '1216', '1218', '1210', '1204', '1202', '1214', '12', '26']" 822,EP_3605532_A1.png,EP3605532A1,AUDIO ENCODER AND DECODER,['FIG1'],['FIG1 is a generalized block diagram of an audio encoding system in accordance with an example embodiment'],"['FIG1 shows a generalized block diagram of an audio encoding system 100 for encoding audio objects 104. The audio encoding system comprises a downmixing component 106 which creates a downmix signal 110 from the audio objects 104. The downmix signal 110 may for example be a 5.1 or 7.1 surround signal which is backwards compatible with established sound decoding systems such as Dolby Digital Plus or MPEG standards such as AAC, USAC or MP3. In further embodiments, the downmix signal is not backwards compatible.', 'The upmix matrix decoder 502 further comprises a decoding component 608 which is configured to represent the at least one second element of the vector of parameters by a parameter value corresponding to the index value associated with the at least one second entropy coded symbol. This representation is thus the decoded version of the parameter encoded by for example the audio encoding system 100 shown in FIG1. In other words, this representation is equal to the quantized parameter encoded by the audio encoding system 100 shown in FIG1.', 'The decoding component 608 is configured to represent the first element of the vector of parameters by a parameter value corresponding to the index value associated with the first entropy coded symbol. This representation is thus the decoded version of the parameter encoded by for example the audio encoding system 100 shown in FIG1.']",17,241,block diagram,G,"[{'element_identifier': '202', 'terms': ['receiving component']}, {'element_identifier': '1', 'terms': ['elements may be one', 'e.g. -', 'value', 'EEE']}, {'element_identifier': '100', 'terms': ['audio encoding system']}, {'element_identifier': '208', 'terms': ['encoding component']}, {'element_identifier': '206', 'terms': ['associating component']}, {'element_identifier': '204', 'terms': ['indexing component']}, {'element_identifier': '2', 'terms': ['e.g.', 'EEE']}, {'element_identifier': '104', 'terms': ['audio objects']}, {'element_identifier': '112', 'terms': ['upmix parameter analysis component']}, {'element_identifier': '102', 'terms': ['encoder']}, {'element_identifier': '108', 'terms': ['filter bank']}, {'element_identifier': '106', 'terms': ['downmixing component']}, {'element_identifier': '110', 'terms': ['downmix signal']}, {'element_identifier': '114', 'terms': ['upmix parameters']}]","['1. A method for encoding an upmix matrix in an audio encoding system (100), each row of the upmix matrix comprising M elements allowing reconstruction of a time/frequency tile of an audio object from a downmix signal comprising M channels, the method comprising: for each row in the upmix matrix: selecting a subset of elements from the M elements of the row in the upmix matrix, wherein the selected subset of elements comprises the same number of elements for each row of the upmix matrix; representing each element in the selected subset of elements by a value and a position in the upmix matrix; encoding the value and the position in the upmix matrix of each element in the selected subset of elements, wherein, for each row in the upmix matrix and for a plurality of frequency bands or a plurality of time frames, the values of the elements and/or the positions of the elements of the selected subsets of elements form one or more vectors (114, 902, 1002) of parameters, each parameter in the vector of parameters corresponding to one of the plurality of frequency bands or the plurality of time frames, wherein each vector of the one or more vectors of parameters has a first element (1002) and at least one second element (902), and wherein the one or more vectors of parameters are encoded by: representing (S702, S802) each parameter in the vector by an index value which takes one of N possible values; associating each of the at least one second element with a symbol, the symbol being calculated by: calculating (S704) a difference between the index value of the second element and the index value of its preceding element in the vector; and applying (S706) modulo N to the difference; encoding (S708) each of the at least one second element by entropy coding of the symbol associated with the at least one second element based on a probability table comprising probabilities of the symbols; associating the first element in the vector with a symbol, the symbol being calculated by: shifting (S804) the index value representing the first element in the vector by subtracting an off-set value from the index value; and applying (S806) modulo N to the shifted index value; and encoding the first element by entropy coding of the symbol associated with the first element using the same probability table that is used to encode the at least one second element.', '4. An encoder (100) for encoding an upmix matrix in an audio encoding system (100), each row of the upmix matrix comprising M elements allowing reconstruction of a time/frequency tile of an audio object from a downmix signal comprising M channels, the encoder comprising: a receiving component adapted to receive each row in the upmix matrix; a selection component adapted to select a subset of elements from the M elements of the row in the upmix matrix, wherein the selected subset of elements comprises the same number of elements for each row of the upmix matrix; an encoding component adapted to represent each element in the selected subset of elements by a value and a position in the upmix matrix, the encoding component further adapted to encode the value and the position in the upmix matrix of each element in the selected subset of elements wherein, for each row in the upmix matrix and for a plurality of frequency bands or a plurality of time frames, the values of the elements and/or the positions of the elements of the selected subsets of elements form one or more vectors (114, 902, 1002) of parameters, each parameter in the vector of parameters corresponding to one of the plurality of frequency bands or the plurality of time frames, the vector of parameters having a first element (1002) and at least one second element (902), wherein the encoding component is adapted to encode the one or more vectors of parameters by for each vector: representing (S702, S802) each parameter in the vector by an index value which takes one of N possible values; associating each of the at least one second element with a symbol, the symbol being calculated by: calculating (S704) a difference between the index value of the second element and the index value of its preceding element in the vector; applying (S706) modulo N to the difference; encoding (S708) each of the at least one second element by entropy coding of the symbol associated with the at least one second element based on a probability table comprising probabilities of the symbols associating the first element in the vector with a symbol, the symbol being calculated by: shifting (S804) the index value representing the first element in the vector by subtracting an off-set value from the index value; applying (S806) modulo N to the shifted index value; encoding the first element by entropy coding of the symbol associated with the first element using the same probability table that is used to encode the at least one second element.']",True,"['100', '104', '106', '110', '108', '1', '112', '102', '114', '102', '202', '204', '206', '2', '208', '21']" 823,EP_3605565_A1 (1).png,EP3605565A1,COIL COMPONENT,['FIG4'],['FIG4 is a right side view showing the coil member of FIG3 in a direction C'],"['As shown in FIG4, there is a gap 26a, 26b between an inner surface of a thin portion of the resin case 3 (4a, 4b) and an outer surface of the magnetic core 250, on the end side of the magnetic core 250. In the figure, the gaps 26a, 26b are marked by black for clarity. As shown in FIG3, each projection plate 25a, 25b is a thin plate portion extending from the resin case 3 in the assembling direction of the coil members, slightly receding from an outer surface of the resin case 3. Each projection plate 25a, 25b is in a U shape when viewed in the assembling direction, such that it partially surrounds the magnetic core 250. A projection plate of one coil member can be inserted into the gap of the other coil member. Namely, the projection plate 25a is inserted into the gap 26a, and the projection plate 25b is inserted into the gap 26b, between the opposing coil members. In a state where the coil members 2a, 2b are assembled, abutting portions of the opposing magnetic cores 250 are surrounded by the projection plates 25a, 25b of the reinforcing parts, providing high strength to the connecting portions. Before the coil members 2a, 2b are adhered, the movement of the coil members can be limited in the assembling direction. As a result, cooperating with the connecting parts, the disconnection of the coil members 2a, 2b can be prevented during production.']",16,279,right side view,H,"[{'element_identifier': '21', 'terms': ['arm portions', 'arm portion']}, {'element_identifier': '30', 'terms': ['flanges', 'flange']}, {'element_identifier': '250', 'terms': ['magnetic core', 'magnetic cores']}, {'element_identifier': '22', 'terms': ['portions']}]","['1. A coil device comprising a pair of annularly assembled coil members each comprising a coil arranged on a resin case containing a U-shaped magnetic core; each of said coil members having connecting portions on both end sides of said magnetic core; each of said connecting portions having a connecting part and a reinforcing part; said reinforcing part being constituted by a gap between an inner wall of the resin case and an outer wall of the magnetic core, and a projection plate extending in the assembling direction of the coil members, a projection plate of one coil member being insertable into the gap of the other coil member; and said connecting part comprising a hook-shaped projection extending in said assembling direction and a projection receiver, the hook-shaped projection of one coil member being loosely fittable into the projection receiver of the other coil member.', '7. The coil device according to any one of claims 1-6, wherein said resin case has flanges for positioning said coil.']",True,"['21', '22', '250', '30', '30', '4', '250', '250']" 824,EP_3605565_A1 (2).png,EP3605565A1,COIL COMPONENT,['FIG5'],['FIG5 is a front view showing the coil member of FIG3 in a direction B'],"['As shown in FIG5, end portions of the magnetic cores 250 slightly project at the connecting portions of the resin case 3 in the assembled coil members, such that the end surfaces of the magnetic cores 250 can abut each other. The projecting width D is preferably 0.5 mm or less. The reinforcing parts restrict the moving directions of the coil members, and the loose fitting of the connecting parts enables the use of common resin cases without necessitating different resin cases, even when the uneven sizes of the magnetic cores 250 provide different projecting widths D between the coil members, and even when an insulating spacer such as a resin film, a ceramic or oil paper, etc. is placed between the end surfaces of the magnetic cores 250 to constitute a magnetic gap. Also, an annular coil device whose gap may vary from 0 can be easily obtained regardless of a combination of coil members 2a, 2b.']",15,172,front view,H,"[{'element_identifier': '14', 'terms': ['receded step']}, {'element_identifier': '250', 'terms': ['magnetic core', 'magnetic cores']}, {'element_identifier': '13', 'terms': ['U-shaped space']}]","['1. A coil device comprising a pair of annularly assembled coil members each comprising a coil arranged on a resin case containing a U-shaped magnetic core; each of said coil members having connecting portions on both end sides of said magnetic core; each of said connecting portions having a connecting part and a reinforcing part; said reinforcing part being constituted by a gap between an inner wall of the resin case and an outer wall of the magnetic core, and a projection plate extending in the assembling direction of the coil members, a projection plate of one coil member being insertable into the gap of the other coil member; and said connecting part comprising a hook-shaped projection extending in said assembling direction and a projection receiver, the hook-shaped projection of one coil member being loosely fittable into the projection receiver of the other coil member.']",True,"['5', '250', '9', '13', '14', '11', '10']" 825,EP_3605573_A1 (6).png,EP3605573A1,"ELECTRODE FOIL, WOUND CAPACITOR, METHOD FOR MANUFACTURING ELECTRODE FOIL, AND METHOD FOR MANUFACTURING WOUND CAPACITOR",['FIG8'],['FIG8 is a graph showing Erichsen test results of Example 1 and Comparative Example 1'],"['The results of the Erichsen test are shown in FIG8. FIG8 is a graph in which the horizontal axis is a punch stroke and the vertical axis is a punch load. The punch stroke is the distance that the punch is pushed in, and the punch load is the load required to achieve each punch stroke. As shown in FIG8, while the electrode foil of Comparative Example 1 was torn before the punch stroke reached 1.1 mm, the electrode foil 1 of Example 1 had a punch stroke beyond 1.1 mm before being torn. That is, in the electrode foil 1 of Example 1, the stretchability is improved by providing the separation parts 4.', 'Further, as shown in FIG8, for the electrode foil of Comparative Example 1, for example, a load of 1.8 N was required to make the punch stroke 0.7 mm, however the electrode foil 1 of Example 1 achieved a punch stroke of 0.7 mm with a load of 1.6 N. That is, in the electrode foil 1 of Example 1, the flexibility is improved by about 11% by providing the separation parts 4. That is, it was confirmed that Example 1 in which the stretchability and the flexibility were improved was less likely to generate cracks at the time of winding and was less likely to expose the unoxidized metal portion, compared with Comparative Example 1.']",15,253,graph,H,"[{'element_identifier': '8', 'terms': ['separator']}, {'element_identifier': '7', 'terms': ['foil']}, {'element_identifier': '1', 'terms': ['electrode foil', 'electrode foils']}, {'element_identifier': '4', 'terms': ['separation parts', 'separation part']}, {'element_identifier': '2', 'terms': ['core part']}, {'element_identifier': '0', 'terms': ['is from', 'punch was', 'punch stroke']}, {'element_identifier': '3', 'terms': ['surface enlarged parts', 'surface enlarged part']}]","['1. 1. An electrode foil, which is made of a belt-like foil, comprising: surface enlarged parts that are formed on a surface of the foil and are formed of a plurality of tunnel-shaped pits; a core part which is a part remained when excluding the surface enlarged parts within the foil; a plurality of separation parts that extends discontinuously on the surface enlarged parts, and divides the surface enlarged parts; and a dielectric film formed on surfaces of the surface enlarged parts or on surfaces of the surface enlarged part and the separation parts.']",True,"['7', '4', '3', '2', '1', '0', '1', '1', '0', '0', '1', '2', '3', '0', '1', '2', '3', '8', '15']" 826,EP_3605612_A1 (1).png,EP3605612A1,"PIXEL DEFINING LAYER, ORGANIC LIGHT-EMITTING DEVICE AND PREPARATION METHOD THEREOF, AND DISPLAY DEVICE","['FIG5', ' FIG6', ' FIG7']","['FIG5 is a schematic diagram of a sectional structure of an organic light-emitting device provided by at least one embodiment of the present disclosure ', 'FIG7 is a block diagram of a display apparatus provided by at least one embodiment of the present disclosure ', 'FIG6 is a schematic diagram of a sectional structure of an organic functional layer provided by at least one embodiment of the present disclosure']","['At least one embodiment of the present disclosure further provides an organic light-emitting device, and for example, FIG5 is a schematic diagram of a sectional structure of an organic light-emitting device provided by at least one embodiment of the present disclosure. As illustrated in FIG5, the organic light-emitting device 20 comprises: a base substrate 201; a pixel definition layer 10 disposed on the base substrate 201, the pixel definition layer 10 is any one of the above mentioned pixel definition layers 10; and an organic functional layer 205 disposed in the plurality of openings 101 of the base definition layer 102. ', 'At least one embodiment of the present disclosure further provides a display apparatus, and the display apparatus comprises: any one of the organic light-emitting device described above. For example, FIG7 is a block diagram of a display apparatus provided by at least one embodiment of the present disclosure. As illustrated in FIG7, the display apparatus 30 includes the organic light-emitting device 20. ', 'For example, FIG6 is a schematic diagram of a sectional structure of an organic functional layer provided by at least one embodiment of the present disclosure. As illustrated in FIG6, the organic functional layer 205, for example, is an organic light-emitting layer, or the organic functional layer 205 comprises a hole injection layer 2051 and an organic light-emitting layer 2053 which are stacked.', 'For example, as illustrated in FIG6, the organic functional layer 205 further comprises a hole transport layer 2052 disposed between the hole injection layer 2051 and the organic light-emitting layer 2053, and an electron transport layer 2054 and an electron injection layer 2055 disposed on the organic light-emitting layer 2053 in sequence. It is understood that, in order to satisfy the requirements on light-emitting of different colors and brightness, the number of layers of the organic functional layers or the order of printing can be changed.']",69,363,"block diagram, schematic diagram",H,"[{'element_identifier': '201', 'terms': ['base substrate']}, {'element_identifier': '202', 'terms': ['driving transistor']}, {'element_identifier': '2022', 'terms': ['source electrode']}, {'element_identifier': '2055', 'terms': []}, {'element_identifier': '208', 'terms': ['encapsulation layer']}, {'element_identifier': '20', 'terms': ['organic light-emitting device']}, {'element_identifier': '205', 'terms': ['organic functional layer']}, {'element_identifier': '2023', 'terms': ['drain electrode']}, {'element_identifier': '2052', 'terms': ['hole transport layer']}, {'element_identifier': '103', 'terms': ['definition layer', 'definition layers']}, {'element_identifier': '30', 'terms': ['is']}, {'element_identifier': '203', 'terms': ['first electrode']}, {'element_identifier': '204', 'terms': ['second electrode']}, {'element_identifier': '6', 'terms': ['coumarin']}, {'element_identifier': '2051', 'terms': ['hole injection layer']}, {'element_identifier': '2054', 'terms': ['electron transport layer']}, {'element_identifier': '207', 'terms': ['passivation layer']}, {'element_identifier': '102', 'terms': ['base definition layer']}, {'element_identifier': '2053', 'terms': ['organic light-emitting layer']}]","['1. A pixel definition layer, comprising: a base definition layer having a plurality of openings for defining pixel regions, and a first definition layer arranged on a side surface of at least one of the openings of the base definition layer, wherein a hydrophilic property of the base definition layer is different from a hydrophilic property of the first definition layer.', '10. An organic light-emitting device, comprising: a base substrate; the pixel definition layer according to any one of claims 1 to 9 is arranged on the base substrate; and an organic functional layer disposed in the plurality of openings of the base definition layer.', '11. The organic light-emitting device according to claim 10, wherein the organic functional layer comprises a hole injection layer and an organic light-emitting layer which are stacked.']",True,"['207', '103', '208', '204', '102', '201', '2022', '20212024', '2023', '203', '205', '202', '20', '5', '2055', '2054', '2053', '2052', '2051', '6', '20', '30', '7', '13']" 827,EP_3605620_A1 (3).png,EP3605620A1,SEMICONDUCTOR ELEMENT PACKAGE AND AUTOFOCUSING DEVICE,['FIG10'],['FIG10 is a plan view illustrating the semiconductor element package according to the fourth embodiment'],"['As shown in FIG10, the first protective layer 145 may be disposed around a first outer side surface of the substrate 110, around a first outer side surface of the housing 130, on an upper surface of one side of the housing 130, and in a partial region of a first end of the diffusion part 140. The second protective layer 146 may be disposed around a second outer side surface of the substrate 110, around a second outer side surface of the housing 130, on an upper surface of the other side of the housing 130, and in a partial region of a second end of the diffusion part 140.']",15,120,plan view,G,"[{'element_identifier': '146', 'terms': ['second protective layer', 'second protective layers']}, {'element_identifier': '145', 'terms': ['protective layer', 'protective layers']}, {'element_identifier': '153', 'terms': ['pad', 'pads']}, {'element_identifier': '10', 'terms': ['third resistor R3 has']}]","['2. The semiconductor element package of claim 1, further comprising: a second substrate disposed under the first substrate; a pad disposed along an edge of the diffusion part; a plurality of connection wirings disposed in the plurality of via holes; first and second bonding portions disposed under the first substrate and electrically connecting the connection wiring to the second substrate; and third and fourth bonding portions disposed at the step of the housing to electrically connect the connection wiring to the pad.', '5. The semiconductor element package of claim 2, further comprising a protective layer having a first region disposed along the edge of the diffusion part and a second region extending from the first region to contact the second substrate via the housing.', '9. The semiconductor element package of claim 7, wherein the protective layer includes a conductive material, and the protective layer includes a first protective layer and a second protective layer spaced apart from each other.']",False,"['10', '146', '145', '153', '38']" 828,EP_3605620_A1 (6).png,EP3605620A1,SEMICONDUCTOR ELEMENT PACKAGE AND AUTOFOCUSING DEVICE,['FIG13'],['FIG13 is a second exemplary view illustrating a shape of an electrode pad'],"['As shown in FIG13, it is possible to include the electrode pad 150 disposed on the diffusion part 140.', 'As an example, as shown in FIG13, the first region 151 and the second region 152 of the electrode pad 150 may be disposed in diagonal regions facing each other. The electrode pad 150 may include the first region 151 provided at a first corner with respect to the upper surface of the diffusion part 140. In addition, the electrode pad 150 may include the second region 152 provided at a third corner facing the first corner with respect to the upper surface of the diffusion part 140.', 'Meanwhile, in the embodiment described with reference to FIG13, description has been made based on a case in which the first region 151 and the second region 152 of the electrode pad 150 are disposed on a diagonal corner facing each other with respect to the upper surface of the diffusion part 140. However, according to another embodiment, a region in which a connection wiring is bonded in the electrode pad 150 may be disposed on at least two corner regions of four corners with respect to the upper surface of the diffusion part 140.']",13,218,view,G,"[{'element_identifier': '151', 'terms': ['first region']}, {'element_identifier': '140', 'terms': ['diffusion part']}, {'element_identifier': '150', 'terms': ['pad']}]","['1. A semiconductor element package comprising: a first substrate; a semiconductor element disposed on the first substrate; first and second electrodes disposed on the first substrate, and electrically connected to the semiconductor element; a housing disposed on the first substrate, disposed around the semiconductor element, and having a step in an upper region thereof; a diffusion part disposed at the step of the housing, and disposed on the semiconductor element; and a plurality of via holes passing through the first substrate and the housing.', '2. The semiconductor element package of claim 1, further comprising: a second substrate disposed under the first substrate; a pad disposed along an edge of the diffusion part; a plurality of connection wirings disposed in the plurality of via holes; first and second bonding portions disposed under the first substrate and electrically connecting the connection wiring to the second substrate; and third and fourth bonding portions disposed at the step of the housing to electrically connect the connection wiring to the pad.', '5. The semiconductor element package of claim 2, further comprising a protective layer having a first region disposed along the edge of the diffusion part and a second region extending from the first region to contact the second substrate via the housing.']",False,"['13', '151', '140', '150', '27', '41']" 829,EP_3605627_A1.png,EP3605627A1,PIEZOELECTRIC DEVICE AND METHOD FOR MANUFACTURING PIEZOELECTRIC DEVICE,"['FIG1', ' FIG2']","['FIG1 is a schematic diagram of a piezoelectric sensor according to an embodiment ', 'FIG2 shows cross-sectional transmission electron microscopy(TEM) images of stacking a piezoelectric layer over an orientation control layer of amorphous phase fabricated according to the embodiment']","['FIG1 is a schematic diagram of a piezoelectric sensor 10A which is an example of the piezoelectric device. The piezoelectric sensor 10A is formed in a layered structure including a pair of electrodes 11 and 19 and a plastic layer 12, in which a stacking 15 of an orientation control layer 13 and a piezoelectric layer 14 is provided between the electrodes 11 and 19. In the example of FIG1, the electrode 11 serves as a transparent bottom electrode, and the electrode 19 serves as a transparent top electrode. The transparency of the electrode 11 and the electrode 19 is not always required; however, when applied to a display, including a touch panel, it is desirable for the piezoelectric sensor 10A to have a transparent electrode made of ITO, IZO or the like.', 'Although in the configuration of FIG1, the plastic layer 12 is provided between the electrode 11 and the stacking 15, the position of the plastic layer 12 is not limited to this example, and a suitable position may be selected as long as the plastic layer 12 imparts the flexibility to the piezoelectric sensor 10A. ', 'FIG2 shows cross-sectional TEM images of the stacking of the orientation control layer 13 and the piezoelectric layer 14 actually fabricated over a plastic (PET) base film 20. FIG2 (A) is an enlarged view at magnifications of 500,000 times, and FIG2 (B) is an enlarged view at magnifications of 2 million times. Amorphous SAZO is used as the orientation control layer 13 and zinc oxide (ZnO) is used as the piezoelectric layer 14. In general, ""AZO"" comprised of ZnO as the basic component with Al2O3 added as a sub component is a conductive film with high crystallinity. By further adding SiO2, an amorphous and electrically insulating SAZO film can be obtained. The thickness of this orientation control layer 13 is 10 nm, and the thickness of the piezoelectric layer 14 is 50 nm. As can be observed from the TEM image of FIG2 (A), the piezoelectric layer 14 is formed over the amorphous orientation control layer 13 having a smooth and uniform surface. In the TEM image of FIG2 (B), a large number of lines running in the vertical direction of the piezoelectric layer 14 indicate the direction of crystal growth. It is clearly shown that the c-axis of the piezoelectric layer 14 is aligned vertical to the substrate.']",41,446,"cross-sectional view, schematic diagram",H,"[{'element_identifier': '15', 'terms': ['stacking']}, {'element_identifier': '50', 'terms': ['preferably', 'is']}, {'element_identifier': '10', 'terms': ['piezoelectric device', 'Example', 'Examples']}]","['1. A piezoelectric device comprising: a layered structure in which at least a first electrode, a plastic layer, an orientation control layer, a piezoelectric layer, and a second electrode are stacked, wherein the orientation control layer is amorphous, and the piezoelectric layer with a thickness of 20 nm to 250 nm is provided over the orientation control layer, the piezoelectric layer having a wurtzite crystal structure, and wherein the orientation control layer and the piezoelectric layer are provided between the first electrode and the second electrode.', '15. A manufacturing method of a piezoelectric device having a layered structure in which at least a first electrode, a plastic layer, an orientation control layer, a piezoelectric layer, and a second electrode are stacked, the method comprising: forming an orientation control layer in amorphous phase on the plastic layer or on a stacking of layers including the plastic layer, and forming the piezoelectric layer having a wurtzite crystal structure over the orientation control layer of the amorphous phase.']",True,"['15', '50', '10', '15']" 830,EP_3605631_A1.png,EP3605631A1,"ORGANIC SEMICONDUCTOR ELEMENT, ORGANIC SEMICONDUCTOR COMPOSITION, ORGANIC SEMICONDUCTOR FILM PRODUCTION METHOD, ORGANIC SEMICONDUCTOR FILM, AND COMPOUND AND POLYMER USED THEREFOR",['FIG2'],['FIG2 is a cross-sectional schematic view illustrating a bottom gate-top contact-type organic thin film transistor element which is an example of the semiconductor element according to the embodiment of the present invention '],"['FIG2 is a cross-sectional schematic view indicating a bottom gate-top contact-type organic thin film transistor element 200 which is an example of the semiconductor element of the present invention.', 'As illustrated in FIG2, the organic thin film transistor element 200 has a base material 10, a gate electrode 20, a gate insulating film 30, a source electrode 40, a drain electrode 42, an organic semiconductor film 50, and a sealing layer 60.']",38,88,cross-sectional view,C,"[{'element_identifier': '30', 'terms': ['preferably']}, {'element_identifier': '100', 'terms': ['element']}, {'element_identifier': '2', 'terms': ['Formula']}, {'element_identifier': '20', 'terms': ['preferably']}, {'element_identifier': '40', 'terms': ['source electrode']}, {'element_identifier': '42', 'terms': ['drain electrode']}, {'element_identifier': '200', 'terms': ['thin film transistor element']}, {'element_identifier': '0', 'terms': ['preferably']}, {'element_identifier': '50', 'terms': ['preferably']}, {'element_identifier': '60', 'terms': ['sealing layer']}]","['1. An organic semiconductor element, comprising: an organic semiconductor layer containing a compound represented by Formula (1), a compound represented by Formula (2), and/or a compound represented by Formula (3), or containing a polymer having at least one structural unit represented by any one of Formulae (8) to (10), in each formula, X 1 represents a nitrogen atom or CR a , rings A and B each are a 5-membered or 6-membered aromatic heterocyclic ring having a nitrogen atom as a ring-constituting atom or a fused ring including a 5-membered or 6-membered aromatic heterocyclic ring having a nitrogen atom as a ring-constituting atom, Y 1 represents an oxygen atom, a sulfur atom, CR b 2 , or NR c , V 1 represents NR d , an oxygen atom, a sulfur atom, or a selenium atom, R a , R b , R c , and R d each represent a hydrogen atom or a substituent, R 1 represents a halogen atom or a group represented by Formula (W), and p is an integer of 0 to 2, n represents 1 or 2, * represents a bonding site, *-L-T Formula (W) in Formula (W), L is a single bond, or a divalent group represented by any one of Formulae (L-1) to (L-25), or a divalent group formed by bonding two or more divalent groups represented by any of (L-1) to (L-25), T represents a hydrogen atom, a halogen atom, or a cyano group, * represents a bonding site, in Formulae (L-1) to (L-25), the wavy line portion represents a bonding site to a ring structure represented by Formula (1) to (3), and (8) to (10), or a bonding site to * of a divalent group represented by any one of Formulae (L-1) to (L-25), * represents a bonding site to T, or a bonding site to a wavy line portion of a divalent group represented by any one of Formulae (L-1) to (L-25), in Formulae (L-1), (L-2), (L-6), and (L-13) to (L-24), R A represents a hydrogen atom or a substituent, in Formula (L-13), m is an integer of 1 to 4, m in Formulae (L-14) and (L-15) is an integer of 1 to 3, and m in Formulae (L-16) to (L-20) is 1 or 2, and m in Formula (L-22) is an integer of 1 to 6, in Formulae (L-20) and (L-24), R N represents a hydrogen atom or a substituent, and in Formula (L-25), R si represents a hydrogen atom, an alkyl group, an alkenyl group, or an alkynyl group.', '14. The organic semiconductor element according to any one of claims 1 to 12, wherein the organic semiconductor element is an organic thin film transistor element.']",False,"['100', '50', '60', '40', '42', '30', '20', '2', '200', '50', '60', '40', '30', '0', '20', '74']" 831,EP_3605640_A1 (1).png,EP3605640A1,"PACKAGE STRUCTURE AND MANUFACTURING METHOD THEREOF, AND DISPLAY DEVICE",['FIG4'],['FIG4 is an application scenario diagram of yet another encapsulation structure provided in an embodiment of the present disclosure'],"['As shown in FIG4, a device to be encapsulated 04 is disposed on a base substrate 05. Exemplarily, a TFT layer 051 is provided on the base substrate 05. The TFT layer 051 may include a plurality of TFTs. The device to be encapsulated 04 is disposed on the TFT Layer 051. It can be seen from FIG4 that in the embodiment of the present disclosure, an inorganic layer 031 coated on the device to be encapsulated 04 is formed on the outside of the device to be encapsulated 04. That is, the inorganic layer 031 is formed on the base substrate 05 on which the device to be encapsulated 04 is formed, and the inorganic layer 031 covers the outside of the device to be encapsulated 04.', 'The schematic diagram after a cover plate 034 is provided on the barrier layer 033 may be referred to FIG4. The cover plate may be a transparent substrate, or may be a flexible substrate. Exemplarily, an optical adhesive may be used to attach the cover plate 034 onto the barrier layer 033. The optical adhesive may be, for example, an optically clear adhesive (OCA). For the process of disposing the cover plate 034 on the barrier layer 033, reference may be made to the related art, and the details will not be repeated in the embodiment of the present disclosure.']",19,253,diagram,C,"[{'element_identifier': '042', 'terms': ['green light emitting unit']}, {'element_identifier': '043', 'terms': ['blue light emitting unit']}, {'element_identifier': '032', 'terms': ['organic layer']}, {'element_identifier': '0321', 'terms': ['polymer matrix', 'polymer matrixes']}, {'element_identifier': '0322', 'terms': ['microstructure', 'microstructures']}, {'element_identifier': '04', 'terms': ['be encapsulated']}, {'element_identifier': '033', 'terms': ['barrier layer']}, {'element_identifier': '031', 'terms': ['inorganic layer', 'inorganic layers']}, {'element_identifier': '034', 'terms': ['cover plate']}, {'element_identifier': '05', 'terms': ['base substrate']}]","['1. An encapsulation structure, comprising a plurality of film layers coated on the outside of a device to be encapsulated, wherein the plurality of film layers comprises an inorganic layer and an organic layer that are overlaid, and the organic layer comprises a polymer matrix and a repairing microstructure.', '12. The encapsulation structure according to any one of claims 1 to 11, wherein the encapsulation structure further comprises: a barrier layer disposed on the outside of the plurality of film layers, and a cover plate disposed on the barrier layer.', '13. The encapsulation structure according to any one of claims 1 to 11, wherein the device to be encapsulated is a display device, the display device is disposed on a display area of a base substrate, and both the inorganic layer and the organic layer cover the display area.']",True,"['034', '033', '05', '042', '04', '4', '043', '031', '032', '031', '05', '5', '032', '0322', '0321', '032', '0322', '0321', '032', '0322', '0321', '6', '13']" 832,EP_3605640_A1 (3).png,EP3605640A1,"PACKAGE STRUCTURE AND MANUFACTURING METHOD THEREOF, AND DISPLAY DEVICE","['FIG10', ' FIG11', ' FIG12', ' FIG13']","['FIG12 is a schematic diagram after an inorganic layer coated on an organic layer is formed on the outside of the organic layer provided in an embodiment of the present disclosure ', 'FIG13 is a schematic diagram after a barrier layer is formed on an inorganic layer coated on an organic layer provided in an embodiment of the present disclosure ', 'FIG10 is a schematic diagram after an inorganic layer coated on a display device to be encapsulated is formed on the outside of the display device provided in an embodiment of the present disclosure ', 'FIG11 is a schematic diagram after an organic layer coated on an inorganic layer is formed on the outside of the inorganic layer provided in an embodiment of the present disclosure']","['Refer to FIG12, which shows a schematic diagram after an inorganic layer 031 coated on the organic layer 032 is formed on the outside of the organic layer 032 provided in accordance with an embodiment of the present disclosure. Referring to FIG12, the inorganic layer 031 is coated on the outside of the organic layer 032. For the implementation process of step 903, reference may be made to step 901, and details are not repeated in the embodiment of the present disclosure. ', 'Refer to FIG13, which shows a schematic diagram after a barrier layer 033 is formed on the inorganic layer 031 coated on the organic layer 032 in accordance with an embodiment of the present disclosure. The barrier layer 033 may be formed by silicon dioxide or silicon nitride, and the thickness of the barrier layer 033 may be set based on actual needs. For example, a layer of silicon dioxide may be deposited on the inorganic layer 031 coated on the organic layer 032 with a method, such as coating, magnetron sputtering, thermal evaporation, or plasma enhanced chemical vapor deposition (PECVD), to obtain a silicon dioxide layer, and then the silicon dioxide layer is processed through a single patterning process to obtain the barrier layer 033. The process of processing the silicon dioxide layer through a single patterning process to obtain the barrier layer 033 is similar to the process of processing the SiNx layer through a single patterning process to obtain the inorganic layer 031, and details are not repeated in the embodiment of the present disclosure. ', 'Refer to FIG10, which shows a schematic diagram of the base substrate 05 provided with the device to be encapsulated 04 after the inorganic layer 031 is formed on the base substrate 05 provided in accordance with an embodiment of the present disclosure. A TFE CVD process may be adopted to deposit a layer of SiNx on the base substrate 05 on which the device to be encapsulated 04 is formed to form a SiNx layer, and then the SiNx layer is processed through a single patterning process to obtain the inorganic layer 031. The single patterning process includes photoresist coating, exposure, developing, etching, and photoresist stripping. Therefore, processing the SiNx layer through the single patterning process to obtain the inorganic layer 031 includes: coating a layer of photoresist on the SiNx layer to obtain a photoresist layer, exposing the photoresist layer with a mask plate to form a fully exposed area and a non-exposed area on the photoresist layer, processing the exposed photoresist layer through a developing process to remove the photoresist in the fully exposed area and retain the photoresist in the non-exposed area, etching the area on the SiNx layer corresponding to the fully exposed area, and finally stripping off the photoresist in the non-exposed area, to form the inorganic layer 031 in the area on the SiNx layer corresponding to the non-exposed area. It should be noted that the embodiment of the present disclosure is described by taking an example in which a positive photoresist is used to form the inorganic layer 031. In practice, a negative photoresist may also be used to form the inorganic layer 031, which is not repeated in detail in the embodiment of the present disclosure. ', 'The preset process may include an ink-jet printing process or a coating process. For example, refer to FIG11, which shows a schematic diagram after the organic layer 032 covering the inorganic layer 031 is formed on the outside of the inorganic layer 031 provided in accordance with an embodiment of the present disclosure. Referring to FIG11, the organic layer 032 is coated on the outside of the inorganic layer 031. In the embodiment of the present disclosure, the mixture including the polymeric monomer, the initiator, the chain transfer agent, and the repairing microstructure may be coated (or ink-jet printed) on the outside of the inorganic layer 031 to obtain the mixture layer, and then the mixture layer may be heated so that the polymeric monomer in the mixture layer undergoes a polymerization reaction under the action of the initiator and the chain transfer agent to obtain the organic layer 032. The mixture layer may be heated so that the temperature of the mixture layer is within a preset temperature range of 30 degrees Celsius to 70 degrees Celsius. In actual implementation, a substrate formed with the mixture layer may be placed in an environment of 30 degrees Celsius to 70 degrees Celsius for a preset duration. In the environment of 30 degrees Celsius to 70 degrees Celsius, the polymeric monomer may undergo a polymerization reaction within a preset period of time under the action of the initiator and the chain transfer agent to obtain the organic layer 032. The preset duration may be set in accordance with actual needs, and the preset duration may generally be changed. The preset duration is related to the temperature. For example, in the temperature range from 30 degrees Celsius to 70 degrees Celsius, the higher the temperature is, the shorter the preset duration is.']",124,927,schematic diagram,C,"[{'element_identifier': '051', 'terms': ['TFT layer']}, {'element_identifier': '042', 'terms': ['green light emitting unit']}, {'element_identifier': '032', 'terms': ['organic layer']}, {'element_identifier': '04', 'terms': ['be encapsulated']}, {'element_identifier': '033', 'terms': ['barrier layer']}, {'element_identifier': '041', 'terms': ['red light emitting unit']}, {'element_identifier': '031', 'terms': ['inorganic layer', 'inorganic layers']}, {'element_identifier': '043', 'terms': ['blue light emitting unit']}, {'element_identifier': '03', 'terms': ['encapsulation structure']}]","['1. An encapsulation structure, comprising a plurality of film layers coated on the outside of a device to be encapsulated, wherein the plurality of film layers comprises an inorganic layer and an organic layer that are overlaid, and the organic layer comprises a polymer matrix and a repairing microstructure.', '12. The encapsulation structure according to any one of claims 1 to 11, wherein the encapsulation structure further comprises: a barrier layer disposed on the outside of the plurality of film layers, and a cover plate disposed on the barrier layer.']",True,"['031', '042', '04', '04', '032', '03', '04', '042', '04', '11', '043', '031', '032', '031', '04', '042', '04', '12', '04', '033', '032', '031', '051', '041', '042', '04', '043', '15']" 833,EP_3605728_A1 (3).png,EP3605728A1,ANTENNA DEVICE AND ELECTRONIC DEVICE COMPRISING SAME,['FIG9'],['FIG9 is diagram illustrating an impact compensation structure of an electronic device according to various embodiments of the disclosure'],"['FIG9 is diagram illustrating an impact compensation structure of an electronic device 100 according to various embodiments of the disclosure.', 'As illustrated in FIG9, when a cross section of the electronic device 100 is viewed in a longitudinal direction, the insulated metal layer 210 and the antenna device 220 may have the same length. The circuit board layer 230 may be longer than the insulated metal layer 210 and the antenna device 220.']",19,79,diagram,H,"[{'element_identifier': '233', 'terms': ['third circuit board']}, {'element_identifier': '210', 'terms': ['insulated metal layer']}, {'element_identifier': '230', 'terms': ['circuit board layer', 'circuit board layers']}, {'element_identifier': '221', 'terms': ['antenna substrate', 'antenna substrates']}, {'element_identifier': '310', 'terms': ['first conductor']}, {'element_identifier': '220', 'terms': ['antenna device']}, {'element_identifier': '222', 'terms': ['antenna substrate', 'antenna substrates']}, {'element_identifier': '261', 'terms': ['FPCBs']}, {'element_identifier': '232', 'terms': ['circuit board']}, {'element_identifier': '320', 'terms': ['second conductor']}, {'element_identifier': '231', 'terms': ['circuit board', 'circuit boards']}, {'element_identifier': '240', 'terms': ['ground']}, {'element_identifier': '251', 'terms': ['through electrode', 'through electrodes']}, {'element_identifier': '120', 'terms': ['component', 'components']}]","['1. An electronic device for forming a space between a front surface and a rear surface, the electronic device comprising: a first cover disposed on the front surface; a second cover disposed on the rear surface; a frame enclosing the first cover and the second cover; a multilayer circuit board coupled to the second cover to constitute a housing of the electronic device, wherein the multilayer circuit board comprises: an insulated metal layer having one surface coupled to the second cover; and an antenna device of a substrate structure having one surface coupled to the insulated metal layer.', '3. The electronic device of claim 2, wherein the antenna device comprises a plurality of antenna substrates, and wherein each antenna substrate is electrically connected through a through electrode and comprises a different antenna pattern.', '4. The electronic device of claim 1, wherein the multilayer circuit board further comprises circuit board layers coupled to the antenna device and configured to dispose at least one component at a surface opposite to a coupled surface of the antenna device.', '6. The electronic device of claim 4, further comprising a ground at a surface to which the circuit board layer and the antenna device are coupled.', '8. The electronic device of claim 4, wherein in the multilayer circuit board, the insulated metal layer and the antenna device have the same length in a longitudinal direction, and the circuit board layer has a longer length in a longitudinal direction than that of the antenna device, wherein the circuit board layer comprises: a first conductor coupled to one side in which the insulated metal layer, the antenna device, and the circuit board layer are aligned without a step in a longitudinal direction; and a second conductor coupled on the insulated metal layer, a side surface of the antenna device, and the circuit board layer at the other side having a step, wherein the at least one component is disposed at a surface opposite to a surface to which the second conductor is coupled on the circuit board layer.']",False,"['9', '310', '210', '251', '222', '221', '320', '21', '220', '230', '262', '261', '263', '120', '235', '234', '233', '232', '231', '240']" 834,EP_3605747_A1.png,EP3605747A1,CHARGER,['FIG2'],['FIG2 is a schematic view showing a state in which a first connector and a second connector are connected to each other in the charger according to this embodiment'],"['FIG2 is a schematic view showing a state in which the first connector 3 and the second connector 4 are connected to each other. As shown in FIG2, the charger 1 is configured to be charged in a state in which the first connector 3 and the second connector 4 are connected to each other by a magnetic force.', 'Next, a method of setting the elastic force when the male power terminal 32 includes the elastic member 35 is described below. In the following description, a reference is made also to FIG2 as appropriate.']",29,102,schematic view,B,"[{'element_identifier': '5', 'terms': ['wire']}, {'element_identifier': '2', 'terms': ['charger body']}, {'element_identifier': '6', 'terms': ['moving body']}, {'element_identifier': '1', 'terms': ['charger']}]","['1. A charger (1) comprising: a first connector (3) provided on a power supply side; and a second connector (4) provided on a moving body side, wherein the charger (1) is configured to be charged in a state in which the first connector (3) and the second connector (4) are connected to each other by a magnetic force, the first connector (3) and the second connector (4) include opposing surfaces facing each other, one of the opposing surface of the first connector (3) and the opposing surface of the second connector (4) includes, on a first opposing surface (31), a male power terminal (32) and a male signal terminal (33) for a power cutoff signal projecting from the first opposing surface (31), and the other one of the opposing surface of the first connector (3) and the opposing surface of the second connector (4) is provided with a female power terminal (42) which the male power terminal (32) is to be fitted into and a female signal terminal (43) which the male signal terminal (33) is to be fitted into on a second opposing surface (41), and a length of the male signal terminal (33) in a direction in which the male signal terminal (33) projects is shorter than a length of the male power terminal (32) in a direction in which the male power terminal (32) projects.']",True,"['1', '6', '5', '2', '2', '6', '8']" 835,EP_3605767_A1 (2).png,EP3605767A1,POWER SUPPLY CIRCUIT,['FIG3'],['FIG3 is a diagram showing a schematic waveform of a surge voltage that may occur in the power supply circuit shown in FIG1'],"['At the start-up of power supply circuit 10A, a current i1 flows through coil L1 for charging capacitor C1. Current i1 in this case is an instantaneously high current (that is, an inrush current). Since transistor TR1 is off, current i1 flows into capacitor C1. When current i1 instantaneously increases, the voltage on coil L1, that is, the voltage across capacitor C1 (voltage Vi), suddenly rises as shown in FIG3.']",23,87,diagram,H,"[{'element_identifier': '10', 'terms': ['power supply circuit']}]","['1. A power supply circuit (10) comprising: a coil (L1) having a first end that receives an input voltage and a second end; a switching element (TR1) connected to the second end of the coil (L1); a first capacitor (C1) connected to the second end of the coil (L1); and a surge protection circuit (11) connected to the second end of the coil (L1) in parallel with the first capacitor (C1), the surge protection circuit (11) including a diode, a second capacitor (C2), and a resistance (R1), the diode, the second capacitor (C2), and the resistance (R1) being connected in series to the second end of the coil (L1).']",False,['10'] 836,EP_3605767_A1 (3).png,EP3605767A1,POWER SUPPLY CIRCUIT,['FIG4'],['FIG4 is a circuit diagram showing an example of a step-down chopper shown in FIG2 for which commonly-used surge countermeasures are taken'],"['FIG4 is a circuit diagram showing an example of a step-down chopper shown in FIG2 for which commonly-used surge countermeasures are taken. As shown in FIG4, Zener diode ZD1 is provided in parallel with capacitor C1. Zener diode ZD1 should not operate during the normal operation of power supply circuit 10A. Thus, the operating voltage of Zener diode ZD1 should be higher than the design value of the input voltage. On the other hand, in order to protect transistor TR1, the operating voltage of Zener diode ZD1 should be lower than the rated voltage of transistor TR1.', 'From a point of view of the efficiency of power supply circuit 10A, it is desirable to reduce the loss during switching of transistor TR1 as much as possible. Generally, in the transistor with low switching loss, the rated voltage is also low. However, when the rated voltage of transistor TR1 is low, the difference between the input voltage during the normal operation of power supply circuit 10A and the rated voltage of transistor TR1 is relatively small. For example, when the voltage of AC power supply 20 is 100 VAC, a peak voltage Vpeak (and the voltage after rectification) is 141 V. Thus, the input voltage during the normal operation of power supply circuit 10A (voltage Vi) is 141 V. In the case of power supply circuit 10A shown in FIG4, the operating voltage of Zener diode ZD1 should be 180 V higher than 141 V.']",26,273,circuit diagram,H,"[{'element_identifier': '11', 'terms': ['surge protection circuit']}, {'element_identifier': '20', 'terms': ['AC power supply']}]","['1. A power supply circuit (10) comprising: a coil (L1) having a first end that receives an input voltage and a second end; a switching element (TR1) connected to the second end of the coil (L1); a first capacitor (C1) connected to the second end of the coil (L1); and a surge protection circuit (11) connected to the second end of the coil (L1) in parallel with the first capacitor (C1), the surge protection circuit (11) including a diode, a second capacitor (C2), and a resistance (R1), the diode, the second capacitor (C2), and the resistance (R1) being connected in series to the second end of the coil (L1).']",False,"['11', '20']" 837,EP_3605767_A1 (5).png,EP3605767A1,POWER SUPPLY CIRCUIT,['FIG6'],['FIG6 is a diagram for illustrating surge protection in the power supply circuit shown in FIG1'],"['FIG6 is a diagram for illustrating surge protection in power supply circuit 10 shown in FIG1. In surge protection circuit 11, capacitor C2 and resistance R1 are connected in series to Zener diode ZD1. The operating voltage (Zener voltage Vz) of Zener diode ZD1 is assumed to be 150 V.']",16,55,diagram,H,"[{'element_identifier': '10', 'terms': ['power supply circuit']}, {'element_identifier': '20', 'terms': ['AC power supply']}]","['1. A power supply circuit (10) comprising: a coil (L1) having a first end that receives an input voltage and a second end; a switching element (TR1) connected to the second end of the coil (L1); a first capacitor (C1) connected to the second end of the coil (L1); and a surge protection circuit (11) connected to the second end of the coil (L1) in parallel with the first capacitor (C1), the surge protection circuit (11) including a diode, a second capacitor (C2), and a resistance (R1), the diode, the second capacitor (C2), and the resistance (R1) being connected in series to the second end of the coil (L1).']",False,"['10', '13', '20']" 838,EP_3605814_A1 (3).png,EP3605814A1,SYSTEMS AND METHODS OF OPERATION FOR POWER CONVERTERS HAVING SERIES-PARALLEL MODE ACTIVE CLAMPS,['FIG9'],['FIG9 shows an alternate embodiment of the series-parallel mode active clamp circuit of FIG2 using a high side auxiliary winding'],"['Referring now to FIG9, another embodiment of the series-parallel mode active clamp circuit discussed in detail above with respect to FIG2, which uses a high side auxiliary winding is shown. According to the embodiment shown in converter circuit 900 of FIG9, the second snubber capacitor, C3, and diode D4 are removed from the circuit of FIG2. In their place, the diode D2 is instead connected between the primary winding P1 and auxiliary primary winding P2 of the transformer TX1, as well as to power switch Q1 (rather than clamp switch Q2). According to the operation of the circuit 900 shown in FIG9, the energy from the leakage inductance is transferred to the snubber capacitor C1 at the turn off transition through D2. This energy does not transfer back in to the transformer, as the diode D3 is reverse biased due to much higher reflected voltage at its cathode node impressed by auxiliary winding. If the two primary windings P1 and P2 have equal turns, and if the reflected voltage across primary P1 is 80V, then the reflected voltage at the source node of clamp switch Q2 would be 160V with respect to Vin. Thus, the current from the snubber capacitor C1 does not transfer energy through clamp switch Q2. When the transformer energy is discharged and it starts to resonate with the equivalent capacitance at the drain node of power switch Q1, energy transfer starts in a manner similar to that presented with respect to FIG2 above, i.e., through D3 and Q2. The turns ratio of the primary and auxiliary winding may be varied during circuit optimization.']",22,295,embodiment,H,"[{'element_identifier': '33', 'terms': ['load.Example']}, {'element_identifier': '9', 'terms': ['example']}, {'element_identifier': '900', 'terms': ['circuit']}]","['1. A method of operating a power conversion circuit (200) comprising a transformer (TX1), first and second capacitors (C1, C3), first and second switches (Q1, Q2), and a controller operating the first and second switches to produce a regulated output voltage (Vout) for delivery to a load in an output system, the method comprising: switching the first switch (Q1) on at a first switching frequency, so as to store energy in a primary winding (P1) of the transformer; charging the first and second capacitors (C1, C3) in series via a first diode coupled between the first and second capacitors (C1, C3) by switching the first switch (Q1) off; switching the second switch (Q2) on when current is flowing through a body diode of the second switch; discharging the first and second capacitors (C1, C3) in parallel via a second diode coupled across the first capacitor (C1) and the first diode and a third diode coupled across the second capacitor (C2) and the first diode after all leakage inductance energy has been transferred from the transformer to the first and second capacitors; switching the second switch (Q2) off at a first amount of time before the next switching on of the first switch (Q1), wherein the first amount of time is determined so as to achieve zero voltage switching of the first switch; wherein at least one of the first switching frequency and the first amount of time is variable as determined by operating conditions.']",False,"['900', '33', '9']" 839,EP_3605823_A1 (1).png,EP3605823A1,POWER CONVERSION DEVICE AND TEST METHOD FOR SAME,['FIG2'],['FIG2 is a circuit block diagram showing a configuration of a unit converter shown in FIG1'],"['FIG2 is a circuit block diagram showing a configuration of unit converter 5. In FIG2, unit converter 5 includes AC terminals 5a and 5b, a switch S7, an inverter 10, DC lines PL and NL, a capacitor 15, a voltage detector 16, and a driver 17.', 'When gate signals Auv and Buv are at ""H"" level and ""L"" level, respectively, IGBTs 11 and 14 included in the corresponding inverter 10 turn on and IGBTs 12 and 13 turn off. In this case, in FIG2, the positive-side terminal (positive-side DC line PL) of capacitor 15 is connected to AC terminal 5a through IGBT 11, AC terminal 5b is connected to the negative-side terminal (negative-side DC line NL) of capacitor 15 through IGBT 14, and the terminal-to-terminal voltage of capacitor 15 is output between AC terminals 5a and 5b. In other words, a positive DC voltage is output between AC terminals 5a and 5b.']",16,192,circuit block diagram,G,"[{'element_identifier': '5', 'terms': ['unit converters', 'unit converter']}, {'element_identifier': '11', 'terms': ['IGBTs']}, {'element_identifier': '16', 'terms': ['voltage detector']}, {'element_identifier': '10', 'terms': ['inverter', 'inverters']}, {'element_identifier': '15', 'terms': ['capacitor', 'capacitors']}]","['1. A power conversion device comprising: three arms that are delta-connected; each of the three arms including a capacitor configured to store DC power, and an inverter configured to convert DC power into AC power; a first controller configured to control the inverter of each of the three arms such that circulating current of the three arms follows a first reference in a test period in which a power system is cut off from the three arms; and a second controller configured to control the inverter of each of the three arms such that electric power transferred between the power system and the three arms follows a second reference in normal operation in which there is electrical continuity between the power system and the three arms, wherein it is determined whether the power conversion device is normal, based on the circulating current in the test period.', '8. The power conversion device according to claim 1, wherein each of the three arms includes a plurality of unit converters, each of the unit converters includes the capacitor and the inverter, and a plurality of the inverters are cascaded.']",False,"['5', '10', '15', '16', '11']" 840,EP_3605823_A1 (4).png,EP3605823A1,POWER CONVERSION DEVICE AND TEST METHOD FOR SAME,['FIG8'],['FIG8 is a block diagram showing a configuration of a voltage command unit included in the control device shown in FIG1'],"['FIG8 is a block diagram showing a configuration of a voltage command unit 50 included in control device 4. In FIG8, voltage command unit 50 includes a PI (Proportional Integral) controllers 51 to 53, a selector 54, switches S11 to S13, and adders 55 to 57.']",21,54,block diagram,G,"[{'element_identifier': '17', 'terms': ['driver', 'drivers']}, {'element_identifier': '5', 'terms': ['unit converters', 'unit converter']}, {'element_identifier': '56', 'terms': ['Adder']}, {'element_identifier': '57', 'terms': ['Adder']}, {'element_identifier': '52', 'terms': ['PI controller']}, {'element_identifier': '50', 'terms': ['voltage command unit']}, {'element_identifier': '54', 'terms': ['selector']}, {'element_identifier': '55', 'terms': ['adders']}]","['8. The power conversion device according to claim 1, wherein each of the three arms includes a plurality of unit converters, each of the unit converters includes the capacitor and the inverter, and a plurality of the inverters are cascaded.']",False,"['50', '5', '52', '54', '17', '56', '57', '55']" 841,EP_3605823_A1.png,EP3605823A1,POWER CONVERSION DEVICE AND TEST METHOD FOR SAME,['FIG1'],['FIG1 is a circuit block diagram showing a configuration of a power conversion device according to an embodiment of the present invention'],"['FIG1 is a circuit block diagram showing a configuration of a power conversion device according to an embodiment of the present invention. In FIG1, this power conversion device is used as a reactive power compensator that compensates for reactive power of a power system 1 and includes switches S1 to S6, transformers 2 and 3, current-limiting resistors R1 to R3, AC lines UL, VL, and WL, current transformers C1 to C3, reactors L1 to L3, arms Al to A3, and a control device 4. Each of arms A1 to A3 includes a plurality of cascaded unit converters 5.', 'Returning to FIG1, control device 4 controls each of three arms A1 to A3 (that is, each of a plurality of unit converters 5), based on external test signal TE, activation signal EN, and reactive power reference Qr, AC voltages Vu, Vv, and Vw from transformer 3, and AC currents Iuv, Ivw, and Iwu from current detectors C1 to C3.', 'As shown in FIG1, it is assumed that each of switches S1 to S3 has one terminal connected to the corresponding one of three phase transmission lines 1u, 1v, 1w of power system 1. In this state, if normal operation of arms A1 to A3 is started immediately after switches S1 to S3 and switches S4 to S6 are successively turn on to charge capacitor 15 of each unit converter 5, power system 1 is adversely affected in the case of a fault of the power conversion device.']",22,284,circuit block diagram,G,"[{'element_identifier': '7', 'terms': ['wave signal ϕ22 is', 'same pulse width']}, {'element_identifier': '5', 'terms': ['unit converters', 'unit converter']}, {'element_identifier': '4', 'terms': ['control device']}, {'element_identifier': '10', 'terms': ['inverter', 'inverters']}]","['1. A power conversion device comprising: three arms that are delta-connected; each of the three arms including a capacitor configured to store DC power, and an inverter configured to convert DC power into AC power; a first controller configured to control the inverter of each of the three arms such that circulating current of the three arms follows a first reference in a test period in which a power system is cut off from the three arms; and a second controller configured to control the inverter of each of the three arms such that electric power transferred between the power system and the three arms follows a second reference in normal operation in which there is electrical continuity between the power system and the three arms, wherein it is determined whether the power conversion device is normal, based on the circulating current in the test period.', '8. The power conversion device according to claim 1, wherein each of the three arms includes a plurality of unit converters, each of the unit converters includes the capacitor and the inverter, and a plurality of the inverters are cascaded.']",False,"['4', '7', '5', '5', '5', '5', '5', '10']" 842,EP_3605844_A1.png,EP3605844A1,FAST OVER VOLTAGE AND SURGE DETECTION FOR HIGH SPEED AND LOAD SWITCHES,['FIG1'],['FIG1 illustrates a connection scheme of a printed circuit board (PCB) in accordance with embodiments described herein'],['FIG1 illustrates a connection scheme 100 of a printed circuit board (PCB) 105 in accordance with embodiments described herein. The PCB 105 may be connected through a pad 110a on a connector/device side through a PCB line 115 to a connector 120. The connector 120 may be a USB Type-C connector or the like. The PCB 105 may be connected through a second pad 110b on a processor/host side through the PCB line 115 to a host (not illustrated). The host side may include a processor or other load. The connector 120 may receive an opposing connector attached to a cable 125 or other device.'],19,121,scheme,H,"[{'element_identifier': '130', 'terms': ['protection circuit']}, {'element_identifier': '1', 'terms': ['be', 'is']}, {'element_identifier': '100', 'terms': ['connection scheme', 'may be less than']}, {'element_identifier': '105', 'terms': ['PCB']}, {'element_identifier': '138', 'terms': ['output signal']}, {'element_identifier': '115', 'terms': ['PCB line']}, {'element_identifier': '125', 'terms': ['cable']}, {'element_identifier': '140', 'terms': ['switches', 'switch']}, {'element_identifier': '135', 'terms': ['gates']}, {'element_identifier': '120', 'terms': ['connector']}]","['1. A protection circuit, comprising: a pad configured to input an external voltage from a connector; a first circuit branch connected to the pad and configured to receive a fast ramp-up surge at the pad; a second circuit branch connected to the pad and configured to receive a ramp-up surge at the pad; a third circuit branch connected to the pad and configured to output a surge detection signal when a surge voltage is received at the pad; an enabling transistor connected between the second circuit branch and the third circuit branch; at least one switch to be protected; and a controller configured to control components of the second circuit branch and third circuit branch of the protection circuit based on an on-state of the at least one switch to be protected.']",False,"['100', '140', '120', '125', '115', '115', '8', '130', '138', '135', '105', '1']" 843,EP_3605845_A1 (4).png,EP3605845A1,TOUCH SENSOR ASSEMBLY AND REFRIGERATOR DOOR INCLUDING A TOUCH SENSOR ASSEMBLY,['FIG19'],['FIG19 is a perspective view illustrating the cover in FIG12'],"['A plurality of coupling hooks 210 that extend in a thickness-wise or depth direction (i.e., a front-rear direction) of the cover 200-1 may be provided at lateral (i.e., left and right) sides of the cover 200-1. The plurality of coupling hooks 210 may be formed in locations corresponding to positions of a plurality of hook grooves 315 (FIG19) of the display cover 30-1 (FIG19). The plurality of coupling hooks 210 may be provided in locations that face each other on the left and right sides of the cover 200-1 and may be regularly spaced apart from each other in the up-down (i.e., length-wise) direction.', 'A plurality of support hooks or clips 380 may have a different shape from the support hooks 318 in FIG19 provided in the display cover 30-1 and may be provided at side edges of the accommodation portion 311. The plurality of support hooks 380 may be provided in locations that face or align with each other on left and right sides of the accommodation portion 311 and may be spaced apart from each other by predetermined intervals in the up-down direction to evenly support the cover 200-2. The support hooks 380 may be bent or curved.']",10,242,perspective view,F,"[{'element_identifier': '210', 'terms': ['coupling hooks', 'coupling hook']}, {'element_identifier': '310', 'terms': ['accommodation portion']}, {'element_identifier': '237', 'terms': ['opening']}, {'element_identifier': '318', 'terms': ['support hooks', 'support hook']}, {'element_identifier': '320', 'terms': ['holes', 'hole']}, {'element_identifier': '315', 'terms': ['hook grooves', 'hook groove']}, {'element_identifier': '340', 'terms': ['guide rail']}, {'element_identifier': '120', 'terms': ['substrate']}]","['1. A touch sensor assembly (100), comprising: a substrate (120) that is attached to a rear surface of a panel (200) on which touch points (21) are illuminated through a front surface of the panel (20); at least one piezo disc (130) having a first pole (136) provided over a second pole (138), wherein the first pole (130) is configured to contact the substrate (120); a holder (140) that is configured to support the piezo disc (130) and to fix the piezo disc (130) to the substrate (120); and a cover (200) attached to the substrate (120).', '2. The touch sensor assembly of claim 1, wherein the cover (200) includes at least one cavity (225) which is concavely formed in the cover (200) to face the substrate (120) and cover the holder (140) and/or the cover (200) which adheres to the rear of the substrate (120) includes at least one opening through which the holder (140) is exposed.', '7. The touch sensor assembly of claim 6, wherein the cover (200) is supported by a display cover (30) that is attached to the panel (20), an accommodation portion (310) is formed in the display cover (30), and the plurality of coupling hooks (210) are held respectively in a plurality of hook grooves (315) that are formed along side edges of the accommodation portion (310) and are configured to move in the front-rear direction.', '9. The touch sensor assembly of claim 8, wherein at least one opening formed of at least one hole (122) is formed in an area of the substrate (120) corresponding to the touch points (21), wherein the press region (126) is provided in a central portion of the opening, and at least one leg (124) connects an outer edge of the opening to the press region (126) such that the at least one hole (122) is formed between the leg (124) and the press region (126).', '15. The touch sensor assembly of any one of the preceding claims, wherein the cover (200) is supported by a display cover (30) that is attached to the rear of the panel (20), an accommodation portion (310) is formed in the display cover (30), and a plurality of support hooks (318) that are provided on edges of the accommodation portion support a rear of the cover (200).']",True,"['210', '237', '120', '18', '340', '19', '340', '320', '315', '318', '310', '315', '28']" 844,EP_3605890_A1 (1).png,EP3605890A1,SUBMARINE CABLE BRANCHING UNITS WITH FIBER PAIR SWITCHING,['FIG2'],['FIG2 is a functional block diagram of one example of a fiber pair switching branching unit consistent with the present disclosure'],"['FIG2 illustrates one example of a branching configuration 163a consistent with the present disclosure. The illustrated example branching configuration 163a includes a FPS-BU 130a and an optional WMU 150. The FPS-BU 130a includes an optical bypass switch portion 202, a controllable optical routing device (RORD) 204, and a controller 206. The branching configuration 163a is coupled between a west portion of an optical cable 112, an east portion of an optical cable 112 and a branch cable 162. For simplicity and east of description, the terms west and east, and other directional or positional terms, may be used herein to describe the general relative orientation or position of components or elements of a system. These terms are not limited to the specific directions, e.g. west or east, referenced but are instead used to describe relative orientation, e.g. opposite sides or directions of travel.', 'Each of the couplers couples a portion of the east bound signal to an input of the drop WSS 418. The output of the drop WSS 418 is coupled to the west side branch cable drop fiber 406. Each of the WSSs is coupled to an output of the splitter 420. The input to the splitter 420 is coupled to the west side branch cable add fiber 408. The state of the outputs of the WSSs may each be selectively controlled by a controller, e.g. controller 204 (FIG2) in response to a remote command signal.', 'The east side portion of the FPS-BU 103c includes an optical coupler coupled to each of the fibers 416-1...416-N carrying west bound signals, a WSSs coupled to each of the fibers 414-1...414-N carrying east bounds signals, a NxM drop WSS 422 and an NxM add optical splitter/coupler 424. Each of the couplers couples a portion of the east bound signal to an input of the drop WSS 422. The output of the drop WSS 422 is coupled to the west side branch cable drop fiber 412. Each of the WSSs is coupled to an output of the splitter 424. The input to the splitter 424 is coupled to the west side branch cable add fiber 410. The state of the outputs of the WSSs may each be selectively controlled by the controller, e.g. controller 204 (FIG2) in response to a remote command signal.']",21,439,block diagram,G,"[{'element_identifier': '202', 'terms': ['bypass switch portion']}, {'element_identifier': '218', 'terms': ['west side fiber pair']}, {'element_identifier': '220', 'terms': ['east side fiber pair']}, {'element_identifier': '208', 'terms': ['port']}, {'element_identifier': '206', 'terms': ['controller']}, {'element_identifier': '204', 'terms': ['RORD']}, {'element_identifier': '222', 'terms': ['branch cable. One fiber']}, {'element_identifier': '228', 'terms': ['other fiber']}, {'element_identifier': '226', 'terms': ['One fiber']}, {'element_identifier': '2', 'terms': ['N is']}, {'element_identifier': '162', 'terms': ['branch cable', 'branch cables']}, {'element_identifier': '112', 'terms': ['cable']}, {'element_identifier': '224', 'terms': ['other fiber']}, {'element_identifier': '150', 'terms': ['WMU']}]","['1. An optical communication system comprising: a trunk terminal configured to provide trunk signals on a plurality of fiber pairs of a trunk cable; a branch terminal configured to provide a branch add signal on a branch cable; and a fiber pair switching branching unit coupled to the trunk cable and the branch cable for receiving the trunk signals and the branch add signal, the branching unit comprising: at least a first optical routing device coupled to the trunk cable and configured to receive the trunk signals from each of the plurality of fiber pairs, the first optical routing device being controllable to couple signals from selected one of the plurality of fiber pairs to a drop fiber of the branch cable; and at least a second optical routing device coupled to the branch cable and configured to receive the branch add signal from the branch cable, the second optical routing device being controllable to couple the branch add signal to a fiber of one of the plurality of fiber pairs.', '3. The optical communication system of claim 1, wherein the second optical routing device is coupled to the branch cable through an associated optical splitter, wherein the optical splitter has an input port coupled to the branch cable to receive the branch add signal and a plurality of output ports, one of the plurality of output ports being coupled to the second optical routing device; wherein a second one of the output ports is coupled to a third optical routing device, the third wavelength device being controllable to couple the branch add signal to separate fiber of one of the plurality of fiber pairs.']",False,"['202', '112', '112', '208', '218', '222', '204', '228', '220', '11', '206', '226', '224', '150', '162', '2']" 845,EP_3605890_A1 (3).png,EP3605890A1,SUBMARINE CABLE BRANCHING UNITS WITH FIBER PAIR SWITCHING,['FIG4'],['FIG4 is a functional block diagram of another one example of a fiber pair switching branching unit consistent with the present disclosure '],"['FIG4 illustrates another example of a FPS-BU 130c consistent with the present disclosure. In general, in the FPS-BU 130c optical couplers are used to tap each input trunk fiber to obtain a copy of the inbound optical spectrum and connect it to the optical filtering devices, e.g. WSSs. The inbound spectra on each on trunk fiber is filtered and combined to form the output spectrum on each drop fiber of the branch cable. The outbound spectrum on each add fiber of the branch cable is filtered and combined with the trunk traffic on each trunk output fiber of the trunk cable to form the output spectrum on each trunk output fiber.', 'A system consistent with the present disclosure is not limited to the examples described herein and can be provided in a variety of configurations. For example, the embodiment shown in FIG4 may be described as a ""broadcast and select"" configuration. However, the positions of the couplers, NxM drop WSS, the WSSs and the NxM splitter could be reversed to provide a ""filter and combine"" architecture consistent with the present disclosure. Also, the selectively controllable RORD, WSSs, N x M drop WSS and/the NxM add splitter can be implemented as single units, or may be implemented with a combination of lower port count optical filter devices. A system consistent with the present disclosure could be implemented with single-instance or with redundant reconfigurable optical filtering units on each path.']",22,270,block diagram,G,"[{'element_identifier': '420', 'terms': ['splitter']}, {'element_identifier': '412', 'terms': ['drop fiber']}, {'element_identifier': '422', 'terms': ['drop WSS']}, {'element_identifier': '402', 'terms': ['branch cable fiber pair']}, {'element_identifier': '162', 'terms': ['branch cable', 'branch cables']}, {'element_identifier': '112', 'terms': ['cable']}, {'element_identifier': '406', 'terms': ['drop fiber']}, {'element_identifier': '404', 'terms': ['branch cable fiber pair', 'side branch cable fiber']}, {'element_identifier': '410', 'terms': ['add fiber']}, {'element_identifier': '408', 'terms': ['add fiber']}]","['1. An optical communication system comprising: a trunk terminal configured to provide trunk signals on a plurality of fiber pairs of a trunk cable; a branch terminal configured to provide a branch add signal on a branch cable; and a fiber pair switching branching unit coupled to the trunk cable and the branch cable for receiving the trunk signals and the branch add signal, the branching unit comprising: at least a first optical routing device coupled to the trunk cable and configured to receive the trunk signals from each of the plurality of fiber pairs, the first optical routing device being controllable to couple signals from selected one of the plurality of fiber pairs to a drop fiber of the branch cable; and at least a second optical routing device coupled to the branch cable and configured to receive the branch add signal from the branch cable, the second optical routing device being controllable to couple the branch add signal to a fiber of one of the plurality of fiber pairs.', '3. The optical communication system of claim 1, wherein the second optical routing device is coupled to the branch cable through an associated optical splitter, wherein the optical splitter has an input port coupled to the branch cable to receive the branch add signal and a plurality of output ports, one of the plurality of output ports being coupled to the second optical routing device; wherein a second one of the output ports is coupled to a third optical routing device, the third wavelength device being controllable to couple the branch add signal to separate fiber of one of the plurality of fiber pairs.']",False,"['112', '112', '13', '422', '420', '162', '412', '404', '402', '406', '408', '410', '4']" 846,EP_3605890_A1.png,EP3605890A1,SUBMARINE CABLE BRANCHING UNITS WITH FIBER PAIR SWITCHING,['FIG1'],['FIG1 is a schematic illustration of one example of an optical communication system consistent with the present disclosure'],"['FIG1 illustrates an exemplary branched optical communication system 100 consistent with the present disclosure. The system 100 has been depicted in highly-simplified form for ease of explanation. The illustrated system 100 includes land-based trunk terminals 110 and 120 coupled to a trunk cable 112, and a land-based branch terminal 160 coupled to the trunk cable 112 through a branch cable 162. In some embodiments, the system 100 may be configured as a long-haul system, e.g. having a length between at least two of the terminals of more than about 600km, which spans a body of water, e.g. an ocean. The trunk cable 112 may thus span between beach landings.', 'Consistent with present disclosure, at least one fiber pair switching branching unit (FPS-BU) 130 may be coupled to the trunk cable between the trunk terminals 110, 120. As will be described in greater detail below, the FPS-BU 130 is configured to allow remote and selectively controllable routing of trunk cable fiber pairs to branch cable fiber pairs. In some embodiments, the FPS-BU 130 is configured to allow remote and selectively controllable routing of two or more trunk cable fiber pairs to a fewer number of branch cable fiber pairs. Although the FPS-BU 130 is illustrated as a single element in FIG1, it is to be understood that the functionality of the FPS-BU 130 may be integrated into a single element disposed in a single housing, or portions of the functionality may be physically separate from each other, e.g. by several kilometres or by one or more water depths to allow the elements to be retrieved from an ocean floor for repair or replacement independently of one another.', 'Although illustrated a separate element in FIG1, the WMU 150 may be integral with the FPS-BU 130 or a portion thereof, i.e. incorporated into the housing of the FPS-BU 130, or may be physically separate therefrom, e.g. by several kilometers or one or more water depths. The FPS-BU 130 and the optional WMU 150 may be coupled to the branch terminal 160 through the branch cable 162. The FPS-BU 130 and WMU 150 may together form a branching configuration 163. The FPS-BU 130 allows selectively controllable routing of trunk cable fiber pairs to branch cable fiber pairs and, optionally via the WMU 150, directs optical signals to and from the branch cable 162 and branch terminal 160, by dropping and adding allocated channel wavelengths.']",18,465,schematic,G,"[{'element_identifier': '160', 'terms': ['branch terminal', 'branch terminals']}, {'element_identifier': '130', 'terms': ['FPS-BU']}, {'element_identifier': '100', 'terms': ['system']}, {'element_identifier': '170', 'terms': ['repeaters']}, {'element_identifier': '112', 'terms': ['cable']}, {'element_identifier': '162', 'terms': ['branch cable', 'branch cables']}, {'element_identifier': '163', 'terms': ['branching configuration']}, {'element_identifier': '110', 'terms': ['terminals']}, {'element_identifier': '150', 'terms': ['WMU']}, {'element_identifier': '114', 'terms': ['e.g. cable segments']}, {'element_identifier': '120', 'terms': ['includes land-based trunk terminals']}]","['1. An optical communication system comprising: a trunk terminal configured to provide trunk signals on a plurality of fiber pairs of a trunk cable; a branch terminal configured to provide a branch add signal on a branch cable; and a fiber pair switching branching unit coupled to the trunk cable and the branch cable for receiving the trunk signals and the branch add signal, the branching unit comprising: at least a first optical routing device coupled to the trunk cable and configured to receive the trunk signals from each of the plurality of fiber pairs, the first optical routing device being controllable to couple signals from selected one of the plurality of fiber pairs to a drop fiber of the branch cable; and at least a second optical routing device coupled to the branch cable and configured to receive the branch add signal from the branch cable, the second optical routing device being controllable to couple the branch add signal to a fiber of one of the plurality of fiber pairs.']",False,"['100', '110', '112', '120', '112', '170', '130', '170', '114', '163', '115', '162', '116', '150', '170', '160', '10', '1']" 847,EP_3605892_A1.png,EP3605892A1,"INFORMATION TRANSMISSION METHOD AND DEVICE, AND STORAGE MEDIUM",['FIG5'],['FIG5 is a schematic diagram illustrating periodic CSI reporting in which CQI reporting periods corresponding to different target BLERs are independent from each other according to an embodiment of the present application'],"['In a manner 1-2, the CQI reporting periods corresponding to the target BLERs are independently configured. FIG5 is a schematic diagram illustrating periodic CSI reporting in which CQI reporting periods corresponding to different target BLERs are independent from each other according to an embodiment of the present application.', 'FIG5 is a schematic diagram illustrating periodic CSI reporting in which CQI reporting periods corresponding to different target BLERs are independent from each other according to an embodiment of the present application. It is to be noted that CSI includes at least a CQI, and the CSI is replaced with the CQI for description below. In a case 1, a CQI corresponding to a single target BLER is reported at a period of 5 ms which is used as an example. It is to be noted that the value (5) of the period is not limited to the example, and a unit (ms) of the period is not limited to the example. In a case 2, CQIs corresponding to three kinds of target BLERs are reported, a CQI reporting period for a target BLER equal to 10% is 10 ms, a CQI reporting period for a target BLER equal to 1% is 10 ms, a CQI reporting period for a target BLER equal to 0.1% is 10 ms, and a period for reporting the CQIs corresponding to all the three target BLERs is less than the period of 5 ms for reporting the CQI corresponding to the single target BLER in the case 1 and comprehensively calculated as 2.5 ms. The CQIs corresponding to more kinds of target BLERs are reported in a similar manner, which is not repeated.']",32,305,schematic diagram,H,"[{'element_identifier': '5', 'terms': ['in Table']}, {'element_identifier': '2', 'terms': ['case']}, {'element_identifier': '20', 'terms': ['reporting module', 'is']}]","['3. The method of claim 2, wherein the uniform configuring in which all of the CSI transmission periods corresponding to the different target transmission error probabilities are the same is implemented by the following manner: configuring a period of N p to transmit CSI corresponding to B kinds of target transmission error probabilities at a same period of N p , wherein CSI reporting time corresponding to each kind of target transmission error probability has a different offset value of N OFFSET,CQI,i , and B is a positive integer.']",True,"['20', '2', '5', '19']" 848,EP_3605913_A1 (4).png,EP3605913A1,INFORMATION TRANSMISSION METHOD AND DEVICE,['FIG8'],['FIG8 is a flowchart of an embodiment of an information transmission method according to this application'],"['FIG8 is a flowchart of an embodiment of an information transmission method according to this application. As shown in FIG8, in this embodiment, for example, at least two of PUCCH resources indicated by a plurality of pieces of DCI are different PUCCH resources, and a terminal device determines a target PUCCH resource in the at least two different PUCCH resources according to a preset rule. The method of this embodiment may include the following steps.']",16,82,flowchart,H,"[{'element_identifier': '2', 'terms': ['No.']}]","['2. The method according to claim 1, wherein the PUCCH resources indicated by the plurality of pieces of DCI are a same PUCCH resource, and the sending, by the terminal device, target UCI on a target PUCCH resource comprises: sending, by the terminal device, the target UCI and indication information on the target PUCCH resource, wherein the indication information is used to indicate a type of the target UCI, the type of the target UCI comprises a first type and a second type, UCI of the first type comprises channel state information CSI, and UCI of the second type does not comprise CSI, or, a quantity of bits of UCI of the first type is within a first preset range, and a quantity of bits of UCI of the second type is within a second preset range.']",True,"['4', '8', '2', '2', '9', '30']" 849,EP_3605913_A1 (5).png,EP3605913A1,INFORMATION TRANSMISSION METHOD AND DEVICE,"['FIG10', ' FIG11']","['FIG10 is a schematic diagram of PUCCH resources respectively indicated by DCIO and DCI1 ', 'FIG11 is a schematic structural diagram of an embodiment of a terminal device according to this application']","['FIG10 a schematic diagram of the PUCCH resources respectively indicated by DCIO and DCI1. As shown in FIG10, the No. 1 PUCCH resource and the No. 2 PUCCH resource are different PUCCH resources. A quantity of encoded bits that the No. 1 PUCCH resource can carry is greater than that the No. 2 PUCCH resource can. Specifically, because a quantity of bits of UCI required to report only A/N1 may be greatly different from a quantity of bits of UCI required to report both A/N1 and the CSI, DCI1 allocates another PUCCH resource, namely, the No. 2 PUCCH resource. However, the No. 2 resource and the No. 1 resource occupy a same OFDM symbol. To be specific, the CSI, A/N0, and A/N1 that correspond to DCIO and DCI1 are reported at a same moment but by using different PUCCH resources. ', 'FIG11 is a schematic structural diagram of an embodiment of a terminal device according to this application. As shown in FIG11, the terminal device of this embodiment may include a receiving module 11 and a sending module 12. The receiving module 11 is configured to receive a plurality of pieces of downlink control information DCI, where each of the plurality of pieces of DCI is used to trigger reporting of one piece of UCI and indicate a physical uplink control channel PUCCH resource carrying the UCI, the UCI includes at least one piece of channel state information CSI and response information, and PUCCH resources indicated by the plurality of pieces of downlink DCI occupy at least one same orthogonal frequency division multiplexing OFDM symbol. The sending module 12 is configured to send target UCI on a target PUCCH resource, where the target UCI includes UCI triggered by the plurality of pieces of DCI, and the target PUCCH resource is one of the PUCCH resources indicated by the plurality of pieces of DCI.']",31,352,"schematic diagram, schematic structural diagram",H,"[{'element_identifier': '12', 'terms': ['sending module']}, {'element_identifier': '2', 'terms': ['No.']}, {'element_identifier': '11', 'terms': ['receiving module']}, {'element_identifier': '1', 'terms': ['No.']}]","['2. The method according to claim 1, wherein the PUCCH resources indicated by the plurality of pieces of DCI are a same PUCCH resource, and the sending, by the terminal device, target UCI on a target PUCCH resource comprises: sending, by the terminal device, the target UCI and indication information on the target PUCCH resource, wherein the indication information is used to indicate a type of the target UCI, the type of the target UCI comprises a first type and a second type, UCI of the first type comprises channel state information CSI, and UCI of the second type does not comprise CSI, or, a quantity of bits of UCI of the first type is within a first preset range, and a quantity of bits of UCI of the second type is within a second preset range.', '22. A terminal device, comprising: a receiving module, configured to receive a plurality of pieces of downlink control information DCI, wherein each of the plurality of pieces of DCI is used to trigger reporting of one piece of UCI and indicate a physical uplink control channel PUCCH resource carrying the UCI, the UCI comprises at least one piece of channel state information CSI and response information, and PUCCH resources indicated by the plurality of pieces of downlink DCI occupy at least one same orthogonal frequency division multiplexing OFDM symbol; and a sending module, configured to send target UCI on a target PUCCH resource, wherein the target UCI comprises UCI triggered by the plurality of pieces of DCI, and the target PUCCH resource is one of the PUCCH resources indicated by the plurality of pieces of DCI.']",True,"['2', '10', '1', '12', '11', '31']" 850,EP_3605913_A1 (6).png,EP3605913A1,INFORMATION TRANSMISSION METHOD AND DEVICE,"['FIG12', ' FIG13']","['FIG12 is a schematic structural diagram of an embodiment of a terminal device according to this application ', 'FIG13 is a schematic structural diagram of an embodiment of a network device according to this application']","['FIG12 is schematic structural diagram of an embodiment of a terminal device according to this application. As shown in FIG12, based on the apparatus structure shown in FIG12, the apparatus of this embodiment may further include a determining module 13. The determining module 13 is configured to: determine the type of the target UCI based on the plurality of pieces of DCI; and determine the type of the target UCI as the first type if one of the plurality of pieces of DCI triggers CSI reporting, and/or determine the type of the target UCI as the second type if none of the plurality of pieces of DCI triggers CSI reporting. ', 'FIG13 is a schematic structural diagram of an embodiment of a network device according to this application. As shown in FIG13, the network device in this embodiment may include a sending module 21 and a receiving module 22. The sending module 21 is configured to send a plurality of pieces of downlink control information DCI, where each of the plurality of pieces of DCI is used to trigger reporting of one piece of UCI and indicate a physical uplink control channel PUCCH resource carrying the UCI, the UCI includes at least one piece of channel state information CSI and response information, and PUCCH resources indicated by the plurality of pieces of downlink DCI occupy at least one same orthogonal frequency division multiplexing OFDM symbol. The receiving module 22 is configured to receive target UCI on a target PUCCH resource, where the target PUCCH resource is one of the PUCCH resources indicated by the plurality of pieces of DCI, and the target UCI includes UCI triggered by all or some of the plurality of pieces of DCI.']",34,304,schematic structural diagram,H,"[{'element_identifier': '12', 'terms': ['sending module']}, {'element_identifier': '11', 'terms': ['receiving module']}, {'element_identifier': '22', 'terms': ['receiving module']}, {'element_identifier': '21', 'terms': ['sending module']}, {'element_identifier': '23', 'terms': ['determining module']}, {'element_identifier': '13', 'terms': ['determining module']}]","['22. A terminal device, comprising: a receiving module, configured to receive a plurality of pieces of downlink control information DCI, wherein each of the plurality of pieces of DCI is used to trigger reporting of one piece of UCI and indicate a physical uplink control channel PUCCH resource carrying the UCI, the UCI comprises at least one piece of channel state information CSI and response information, and PUCCH resources indicated by the plurality of pieces of downlink DCI occupy at least one same orthogonal frequency division multiplexing OFDM symbol; and a sending module, configured to send target UCI on a target PUCCH resource, wherein the target UCI comprises UCI triggered by the plurality of pieces of DCI, and the target PUCCH resource is one of the PUCCH resources indicated by the plurality of pieces of DCI.', '24. The terminal device according to claim 23, further comprising: a determining module, configured to: determine the type of the target UCI based on the plurality of pieces of DCI; and determine the type of the target UCI as the first type if one of the plurality of pieces of DCI triggers CSI reporting, and/or determine the type of the target UCI as the second type if none of the plurality of pieces of DCI triggers CSI reporting.']",True,"['11', '13', '12', '12', '21', '22', '13', '21', '23', '22', '14', '32']" 851,EP_3605913_A1.png,EP3605913A1,INFORMATION TRANSMISSION METHOD AND DEVICE,['FIG2'],['FIG2 is a schematic diagram of a to-be-coded information bit sequence formed by a terminal device'],"['In this application, based on the resolution of transmission, on a PUCCH resource, of aperiodic CSI triggered by DCI, further, when the aperiodic CSI is transmitted, the aperiodic CSI is triggered by the DCI, and the PUCCH resource is also allocated by the DCI that triggers the CSI. For example, DCIO triggers the aperiodic CSI and downlink data packet scheduling, and after DCI0, DCI1 triggers downlink data scheduling for the second time, and DCIO and DCI1 indicate that CSI, A/N0, and A/N1 are reported by using a same PUCCH resource at a moment n+2. According to the prior art, the terminal device may determine, based on the used PUCCH resource and according to a predefined rule, a length K of an information bit sequence of the UCI when the UCI is transmitted by using the PUCCH resource, where K is a positive integer. Then, the terminal device forms an information bit sequence in a mapping manner that an information bit sequence of an A/N is in front of an information bit sequence of CSI, and determines, based on a comparison between a length X of the information bit sequence and K, whether to pad K-X dummy bits behind the sequence, so that a length of a to-be-coded information bit sequence reaches K. Then, the terminal device performs operations such as coding and modulation on the to-be-coded information bit sequence with the length of K, and then adds the information bit sequence to the PUCCH resource for reporting to the network device. In this manner, FIG2 is a schematic diagram of the to-be-coded information bit sequence formed by the terminal device. In FIG2, it is assumed that the length K is exactly equal to X. Certainly, K may be alternatively greater than X, provided that the terminal device pads dummy bits in predefined positions. After performing operations such as demodulation and channel decoding, the network device obtains the information bit sequence with the length of K, and sequentially obtains A/N0, A/N1, and CSI based on a sequence in FIG2.']",20,401,schematic diagram,H,"[{'element_identifier': '3', 'terms': ['not described herein again.']}, {'element_identifier': '2', 'terms': ['No.']}]","['2. The method according to claim 1, wherein the PUCCH resources indicated by the plurality of pieces of DCI are a same PUCCH resource, and the sending, by the terminal device, target UCI on a target PUCCH resource comprises: sending, by the terminal device, the target UCI and indication information on the target PUCCH resource, wherein the indication information is used to indicate a type of the target UCI, the type of the target UCI comprises a first type and a second type, UCI of the first type comprises channel state information CSI, and UCI of the second type does not comprise CSI, or, a quantity of bits of UCI of the first type is within a first preset range, and a quantity of bits of UCI of the second type is within a second preset range.']",True,"['2', '3', '4', '26']" 852,EP_3605917_A1 (4).png,EP3605917A1,"INFORMATION PROCESSING METHOD AND APPARATUS, AND COMMUNICATION DEVICE","['FIG3', ' FIG4']","['FIG3 is a flowchart of an information processing method according to another embodiment of the present invention ', 'FIG4 is a flowchart of an information processing method according to another embodiment of the present invention']","['FIG3 is a flowchart of an information processing method according to an embodiment of the present invention, and the information processing method may be applied to a channel on which LDPC encoding is used, and includes:301. Add redundancy check bits to a bit sequence A corresponding to first information to obtain a bit sequence C. ', 'In another embodiment of the present invention, LDPC encoding may be performed first on a bit sequence C to which redundancy check bits are added, and then cyclic shift is performed based on a shift t and a lifting factor z. FIG4 is a flowchart of an information processing method according to an embodiment of the present invention, and the information processing method may be applied to a channel on which LDPC encoding is used, and includes:401. Add redundancy check bits to a bit sequence A corresponding to first information to obtain a bit sequence C.']",34,159,flowchart,H,"[{'element_identifier': '3', 'terms': ['equation']}, {'element_identifier': '4', 'terms': ['lifting factor is', 'every', 'equation']}, {'element_identifier': '403', 'terms': ['in step']}, {'element_identifier': '301', 'terms': ['step']}, {'element_identifier': '302', 'terms': ['step']}, {'element_identifier': '402', 'terms': ['D obtained in step']}, {'element_identifier': '401', 'terms': ['step']}]","['2. The method according to claim 1, wherein the performing cyclic shift on the bit sequence C based on a shift t and a lifting factor z to obtain a bit sequence C t comprises: separately performing t-bit cyclic shift on every z bits in the bit sequence C to obtain the bit sequence C t .']",True,"['301', '4', '302', '7', '303', '3', '401', '402', '4', '403', '4', '25']" 853,EP_3605917_A1 (5).png,EP3605917A1,"INFORMATION PROCESSING METHOD AND APPARATUS, AND COMMUNICATION DEVICE","['FIG5', ' FIG6']","['FIG5 is a flowchart of an information processing method according to another embodiment of the present invention ', 'FIG6 is a flowchart of an information processing method according to another embodiment of the present invention']","['FIG5 is a schematic flowchart of an information processing method according to another embodiment of the present invention, and the method may be applied to a channel on which LDPC encoding is used, and includes:501. Perform low-density parity-check LDPC decoding based on a first soft value sequence to obtain a bit sequence Ct. ', 'FIG6 is a schematic flowchart of an information processing method according to another embodiment of the present invention. Alternatively, a shift t may be determined first, and then an LDPC code is decoded after being reversely circularly shifted by t bits. The method may be applied to a channel on which LDPC encoding is used, and includes:601. Perform reverse cyclic shift on a first soft value sequence based on a shift t and a lifting factor z to obtain a soft value sequence corresponding to a bit sequence D, where t is an integer greater than or equal to 0.']",34,169,flowchart,H,"[{'element_identifier': '5', 'terms': ['if Ci includes']}, {'element_identifier': '6', 'terms': ['every']}]","['2. The method according to claim 1, wherein the performing cyclic shift on the bit sequence C based on a shift t and a lifting factor z to obtain a bit sequence C t comprises: separately performing t-bit cyclic shift on every z bits in the bit sequence C to obtain the bit sequence C t .']",True,"['501', '502', '503', '5', '601', '602', '603', '6', '26']" 854,EP_3605924_A1 (3).png,EP3605924A1,WIRELESS COMMUNICATION METHOD AND DEVICE,['FIG4'],['FIG4 is a schematic diagram of different patterns of PTRSs'],"['FIG4 is a schematic diagram of different patterns of PTRSs, and (a) in FIG4 is a schematic diagram of a current pattern of a PTRS. The network device determines the pattern of the phase tracking reference signal based on the at least one of the modulation and coding scheme threshold that is corresponding to the pattern of the phase tracking reference signal and requested by the terminal device, the scheduled resource block quantity threshold that is corresponding to the pattern of the phase tracking reference signal and requested by the terminal device, and the factor of the impact of the phase noise of the terminal device on the signal received by the terminal device that are sent by the terminal device and the at least one of the currently scheduled modulation and coding scheme and the currently scheduled bandwidth. The determined pattern of the PTRS may be (b) in FIG4 or (c) in FIG4. In FIG. (a), a PTRS has a frequency domain density of 1 (there is one PTRS on every 12 subcarriers) and a time domain density of 1. In FIG. (b), a PTRS has a frequency domain density of 1 (there is one PTRS on every 12 subcarriers) and a time domain density of 1/2. In FIG. (c), a PTRS has a frequency domain density of 1/2 (there is one PTRS on every 24 subcarriers) and a time domain density of 1. The network device flexibly adjusts the pattern of the phase tracking reference signal, so that a quantity of subcarriers occupied by the phase tracking reference signal is reduced.']",10,298,schematic diagram,H,"[{'element_identifier': '4', 'terms': ['Table']}]","['3. The method according to claim 1, wherein before the determining, by a network device, a pattern of a phase tracking reference signal based on at least one of a modulation and coding scheme threshold that is corresponding to the pattern of the phase tracking reference signal and requested by a terminal device, a scheduled resource block quantity threshold that is corresponding to the pattern of the phase tracking reference signal and requested by the terminal device, and a factor of impact of phase noise of the terminal device on a signal received by the terminal device and at least one of a modulation and coding scheme currently scheduled by the network device for the terminal device and bandwidth currently scheduled by the network device for the terminal device, the method further comprises: receiving, by the network device, a number of a table of the modulation and coding scheme threshold corresponding to the pattern of the phase tracking reference signal and/or a number of a table of the scheduled resource block quantity threshold corresponding to the pattern of the phase tracking reference signal that are/is sent by the terminal device.']",False,"['4', '37']" 855,EP_3605924_A1.png,EP3605924A1,WIRELESS COMMUNICATION METHOD AND DEVICE,['FIG1'],"['FIG1 is a schematic diagram of a communications system including a wireless communication method, a network device, and a terminal device according to this application']","['FIG1 is a schematic diagram of a communications system 100 including a wireless communication method and a device according to this application. As shown in FIG1, the communications system 100 includes a network device 102. The network device 102 may include a plurality of antennas such as antennas 104, 106, 108, 110, 112, and 114. In addition, the network device 102 may include a transmitter chain and a receiver chain. A person of ordinary skill in the art may understand that the transmitter chain and the receiver chain each may include a plurality of components (for example, a processor, a modulator, a multiplexer, a demodulator, a demultiplexer, or an antenna) related to signal sending and receiving.', 'As shown in FIG1, the terminal device 116 communicates with the antennas 112 and 114. The antennas 112 and 114 send information to the terminal device 116 over a forward link 118, and receive information from the terminal device 116 over a reverse link 120. In addition, the terminal device 122 communicates with the antennas 104 and 106. The antennas 104 and 106 send information to the terminal device 122 over a forward link 124, and receive information from the terminal device 122 over a reverse link 126.', 'In addition, the communications system 100 may be a public land mobile network (Public Land Mobile Network, PLMN), a D2D (Device to Device) network, an M2M (Machine to Machine) network, or another network. FIG1 is merely a simplified schematic diagram of an example. The network may further include another network device that is not shown in FIG1.']",27,306,schematic diagram,H,"[{'element_identifier': '100', 'terms': ['communications system']}, {'element_identifier': '106', 'terms': ['antennas']}, {'element_identifier': '104', 'terms': ['antennas']}, {'element_identifier': '1', 'terms': ['number']}]","['3. The method according to claim 1, wherein before the determining, by a network device, a pattern of a phase tracking reference signal based on at least one of a modulation and coding scheme threshold that is corresponding to the pattern of the phase tracking reference signal and requested by a terminal device, a scheduled resource block quantity threshold that is corresponding to the pattern of the phase tracking reference signal and requested by the terminal device, and a factor of impact of phase noise of the terminal device on a signal received by the terminal device and at least one of a modulation and coding scheme currently scheduled by the network device for the terminal device and bandwidth currently scheduled by the network device for the terminal device, the method further comprises: receiving, by the network device, a number of a table of the modulation and coding scheme threshold corresponding to the pattern of the phase tracking reference signal and/or a number of a table of the scheduled resource block quantity threshold corresponding to the pattern of the phase tracking reference signal that are/is sent by the terminal device.']",False,"['100', '26', '108', '106', '104', '1', '34']" 856,EP_3605948_A2 (3).png,EP3605948A2,DISTRIBUTING OVERLAY NETWORK INGRESS INFORMATION,['FIG5'],['FIG5 is yet another diagram of the system of FIG1'],"['The client device may receive the response and use the additional data to set up a connection. For example, if the additional data has been encrypted, the client device may decrypt the additional data in order to access the information additional data identifying bastion host 180, the port for the bastion host, and the connection method. As shown in FIG5, client device 110 may then request to connect to resource R-2 via bastion host 180 by way of the connection method identified in the response 410. Bastion host 180 may verify the request based on the connection method used by client device 110. If the request is not verified, the bastion host 180 may deny the client device access to the resource R-2. If the request is verified, the bastion host may establish connection 510 between the bastion host and the client device. In one example, connection 510 may be a tunnel connection though network 150.']",10,171,diagram,H,"[{'element_identifier': '160', 'terms': ['network']}, {'element_identifier': '180', 'terms': ['bastion host']}, {'element_identifier': '190', 'terms': ['bastion hosts', 'bastion host']}, {'element_identifier': '510', 'terms': ['connection']}, {'element_identifier': '110', 'terms': ['client device', 'client devices']}, {'element_identifier': '150', 'terms': ['network', 'networks']}, {'element_identifier': '170', 'terms': ['bastion hosts', 'bastion host']}, {'element_identifier': '120', 'terms': ['DNS']}]","['1. A computer-implemented method for providing a resource record for reaching a protected resource of a first network, the method comprising: receiving, over a second network from a client device, a request identifying the protected resource; querying memory to identify a network address of the protected resource; determining, by a processor, whether the protected resource is generally accessible based on the identified network address, wherein a resource is generally accessible if it is not in shared address space; if the protected resource is not generally accessible, identifying reachability information for the protected resource; generating additional information based on the reachability information; and transmitting the additional information and the network address to the client device.', '4. A computer-implemented method for accessing a publically available resource of a first, public network, the method comprising: transmitting, over a second, private network, a request identifying the public resource; receiving, from an authentication server, information identifying a bastion host, a port, and a connection method; generating, by a processor, a request to access the public resource based on the connection method; transmitting the request to the port in order to establish a tunnel connection between the bastion host and the client device; and accessing the public resource via the tunnel connection with the bastion host.', '5. The method of claim 4, wherein the authentication server is a DNS server that provides network addresses in response to queries from client devices associated with network locations within the first, private network.']",False,"['160', '170', '180', '190', '510', '110', '150', '15', '120', '5']" 857,EP_3605948_A2 (4).png,EP3605948A2,DISTRIBUTING OVERLAY NETWORK INGRESS INFORMATION,['FIG6'],['FIG6 is a further diagram of the system of FIG1'],"['Once the connection has been successfully established, the client may use the connection to access the resource. For example, the client device may use the overlay network interface of the tunnel to establish an application-layer connection 610 to resource R-2 at scheme://resource_R2.internal.corp.example, as shown in FIG6.']",10,53,diagram,H,"[{'element_identifier': '160', 'terms': ['network']}, {'element_identifier': '16', 'terms': ['November']}, {'element_identifier': '190', 'terms': ['bastion hosts', 'bastion host']}, {'element_identifier': '610', 'terms': ['application-layer connection']}, {'element_identifier': '510', 'terms': ['connection']}, {'element_identifier': '110', 'terms': ['client device', 'client devices']}, {'element_identifier': '150', 'terms': ['network', 'networks']}, {'element_identifier': '170', 'terms': ['bastion hosts', 'bastion host']}, {'element_identifier': '120', 'terms': ['DNS']}]","['1. A computer-implemented method for providing a resource record for reaching a protected resource of a first network, the method comprising: receiving, over a second network from a client device, a request identifying the protected resource; querying memory to identify a network address of the protected resource; determining, by a processor, whether the protected resource is generally accessible based on the identified network address, wherein a resource is generally accessible if it is not in shared address space; if the protected resource is not generally accessible, identifying reachability information for the protected resource; generating additional information based on the reachability information; and transmitting the additional information and the network address to the client device.', '4. A computer-implemented method for accessing a publically available resource of a first, public network, the method comprising: transmitting, over a second, private network, a request identifying the public resource; receiving, from an authentication server, information identifying a bastion host, a port, and a connection method; generating, by a processor, a request to access the public resource based on the connection method; transmitting the request to the port in order to establish a tunnel connection between the bastion host and the client device; and accessing the public resource via the tunnel connection with the bastion host.', '5. The method of claim 4, wherein the authentication server is a DNS server that provides network addresses in response to queries from client devices associated with network locations within the first, private network.']",False,"['160', '170', '610', '510', '110', '190', '150', '16', '120', '6']" 858,EP_3605974_A1 (4).png,EP3605974A1,INFORMATION TRANSFER METHOD AND DEVICE,['FIG11'],['FIG11 is a schematic diagram of an information transfer device according to an embodiment of the present application'],"['As shown in FIG11, in an embodiment of the present disclosure, there is further provided an information transfer device applied to a user side node, the device including:a first sending module 1101 configured to send a multicast protocol message or routing protocol message carrying a user side flag to a forwarding side node.']",18,59,schematic diagram,H,"[{'element_identifier': '1201', 'terms': ['second receiving module']}, {'element_identifier': '1203', 'terms': ['anda second sending module']}, {'element_identifier': '2', 'terms': ['Receiver']}, {'element_identifier': '1101', 'terms': ['first sending module']}, {'element_identifier': '1202', 'terms': ['processing module']}, {'element_identifier': '1102', 'terms': ['first receiving module']}]","['9. An information transfer device applied to a user side node, comprising: a first sending module (1101) configured to send a multicast protocol message or routing protocol message carrying a user side flag to a forwarding side node.', '13. An information transfer device applied to a forwarding side node, comprising: a second receiving module (1201) configured to receive a multicast protocol message or routing protocol message carrying a user side flag sent from a directly connected user side node; a processing module (1202) configured to identify, after the multicast protocol message or the routing protocol message carrying the user side flag sent from the directly connected user side node is received by the second receiving module (1201), the user side node in a forwarding table; and a second sending module (1203) configured to forward a packet to the user side node according to the forwarding table, wherein a destination address of the packet is encapsulated as an address of the user side node.']",True,"['2', '00', '9', '2', '19', '10', '1101', '1102', '11', '12', '1201', '1202', '1203', '17']" 859,EP_3605974_A1 (5).png,EP3605974A1,INFORMATION TRANSFER METHOD AND DEVICE,"['FIG13', ' FIG14']","['FIG14 is a schematic structural diagram of a forwarding side node for implementing the information transfer method according to an embodiment of the present application ', 'FIG13 is a schematic structural diagram of a user side node for implementing the information transfer method according to an embodiment of the present application']","['As shown in FIG14, in an embodiment of the present disclosure, there is further provided an information transfer device applied to a forwarding side node 1400, the device including: a transmitting module 1406, a memory 1404, and one or more processors 1402 (only one shown in the figure); wherein the memory 1404 is configured to store a program for information transfer which, when read and executed by the processor 1402, causes the following operations to be performed:identifying, after the transmitting module 1406 receives a multicast protocol message or routing protocol message carrying a user side flag sent from a directly connected user side node, the user side node in a forwarding table; and forwarding a packet to the user side node according to the forwarding table, wherein a destination address of the packet is encapsulated as an address of the user side node.', 'It will be understood by those ordinary skilled in the art that the structure shown in FIG14 is merely illustrative, and does not form any limitation to the structure of the above electronic device. For example, the forwarding side node may include more or fewer components than those shown in FIG14, or have a configuration different from that shown in FIG14. ', 'As shown in FIG13, in an embodiment of the present disclosure, there is further provided an information transfer device applied to a user side node 1300, the device including: a transmitting module 1306, a memory 1304, and one or more processors 1302 (only one shown in the figure); wherein the memory 1304 is configured to store a program for information transfer which, when read and executed by the processor 1302, causes the following operation to be performed: transmitting, by the transmitting module 1306, a multicast protocol message or routing protocol message carrying a user side flag to a forwarding side node.', 'It will be understood by those ordinary skilled in the art that the structure shown in FIG13 is merely illustrative, and does not form any limitation to the structure of the above electronic device. For example, the user side node 1300 may include more or fewer components than those shown in FIG13, or have a different configuration than that shown in FIG13.']",50,412,schematic structural diagram,H,"[{'element_identifier': '1300', 'terms': ['user side node']}, {'element_identifier': '1304', 'terms': ['memory']}, {'element_identifier': '14', 'terms': ['andFig.']}, {'element_identifier': '1406', 'terms': ['transmitting module']}, {'element_identifier': '1404', 'terms': ['memory']}, {'element_identifier': '1302', 'terms': ['processor', 'processors']}, {'element_identifier': '1400', 'terms': ['forwarding side node']}, {'element_identifier': '1306', 'terms': ['transmitting module']}, {'element_identifier': '1402', 'terms': ['processor', 'processors']}]","['1. An information transfer method, comprising: sending (S201), by a user side node, a multicast protocol message or routing protocol message carrying a user side flag to a forwarding side node.', '15. An information transfer device, comprising: a transmitting module (1306), a memory (1304), and a processor (1302); wherein the memory (1304) is configured to store a program for information transfer which, when read and executed by the processor (1302), causes the following operation to be performed: transmitting, by the transmitting module (1306), a multicast protocol message or routing protocol message carrying a user side flag to a forwarding side node.']",True,"['1300', '1306', '1302', '1304', '13', '1400', '1406', '1402', '1404', '14', '18']" 860,EP_3605983_A1 (3).png,EP3605983A1,"SIGNAL PROCESSING METHOD, SIGNAL PROCESSING DEVICE, COMPUTER-READABLE STORAGE MEDIUM, AND COMPUTER PROGRAM PRODUCT","['FIG5', ' FIG7']","['FIG7 is a schematic structural diagram of another terminal device according to an embodiment of this application ', 'FIG5 is a schematic diagram of processing a first signal by a network device according to an embodiment of this application']","['As shown in FIG7, a signal processing apparatus 700 includes a processor 701 and a transceiver 703. Optionally, the signal processing apparatus 700 further includes a memory 702.', 'It may be understood that FIG7 shows merely a simplified design of the signal processing apparatus 700. In actual application, the signal processing apparatus 700 may include any quantities of transceivers, processors, memories, and the like, and all signal processing apparatuses 700 that can implement the embodiments of this application fall within the protection scope of the embodiments of this application. ', 'Optionally, FIG5 is a schematic diagram of a process in which the network device processes the first signal. The network device obtains all possible sequences by traversing a locally stored sequence fn′, and separately performs related processing and maximum likelihood comparison on the obtained sequence {fn} and all the possible sequences of the sequence fn′, to obtain data transmitted by the terminal device.']",38,171,"schematic diagram, schematic structural diagram",H,"[{'element_identifier': '601', 'terms': ['processing unit']}, {'element_identifier': '600', 'terms': ['signal processing apparatus']}, {'element_identifier': '701', 'terms': ['processor']}, {'element_identifier': '702', 'terms': ['memory']}, {'element_identifier': '602', 'terms': ['transceiver unit']}, {'element_identifier': '703', 'terms': ['transceiver']}, {'element_identifier': '700', 'terms': ['signal processing apparatus', 'signal processing apparatuses']}]","['7. A signal processing apparatus, comprising: a processing unit, configured to determine a sequence { f n } comprising N elements, wherein f n is an element in the sequence { f n }, the sequence { f n } meets fn = A·x n ·e 2 π·j·a·n , a value of n ranges from 0 to N-1, A is a non-zero complex number, a is a real number, an element x n = u · e ρ M π · j · s n / M , u is a non-zero complex number, M is 4, 12, or 16, ρ M is a real number, ρ M is 1 or -1 when M is 4, ρ M is 2 or -2 when M is 12 or 16, and a sequence { s n } comprising an element s n is a sequence in a first sequence set or an equivalent sequence of the sequence in the first sequence set, or a sequence in a second sequence set or an equivalent sequence of the sequence in the second sequence set, or a sequence in a third sequence set or an equivalent sequence of the sequence in the third sequence set, wherein the first sequence set comprises some or all of the following sequences, and M is 4: {-1, -1, -1, -1, -1, -1, 3, -1, 3, 3, -1, -1}, {3, 3, -1, 3, -1, 3, 3, -1, -1, -1, -1, -1}, {-1, -1, -1, -1, -3, 3, -1, 3, -3, -1, -1, -1}, {-1, -1, -1, -1, 1, 3, -1, 3, 1, -1, -1, -1}, {-3, 3, -1, -1, -3, -1, -1, 3, -3, 3, -1, -1}, {1, 3, -1, -1, 1, -1, -1, 3, 1, 3, -1, -1}, {-1, 3, -1, 3, -1, 3, 3, -1, -1, -1, -1, -1}, {-3, 3, -1, -3, 1, -1, 1, 3, 1, 1, -1, -1}, {1, 3, -1, 1, -3, -1, -3, 3, -3, -3, -1, -1}, {-3, 3, -1, 3, -1, 3, 3, -1, -1, -1, -1, -1}, {1, 3, -1, 3, -1, 3, 3, -1, -1, -1, -1, -1}, {3, -1, 3, 3, -1, 3, 3, 3, -1, -1, -1, -1}, {-1, 3, 1, -1, -3, 1, 3, -1, -1, -1, -1, -1}, {3, 1, 1, 1, -1, 3, 1, 1, 3, -3, -1, -1}, {3, -3, -3, -3, -1, 3, -3, -3, 3, 1, -1, -1}, {3, 1, 1, -3, 3, 1, 3, 1, 3, -3, -1, -1}, {3, -3, -3, 1, 3, -3, 3, -3, 3, 1, -1, -1}, {-3, 3, -3, -3, -3, -1, 3, -3, 3, 1, -1, -1}, {1, 3, 1, 1, 1, -1, 3, 1, 3, -3, -1, -1}, {-3, -3, 1, 3, -3, 3, -3, 1, -1, -3, -1, -1}, {-3, -3, 1, 1, -1, -1, -3, 1, -3, -3, -1, -1}, {1, 1, -3, -3, -1, -1, 1, -3, 1, 1, -1, -1}, {1, 3, -3, 1, -3, -1, -1, -1, -3, 3, -1, -1}, {-3, 3, 1, -3, 1, -1, -1, -1, 1, 3, -1, -1}, {3, -1, -3, -1, -3, 3, 3, -3, -1, 3, -1, -1}, {3, -1, 1, -1, 1, 3, 3, 1, -1, 3, -1, -1}, {-3, 1, -1, -1, 3, 1, 3, -1, -1, 1, -1, -1}, {1, -3, -1, -1, 3, -3, 3, -1, -1, -3, -1, -1}, {1, -1, 1, -1, 3, -1, 1, 3, 3, 1, -1, -1}, {-3, 1, 3, -1, 3, -3, 3, 1, 3, 3, -1, -1}, {1, -3, 3, -1, 3, 1, 3, -3, 3, 3, -1, -1}, and {3, -1, 3, 3, -1, 3, 3, 3, 3, -1, -1, -1}, the second sequence set comprises a sequence in a sequence set 2A and/or a sequence in a sequence set 2B, the sequence set 2A comprises some or all of the following sequences, and M is 12: {0, 0, 6, 7, 10, 10, 10, 5, 10, 4, 2, 11}, {0, 0, 11, 0, 1, 11, 3, 8, 7, 2, 2, 9}, {0, 0, 2, 5, 8, 0, 7, 2, 0, 11, 11, 0}, {0, 0, 3, 4, 5, 3, 0, 7, 0, 4, 8, 8}, {0, 0, 9, 8, 7, 9, 0, 5, 0, 8, 4, 4}, {0, 0, 4, 6, 10, 11, 5, 1, 3, 1, 2, 0}, {0, 0, 0, 4, 4, 6, 0, 4, 1, 11, 6, 2}, {0, 0, 6, 3, 1, 8, 8, 10, 6, 10, 5, 10}, {0, 0, 3, 6, 10, 2, 9, 5, 3, 3, 4, 4}, {0, 0, 4, 3, 9, 8, 3, 6, 2, 5, 4, 6}, {0, 0, 1, 5, 5, 7, 1, 5, 2, 0, 7, 3}, {0, 0, 10, 9, 9, 6, 9, 1, 11, 5, 3, 10}, {0, 0, 8, 7, 6, 2, 4, 7, 4, 9, 7, 1}, {0, 0, 1, 4, 6, 9, 4, 10, 8, 7, 5, 6}, {0, 0, 9, 7, 6, 2, 4, 7, 4, 9, 6, 0}, {0, 0, 6, 7, 0, 1, 8, 4, 7, 5, 5, 5}, {0, 0, 4, 8, 0, 4, 0, 8, 7, 8, 9, 10}, {0, 0, 10, 9, 8, 10, 1, 6, 2, 10, 6, 7}, {0, 0, 4, 1, 7, 5, 10, 0, 8, 9, 7, 9}, {0, 0, 5, 0, 7, 1, 2, 8, 8, 8, 7, 9}, {0, 0, 7, 0, 5, 11, 10, 4, 4, 4, 5, 3}, {0, 0, 8, 8, 7, 7, 10, 2, 9, 5, 1, 11}, {0, 0, 9, 8, 7, 8, 11, 4, 0, 8, 3, 3}, {0, 0, 3, 4, 5, 4, 1, 8, 0, 4, 9, 9}, {0, 0, 4, 0, 6, 4, 9, 11, 7, 7, 6, 8}, {0, 0, 7, 5, 4, 11, 0, 3, 11, 4, 1, 5}, {0, 0, 8, 8, 8, 4, 7, 10, 7, 1, 0, 5}, {0, 0, 4, 0, 5, 2, 6, 7, 3, 3, 0, 0}, {0, 0, 7, 6, 5, 0, 1, 4, 0, 4, 2, 6}, {0, 0, 3, 6, 9, 0, 7, 2, 0, 0, 0, 0}, {0, 0, 1, 2, 4, 3, 8, 2, 2, 10, 10, 7}, {0, 0, 11, 1, 1, 0, 4, 9, 7, 2, 3, 10}, {0, 0, 4, 8, 11, 4, 1, 6, 5, 4, 3, 10}, {0, 0, 8, 4, 1, 8, 11, 6, 7, 8, 9, 2}, {0, 0, 2, 2, 5, 4, 9, 3, 4, 0, 0, 10}, {0, 0, 3, 10, 3, 0, 4, 5, 0, 11, 9, 10}, {0, 0, 11, 0, 1, 11, 3, 8, 7, 2, 2, 10}, {0, 0, 2, 5, 8, 11, 6, 1, 11, 10, 10, 10}, {0, 0, 4, 7, 10, 2, 10, 5, 4, 4, 3, 4}, {0, 0, 6, 6, 8, 7, 6, 0, 4, 10, 7, 2}, {0, 0, 5, 3, 11, 10, 4, 8, 5, 7, 7, 10}, {0, 0, 4, 7, 10, 4, 0, 7, 7, 6, 6, 8}, {0, 0, 8, 7, 5, 6, 9, 1, 9, 4, 10, 10}, {0, 0, 4, 5, 7, 6, 3, 11, 3, 8, 2, 2}, {0, 0, 8, 4, 4, 11, 0, 3, 0, 5, 1, 6}, {0, 0, 5, 5, 7, 6, 5, 11, 3, 9, 6, 1}, {0, 0, 3, 3, 4, 3, 0, 7, 0, 3, 8, 8}, {0, 0, 9, 8, 6, 7, 10, 2, 10, 5, 0, 0}, {0, 0, 0, 10, 0, 6, 8, 6, 0, 10, 6, 0}, {0, 0, 8, 10, 7, 8, 3, 9, 8, 0, 2, 2}, {0, 0, 6, 0, 8, 2, 4, 8, 7, 6, 6, 2}, {0, 0, 6, 0, 4, 10, 8, 4, 5, 6, 6, 10}, {0, 0, 7, 3, 1, 6, 6, 7, 2, 5, 1, 4}, {0, 0, 4, 1, 7, 5, 11, 1, 9, 10, 9, 11}, {0, 0, 4, 1, 10, 4, 3, 4, 10, 1, 9, 0}, {0, 0, 4, 0, 6, 4, 8, 10, 6, 6, 4, 6}, {0, 0, 0, 10, 8, 6, 0, 6, 9, 11, 0, 1}, {0, 0, 4, 2, 11, 2, 1, 7, 9, 5, 10, 0}, {0, 0, 8, 10, 1, 10, 11, 5, 3, 7, 2, 0}, {0, 0, 6, 4, 2, 0, 1, 4, 10, 5, 0, 7}, {0, 0, 4, 6, 11, 4, 10, 7, 5, 5, 6, 7}, {0, 0, 11, 0, 1, 4, 9, 3, 0, 9, 7, 7}, {0, 0, 1, 0, 11, 8, 3, 9, 0, 3, 5, 5}, {0, 0, 4, 6, 10, 2, 9, 5, 4, 4, 5, 5}, {0, 0, 7, 1, 9, 3, 5, 9, 8, 7, 6, 3}, {0, 0, 5, 9, 1, 6, 3, 10, 10, 10, 10, 0}, {0, 0, 2, 3, 6, 6, 11, 6, 7, 4, 4, 1}, {0, 0, 3, 5, 8, 8, 2, 9, 10, 7, 8, 6}, {0, 0, 10, 0, 11, 9, 1, 5, 3, 9, 10, 5}, {0, 0, 5, 10, 3, 9, 7, 3, 4, 5, 6, 9}, {0, 0, 4, 8, 1, 6, 2, 11, 10, 0, 2, 3}, {0, 0, 8, 4, 11, 6, 10, 1, 2, 0, 10, 9}, {0, 0, 4, 1, 9, 3, 1, 2, 8, 10, 6, 8}, {0, 0, 3, 11, 4, 1, 6, 7, 2, 2, 0, 1}, {0, 0, 5, 6, 7, 3, 2, 7, 3, 6, 0, 7}, {0, 0, 7, 6, 5, 9, 10, 5, 9, 6, 0, 5}, {0, 0, 7, 5, 2, 2, 4, 7, 2, 8, 2, 1}, {0, 0, 2, 5, 8, 11, 6, 1, 11, 11, 10, 11}, {0, 0, 4, 8, 1, 6, 3, 11, 11, 0, 0, 2}, {0, 0, 7, 1, 7, 0, 1, 4, 2, 0, 10, 7}, {0, 0, 8, 1, 7, 3, 2, 1, 4, 6, 11, 0}, {0, 0, 10, 7, 4, 1, 6, 11, 1, 1, 1, 2}, {0, 0, 4, 7, 10, 3, 11, 6, 6, 5, 5, 6}, {0, 0, 7, 6, 3, 3, 5, 8, 3, 9, 3, 2}, {0, 0, 9, 10, 2, 3, 4, 0, 6, 1, 1, 9}, {0, 0, 5, 4, 2, 11, 0, 3, 9, 4, 11, 6}, {0, 0, 4, 8, 11, 4, 1, 6, 5, 4, 3, 11}, {0, 0, 8, 4, 1, 8, 11, 6, 7, 8, 9, 1}, {0, 0, 7, 4, 1, 11, 0, 2, 7, 1, 7, 3}, {0, 0, 10, 10, 10, 7, 10, 2, 0, 6, 5, 0}, {0, 0, 0, 9, 9, 7, 1, 8, 11, 1, 4, 3}, {0, 0, 0, 3, 3, 5, 11, 4, 1, 11, 8, 9}, {0, 0, 0, 6, 9, 4, 6, 5, 11, 8, 4, 1}, {0, 0, 7, 8, 11, 11, 11, 6, 11, 6, 4, 0}, {0, 0, 5, 11, 5, 8, 8, 1, 11, 9, 8, 10}, {0, 0, 3, 5, 6, 9, 4, 7, 4, 2, 10, 7}, {0, 0, 6, 4, 3, 10, 11, 1, 9, 2, 10, 3}, {0, 0, 6, 5, 0, 0, 8, 0, 9, 0, 1, 4}, {0, 0, 0, 10, 9, 7, 1, 8, 11, 1, 4, 4}, {0, 0, 8, 7, 5, 6, 9, 1, 9, 4, 11, 10}, {0, 0, 1, 3, 3, 4, 10, 1, 9, 6, 1, 8}, {0, 0, 1, 3, 5, 7, 1, 7, 4, 3, 2, 1}, {0, 0, 1, 10, 0, 9, 0, 5, 4, 11, 9, 5}, {0, 0, 5, 8, 1, 6, 2, 11, 11, 0, 2, 2}, {0, 0, 7, 4, 11, 6, 10, 1, 1, 0, 10, 10}, {0, 0, 6, 11, 4, 8, 8, 10, 7, 4, 1, 9}, {0, 0, 11, 9, 9, 7, 1, 8, 11, 1, 4, 4}, {0, 0, 3, 1, 9, 5, 4, 6, 11, 4, 10, 3}, {0, 0, 3, 7, 10, 2, 10, 5, 4, 3, 3, 4}, {0, 0, 0, 1, 1, 0, 4, 9, 7, 2, 2, 9}, {0, 0, 8, 8, 7, 4, 6, 10, 7, 1, 11, 5}, {0, 0, 5, 9, 1, 5, 1, 9, 8, 9, 10, 11}, {0, 0, 11, 1, 3, 10, 11, 6, 3, 7, 4, 10}, {0, 0, 11, 0, 2, 3, 8, 2, 10, 9, 6, 6}, {0, 0, 10, 0, 9, 11, 7, 1, 1, 5, 7, 9}, {0, 0, 8, 8, 11, 11, 11, 6, 11, 5, 4, 11}, {0, 0, 11, 10, 0, 9, 1, 5, 4, 11, 10, 5}, {0, 0, 9, 2, 10, 6, 5, 5, 8, 0, 5, 7}, {0, 0, 8, 6, 4, 5, 7, 11, 5, 0, 7, 7}, {0, 0, 2, 4, 6, 8, 4, 4, 0, 6, 1, 6}, {0, 0, 2, 3, 5, 4, 9, 3, 3, 11, 0, 8}, {0, 0, 6, 9, 0, 5, 2, 7, 6, 5, 4, 11}, {0, 0, 6, 3, 0, 7, 10, 5, 6, 7, 8, 1}, {0, 0, 6, 4, 11, 10, 5, 8, 5, 7, 8, 11}, {0, 0, 6, 4, 2, 10, 10, 1, 9, 2, 9, 2}, {0, 0, 4, 9, 0, 5, 2, 9, 9, 9, 9, 0}, {0, 0, 3, 7, 10, 2, 10, 5, 4, 4, 4, 5}, {0, 0, 9, 8, 7, 6, 11, 9, 2, 6, 10, 4}, {0, 0, 3, 4, 5, 6, 1, 3, 10, 6, 2, 8}, {0, 0, 3, 5, 7, 9, 5, 8, 4, 1, 10, 6}, {0, 0, 1, 10, 8, 6, 0, 6, 9, 10, 0, 11}, {0, 0, 11, 2, 4, 6, 0, 6, 3, 2, 0, 1}, {0, 0, 2, 4, 5, 9, 3, 9, 7, 5, 4, 5}, {0, 0, 10, 6, 4, 0, 4, 10, 11, 0, 1, 0}, {0, 0, 2, 6, 8, 0, 8, 2, 1, 0, 11, 0}, {0, 0, 4, 5, 7, 6, 4, 11, 5, 9, 3, 3}, {0, 0, 0, 8, 5, 3, 8, 1, 4, 3, 5, 3}, {0, 0, 0, 4, 7, 9, 4, 11, 8, 9, 7, 9}, {0, 0, 7, 6, 5, 4, 6, 10, 5, 1, 9, 4}, {0, 0, 4, 8, 0, 4, 0, 8, 7, 8, 9, 9}, {0, 0, 8, 4, 0, 8, 0, 4, 5, 4, 3, 3}, {0, 0, 0, 0, 1, 11, 3, 8, 7, 2, 2, 9}, {0, 0, 5, 2, 0, 6, 5, 7, 2, 5, 1, 3}, {0, 0, 5, 11, 5, 8, 8, 10, 6, 4, 0, 9}, {0, 0, 8, 1, 5, 0, 4, 3, 10, 10, 0, 0}, {0, 0, 6, 6, 8, 8, 6, 0, 4, 10, 9, 4}, {0, 0, 4, 2, 1, 10, 11, 2, 7, 3, 10, 5}, {0, 0, 8, 7, 5, 6, 8, 0, 7, 2, 9, 8}, {0, 0, 5, 3, 11, 8, 8, 10, 4, 9, 4, 9}, {0, 0, 7, 5, 3, 10, 11, 1, 9, 1, 10, 2}, {0, 0, 3, 6, 8, 0, 8, 0, 10, 8, 6, 1}, {0, 0, 3, 10, 6, 11, 8, 9, 2, 3, 11, 11}, {0, 0, 11, 0, 0, 2, 7, 0, 9, 6, 2, 3}, {0, 0, 1, 0, 0, 10, 5, 0, 3, 6, 10, 9}, {0, 0, 7, 10, 4, 10, 7, 5, 6, 8, 11, 11}, {0, 0, 4, 8, 1, 5, 4, 6, 3, 11, 9, 4}, {0, 0, 1, 1, 4, 2, 7, 1, 1, 10, 8, 6}, {0, 0, 3, 8, 1, 3, 2, 6, 3, 0, 10, 10}, {0, 0, 4, 7, 10, 2, 10, 4, 3, 2, 1, 2}, {0, 0, 10, 10, 9, 11, 3, 8, 5, 1, 9, 9}, and {0, 0, 2, 2, 3, 1, 9, 4, 7,11, 3,3}, the sequence set 2B comprises some or all of the following sequences, and M is 16: {9, 8, 11, 14, 1, 5, 14, 6, 3, 1, 0, 0}, {13, 12, 14, 1, 4, 7, 0, 8, 4, 3, 0, 0}, {14, 5, 11, 2, 9, 13, 9, 6, 10, 10, 0, 0}, {10, 12, 1, 3, 10, 10, 4, 14, 2, 15, 0, 0}, {12, 9, 12, 6, 12, 7, 12, 13, 5, 4, 0, 0}, {13, 12, 0, 2, 4, 8, 1, 8, 5, 3, 0, 0}, {13, 15, 6, 10, 1, 4, 14, 10, 14, 13, 0, 0}, {9, 8, 2, 0, 13, 14, 1, 6, 15, 8, 0, 0}, {7, 8, 14, 0, 3, 2, 15, 10, 1, 8, 0, 0}, {11, 11, 15, 3, 8, 13, 7, 1, 15, 15, 0, 0}, {7, 3, 6, 14, 7, 11, 6, 4, 9, 9, 0, 0}, {12, 12, 7, 6, 5, 7, 11, 2, 11, 6, 0, 0}, {4, 4, 9, 10, 11, 9, 5, 14, 5, 10, 0, 0}, {13, 14, 9, 8, 6, 8, 12, 2, 12, 6, 0, 0}, {3, 2, 7, 8, 10, 8, 4, 14, 4, 10, 0, 0}, {2, 10, 14, 4, 12, 15, 10, 7, 11, 11, 0, 0}, {4, 3, 4, 6, 8, 11, 3, 10, 6, 3, 0, 0}, {9, 6, 9, 4, 10, 5, 11, 12, 4, 4, 0, 0}, {2, 14, 0, 9, 15, 9, 14, 14, 5, 4, 0, 0}, {7, 6, 1, 15, 12, 13, 0, 5, 14, 7, 0, 0}, {13, 13, 9, 8, 6, 8, 12, 2, 12, 6, 0, 0}, {3, 3, 7, 8, 10, 8, 4, 14, 4, 10, 0, 0}, {6, 5, 8, 11, 15, 3, 12, 5, 2, 1, 0, 0}, {7, 15, 4, 13, 5, 9, 6, 3, 8, 8, 0, 0}, {13, 13, 1, 5, 10, 14, 8, 2, 15, 0, 0, 0}, {10, 9, 5, 5, 15, 0, 7, 14, 11, 15, 0, 0}, {13, 12, 6, 7, 1, 0, 8, 14, 12, 14, 0, 0}, {0, 6, 10, 13, 5, 6, 0, 11, 15, 13, 0, 0}, {11, 11, 13, 0, 3, 6, 15, 7, 4, 2, 0, 0}, {6, 2, 4, 13, 2, 12, 0, 0, 7, 5, 0, 0}, {6, 9, 3, 10, 0, 8, 6, 15, 15, 1, 0, 0}, {13, 4, 15, 11, 6, 1, 5, 13, 14, 15, 0, 0}, {8, 1, 6, 14, 6, 10, 6, 4, 9, 9, 0, 0}, {15, 15, 0, 2, 5, 8, 0, 8, 4, 2, 0, 0}, {13, 2, 9, 0, 8, 12, 8, 5, 10, 10, 0, 0}, {2, 2, 13, 15, 10, 11, 3, 11, 9, 13, 0, 0}, {9, 0, 6, 14, 6, 10, 7, 4, 9, 9, 0, 0}, {1, 10, 6, 3, 15, 11, 0, 9, 12, 14, 0, 0}, {13, 2, 11, 3, 10, 3, 2, 12, 13, 15, 0, 0}, {6, 11, 10, 0, 9, 15, 4, 2, 14, 12, 0, 0}, {6, 6, 1, 15, 12, 13, 0, 5, 14, 7, 0, 0}, {8, 8, 3, 4, 14, 14, 6, 13, 11, 14, 0, 0}, {7, 8, 4, 4, 3, 5, 9, 0, 10, 6, 0, 0}, {1, 6, 10, 13, 5, 6, 0, 11, 15, 13, 0, 0}, {1, 4, 0, 1, 0, 2, 7, 14, 9, 5, 0, 0}, {15, 8, 3, 8, 1, 11, 14, 0, 11, 10, 0, 0}, {1, 8, 13, 8, 15, 5, 2, 0, 5, 6, 0, 0}, {9, 15, 10, 4, 0, 8, 12, 2, 1, 1, 0, 0}, {7, 9, 4, 5, 3, 5, 10, 0, 12, 6, 0, 0}, {0, 15, 10, 9, 7, 9, 13, 3, 13, 7, 0, 0}, {0, 1, 6, 7, 9, 7, 3, 13, 3, 9, 0, 0}, {7, 10, 15, 1, 8, 9, 2, 13, 1, 15, 0, 0}, {9, 11, 1, 3, 9, 10, 4, 14, 2, 15, 0, 0}, {9, 1, 5, 9, 1, 3, 13, 9, 13, 12, 0, 0}, {12, 2, 7, 10, 2, 4, 14, 10, 14, 13, 0, 0}, {10, 8, 11, 14, 1, 5, 14, 6, 3, 1, 0, 0}, {7, 12, 1, 7, 14, 1, 12, 8, 12, 11, 0, 0}, {9, 8, 11, 13, 1, 5, 13, 6, 2, 1, 0, 0}, {6, 6, 6, 9, 10, 12, 4, 11, 6, 4, 0, 0}, {10, 10, 10, 7, 6, 4, 12, 5, 10, 12, 0, 0}, {12, 3, 3, 10, 4, 11, 0, 15, 12, 11, 0, 0}, {6, 6, 10, 11, 1, 0, 9, 2, 5, 1, 0, 0}, {10, 13, 1, 3, 10, 10, 4, 14, 2, 15, 0, 0}, {9, 8, 11, 14, 1, 5, 14, 6, 3, 2, 0, 0}, {6, 11, 15, 1, 8, 9, 2, 13, 1, 15, 0, 0}, {1, 8, 2, 9, 1, 5, 9, 7, 2, 15, 0, 0}, {12, 11, 14, 0, 3, 7, 15, 7, 3, 1, 0, 0}, {9, 7, 11, 13, 0, 5, 14, 6, 4, 2, 0, 0}, {11, 1, 2, 9, 3, 10, 0, 15, 12, 11, 0, 0}, {7, 7, 1, 2, 13, 14, 5, 13, 10, 15, 0, 0}, {0, 0, 5, 7, 13, 13, 6, 0, 3, 0, 0, 0}, {13, 3, 9, 0, 8, 12, 8, 5, 10, 10, 0, 0}, {5, 10, 15, 1, 8, 9, 2, 13, 0, 14, 0, 0}, {2, 5, 11, 13, 5, 7, 1, 12, 0, 15, 0, 0}, {0, 14, 1, 10, 3, 8, 3, 2, 7, 7, 0, 0}, {4, 5, 9, 10, 0, 15, 8, 1, 4, 0, 0, 0}, {10, 6, 10, 0, 5, 15, 2, 1, 8, 5, 0, 0}, {4, 0, 2, 11, 1, 11, 15, 15, 6, 5, 0, 0}, {10, 1, 6, 14, 6, 10, 6, 4, 9, 9, 0, 0}, {9, 5, 9, 0, 9, 12, 7, 5, 10, 9, 0, 0}, {15, 0, 10, 9, 7, 9, 13, 3, 13, 7, 0, 0}, {1,0,6,7, 9, 7, 3, 13, 3, 9, 0, 0}, {14, 4, 11, 2, 9, 13, 9, 6, 10, 10, 0, 0}, {5, 4, 0, 14, 11, 12, 15, 4, 14, 7, 0, 0}, {11, 2, 7, 15, 7, 11, 7, 4, 9, 9, 0, 0}, {13, 6, 0, 13, 4, 14, 0, 9, 10, 11, 0, 0}, {4, 12, 15, 6, 13, 0, 11, 7, 11, 10, 0, 0}, {7, 3, 7, 14, 7, 11, 6, 4, 9, 9, 0, 0}, {9, 1, 6, 13, 6, 10, 6, 4, 9, 10, 0, 0}, {11, 8, 11, 4, 11, 6, 11, 12, 4, 3, 0, 0}, {14, 11, 14, 7, 13, 8, 13, 13, 5, 4, 0, 0}, {4, 14, 0, 6, 14, 1, 11, 8, 12, 11, 0, 0}, {6, 8, 9, 14, 7, 13, 5, 3, 14, 13, 0, 0}, {1, 0, 4, 8, 12, 0, 10, 3, 1, 0, 0, 0}, {9, 9, 14, 2, 7, 12, 6, 0, 15, 15, 0, 0}, {15, 15, 2, 4, 6, 9, 2, 9, 5, 3, 0, 0}, {4, 0, 3, 11, 1, 11, 15, 15, 6, 4, 0, 0}, {5, 5, 9, 12, 15, 3, 12, 5, 2, 1, 0, 0}, {15, 12, 15, 8, 14, 9, 13, 14, 6, 4, 0, 0}, {9, 13, 3, 8, 15, 2, 13, 9, 13, 12, 0, 0}, {12, 0, 4, 6, 12, 12, 5, 15, 2, 15, 0, 0}, {14, 12, 15, 2, 4, 8, 1, 8, 5, 3, 0, 0}, {5, 6, 3, 3, 1, 4, 9, 15, 11, 5, 0, 0}, {8, 8, 4, 4, 2, 5, 10, 0, 12, 6, 0, 0}, {8, 8, 12, 12, 14, 11, 6, 0, 4, 10, 0, 0}, {2, 13, 3, 14, 7, 4, 2, 5, 11, 0, 0, 0}, {14, 3, 13, 2, 9, 12, 14, 11, 5, 0, 0, 0}, {4, 10, 10, 0, 9, 15, 4, 2, 14, 13, 0, 0}, {9, 1, 6, 14, 6, 10, 6, 4, 9, 9, 0, 0}, {6, 10, 10, 0, 9, 15, 4, 2, 14, 12, 0, 0}, {1, 10, 14, 4, 12, 15, 10, 7, 11, 11, 0, 0}, {13, 2, 15, 4, 13, 2, 7, 5, 0, 13, 0, 0}, {5, 9, 6, 8, 9, 12, 2, 10, 6, 3, 0, 0}, {2, 2, 7, 8, 10, 8, 4, 13, 4, 9, 0, 0}, {12, 10, 13, 0, 2, 7, 0, 7, 5, 3, 0, 0}, {9, 6, 9, 0, 5, 15, 2, 1, 9, 6, 0, 0}, {15, 13, 7, 7, 1, 1, 9, 15, 12, 15, 0, 0}, {7, 10, 3, 10, 0, 8, 6, 15, 15, 1, 0, 0}, {13, 15, 4, 6, 12, 12, 5, 15, 2, 15, 0, 0}, {7, 10, 3, 10, 0, 8, 7, 0, 15, 1, 0, 0}, {14, 9, 12, 3, 12, 12, 6, 10, 9, 15, 0, 0}, {14, 15, 1, 4, 12, 2, 8, 5, 0, 14, 0, 0}, {4, 6, 11, 15, 6, 7, 1, 12, 0, 14, 0, 0}, {2, 1, 6, 9, 13, 1, 10, 3, 0, 0, 0, 0}, {11, 3, 15, 11, 6, 1, 5, 13, 15, 0, 0, 0}, {13, 11, 2, 11, 7, 0, 5, 9, 7, 7, 0, 0}, {3, 5, 14, 5, 9, 0, 11, 7, 9, 9, 0, 0}, {4, 8, 12, 14, 6, 7, 1, 12, 1, 15, 0, 0}, {4, 7, 11, 15, 6, 7, 1, 12, 0, 14, 0, 0}, {1, 14, 0, 9, 15, 9, 14, 14, 5, 4, 0, 0}, {0, 11, 14, 7, 14, 8, 12, 13, 4, 3, 0, 0}, {9, 9, 13, 13, 14, 11, 7, 0, 6, 11, 0, 0}, {7, 7, 3, 3, 2, 5, 9, 0, 10, 5, 0, 0}, {3, 8, 5, 15, 9, 5, 7, 3, 7, 12, 0, 0}, {13, 8, 11, 1, 7, 11, 9, 13, 9, 4, 0, 0}, {0, 0, 11, 10, 8, 10, 13, 3, 12, 6, 0, 0}, {0, 0, 5, 6, 8, 6, 3, 13, 4, 10, 0, 0}, {5, 4, 7, 9, 13, 2, 10, 4, 1, 0, 0, 0}, {5, 12, 14, 1, 8, 9, 2, 13, 0, 14, 0, 0}, {7, 10, 3, 10, 0, 8, 6, 15, 15, 0, 0, 0}, {11, 3, 4, 11, 1, 4, 14, 10, 13, 12, 0, 0}, {7, 4, 7, 14, 7, 11, 6, 4, 9, 9, 0, 0}, {15, 14, 15, 1, 3, 8, 0, 8, 5, 2, 0, 0}, {0, 9, 12, 3, 11, 14, 9, 6, 10, 10, 0, 0}, {12, 1, 13, 6, 15, 10, 11, 6, 9, 13, 0, 0}, {2, 13, 3, 9, 0, 5, 4, 9, 6, 3, 0, 0}, {13, 12, 10, 6, 2, 14, 4, 11, 14, 15, 0, 0}, {13, 9, 12, 6, 12, 7, 12, 13, 5, 4, 0, 0}, {2, 7, 15, 7, 13, 6, 5, 14, 14, 0, 0, 0}, {3, 10, 7, 4, 0, 12, 1, 10, 12, 14, 0, 0}, {10, 9, 4, 15, 10, 5, 10, 0, 1, 1, 0, 0}, {3, 14, 2, 7, 15, 1, 11, 8, 12, 10, 0, 0}, {14, 15, 11, 10, 7, 9, 13, 2, 13, 6, 0, 0}, {10, 7, 8, 10, 11, 14, 6, 12, 8, 5, 0, 0}, {10, 0, 6, 14, 6, 10, 6, 4, 9, 9, 0, 0}, {5, 15, 4, 13, 5, 9, 5, 3, 8, 8, 0, 0}, {5, 4, 4, 6, 8, 11, 2, 10, 5, 3, 0, 0}, {15, 15, 5, 6, 8, 6, 3, 12, 4, 9, 0, 0}, {1, 1, 11, 10, 8, 10, 13, 4, 12, 7, 0, 0}, {13, 11, 5, 6, 0, 0, 8, 14, 12, 15, 0, 0}, {7, 13, 8, 0, 7, 7, 12, 8, 8, 2, 0, 0}, {10, 12, 2, 4, 10, 10, 4, 14, 2, 15, 0, 0}, {5, 5, 9, 9, 11, 9, 5, 15, 5, 10, 0, 0}, {11, 11, 7, 7, 5, 7, 11, 1, 11, 6, 0, 0}, {5, 15, 3, 12, 5, 9, 5, 3, 8, 8, 0, 0}, {13, 4, 13, 5, 13, 5, 5, 14, 14, 0, 0, 0}, {14, 2, 9, 0, 8, 12, 8, 5, 10, 10, 0, 0}, {6, 5, 10, 12, 15, 4, 13, 5, 3, 1, 0, 0}, {15, 13, 15, 2, 4, 8, 1, 8, 5, 2, 0, 0}, {11, 14, 4, 9, 0, 3, 13, 9, 14, 13, 0, 0}, {15, 14, 15, 0, 3, 8, 15, 8, 4, 1, 0, 0}, {4, 4, 7, 10, 14, 2, 11, 4, 1, 0, 0, 0}, {8, 3, 5, 13, 3, 13, 0, 0, 7, 5, 0, 0}, {0, 4, 13, 5, 12, 5, 4, 13, 14, 0, 0, 0}, {13, 4, 10, 5, 12, 3, 0, 15, 4, 5, 0, 0}, {3, 12, 6, 11, 4, 13, 0, 1, 12, 11, 0, 0}, {5, 5, 14, 10, 3, 12, 1, 5, 5, 3, 0, 0}, {11, 11, 2, 6, 13, 4, 15, 11, 11, 13, 0, 0}, {8, 7, 7, 9, 10, 13, 4, 11, 6, 3,0, 0}, {3, 2, 5, 8, 12, 1, 9, 3, 0, 0, 0, 0}, {10, 6, 8, 0, 5, 15, 2, 1, 8, 6, 0, 0}, {2, 14, 0, 6, 11, 14, 11, 15, 10, 5, 0, 0}, {14, 2, 0, 10, 5, 2, 5, 1, 6, 11, 0, 0}, {11, 7, 11, 4, 11, 6, 11, 12, 4, 3, 0, 0}, {11, 1, 7, 1, 6, 13, 12, 3, 0, 15, 0, 0}, {15, 13, 2, 1, 2, 15, 9, 2, 6, 11, 0, 0}, {9, 11, 0, 2, 9, 10, 4, 14, 2, 0, 0, 0}, {13, 5, 9, 0, 9, 12, 8, 5, 10, 10, 0, 0}, {9, 8, 10, 13, 1, 4, 13, 6, 2, 2, 0, 0}, {2, 3, 7, 8, 10, 8, 4, 14, 4, 10, 0, 0}, {14, 13, 9, 8, 6, 8, 12, 2, 12, 6, 0, 0}, {0, 1, 5, 7, 13, 13, 6, 0, 3, 0, 0, 0}, {0, 5, 3, 8, 0, 5, 8, 5, 0, 13, 0, 0}, {1, 12, 15, 5, 13, 0, 10, 7, 11, 10, 0, 0}, {6, 3, 6, 14, 7, 11, 6, 4, 9, 9, 0, 0}, {13, 12, 0, 0, 1, 14, 8, 1, 5, 10, 0, 0}, {1, 9, 13, 4, 12, 15, 10, 7, 11, 10, 0, 0}, {15, 4, 13, 5, 12, 5, 4, 13, 14, 0, 0, 0}, {9, 12, 7, 0, 8, 1, 1, 11, 12, 14, 0, 0}, {11, 6, 8, 0, 5, 15, 2, 1, 8, 6, 0, 0}, {1, 14, 1, 10, 3, 8, 3, 2, 7, 7, 0, 0}, {13, 3, 12, 4, 12, 4, 4, 13, 14, 15, 0, 0}, {6, 12, 11, 1, 10, 0, 4, 2, 14, 12, 0, 0}, {13, 12, 15, 2, 4, 8, 1, 8, 5, 3, 0, 0}, {2, 5, 11, 14, 5, 7, 1, 12, 0, 14, 0, 0}, {1, 13, 15, 8, 14, 8, 13, 13, 4, 3, 0, 0}, {12, 3, 8, 0, 8, 12, 8, 5, 10, 10, 0, 0}, {1, 13, 9, 6, 14, 9, 12, 6, 8, 11, 0, 0}, {9, 5, 7, 15, 4, 14, 1, 1, 8, 5, 0, 0}, {13, 14, 9, 9, 7, 8, 12, 2, 12, 7, 0, 0}, {15, 12, 15, 1, 4, 8, 1, 8, 5, 3, 0, 0}, and {2, 14, 2, 10, 0, 10, 14, 14, 6, 4, 0, 0}, the third sequence set comprises a sequence in a sequence set 3A and/or a sequence in a sequence set 3B, the sequence set 3A comprises some or all of the following sequences, and M is 4: {3, -3, 1, 1, -1, -3, -3, 3, -3, 1, 3, 3, -3, 3, -1, -3, 3, -1}, {3, 1, -3, -3, -1, 1, 1, 3, 1, -3, 3, 3, 1, 3, -1, 1, 3, -1}, {-1, -1, 3, -1, -1, 3, -1, -1, 3, 3, 3, 3, -1, 3, -1, 3, -1, 3}, {-1, 1, -3, 1, -1, -3, -3, 3, 3, -1, 3, 3, -3, -3, -1, 1, -3, 1}, {-1, -3, 1, -3, -1, 1, 1, 3, 3, -1, 3, 3, 1, 1, -1, -3, 1, -3}, {-3, 1, -3, -1, -1, 1, -3, -1, 3, 3, 3, 3, -1, -3, 3, 1, -3, 3}, {1, -3, 1, -1, -1, -3, 1, -1, 3, 3, 3, 3, -1, 1, 3, -3, 1, 3}, {1, -3, -3, 1, 1, 3, -1, -1, 3, 1, 3, 3, 3, 1, -3, -1, 3, 1}, {-3, 1, 1, -3, -3, 3, -1, -1, 3, -3, 3, 3, 3, -3, 1, -1, 3, -3}, {-3, 1, 3, -3, 1, 3, -1, 3, 1, 1, 3, 3, -3, 1, -1, -3, -3, 3}, {1,-3, 3, 1, -3, 3, -1, 3, -3, -3, 3, 3, 1, -3, -1, 1, 1, 3}, {1, -1, -3, 3, -1, 1, 3, -1, 3, 1, 3, 3, 3, 1, -1, -1, 1, 3}, {-3, -1, 1, 3, -1, -3, 3, -1, 3, -3, 3, 3, 3, -3, -1, -1, -3, 3}, {-1, -3, 3, 3, 1, 3, 3, -3, 1, -1, 3, 3, 1, 3, -1, 1, -3, -3}, {-1, 1, 3, 3, -3, 3, 3, 1, -3, -1, 3, 3, -3, 3, -1, -3, 1, 1}, {1, 3, 3, 3, 1, 3, 3, -3, 1, -1, 3, 3, 1, 3, -1, -1, -3, -3}, {-3, 3, 3, 3, -3, 3, 3, 1, -3, -1, 3, 3, -3, 3, -1, -1, 1, 1}, {3, -1, 1, -3, -1, -1, -1, -3, -1, -1, 3, 3, 1, -3, -1, -3, 3, 1}, {3, -1, -3, 1, -1, -1, -1, 1, -1, -1, 3, 3, -3, 1, -1, 1, 3, -3}, {-1, -3, 3, -1, -1, 3, 3, -1, 3, 3, 3, 3, -1, -3, -1, 3, 3, 3}, {-1, 1, 3, -1, -1, 3, 3, -1, 3, 3, 3, 3, -1, 1, -1, 3, 3, 3}, {-1, -1, 3, 3, -1, -1, 3, -1, -1, 3, 3, 3, 3, -1, 3, -1, 3, -1}, {-1, 3, -3, -1, -3, 1, -1, 3, -1, 1, 3, 3, 3, 1, 1, -1, 1, 3}, {-1, 3, 1, -1, 1, -3, -1, 3, -1, -3, 3, 3, 3, -3, -3, -1, -3, 3}, {1, -3, -1, 1, 3, -1, -1, -3, 3, 1, 3, 3, 3, -3, 1, -3, 1,-3}, {-3, 1, -1, -3, 3, -1, -1, 1, 3, -3, 3, 3, 3, 1, -3, 1, -3, 1}, {3, -3, -1, 1, 3, 3, -3, 3, -1, -3, 3, 3, 1, 3, -1, 1, -3, -1}, {3, 1, -1, -3, 3, 3, 1, 3, -1, 1, 3, 3, -3, 3, -1, -3, 1, -1}, {3, -1, 3, 1, -3, 1, -3, -3, -3, -1, 3, 3, 1, -3, -3, 3, 3, -3}, {3, -1, 3, -3, 1, -3, 1, 1, 1, -1, 3, 3, -3, 1, 1, 3, 3, 1}, {-3, 1, -1, 1, -1, -3, -3, 3, -1, 3, 3, 3, -3, -1, 3, -3, -1, 1}, {1, -3, -1, -3, -1, 1, 1, 3, -1, 3, 3, 3, 1, -1, 3, 1, -1, -3}, {3, 1, -3, -3, 3, 1, 1, -3, 3, -3, 3, 3, -3, 1, 3, -1, -1, 1}, {3, -3, 1, 1, 3, -3, -3, 1, 3, 1, 3, 3, 1, -3, 3, -1, -1, -3}, {3, -1, 1, 3, 1, -1, 1, 1, 1, -1, 3, 3, -3, 1, -1, -1, 3, -3}, {3, -1, -3, 3, -3, -1, -3, -3, -3, -1, 3, 3, 1, -3, -1, -1, 3, 1}, {3, 1, 3, -1, 3, -3, 3, -1, -3, 3, 3, 3, -3, -1, 1, -3, -1, 1}, {3, -3, 3, -1, 3, 1, 3, -1, 1, 3, 3, 3, 1, -1, -3, 1, -1, -3}, {-1, -1, -1, 3, 3, -1, 3, -1, -1, 3, 3, 3, -3, 3, 3, 3, -1, -1}, {-1, -1, -1, 3, 3, -1, 3, -1, -1, 3, 3, 3, 1, 3, 3, 3, -1, -1}, {-1, 1, 3, -3, -1, 1, -3, -3, 3, -1, 3, 3, 3, 3, -3, -3, -1, -3}, {-1, -3, 3, 1, -1, -3, 1, 1, 3, -1, 3, 3, 3, 3, 1, 1, -1, 1}, {1, -1, 3, 1, -3, -1, 1, 1, 3, -1, 3, 3, 1, 1, -1, 1, -1, -3}, {-3, -1, 3, -3, 1, -1, -3, -3, 3, -1, 3, 3, -3, -3, -1, -3, -1, 1}, {1, -3, -1, 1, 3, 3, -3, 3, -3, 1, 3, 3, 1, -1, -3, 3, -3, 1}, {-3, 1, -1, -3, 3, 3, 1, 3, 1, -3, 3, 3, -3, -1, 1, 3, 1, -3}, {3, -1, 1, -3, -1, 3, -3, 3, 1, -3, 3, 3, 3, -3, -1, -1, 1, -3}, {3, -1, -3, 1, -1, 3, 1, 3, -3, 1, 3, 3, 3, 1, -1, -1, -3, 1}, {1, -3, -3, 1, -3, 1, -3, 1, 3, 3, 3, 3, -1, -1, 3, -3, -3, 3}, {-3, 1, 1, -3, 1, -3, 1, -3, 3, 3, 3, 3, -1, -1, 3, 1, 1, 3}, {-1, -1, -1, 3, 3, -1, 3, -3, 3, -1, 3, 3, -1, -1, -1, -1, 3, 3}, {-1, -1, -1, 3, 3, -1, 3, 1, 3, -1, 3, 3, -1, -1, -1, -1, 3, 3}, {1, 3, -1, 1, 3, -1, -3, -3, 1, 1, 3, 3, 1, 3, 1, -3, 1, 3}, {-3, 3, -1, -3, 3, -1, 1, 1, -3, -3, 3, 3, -3, 3, -3, 1, -3, 3}, {1, -3, 1, -1, -1, -1, -1, 1, -1, -1, 3, 3, -3, 1, -1, 1, -3, -3}, {-3, 1, -3, -1, -1, -1, -1, -3, -1, -1, 3, 3, 1, -3, -1, -3, 1, 1}, {-3, 1, -3, 3, -1, -1, 3, -1, -3, -3, 3, 3, -3, -1, -3, -1, 1, 1}, {1,-3, 1, 3, -1, -1, 3, -1, 1, 1, 3, 3, 1, -1, 1, -1, -3, -3}, {3, 1, -1, 1, -3, -1, 3, -1, -3, 3, 3, 3, -3, -3, -1, -3, 3, 3}, {3, -3, -1, -3, 1, -1, 3, -1, 1, 3, 3, 3, 1, 1, -1, 1, 3, 3}, {-3, 3, -1, 3, -1, -1, 1, -1, -1, -1, 3, 3, -1, -3, -1, 1, -3, 3}, {1, 3, -1, 3, -1, -1, -3, -1, -1, -1, 3, 3, -1, 1, -1, -3, 1, 3}, {1, 1, -1, 1, -3, -1, 1, -1, -1, 3, 3, 3, -1, 3, 1, -3, -3, -1}, {-3, -3, -1, -3, 1, -1, -3, -1, -1, 3, 3, 3, -1, 3, -3, 1, 1, -1}, {-3, -1, 3, 1, -1, 3, 3, -1, 3, 3, 3, 3, -1, 1, -1, 3, -1, 3}, {1, -1, 3, -3, -1, 3, 3, -1, 3, 3, 3, 3, -1, -3, -1, 3, -1, 3}, {-1, 1, 3, 3, -3, 3, -1, -1, 1, -3, 3, 3, 1, 3, 3, 3, 1, 3}, {-1, -3, 3, 3, 1, 3, -1, -1, -3, 1, 3, 3, -3, 3, 3, 3, -3, 3}, {3, -1, 3, -1, -3, 1, -3, 3, 1, 1, 3, 3, 3, -1, 1, -3, 1, 3}, {3, -1, 3, -1, 1, -3, 1, 3, -3, -3, 3, 3, 3, -1, -3, 1, -3, 3}, {1, 3, -1, -1, 3, -3, -1, -3, 3, 1, 3, 3, 3, -3, 1, -3, 3, -3}, {-3, 3, -1, -1, 3, 1, -1, 1, 3, -3, 3, 3, 3, 1, -3, 1, 3, 1}, {1, 3, -3, 3, 3, 1, 3, 1, 1, -1, 3, 3, -3, 1, -3, -3, -1, 1}, {-3, 3, 1, 3, 3, -3, 3, -3, -3, -1, 3, 3, 1, -3, 1, 1, -1, -3}, {-1, 3, 3, -1, 3, 3, -1, -1, 3, 3, 3, 3, -1, 3, -1, 3, -1, -1}, {-3, 3, -3, 1, -3, -1, 3, 3, 1, 1, 3, 3, -1, -3, 1, -3, 3, -3}, {1, 3, 1, -3, 1, -1, 3, 3, -3, -3, 3, 3, -1, 1, -3, 1, 3, 1}, {-3, -1, 3, 3, 1, -3, -1, -3, 3, 1, 3, 3, 3, -1, 3, 3, -3, -1}, {1, -1, 3, 3, -3, 1, -1, 1, 3, -3, 3, 3, 3, -1, 3, 3, 1, -1}, {3, 1, -1, 1, -1, -3, 3, 1, 3, -1, 3, 3, -3, -3, -3, 1, 3, 3}, {3, -3, -1, -3, -1, 1, 3, -3, 3, -1, 3, 3, 1, 1, 1, -3, 3, 3}, {-1, 3, 1, -1, -1, 3, -1, -3, -3, 1, 3, 3, -3, 3, -3, -3, -1, -3}, {-1, 3, -3, -1, -1, 3, -1, 1, 1, -3, 3, 3, 1, 3, 1, 1, -1, 1}, {-1, 1, 3, -1, -1, 3, -1, -1, 3, 3, 3, 3, -1, 3, -1, 3, -1, 1}, {-1, -3, 3, -1, -1, 3, -1, -1, 3, 3, 3, 3, -1, 3, -1, 3, -1, -3}, {-1, -3, -1, -3, -1, 1, 1, 3, 3, -1, 3, 3, 1, 1, -1, -3, 1, -3}, and {-1, 1, -1, 1, -1, -3, -3, 3, 3, -1, 3, 3, -3, -3, -1, 1, -3, 1}, and the sequence set 3B comprises some or all of the following sequences, and M is 4: {-3, -3, -3, 1, 1, -3, -3, 1, 1, -3, -3, -3, -3, -3, 1, -3, 1, -3, -3, 1, -3, 1, 1, 1}, {-3, 1, 1, 1, 1, -3, 1, -3, 1, -3, -3, -3, -3, 1, 1, -3, -3, 1, -3, -3, 1, 1, 1, 1}, {1, 1, -3, 1, -3, -3, 1, -3, 1, 1, -3, 1, 1, 1, -3, 1, 1, 1, -3, -3, -3, -3, 1, 1}, {1, -3, -3, -3, 1, 1, -3, -3, 1, 1, -3, -3, -3, -3, -3, 1, -3, 1, -3, -3, 1, -3, 1, 1}, {3, 3, -3, -3, 1, 3, 3, -3, -3, 3, -1, 3, -1, 3, 3, 1, 1, -3, -1, -1, -3, -3, 1, 1}, {-1, -1, -3, -3, 1, -1, -1, -3, -3, -1, 3, -1, 3, -1, -1, 1, 1, -3, 3, 3, -3, -3, 1, 1}, {3, 3, -1, -3, 1, 3, 1, 1, -1, 3, 3, -3, -3, 3, -3, 1, 3, 3, -1, -3, 1, 3, 1, 1}, {-1, -1, 3, -3, 1, -1, 1, 1, 3, -1, -1, -3, -3, -1, -3, 1, -1, -1, 3, -3, 1, -1, 1, 1}, {-1, 1, -1, 1, -3, -3, 1, 1, 3, 1, 3, 1, 1, -3, -3, 1, -1, 1, -1, 1, -3, -3, 1, 1}, {3, 1, 3, 1, -3, -3, 1, 1, -1, 1, -1, 1, 1, -3, -3, 1, 3, 1, 3, 1, -3, -3, 1, 1}, {1,3, 3, -1, 1, -1, 1, 1, 1, 3, -1, 3, 1, -1, -3, -3, 1, 3, 3, -1, 1, -1, 1, 1}, {1,-1,-1,3, 1, 3, 1, 1, 1, -1, 3, -1, 1, 3, -3, -3, 1, -1, -1, 3, 1, 3, 1, 1}, {1, 1, -1, -1, 3, 3, 1, 1, -3, -1, 3, -1, 3, 1, 3, 3, -1, -1, 1, 1, -1, -1, 1, 1}, {1, 1, 3, 3, -1, -1, 1, 1, -3, 3, -1, 3, -1, 1, -1, -1, 3, 3, 1, 1, 3, 3, 1, 1}, {-3, -3, 3, -3, -1, -3, 1, 1, 1, -3, -1, -3, 3, -3, -3, 1, -3, -3, 3, -3, -1, -3, 1, 1}, {-3, -3, -1, -3, 3, -3, 1, 1, 1, -3, 3, -3, -1, -3, -3, 1, -3, -3, -1, -3, 3, -3, 1, 1}, {3, 1, -3, -1, 3, -1, 1, 1, 3, -3, -3, 3, 3, 3, 1, -3, 3, 1, -3, -1, 3, -1, 1, 1}, {-1, 1, -3, 3, -1, 3, 1, 1, -1, -3, -3, -1, -1, -1, 1, -3, -1, 1, -3, 3, -1, 3, 1, 1}, {3, -3, -3, -1, -3, 1, -3, -1, 3, -1, 3, 3, -3, -1, -1, -3, -3, 3, 1, -3, 3, 1, 1, 1}, {-1, -3, -3, 3, -3, 1, -3, 3, -1, 3, -1, -1, -3, 3, 3, -3, -3, -1, 1, -3, -1, 1, 1, 1}, {3, -3, -1, 1, 3, -1, 1, 3, -3, 1, 1, 1, 1, -3, 1, -3, 3, 3, -1, -3, 1, 1, 1, 1}, {-1, -3, 3, 1, -1, 3, 1, -1, -3, 1, 1, 1, 1, -3, 1, -3, -1, -1, 3, -3, 1, 1, 1, 1}, {-1, -1, -3, -3, 3, 3, 3, 3, 1, 3, -3, -3, 3, -1, 1, -3, 3, -1, 3, 3, -1, -3, 1, 1}, {3, 3, -3, -3, -1, -1, -1, -1, 1, -1, -3, -3, -1, 3, 1, -3, -1, 3, -1, -1, 3, -3, 1, 1}, {1, 3, 3, -1, 3, -3, -1, -3, -1, 3, -1, -3, 1, 1, 3, 3, 1, 1, -1, -1, 3, 3, 1, 1}, {1, -1, -1, 3, -1, -3, 3, -3, 3, -1, 3, -3, 1, 1, -1, -1, 1, 1, 3, 3, -1, -1, 1, 1}, {-1, 3, -3, -3, 1, -3, 3, -3, -3, 1, -3, -3, 3, -1, -1, -1, 3, -3, 3, 3, 3, -1, 1, 1}, {3, -1, -3, -3, 1, -3, -1, -3, -3, 1, -3, -3, -1, 3, 3, 3, -1, -3, -1, -1, -1, 3, 1, 1}, {-1, 3, 3, -3, -1, -3, 1, 1, -1, -1, -1, -3, -1, 1, -3, 1, -1, 3, 3, -3, -1, -3, 1, 1}, {3, -1, -1, -3, 3, -3, 1, 1, 3, 3, 3, -3, 3, 1, -3, 1, 3, -1, -1, -3, 3, -3, 1, 1}, {-3, 1, -1, 3, 1, 1, 1, 1, -3, 1, 3, -1, 1, 1, -3, -3, -3, 1, -1, 3, 1, 1, 1, 1}, {-3, 1, 3, -1, 1, 1, 1, 1, -3, 1, -1, 3, 1, 1, -3, -3, -3, 1, 3, -1, 1, 1, 1, 1}, {1, -3, -1, 3, -3, 3, -3, 1, 3, -1, 1, 1, 3, 1, -3, 3, 1, 1, -3, -3, -3, 3, 1, 1}, {1, -3, 3, -1, -3, -1, -3, 1, -1, 3, 1, 1, -1, 1, -3, -1, 1, 1, -3, -3, -3, -1, 1, 1}, {-3, 1, -1, 3, -3, -3, 1, 1, -3, 1, 3, -1, -3, -3, -3, -3, -3, 1, -1, 3, -3, -3, 1, 1}, {-3, 1, 3, -1, -3, -3, 1, 1, -3, 1, -1, 3, -3, -3, -3, -3, -3, 1, 3, -1, -3, -3, 1, 1}, {1, 3, -3, 1, -3, -1, 3, -3, 1, 1, 3, 3, 1, -3, 3, -1, 1, -1, -3, -3, -3, 1, 1, 1}, {1, -1, -3, 1, -3, 3, -1, -3, 1, 1, -1, -1, 1, -3, -1, 3, 1, 3, -3, -3, -3, 1, 1, 1}, {-1, 1, -1, -1, 3, -1, 3, -3, -3, -1, -3, 1, 1, -3, 1, 1, 1, -1, -1, 3, 3, -1, 1, 1}, {3, 1, 3, 3, -1, 3, -1, -3, -3, 3, -3, 1, 1, -3, 1, 1, 1, 3, 3, -1, -1, 3, 1, 1}, {1, -1, -3, -1, 3, -1, 3, 1, -1, 1, -3, 1, 1, -1, 1, 1, 3, -3, -1, -3, -3, -3, 1, 1}, {1, 3, -3, 3, -1, 3, -1, 1, 3, 1, -3, 1, 1, 3, 1, 1, -1, -3, 3, -3, -3, -3, 1, 1}, {-3, -1, -1, 3, -3, 1, 1, 3, -3, 1, 1, 1, 3, 3, 1, -3, 1, -1, -3, -3, 3, 3, 1, 1}, {-3, 3, 3, -1, -3, 1, 1, -1, -3, 1, 1, 1, -1, -1, 1, -3, 1, 3, -3, -3, -1, -1, 1, 1}, {3, -1, -3, -3, 1, 1, -1, 3, -3, 1, -3, -3, -3, 3, -3, 3, 1, -3, -3, -1, -3, 1, 1, 1}, {-1, 3, -3, -3, 1, 1, 3, -1, -3, 1, -3, -3, -3, -1, -3, -1, 1, -3, -3, 3, -3, 1, 1, 1}, {-3, -1, 3, 3, 1, 1, -1, 3, -3, 1, -3, -3, -3, 3, -3, -3, 1, -1, 3, 3, -3, -3, 1, 1}, {-3, 3, -1, -1, 1, 1, 3, -1, -3, 1, -3, -3, -3, -1, -3, -3, 1, 3, -1, -1, -3, -3, 1, 1}, {1, -3, 1, 1, -3, 1, 1, 3, 1, -1, 1, -3, -3, -3, 1, -1, 1, 3, 1, 1, -3, 1, 1, 1}, {1, -3, 1, 1, -3, 1, 1, -1, 1, 3, 1, -3, -3, -3, 1, 3, 1, -1, 1, 1, -3, 1, 1, 1}, {1, -3, -3, -3, 1, 1, -3, -3, -3, 1, -3, -3, -3, -3, 1, -3, 1, 1, -3, -3, 1, -3, 1, 1}, {-1, -1, -1, -3, -1, -3, 3, -3, 3, 3, 3, -1, -3, 1, 3, -3, 3, -3, -1, -1, -3, -3, 1, 1}, {3, 3, 3, -3, 3, -3, -1, -3, -1, -1, -1, 3, -3, 1, -1, -3, -1, -3, 3, 3, -3, -3, 1, 1}, {-3, -3, -3, 1, -3, 1, 1, -3, 1, -3, 1, 1, 1, 1, 1, -3, -3, 1, 1, -3, -3, 1, 1, 1}, {-1, -3, -3, 3, -1, -1, 1, 1, -1, 1, -3, -1, -1, 3, 1, -3, -1, -3, -3, 3, -1, -1, 1, 1}, {3, -3, -3, -1, 3, 3, 1, 1, 3, 1, -3, 3, 3, -1, 1, -3, 3, -3, -3, -1, 3, 3, 1, 1}, {-1, 3, -3, 3, 3, 1, 1, 1, 1, -1, -3, 1, -1, 1, 1, 3, -3, 1, 3, -1, -3, -3, 1, 1}, {3, -1, -3, -1, -1, 1, 1, 1, 1, 3, -3, 1, 3, 1, 1, -1, -3, 1, -1, 3, -3, -3, 1, 1}, {1, 1, -3, 1, -3, -3, -3, -3, 1, -3, 1, 1, 1, -3, 1, 1, 1, 1, -3, -3, 1, 1, 1, 1}, {-1, 3, 3, -3, 3, 3, -3, -1, 3, -1, -1, 3, -1, -3, -1, 3, 3, 3, -1, -1, -1, 3, 1, 1}, {3, -1, -1, -3, -1, -1, -3, 3, -1, 3, 3, -1, 3, -3, 3, -1, -1, -1, 3, 3, 3, -1, 1, 1}, {3, -1, 1, -3, -1, -1, 1, -3, -1, 1, -1, -3, 1, -1, 1, -3, -3, -3, -3, 1, 1, 1, 1, 1}, {-1, 3, 1, -3, 3, 3, 1, -3, 3, 1, 3, -3, 1, 3, 1, -3, -3, -3, -3, 1, 1, 1, 1, 1}, {1, -1, 1, -3, -3, 1, -3, 1, -3, 1, -3, -3, 1, 1, -3, -3, -3, -3, -3, -3, -3, -1, 1, 1}, {1, 3, 1, -3, -3, 1, -3, 1, -3, 1, -3, -3, 1, 1, -3, -3, -3, -3, -3, -3, -3, 3, 1, 1}, {-1, -1, 1, 1, 1, -3, 3, 3, -1, -1, -1, 1, -3, -1, 1, -1, -3, 1, -3, 3, 1, 3, 1, 1}, {3, 3, 1, 1, 1, -3, -1, -1, 3, 3, 3, 1, -3, 3, 1, 3, -3, 1, -3, -1, 1, -1, 1, 1}, {1, -3, 1, 3, -1, -1, 3, 3, 3, -1, 1, 1, -3, 3, 3, -3, 3, -3, 3, -1, 1, -3, 1, 1}, {1, -3, 1, -1, 3, 3, -1, -1, -1, 3, 1, 1, -3, -1, -1, -3, -1, -3, -1, 3, 1, -3, 1, 1}, {3, -1, -1, -1, 1, -1, -1, -3, -1, 3, 3, 1, -3, -3, -1, 3, -1, -3, 1, 3, -3, -3, 1, 1}, {-1, 3, 3, 3, 1, 3, 3, -3, 3, -1, -1, 1, -3, -3, 3, -1, 3, -3, 1, -1, -3, -3, 1, 1}, {1, 3, -3, -3, 3, -3, -3, -3, 1, -3, -3, 3, -1, 3, 3, -3, 1, -1, -1, -1, 3, 3, 1, 1}, {1, -1, -3, -3, -1, -3, -3, -3, 1, -3, -3, -1, 3, -1, -1, -3, 1, 3, 3, 3, -1, -1, 1, 1}, {-3, 1, -3, -3, 3, -3, 3, -1, -1, -1, -1, -3, 1, 3, -1, -3, 3, -1, 1, 3, 3, -1, 1, 1}, {-3, 1, -3, -3, -1, -3, -1, 3, 3, 3, 3, -3, 1, -1, 3, -3, -1, 3, 1, -1, -1, 3, 1, 1}, {3, 1, 3, -1, 3, -3, -1, -1, -1, 1, 3, -3, 3, 1, 3, 1, -1, 3, 3, 1, 1, 3, 1, 1}, {-1, 1, -1, 3, -1, -3, 3, 3, 3, 1, -1, -3, -1, 1,-1, 1, 3, -1, -1, 1, 1, -1, 1, 1}, {1, 1, -1, -1, 3, 3, -1, 1, 3, -3, 3, 1, 1, 3, 1, -3, -1, -3, 1, -1, 1, 1, 1, 1}, {1, 1, 3, 3, -1, -1, 3, 1, -1, -3, -1, 1, 1, -1, 1, -3, 3, -3, 1, 3, 1, 1, 1, 1}, {1, -3, 1, -3, 1, 1, -3, 1, 1, 1, -3, 1, 1, 1, 1, -3, -3, -3, -3, 1, 1, -3, 1, 1}, {-1, 3, 1, -1, 1, 3, 1, 1, -1, 3, 1, -3, -1, 3, 3, 3, 3, -1, -3, -1, 1, 3, 1, 1}, {3, -1, 1, 3, 1, -1, 1, 1, 3, -1, 1, -3, 3, -1, -1, -1, -1, 3, -3, 3, 1, -1, 1, 1}, {-3, -1, -3, 1, -3, 3, -1, 1, 3, -1, 1, 1, 1, 3, 3, 1, -1, -1, -3, 1, -3, 3, 1, 1}, {-3, 3, -3, 1, -3, -1, 3, 1, -1, 3, 1, 1, 1, -1, -1, 1, 3, 3, -3, 1, -3, -1, 1, 1}, {1, -3, -3, 1, -1, -1, 1, 1, -3, 1, -3, 1, 3, 3, 1, 1, 1, -3, -3, 1, -1, -1, 1, 1}, {1, -3, -3, 1, 3, 3, 1, 1, -3, 1, -3, 1, -1, -1, 1, 1, 1, -3, -3, 1, 3, 3, 1, 1}, {3, -1, -1, -3, -3, -3, 1, 1, 3, -1, 1, 3, -1, -3, -1, -1, -1, 3, 1, -1, -1, -1, 1, 1}, {-1, 3, 3, -3, -3, -3, 1, 1, -1, 3, 1, -1, 3, -3, 3, 3, 3, -1, 1, 3, 3, 3, 1, 1}, {-1, 1, -3, 1, -1, -3, 1, -3, -3, 1, -1, -1, -3, -3, -1, -1, 1, -3, 1, 3, 3, -3, 1, 1}, {3, 1, -3, 1, 3, -3, 1, -3, -3, 1, 3, 3, -3, -3, 3, 3, 1, -3, 1, -1, -1, -3, 1, 1}, {3, 3, 1, -3, -1, -3, 1, -1, 1, -1, 3, -3, -3, 1, 1, -3, 1, 1, -1, 1, 1, 1, 1, 1}, {-1, -1, 1, -3, 3, -3, 1, 3, 1, 3, -1, -3, -3, 1, 1, -3, 1, 1, 3, 1, 1, 1, 1, 1}, {-1, 1, 3, 1, 3, -3, -1, 3, -1, -1, -1, 1, 3, -1, -3, 1, -1, -1, -3, -3, -3, 3, 1, 1}, {3, 1, -1, 1, -1, -3, 3, -1, 3, 3, 3, 1, -1, 3, -3, 1, 3, 3, -3, -3, -3, -1, 1, 1}, {1, -1, -3, -3, 1, -1, 3, 3, 1, -1, -3, -1, -3, 1, 3, -3, 1, 3, 3, 3, 3, -3, 1, 1}, {1, 3, -3, -3, 1, 3, -1, -1, 1, 3, -3, 3, -3, 1, -1, -3, 1, -1, -1, -1, -1, -3, 1, 1}, {3, -1, -3, -3, -3, 3, -3, 3, 3, 3, 1, -3, 1, -3, -3, 3, -1, -1, 1, 3, -3, -1, 1, 1}, {-1, 3, -3, -3, -3, -1, -3, -1, -1, -1, 1, -3, 1, -3, -3, -1, 3, 3, 1, -1, -3, 3, 1, 1}, {3, -3, -3, 1, -3, 1, 1, -3, 1, -1, 3, -3, -3, -3, 3, -1, -1, -3, 3, 3, -3, -1, 1, 1}, {-1, -3, -3, 1, -3, 1, 1, -3, 1, 3, -1, -3, -3, -3, -1, 3, 3, -3, -1, -1, -3, 3, 1, 1}, {1, 3, 3, 1, -3, 3, 1, 3, 3, 3, -3, -3, 1, 3, 1, -1, -1, 3, -3, 1, -3, 3, 1, 1}, {1, -1, -1, 1, -3, -1, 1, -1, -1, -1, -3, -3, 1, -1, 1, 3, 3, -1, -3, 1, -3, -1, 1, 1}, {-3, -3, -1, 3, -3, -1, -1, 3, -3, -1, 3, 1, -1, -3, -1, 3, 1, 3, 3, 3, 1, 1, 1, 1}, {-3, -3, 3, -1, -3, 3, 3, -1, -3, 3, -1, 1, 3, -3, 3, -1, 1, -1, -1, -1, 1, 1, 1, 1}, {3, 3, 3, -1, 1, 3, 3, 3, 3, 1, -3, -1, -3, 1, -3, -3, 1, 3, 3, 1, -3, -3, 1, 1}, {-1, -1, -1, 3, 1, -1, -1, -1, -1, 1, -3, 3, -3, 1, -3, -3, 1, -1, -1, 1, -3, -3, 1, 1}, {-3, -3, -1, 3, -3, -1, 1, -3, -1, 3, -1, -3, 1, 1, 3, 3, 3, 1, 1, -1, -3, 3, 1, 1}, {-3, -3, 3, -1, -3, 3, 1, -3, 3, -1, 3, -3, 1, 1, -1, -1, -1, 1, 1, 3, -3, -1, 1, 1}, {3, 1, 1, 1, -1, 1, 1, -1, -3, 1, 1, 3, -1, 1, -1, 3, 3, 3, -3, -1, -3, -1, 1, 1}, {-1, 1, 1, 1, 3, 1, 1, 3, -3, 1, 1, -1, 3, 1, 3, -1, -1, -1, -3, 3, -3, 3, 1, 1}, {1, 1, 1, -1, -1, 1, -1, -3, -3, 1, -3, 3, -1, 1, -3, -3, 3, -3, -1, -1, -1, 1, 1, 1}, {1, 1, 1, 3, 3, 1, 3, -3, -3, 1, -3, -1, 3, 1, -3, -3, -1, -3, 3, 3, 3, 1, 1, 1}, {1, 1, 3, 1, 1, -1, 1, -1, 1, -1, 3, -1, 1, 3, -3, 3, 1, -1, -3, -3, -3, -3, 1, 1}, {1, 1, -1, 1, 1, 3, 1, 3, 1, 3, -1, 3, 1, -1, -3, -1, 1, 3, -3, -3, -3, -3, 1, 1}, {1, 3, -3, -3, 3, -3, -1, 3, 3, 1, 3, -3, 3, -1, 1, -1, -3, -1, -1, 3, 1, -1, 1, 1}, {1, -1, -3, -3, -1, -3, 3, -1, -1, 1, -1, -3, -1, 3, 1, 3, -3, 3, 3, -1, 1, 3, 1, 1}, {-1, -1, 3, -1, -1, -3, 1, 3, -3, -1, 3, 1, -3, 1, 1, 1, 1, 1, -3, -3, 3, 1, 1, 1}, {3, 3, -1, 3, 3, -3, 1, -1, -3, 3, -1, 1, -3, 1, 1, 1, 1, 1, -3, -3, -1, 1, 1, 1}, {3, -3, -1, 1, -1, 3, 1, 1, 3, 1, 3, 1, -1, -1, -3, 1, 3, -3, -1, 1, -1, 3, 1, 1}, {-1, -3, 3, 1, 3, -1, 1, 1, -1, 1, -1, 1, 3, 3, -3, 1, -1, -3, 3, 1, 3, -1, 1, 1}, {3, -1, 3, -1, -3, 1, -3, -3, -1, 1, -1, 1, 3, -1, -3, 3, 3, 3, 1, 1, 3, 3, 1, 1}, {-1, 3, -1, 3, -3, 1, -3, -3, 3, 1, 3, 1, -1, 3, -3, -1, -1, -1, 1, 1, -1, -1, 1, 1}, {-3, 3, -1, 3, 3, -1, -3, 3, -1, 1, 3, 1, 1, -1, 3, -3, 3, 1, 3, 3, -3, 1, 1, 1}, {-3, -1, 3, -1, -1, 3, -3, -1, 3, 1, -1, 1, 1, 3, -1, -3, -1, 1, -1, -1, -3, 1, 1, 1}, {3, -1, 3, -1, -3, 1, -1, -3, 1, -3, -1, 3, -3, -3, -1, -1, -1, -3, 3, 3, 1, 1, 1, 1}, {-1, 3, -1, 3, -3, 1, 3, -3, 1, -3, 3, -1, -3, -3, 3, 3, 3, -3, -1, -1, 1, 1, 1, 1}, {-1, -3, -1, 3, -1, -1, 3, 1, 3, -1, 3, 1, -1, 1, 3, -3, 3, 1, 1, 1, -1, -1, 1, 1}, {3, -3, 3, -1, 3, 3, -1, 1, -1, 3, -1, 1, 3, 1, -1, -3, -1, 1, 1, 1, 3, 3, 1, 1}, {1, -1, -3, 3, 3, -3, 3, -3, 3, 3, 1, -3, -3, -1, -3, 1, 3, 3, -1, 1, 3, -3, 1, 1}, {1, 3, -3, -1, -1, -3, -1, -3, -1, -1, 1, -3, -3, 3, -3, 1, -1, -1, 3, 1, -1, -3, 1, 1}, {1, -3, 1, 3, -3, -1, 1, 1, 1, 1, 1, -1, -3, 3, 1, -3, 1, -3, 1, 3, -3, -1, 1, 1}, {1, -3, 1, -1, -3, 3, 1, 1, 1, 1, 1, 3, -3, -1, 1, -3, 1, -3, 1, -1, -3, 3, 1, 1}, {1, 3, -1, -3, -1, 1, 3, -1, 3, -1, 3, -3, -3, 1, 1, -1, 1, 1, -1, -1, 1, 1, 1, 1}, {1, -1, 3, -3, 3, 1, -1, 3, -1, 3, -1, -3, -3, 1, 1, 3, 1, 1, 3, 3, 1, 1, 1, 1}, {1, 3, -3, -1, -1, 3, 1, 1, -3, 3, -3, 3, 3, 3, 1, -3, 1, 3, -3, -1, -1, 3, 1, 1}, {1, -1, -3, 3, 3, -1, 1, 1, -3, -1, -3, -1, -1, -1, 1, -3, 1, -1, -3, 3, 3, -1, 1, 1}, {3, -1, -3, 1, -1, -3, 1, 3, -1, 1, 3, 3, -3, 3, -1, -3, -3, 3, 3, 3, 3, -3, 1, 1}, {-1, 3, -3, 1, 3, -3, 1, -1, 3, 1, -1, -1, -3, -1, 3, -3, -3, -1, -1, -1, -1, -3, 1, 1}, {-3, -3, 1, 3, 1, -1, 1, -3, -3, -3, 1, -1, 1, 3, 1, 1, -3, 1, 1, 3, 1, -1, 1, 1}, {-3, -3, 1, -1, 1, 3, 1, -3, -3, -3, 1, 3, 1, -1, 1, 1, -3, 1, 1, -1, 1, 3, 1, 1}, {-1, 1, 3, 3, 1, -3, 3, -3, 3, -1, -1, 1, 3, 1, 1, -1, 1, -1, -1, 3, 3, -3, 1, 1}, {3, 1, -1, -1, 1, -3, -1, -3, -1, 3, 3, 1, -1, 1, 1, 3, 1, 3, 3, -1, -1, -3, 1, 1}, {-3, 1, 1, 3, 3, 1, -3, -3, 1, 3, -1, 3, 3, 3, -3, -1, -3, 3, -3, 3, 1, 1, 1, 1}, {-3, 1, 1, -1, -1, 1, -3, -3, 1, -1, 3, -1, -1, -1, -3, 3, -3, -1, -3, -1, 1, 1, 1, 1}, {1, 3, 3, -1, 1, -1, -3, 3, 1, 3, -1, -3, 1, 3, -3, 3, 3, -3, 3, -3, -1, -1, 1, 1}, {1, -1, -1, 3, 1, 3, -3, -1, 1, -1, 3, -3, 1, -1, -3, -1, -1, -3, -1, -3, 3, 3, 1, 1}, {-3, -3, -3, -3, 1, 1, -1, 1, -3, 1, 3, 1, -1, -3, -1, -1, 1, -3, -3, 1, 1, -3, 1, 1}, {-3, -3, -3, -3, 1, 1, 3, 1, -3, 1, -1, 1, 3, -3, 3, 3, 1, -3, -3, 1, 1, -3, 1, 1}, {-1, 3, 1, 1, -1, 3, 3, 1, 3, -3, -3, -1, 1, -3, 1, -1, -3, -1, -3, -3, 3, 3, 1, 1}, {3, -1, 1, 1, 3, -1, -1, 1, -1, -3, -3, 3, 1, -3, 1, 3, -3, 3, -3, -3, -1, -1, 1, 1}, {3, -3, -1, 3, 3, 3, -1, -1, -3, 1, 3, 1, -3, -1, -1, -3, -1, -1, -3, 1, 1, -3, 1, 1}, {-1, -3, 3, -1, -1, -1, 3, 3, -3, 1, -1, 1, -3, 3, 3, -3, 3, 3, -3, 1, 1, -3, 1, 1}, {-1, 1, 1, -1, -3, -3, 1, 1, 3, 1, 1, 3, 1, -3, 1, -3, -1, 1, 1, -1, -3, -3, 1, 1}, {3, 1, 1, 3, -3, -3, 1, 1, -1, 1, 1, -1, 1, -3, 1, -3, 3, 1, 1, 3, -3, -3, 1, 1}, {3, 1, -3, 3, 1, 1, -3, -3, -1, 1, -1, -3, 1, 3, -1, 1, -1, -1, -3, -1, -1, 1, 1, 1}, {-1, 1, -3, -1, 1, 1, -3, -3, 3, 1, 3, -3, 1, -1, 3, 1, 3, 3, -3, 3, 3, 1, 1, 1}, {1, -3, -3, 1, 3, 3, 1, 3, 1, 1, -3, 1, 1, -3, -3, -3, 1, -1, 1, -1, -3, -1, 1, 1}, {1, -3, -3, 1, -1, -1, 1, -1, 1, 1, -3, 1, 1, -3, -3, -3, 1, 3, 1, 3, -3, 3, 1, 1}, {3, -3, -1, 3, -1, -3, 1, 1, 3, -3, 3, -1, -1, -3, -3, -3, 3, -3, -1, 3, -1, -3, 1, 1}, {-1, -3, 3, -1, 3, -3, 1, 1, -1, -3, -1, 3, 3, -3, -3, -3, -1, -3, 3, -1, 3, -3, 1, 1}, {-3, 1, -3, -1, -1, 3, -1, -1, -1, -3, -1, -1, 1, -3, 3, 3, -1, 3, -1, -1, -3, 3, 1, 1}, {-3, 1, -3, 3, 3, -1, 3, 3, 3, -3, 3, 3, 1, -3, -1, -1, 3, -1, 3, 3, -3, -1, 1, 1}, {-3, 3, -3, -1, 3, -1, 3, 1, 1, -3, 1, -3, -3, -1, 1, -1, -3, -1, -1, -1, -3, 3, 1, 1}, {-3, -1, -3, 3, -1, 3, -1, 1, 1, -3, 1, -3, -3, 3, 1, 3, -3, 3, 3, 3, -3, -1, 1, 1}, {-1, -3, -3, -1, -1, 3, 1, 1, -1, 1, -3, 3, -1, -1, 1, -3, -1, -3, -3, -1, -1, 3, 1, 1}, {3, -3, -3, 3, 3, -1, 1, 1, 3, 1, -3, -1, 3, 3, 1, -3, 3, -3, -3, 3, 3, -1, 1, 1}, {3, -1, -1, -3, -3, -3, 1, 3, -1, 1, -3, -3, -3, -1, -1, -3, 3, -1, -3, 1, 3, 3, 1, 1}, {-1, 3, 3, -3, -3, -3, 1, -1, 3, 1, -3, -3, -3, 3, 3, -3, -1, 3, -3, 1, -1, -1, 1, 1}, {3, -1, -1, 1, 1, 3, 1, 1, -1, -1, 3, 1, -3, 3, -3, 1, 3, -1, -1, 1, 1, 3, 1, 1}, {-1, 3, 3, 1, 1, -1, 1, 1, 3, 3, -1, 1, -3, -1, -3, 1, -1, 3, 3, 1, 1, -1, 1, 1}, {1, 3, 1, 1, 3, -1, 3, 3, 1, -3, 1, -3, -1, -1, -3, -3, 1, 1, 3, 3, -3, -1, 1, 1}, and {1, -1, 1, 1, -1, 3, -1, -1, 1, -3, 1, -3, 3, 3, -3, -3, 1, 1, -1, -1, -3, 3, 1, 1}; and a sending unit, configured to send a signal generated based on the sequence { f n }, wherein the sequence { f n } is mapped to N subcarriers.', '22. A signal processing apparatus, wherein the apparatus comprises a processor and a storage medium, the storage medium stores an instruction, and when the instruction is run by the processor, the processor is enabled to perform the signal processing method according to any one of claims 1 to 6 and 13 to']",True,"['5', '601', '602', '600', '6', '701', '702', '703', '700', '7', '52']" 861,EP_3605983_A1 (4).png,EP3605983A1,"SIGNAL PROCESSING METHOD, SIGNAL PROCESSING DEVICE, COMPUTER-READABLE STORAGE MEDIUM, AND COMPUTER PROGRAM PRODUCT","['FIG10', ' FIG8', ' FIG9']","['FIG9 is a schematic structural diagram of another network device according to an embodiment of this application ', 'FIG8 is a schematic structural diagram of a network device according to an embodiment of this application ', 'FIG10 is a schematic structural diagram of a communications system according to an embodiment of this application']","['As shown in FIG9, the signal processing apparatus 900 includes a processor 901 and a transceiver 903. Optionally, the signal processing apparatus 900 further includes a memory 902.', 'It may be understood that FIG9 shows merely a simplified design of the signal processing apparatus 900. In actual application, the signal processing apparatus 900 may include any quantities of interfaces, processors, memories, and the like, and all signal processing apparatuses 900 that can implement the embodiments of this application fall within the protection scope of the embodiments of this application. ', 'FIG8 is a schematic structural diagram of a sequence-based signal processing apparatus 800 according to an embodiment of this application. The signal processing apparatus 800 may be a communications device, or may be a chip in a communications device. The signal processing apparatus 800 includes a transceiver unit 801 and a processing unit 802. ', 'FIG10 is a communications system 1000 according to an embodiment of this application. The communications system 1000 includes a first communications device 1001 and a second communications device 1002. The first communications device 1001 is a device on a transmitter side, and the second communications device 1002 is a device on a terminal side.']",51,219,schematic structural diagram,H,"[{'element_identifier': '8', 'terms': ['modulus']}, {'element_identifier': '801', 'terms': ['transceiver unit']}, {'element_identifier': '900', 'terms': ['signal processing apparatus', 'signal processing apparatuses']}, {'element_identifier': '1002', 'terms': []}, {'element_identifier': '901', 'terms': ['processor']}, {'element_identifier': '902', 'terms': ['memory']}, {'element_identifier': '802', 'terms': ['processing unit']}, {'element_identifier': '903', 'terms': ['transceiver']}, {'element_identifier': '1001', 'terms': ['first communications device', 'first communications devices']}, {'element_identifier': '1000', 'terms': ['communications system']}, {'element_identifier': '800', 'terms': ['signal processing apparatus']}]","['7. A signal processing apparatus, comprising: a processing unit, configured to determine a sequence { f n } comprising N elements, wherein f n is an element in the sequence { f n }, the sequence { f n } meets fn = A·x n ·e 2 π·j·a·n , a value of n ranges from 0 to N-1, A is a non-zero complex number, a is a real number, an element x n = u · e ρ M π · j · s n / M , u is a non-zero complex number, M is 4, 12, or 16, ρ M is a real number, ρ M is 1 or -1 when M is 4, ρ M is 2 or -2 when M is 12 or 16, and a sequence { s n } comprising an element s n is a sequence in a first sequence set or an equivalent sequence of the sequence in the first sequence set, or a sequence in a second sequence set or an equivalent sequence of the sequence in the second sequence set, or a sequence in a third sequence set or an equivalent sequence of the sequence in the third sequence set, wherein the first sequence set comprises some or all of the following sequences, and M is 4: {-1, -1, -1, -1, -1, -1, 3, -1, 3, 3, -1, -1}, {3, 3, -1, 3, -1, 3, 3, -1, -1, -1, -1, -1}, {-1, -1, -1, -1, -3, 3, -1, 3, -3, -1, -1, -1}, {-1, -1, -1, -1, 1, 3, -1, 3, 1, -1, -1, -1}, {-3, 3, -1, -1, -3, -1, -1, 3, -3, 3, -1, -1}, {1, 3, -1, -1, 1, -1, -1, 3, 1, 3, -1, -1}, {-1, 3, -1, 3, -1, 3, 3, -1, -1, -1, -1, -1}, {-3, 3, -1, -3, 1, -1, 1, 3, 1, 1, -1, -1}, {1, 3, -1, 1, -3, -1, -3, 3, -3, -3, -1, -1}, {-3, 3, -1, 3, -1, 3, 3, -1, -1, -1, -1, -1}, {1, 3, -1, 3, -1, 3, 3, -1, -1, -1, -1, -1}, {3, -1, 3, 3, -1, 3, 3, 3, -1, -1, -1, -1}, {-1, 3, 1, -1, -3, 1, 3, -1, -1, -1, -1, -1}, {3, 1, 1, 1, -1, 3, 1, 1, 3, -3, -1, -1}, {3, -3, -3, -3, -1, 3, -3, -3, 3, 1, -1, -1}, {3, 1, 1, -3, 3, 1, 3, 1, 3, -3, -1, -1}, {3, -3, -3, 1, 3, -3, 3, -3, 3, 1, -1, -1}, {-3, 3, -3, -3, -3, -1, 3, -3, 3, 1, -1, -1}, {1, 3, 1, 1, 1, -1, 3, 1, 3, -3, -1, -1}, {-3, -3, 1, 3, -3, 3, -3, 1, -1, -3, -1, -1}, {-3, -3, 1, 1, -1, -1, -3, 1, -3, -3, -1, -1}, {1, 1, -3, -3, -1, -1, 1, -3, 1, 1, -1, -1}, {1, 3, -3, 1, -3, -1, -1, -1, -3, 3, -1, -1}, {-3, 3, 1, -3, 1, -1, -1, -1, 1, 3, -1, -1}, {3, -1, -3, -1, -3, 3, 3, -3, -1, 3, -1, -1}, {3, -1, 1, -1, 1, 3, 3, 1, -1, 3, -1, -1}, {-3, 1, -1, -1, 3, 1, 3, -1, -1, 1, -1, -1}, {1, -3, -1, -1, 3, -3, 3, -1, -1, -3, -1, -1}, {1, -1, 1, -1, 3, -1, 1, 3, 3, 1, -1, -1}, {-3, 1, 3, -1, 3, -3, 3, 1, 3, 3, -1, -1}, {1, -3, 3, -1, 3, 1, 3, -3, 3, 3, -1, -1}, and {3, -1, 3, 3, -1, 3, 3, 3, 3, -1, -1, -1}, the second sequence set comprises a sequence in a sequence set 2A and/or a sequence in a sequence set 2B, the sequence set 2A comprises some or all of the following sequences, and M is 12: {0, 0, 6, 7, 10, 10, 10, 5, 10, 4, 2, 11}, {0, 0, 11, 0, 1, 11, 3, 8, 7, 2, 2, 9}, {0, 0, 2, 5, 8, 0, 7, 2, 0, 11, 11, 0}, {0, 0, 3, 4, 5, 3, 0, 7, 0, 4, 8, 8}, {0, 0, 9, 8, 7, 9, 0, 5, 0, 8, 4, 4}, {0, 0, 4, 6, 10, 11, 5, 1, 3, 1, 2, 0}, {0, 0, 0, 4, 4, 6, 0, 4, 1, 11, 6, 2}, {0, 0, 6, 3, 1, 8, 8, 10, 6, 10, 5, 10}, {0, 0, 3, 6, 10, 2, 9, 5, 3, 3, 4, 4}, {0, 0, 4, 3, 9, 8, 3, 6, 2, 5, 4, 6}, {0, 0, 1, 5, 5, 7, 1, 5, 2, 0, 7, 3}, {0, 0, 10, 9, 9, 6, 9, 1, 11, 5, 3, 10}, {0, 0, 8, 7, 6, 2, 4, 7, 4, 9, 7, 1}, {0, 0, 1, 4, 6, 9, 4, 10, 8, 7, 5, 6}, {0, 0, 9, 7, 6, 2, 4, 7, 4, 9, 6, 0}, {0, 0, 6, 7, 0, 1, 8, 4, 7, 5, 5, 5}, {0, 0, 4, 8, 0, 4, 0, 8, 7, 8, 9, 10}, {0, 0, 10, 9, 8, 10, 1, 6, 2, 10, 6, 7}, {0, 0, 4, 1, 7, 5, 10, 0, 8, 9, 7, 9}, {0, 0, 5, 0, 7, 1, 2, 8, 8, 8, 7, 9}, {0, 0, 7, 0, 5, 11, 10, 4, 4, 4, 5, 3}, {0, 0, 8, 8, 7, 7, 10, 2, 9, 5, 1, 11}, {0, 0, 9, 8, 7, 8, 11, 4, 0, 8, 3, 3}, {0, 0, 3, 4, 5, 4, 1, 8, 0, 4, 9, 9}, {0, 0, 4, 0, 6, 4, 9, 11, 7, 7, 6, 8}, {0, 0, 7, 5, 4, 11, 0, 3, 11, 4, 1, 5}, {0, 0, 8, 8, 8, 4, 7, 10, 7, 1, 0, 5}, {0, 0, 4, 0, 5, 2, 6, 7, 3, 3, 0, 0}, {0, 0, 7, 6, 5, 0, 1, 4, 0, 4, 2, 6}, {0, 0, 3, 6, 9, 0, 7, 2, 0, 0, 0, 0}, {0, 0, 1, 2, 4, 3, 8, 2, 2, 10, 10, 7}, {0, 0, 11, 1, 1, 0, 4, 9, 7, 2, 3, 10}, {0, 0, 4, 8, 11, 4, 1, 6, 5, 4, 3, 10}, {0, 0, 8, 4, 1, 8, 11, 6, 7, 8, 9, 2}, {0, 0, 2, 2, 5, 4, 9, 3, 4, 0, 0, 10}, {0, 0, 3, 10, 3, 0, 4, 5, 0, 11, 9, 10}, {0, 0, 11, 0, 1, 11, 3, 8, 7, 2, 2, 10}, {0, 0, 2, 5, 8, 11, 6, 1, 11, 10, 10, 10}, {0, 0, 4, 7, 10, 2, 10, 5, 4, 4, 3, 4}, {0, 0, 6, 6, 8, 7, 6, 0, 4, 10, 7, 2}, {0, 0, 5, 3, 11, 10, 4, 8, 5, 7, 7, 10}, {0, 0, 4, 7, 10, 4, 0, 7, 7, 6, 6, 8}, {0, 0, 8, 7, 5, 6, 9, 1, 9, 4, 10, 10}, {0, 0, 4, 5, 7, 6, 3, 11, 3, 8, 2, 2}, {0, 0, 8, 4, 4, 11, 0, 3, 0, 5, 1, 6}, {0, 0, 5, 5, 7, 6, 5, 11, 3, 9, 6, 1}, {0, 0, 3, 3, 4, 3, 0, 7, 0, 3, 8, 8}, {0, 0, 9, 8, 6, 7, 10, 2, 10, 5, 0, 0}, {0, 0, 0, 10, 0, 6, 8, 6, 0, 10, 6, 0}, {0, 0, 8, 10, 7, 8, 3, 9, 8, 0, 2, 2}, {0, 0, 6, 0, 8, 2, 4, 8, 7, 6, 6, 2}, {0, 0, 6, 0, 4, 10, 8, 4, 5, 6, 6, 10}, {0, 0, 7, 3, 1, 6, 6, 7, 2, 5, 1, 4}, {0, 0, 4, 1, 7, 5, 11, 1, 9, 10, 9, 11}, {0, 0, 4, 1, 10, 4, 3, 4, 10, 1, 9, 0}, {0, 0, 4, 0, 6, 4, 8, 10, 6, 6, 4, 6}, {0, 0, 0, 10, 8, 6, 0, 6, 9, 11, 0, 1}, {0, 0, 4, 2, 11, 2, 1, 7, 9, 5, 10, 0}, {0, 0, 8, 10, 1, 10, 11, 5, 3, 7, 2, 0}, {0, 0, 6, 4, 2, 0, 1, 4, 10, 5, 0, 7}, {0, 0, 4, 6, 11, 4, 10, 7, 5, 5, 6, 7}, {0, 0, 11, 0, 1, 4, 9, 3, 0, 9, 7, 7}, {0, 0, 1, 0, 11, 8, 3, 9, 0, 3, 5, 5}, {0, 0, 4, 6, 10, 2, 9, 5, 4, 4, 5, 5}, {0, 0, 7, 1, 9, 3, 5, 9, 8, 7, 6, 3}, {0, 0, 5, 9, 1, 6, 3, 10, 10, 10, 10, 0}, {0, 0, 2, 3, 6, 6, 11, 6, 7, 4, 4, 1}, {0, 0, 3, 5, 8, 8, 2, 9, 10, 7, 8, 6}, {0, 0, 10, 0, 11, 9, 1, 5, 3, 9, 10, 5}, {0, 0, 5, 10, 3, 9, 7, 3, 4, 5, 6, 9}, {0, 0, 4, 8, 1, 6, 2, 11, 10, 0, 2, 3}, {0, 0, 8, 4, 11, 6, 10, 1, 2, 0, 10, 9}, {0, 0, 4, 1, 9, 3, 1, 2, 8, 10, 6, 8}, {0, 0, 3, 11, 4, 1, 6, 7, 2, 2, 0, 1}, {0, 0, 5, 6, 7, 3, 2, 7, 3, 6, 0, 7}, {0, 0, 7, 6, 5, 9, 10, 5, 9, 6, 0, 5}, {0, 0, 7, 5, 2, 2, 4, 7, 2, 8, 2, 1}, {0, 0, 2, 5, 8, 11, 6, 1, 11, 11, 10, 11}, {0, 0, 4, 8, 1, 6, 3, 11, 11, 0, 0, 2}, {0, 0, 7, 1, 7, 0, 1, 4, 2, 0, 10, 7}, {0, 0, 8, 1, 7, 3, 2, 1, 4, 6, 11, 0}, {0, 0, 10, 7, 4, 1, 6, 11, 1, 1, 1, 2}, {0, 0, 4, 7, 10, 3, 11, 6, 6, 5, 5, 6}, {0, 0, 7, 6, 3, 3, 5, 8, 3, 9, 3, 2}, {0, 0, 9, 10, 2, 3, 4, 0, 6, 1, 1, 9}, {0, 0, 5, 4, 2, 11, 0, 3, 9, 4, 11, 6}, {0, 0, 4, 8, 11, 4, 1, 6, 5, 4, 3, 11}, {0, 0, 8, 4, 1, 8, 11, 6, 7, 8, 9, 1}, {0, 0, 7, 4, 1, 11, 0, 2, 7, 1, 7, 3}, {0, 0, 10, 10, 10, 7, 10, 2, 0, 6, 5, 0}, {0, 0, 0, 9, 9, 7, 1, 8, 11, 1, 4, 3}, {0, 0, 0, 3, 3, 5, 11, 4, 1, 11, 8, 9}, {0, 0, 0, 6, 9, 4, 6, 5, 11, 8, 4, 1}, {0, 0, 7, 8, 11, 11, 11, 6, 11, 6, 4, 0}, {0, 0, 5, 11, 5, 8, 8, 1, 11, 9, 8, 10}, {0, 0, 3, 5, 6, 9, 4, 7, 4, 2, 10, 7}, {0, 0, 6, 4, 3, 10, 11, 1, 9, 2, 10, 3}, {0, 0, 6, 5, 0, 0, 8, 0, 9, 0, 1, 4}, {0, 0, 0, 10, 9, 7, 1, 8, 11, 1, 4, 4}, {0, 0, 8, 7, 5, 6, 9, 1, 9, 4, 11, 10}, {0, 0, 1, 3, 3, 4, 10, 1, 9, 6, 1, 8}, {0, 0, 1, 3, 5, 7, 1, 7, 4, 3, 2, 1}, {0, 0, 1, 10, 0, 9, 0, 5, 4, 11, 9, 5}, {0, 0, 5, 8, 1, 6, 2, 11, 11, 0, 2, 2}, {0, 0, 7, 4, 11, 6, 10, 1, 1, 0, 10, 10}, {0, 0, 6, 11, 4, 8, 8, 10, 7, 4, 1, 9}, {0, 0, 11, 9, 9, 7, 1, 8, 11, 1, 4, 4}, {0, 0, 3, 1, 9, 5, 4, 6, 11, 4, 10, 3}, {0, 0, 3, 7, 10, 2, 10, 5, 4, 3, 3, 4}, {0, 0, 0, 1, 1, 0, 4, 9, 7, 2, 2, 9}, {0, 0, 8, 8, 7, 4, 6, 10, 7, 1, 11, 5}, {0, 0, 5, 9, 1, 5, 1, 9, 8, 9, 10, 11}, {0, 0, 11, 1, 3, 10, 11, 6, 3, 7, 4, 10}, {0, 0, 11, 0, 2, 3, 8, 2, 10, 9, 6, 6}, {0, 0, 10, 0, 9, 11, 7, 1, 1, 5, 7, 9}, {0, 0, 8, 8, 11, 11, 11, 6, 11, 5, 4, 11}, {0, 0, 11, 10, 0, 9, 1, 5, 4, 11, 10, 5}, {0, 0, 9, 2, 10, 6, 5, 5, 8, 0, 5, 7}, {0, 0, 8, 6, 4, 5, 7, 11, 5, 0, 7, 7}, {0, 0, 2, 4, 6, 8, 4, 4, 0, 6, 1, 6}, {0, 0, 2, 3, 5, 4, 9, 3, 3, 11, 0, 8}, {0, 0, 6, 9, 0, 5, 2, 7, 6, 5, 4, 11}, {0, 0, 6, 3, 0, 7, 10, 5, 6, 7, 8, 1}, {0, 0, 6, 4, 11, 10, 5, 8, 5, 7, 8, 11}, {0, 0, 6, 4, 2, 10, 10, 1, 9, 2, 9, 2}, {0, 0, 4, 9, 0, 5, 2, 9, 9, 9, 9, 0}, {0, 0, 3, 7, 10, 2, 10, 5, 4, 4, 4, 5}, {0, 0, 9, 8, 7, 6, 11, 9, 2, 6, 10, 4}, {0, 0, 3, 4, 5, 6, 1, 3, 10, 6, 2, 8}, {0, 0, 3, 5, 7, 9, 5, 8, 4, 1, 10, 6}, {0, 0, 1, 10, 8, 6, 0, 6, 9, 10, 0, 11}, {0, 0, 11, 2, 4, 6, 0, 6, 3, 2, 0, 1}, {0, 0, 2, 4, 5, 9, 3, 9, 7, 5, 4, 5}, {0, 0, 10, 6, 4, 0, 4, 10, 11, 0, 1, 0}, {0, 0, 2, 6, 8, 0, 8, 2, 1, 0, 11, 0}, {0, 0, 4, 5, 7, 6, 4, 11, 5, 9, 3, 3}, {0, 0, 0, 8, 5, 3, 8, 1, 4, 3, 5, 3}, {0, 0, 0, 4, 7, 9, 4, 11, 8, 9, 7, 9}, {0, 0, 7, 6, 5, 4, 6, 10, 5, 1, 9, 4}, {0, 0, 4, 8, 0, 4, 0, 8, 7, 8, 9, 9}, {0, 0, 8, 4, 0, 8, 0, 4, 5, 4, 3, 3}, {0, 0, 0, 0, 1, 11, 3, 8, 7, 2, 2, 9}, {0, 0, 5, 2, 0, 6, 5, 7, 2, 5, 1, 3}, {0, 0, 5, 11, 5, 8, 8, 10, 6, 4, 0, 9}, {0, 0, 8, 1, 5, 0, 4, 3, 10, 10, 0, 0}, {0, 0, 6, 6, 8, 8, 6, 0, 4, 10, 9, 4}, {0, 0, 4, 2, 1, 10, 11, 2, 7, 3, 10, 5}, {0, 0, 8, 7, 5, 6, 8, 0, 7, 2, 9, 8}, {0, 0, 5, 3, 11, 8, 8, 10, 4, 9, 4, 9}, {0, 0, 7, 5, 3, 10, 11, 1, 9, 1, 10, 2}, {0, 0, 3, 6, 8, 0, 8, 0, 10, 8, 6, 1}, {0, 0, 3, 10, 6, 11, 8, 9, 2, 3, 11, 11}, {0, 0, 11, 0, 0, 2, 7, 0, 9, 6, 2, 3}, {0, 0, 1, 0, 0, 10, 5, 0, 3, 6, 10, 9}, {0, 0, 7, 10, 4, 10, 7, 5, 6, 8, 11, 11}, {0, 0, 4, 8, 1, 5, 4, 6, 3, 11, 9, 4}, {0, 0, 1, 1, 4, 2, 7, 1, 1, 10, 8, 6}, {0, 0, 3, 8, 1, 3, 2, 6, 3, 0, 10, 10}, {0, 0, 4, 7, 10, 2, 10, 4, 3, 2, 1, 2}, {0, 0, 10, 10, 9, 11, 3, 8, 5, 1, 9, 9}, and {0, 0, 2, 2, 3, 1, 9, 4, 7,11, 3,3}, the sequence set 2B comprises some or all of the following sequences, and M is 16: {9, 8, 11, 14, 1, 5, 14, 6, 3, 1, 0, 0}, {13, 12, 14, 1, 4, 7, 0, 8, 4, 3, 0, 0}, {14, 5, 11, 2, 9, 13, 9, 6, 10, 10, 0, 0}, {10, 12, 1, 3, 10, 10, 4, 14, 2, 15, 0, 0}, {12, 9, 12, 6, 12, 7, 12, 13, 5, 4, 0, 0}, {13, 12, 0, 2, 4, 8, 1, 8, 5, 3, 0, 0}, {13, 15, 6, 10, 1, 4, 14, 10, 14, 13, 0, 0}, {9, 8, 2, 0, 13, 14, 1, 6, 15, 8, 0, 0}, {7, 8, 14, 0, 3, 2, 15, 10, 1, 8, 0, 0}, {11, 11, 15, 3, 8, 13, 7, 1, 15, 15, 0, 0}, {7, 3, 6, 14, 7, 11, 6, 4, 9, 9, 0, 0}, {12, 12, 7, 6, 5, 7, 11, 2, 11, 6, 0, 0}, {4, 4, 9, 10, 11, 9, 5, 14, 5, 10, 0, 0}, {13, 14, 9, 8, 6, 8, 12, 2, 12, 6, 0, 0}, {3, 2, 7, 8, 10, 8, 4, 14, 4, 10, 0, 0}, {2, 10, 14, 4, 12, 15, 10, 7, 11, 11, 0, 0}, {4, 3, 4, 6, 8, 11, 3, 10, 6, 3, 0, 0}, {9, 6, 9, 4, 10, 5, 11, 12, 4, 4, 0, 0}, {2, 14, 0, 9, 15, 9, 14, 14, 5, 4, 0, 0}, {7, 6, 1, 15, 12, 13, 0, 5, 14, 7, 0, 0}, {13, 13, 9, 8, 6, 8, 12, 2, 12, 6, 0, 0}, {3, 3, 7, 8, 10, 8, 4, 14, 4, 10, 0, 0}, {6, 5, 8, 11, 15, 3, 12, 5, 2, 1, 0, 0}, {7, 15, 4, 13, 5, 9, 6, 3, 8, 8, 0, 0}, {13, 13, 1, 5, 10, 14, 8, 2, 15, 0, 0, 0}, {10, 9, 5, 5, 15, 0, 7, 14, 11, 15, 0, 0}, {13, 12, 6, 7, 1, 0, 8, 14, 12, 14, 0, 0}, {0, 6, 10, 13, 5, 6, 0, 11, 15, 13, 0, 0}, {11, 11, 13, 0, 3, 6, 15, 7, 4, 2, 0, 0}, {6, 2, 4, 13, 2, 12, 0, 0, 7, 5, 0, 0}, {6, 9, 3, 10, 0, 8, 6, 15, 15, 1, 0, 0}, {13, 4, 15, 11, 6, 1, 5, 13, 14, 15, 0, 0}, {8, 1, 6, 14, 6, 10, 6, 4, 9, 9, 0, 0}, {15, 15, 0, 2, 5, 8, 0, 8, 4, 2, 0, 0}, {13, 2, 9, 0, 8, 12, 8, 5, 10, 10, 0, 0}, {2, 2, 13, 15, 10, 11, 3, 11, 9, 13, 0, 0}, {9, 0, 6, 14, 6, 10, 7, 4, 9, 9, 0, 0}, {1, 10, 6, 3, 15, 11, 0, 9, 12, 14, 0, 0}, {13, 2, 11, 3, 10, 3, 2, 12, 13, 15, 0, 0}, {6, 11, 10, 0, 9, 15, 4, 2, 14, 12, 0, 0}, {6, 6, 1, 15, 12, 13, 0, 5, 14, 7, 0, 0}, {8, 8, 3, 4, 14, 14, 6, 13, 11, 14, 0, 0}, {7, 8, 4, 4, 3, 5, 9, 0, 10, 6, 0, 0}, {1, 6, 10, 13, 5, 6, 0, 11, 15, 13, 0, 0}, {1, 4, 0, 1, 0, 2, 7, 14, 9, 5, 0, 0}, {15, 8, 3, 8, 1, 11, 14, 0, 11, 10, 0, 0}, {1, 8, 13, 8, 15, 5, 2, 0, 5, 6, 0, 0}, {9, 15, 10, 4, 0, 8, 12, 2, 1, 1, 0, 0}, {7, 9, 4, 5, 3, 5, 10, 0, 12, 6, 0, 0}, {0, 15, 10, 9, 7, 9, 13, 3, 13, 7, 0, 0}, {0, 1, 6, 7, 9, 7, 3, 13, 3, 9, 0, 0}, {7, 10, 15, 1, 8, 9, 2, 13, 1, 15, 0, 0}, {9, 11, 1, 3, 9, 10, 4, 14, 2, 15, 0, 0}, {9, 1, 5, 9, 1, 3, 13, 9, 13, 12, 0, 0}, {12, 2, 7, 10, 2, 4, 14, 10, 14, 13, 0, 0}, {10, 8, 11, 14, 1, 5, 14, 6, 3, 1, 0, 0}, {7, 12, 1, 7, 14, 1, 12, 8, 12, 11, 0, 0}, {9, 8, 11, 13, 1, 5, 13, 6, 2, 1, 0, 0}, {6, 6, 6, 9, 10, 12, 4, 11, 6, 4, 0, 0}, {10, 10, 10, 7, 6, 4, 12, 5, 10, 12, 0, 0}, {12, 3, 3, 10, 4, 11, 0, 15, 12, 11, 0, 0}, {6, 6, 10, 11, 1, 0, 9, 2, 5, 1, 0, 0}, {10, 13, 1, 3, 10, 10, 4, 14, 2, 15, 0, 0}, {9, 8, 11, 14, 1, 5, 14, 6, 3, 2, 0, 0}, {6, 11, 15, 1, 8, 9, 2, 13, 1, 15, 0, 0}, {1, 8, 2, 9, 1, 5, 9, 7, 2, 15, 0, 0}, {12, 11, 14, 0, 3, 7, 15, 7, 3, 1, 0, 0}, {9, 7, 11, 13, 0, 5, 14, 6, 4, 2, 0, 0}, {11, 1, 2, 9, 3, 10, 0, 15, 12, 11, 0, 0}, {7, 7, 1, 2, 13, 14, 5, 13, 10, 15, 0, 0}, {0, 0, 5, 7, 13, 13, 6, 0, 3, 0, 0, 0}, {13, 3, 9, 0, 8, 12, 8, 5, 10, 10, 0, 0}, {5, 10, 15, 1, 8, 9, 2, 13, 0, 14, 0, 0}, {2, 5, 11, 13, 5, 7, 1, 12, 0, 15, 0, 0}, {0, 14, 1, 10, 3, 8, 3, 2, 7, 7, 0, 0}, {4, 5, 9, 10, 0, 15, 8, 1, 4, 0, 0, 0}, {10, 6, 10, 0, 5, 15, 2, 1, 8, 5, 0, 0}, {4, 0, 2, 11, 1, 11, 15, 15, 6, 5, 0, 0}, {10, 1, 6, 14, 6, 10, 6, 4, 9, 9, 0, 0}, {9, 5, 9, 0, 9, 12, 7, 5, 10, 9, 0, 0}, {15, 0, 10, 9, 7, 9, 13, 3, 13, 7, 0, 0}, {1,0,6,7, 9, 7, 3, 13, 3, 9, 0, 0}, {14, 4, 11, 2, 9, 13, 9, 6, 10, 10, 0, 0}, {5, 4, 0, 14, 11, 12, 15, 4, 14, 7, 0, 0}, {11, 2, 7, 15, 7, 11, 7, 4, 9, 9, 0, 0}, {13, 6, 0, 13, 4, 14, 0, 9, 10, 11, 0, 0}, {4, 12, 15, 6, 13, 0, 11, 7, 11, 10, 0, 0}, {7, 3, 7, 14, 7, 11, 6, 4, 9, 9, 0, 0}, {9, 1, 6, 13, 6, 10, 6, 4, 9, 10, 0, 0}, {11, 8, 11, 4, 11, 6, 11, 12, 4, 3, 0, 0}, {14, 11, 14, 7, 13, 8, 13, 13, 5, 4, 0, 0}, {4, 14, 0, 6, 14, 1, 11, 8, 12, 11, 0, 0}, {6, 8, 9, 14, 7, 13, 5, 3, 14, 13, 0, 0}, {1, 0, 4, 8, 12, 0, 10, 3, 1, 0, 0, 0}, {9, 9, 14, 2, 7, 12, 6, 0, 15, 15, 0, 0}, {15, 15, 2, 4, 6, 9, 2, 9, 5, 3, 0, 0}, {4, 0, 3, 11, 1, 11, 15, 15, 6, 4, 0, 0}, {5, 5, 9, 12, 15, 3, 12, 5, 2, 1, 0, 0}, {15, 12, 15, 8, 14, 9, 13, 14, 6, 4, 0, 0}, {9, 13, 3, 8, 15, 2, 13, 9, 13, 12, 0, 0}, {12, 0, 4, 6, 12, 12, 5, 15, 2, 15, 0, 0}, {14, 12, 15, 2, 4, 8, 1, 8, 5, 3, 0, 0}, {5, 6, 3, 3, 1, 4, 9, 15, 11, 5, 0, 0}, {8, 8, 4, 4, 2, 5, 10, 0, 12, 6, 0, 0}, {8, 8, 12, 12, 14, 11, 6, 0, 4, 10, 0, 0}, {2, 13, 3, 14, 7, 4, 2, 5, 11, 0, 0, 0}, {14, 3, 13, 2, 9, 12, 14, 11, 5, 0, 0, 0}, {4, 10, 10, 0, 9, 15, 4, 2, 14, 13, 0, 0}, {9, 1, 6, 14, 6, 10, 6, 4, 9, 9, 0, 0}, {6, 10, 10, 0, 9, 15, 4, 2, 14, 12, 0, 0}, {1, 10, 14, 4, 12, 15, 10, 7, 11, 11, 0, 0}, {13, 2, 15, 4, 13, 2, 7, 5, 0, 13, 0, 0}, {5, 9, 6, 8, 9, 12, 2, 10, 6, 3, 0, 0}, {2, 2, 7, 8, 10, 8, 4, 13, 4, 9, 0, 0}, {12, 10, 13, 0, 2, 7, 0, 7, 5, 3, 0, 0}, {9, 6, 9, 0, 5, 15, 2, 1, 9, 6, 0, 0}, {15, 13, 7, 7, 1, 1, 9, 15, 12, 15, 0, 0}, {7, 10, 3, 10, 0, 8, 6, 15, 15, 1, 0, 0}, {13, 15, 4, 6, 12, 12, 5, 15, 2, 15, 0, 0}, {7, 10, 3, 10, 0, 8, 7, 0, 15, 1, 0, 0}, {14, 9, 12, 3, 12, 12, 6, 10, 9, 15, 0, 0}, {14, 15, 1, 4, 12, 2, 8, 5, 0, 14, 0, 0}, {4, 6, 11, 15, 6, 7, 1, 12, 0, 14, 0, 0}, {2, 1, 6, 9, 13, 1, 10, 3, 0, 0, 0, 0}, {11, 3, 15, 11, 6, 1, 5, 13, 15, 0, 0, 0}, {13, 11, 2, 11, 7, 0, 5, 9, 7, 7, 0, 0}, {3, 5, 14, 5, 9, 0, 11, 7, 9, 9, 0, 0}, {4, 8, 12, 14, 6, 7, 1, 12, 1, 15, 0, 0}, {4, 7, 11, 15, 6, 7, 1, 12, 0, 14, 0, 0}, {1, 14, 0, 9, 15, 9, 14, 14, 5, 4, 0, 0}, {0, 11, 14, 7, 14, 8, 12, 13, 4, 3, 0, 0}, {9, 9, 13, 13, 14, 11, 7, 0, 6, 11, 0, 0}, {7, 7, 3, 3, 2, 5, 9, 0, 10, 5, 0, 0}, {3, 8, 5, 15, 9, 5, 7, 3, 7, 12, 0, 0}, {13, 8, 11, 1, 7, 11, 9, 13, 9, 4, 0, 0}, {0, 0, 11, 10, 8, 10, 13, 3, 12, 6, 0, 0}, {0, 0, 5, 6, 8, 6, 3, 13, 4, 10, 0, 0}, {5, 4, 7, 9, 13, 2, 10, 4, 1, 0, 0, 0}, {5, 12, 14, 1, 8, 9, 2, 13, 0, 14, 0, 0}, {7, 10, 3, 10, 0, 8, 6, 15, 15, 0, 0, 0}, {11, 3, 4, 11, 1, 4, 14, 10, 13, 12, 0, 0}, {7, 4, 7, 14, 7, 11, 6, 4, 9, 9, 0, 0}, {15, 14, 15, 1, 3, 8, 0, 8, 5, 2, 0, 0}, {0, 9, 12, 3, 11, 14, 9, 6, 10, 10, 0, 0}, {12, 1, 13, 6, 15, 10, 11, 6, 9, 13, 0, 0}, {2, 13, 3, 9, 0, 5, 4, 9, 6, 3, 0, 0}, {13, 12, 10, 6, 2, 14, 4, 11, 14, 15, 0, 0}, {13, 9, 12, 6, 12, 7, 12, 13, 5, 4, 0, 0}, {2, 7, 15, 7, 13, 6, 5, 14, 14, 0, 0, 0}, {3, 10, 7, 4, 0, 12, 1, 10, 12, 14, 0, 0}, {10, 9, 4, 15, 10, 5, 10, 0, 1, 1, 0, 0}, {3, 14, 2, 7, 15, 1, 11, 8, 12, 10, 0, 0}, {14, 15, 11, 10, 7, 9, 13, 2, 13, 6, 0, 0}, {10, 7, 8, 10, 11, 14, 6, 12, 8, 5, 0, 0}, {10, 0, 6, 14, 6, 10, 6, 4, 9, 9, 0, 0}, {5, 15, 4, 13, 5, 9, 5, 3, 8, 8, 0, 0}, {5, 4, 4, 6, 8, 11, 2, 10, 5, 3, 0, 0}, {15, 15, 5, 6, 8, 6, 3, 12, 4, 9, 0, 0}, {1, 1, 11, 10, 8, 10, 13, 4, 12, 7, 0, 0}, {13, 11, 5, 6, 0, 0, 8, 14, 12, 15, 0, 0}, {7, 13, 8, 0, 7, 7, 12, 8, 8, 2, 0, 0}, {10, 12, 2, 4, 10, 10, 4, 14, 2, 15, 0, 0}, {5, 5, 9, 9, 11, 9, 5, 15, 5, 10, 0, 0}, {11, 11, 7, 7, 5, 7, 11, 1, 11, 6, 0, 0}, {5, 15, 3, 12, 5, 9, 5, 3, 8, 8, 0, 0}, {13, 4, 13, 5, 13, 5, 5, 14, 14, 0, 0, 0}, {14, 2, 9, 0, 8, 12, 8, 5, 10, 10, 0, 0}, {6, 5, 10, 12, 15, 4, 13, 5, 3, 1, 0, 0}, {15, 13, 15, 2, 4, 8, 1, 8, 5, 2, 0, 0}, {11, 14, 4, 9, 0, 3, 13, 9, 14, 13, 0, 0}, {15, 14, 15, 0, 3, 8, 15, 8, 4, 1, 0, 0}, {4, 4, 7, 10, 14, 2, 11, 4, 1, 0, 0, 0}, {8, 3, 5, 13, 3, 13, 0, 0, 7, 5, 0, 0}, {0, 4, 13, 5, 12, 5, 4, 13, 14, 0, 0, 0}, {13, 4, 10, 5, 12, 3, 0, 15, 4, 5, 0, 0}, {3, 12, 6, 11, 4, 13, 0, 1, 12, 11, 0, 0}, {5, 5, 14, 10, 3, 12, 1, 5, 5, 3, 0, 0}, {11, 11, 2, 6, 13, 4, 15, 11, 11, 13, 0, 0}, {8, 7, 7, 9, 10, 13, 4, 11, 6, 3,0, 0}, {3, 2, 5, 8, 12, 1, 9, 3, 0, 0, 0, 0}, {10, 6, 8, 0, 5, 15, 2, 1, 8, 6, 0, 0}, {2, 14, 0, 6, 11, 14, 11, 15, 10, 5, 0, 0}, {14, 2, 0, 10, 5, 2, 5, 1, 6, 11, 0, 0}, {11, 7, 11, 4, 11, 6, 11, 12, 4, 3, 0, 0}, {11, 1, 7, 1, 6, 13, 12, 3, 0, 15, 0, 0}, {15, 13, 2, 1, 2, 15, 9, 2, 6, 11, 0, 0}, {9, 11, 0, 2, 9, 10, 4, 14, 2, 0, 0, 0}, {13, 5, 9, 0, 9, 12, 8, 5, 10, 10, 0, 0}, {9, 8, 10, 13, 1, 4, 13, 6, 2, 2, 0, 0}, {2, 3, 7, 8, 10, 8, 4, 14, 4, 10, 0, 0}, {14, 13, 9, 8, 6, 8, 12, 2, 12, 6, 0, 0}, {0, 1, 5, 7, 13, 13, 6, 0, 3, 0, 0, 0}, {0, 5, 3, 8, 0, 5, 8, 5, 0, 13, 0, 0}, {1, 12, 15, 5, 13, 0, 10, 7, 11, 10, 0, 0}, {6, 3, 6, 14, 7, 11, 6, 4, 9, 9, 0, 0}, {13, 12, 0, 0, 1, 14, 8, 1, 5, 10, 0, 0}, {1, 9, 13, 4, 12, 15, 10, 7, 11, 10, 0, 0}, {15, 4, 13, 5, 12, 5, 4, 13, 14, 0, 0, 0}, {9, 12, 7, 0, 8, 1, 1, 11, 12, 14, 0, 0}, {11, 6, 8, 0, 5, 15, 2, 1, 8, 6, 0, 0}, {1, 14, 1, 10, 3, 8, 3, 2, 7, 7, 0, 0}, {13, 3, 12, 4, 12, 4, 4, 13, 14, 15, 0, 0}, {6, 12, 11, 1, 10, 0, 4, 2, 14, 12, 0, 0}, {13, 12, 15, 2, 4, 8, 1, 8, 5, 3, 0, 0}, {2, 5, 11, 14, 5, 7, 1, 12, 0, 14, 0, 0}, {1, 13, 15, 8, 14, 8, 13, 13, 4, 3, 0, 0}, {12, 3, 8, 0, 8, 12, 8, 5, 10, 10, 0, 0}, {1, 13, 9, 6, 14, 9, 12, 6, 8, 11, 0, 0}, {9, 5, 7, 15, 4, 14, 1, 1, 8, 5, 0, 0}, {13, 14, 9, 9, 7, 8, 12, 2, 12, 7, 0, 0}, {15, 12, 15, 1, 4, 8, 1, 8, 5, 3, 0, 0}, and {2, 14, 2, 10, 0, 10, 14, 14, 6, 4, 0, 0}, the third sequence set comprises a sequence in a sequence set 3A and/or a sequence in a sequence set 3B, the sequence set 3A comprises some or all of the following sequences, and M is 4: {3, -3, 1, 1, -1, -3, -3, 3, -3, 1, 3, 3, -3, 3, -1, -3, 3, -1}, {3, 1, -3, -3, -1, 1, 1, 3, 1, -3, 3, 3, 1, 3, -1, 1, 3, -1}, {-1, -1, 3, -1, -1, 3, -1, -1, 3, 3, 3, 3, -1, 3, -1, 3, -1, 3}, {-1, 1, -3, 1, -1, -3, -3, 3, 3, -1, 3, 3, -3, -3, -1, 1, -3, 1}, {-1, -3, 1, -3, -1, 1, 1, 3, 3, -1, 3, 3, 1, 1, -1, -3, 1, -3}, {-3, 1, -3, -1, -1, 1, -3, -1, 3, 3, 3, 3, -1, -3, 3, 1, -3, 3}, {1, -3, 1, -1, -1, -3, 1, -1, 3, 3, 3, 3, -1, 1, 3, -3, 1, 3}, {1, -3, -3, 1, 1, 3, -1, -1, 3, 1, 3, 3, 3, 1, -3, -1, 3, 1}, {-3, 1, 1, -3, -3, 3, -1, -1, 3, -3, 3, 3, 3, -3, 1, -1, 3, -3}, {-3, 1, 3, -3, 1, 3, -1, 3, 1, 1, 3, 3, -3, 1, -1, -3, -3, 3}, {1,-3, 3, 1, -3, 3, -1, 3, -3, -3, 3, 3, 1, -3, -1, 1, 1, 3}, {1, -1, -3, 3, -1, 1, 3, -1, 3, 1, 3, 3, 3, 1, -1, -1, 1, 3}, {-3, -1, 1, 3, -1, -3, 3, -1, 3, -3, 3, 3, 3, -3, -1, -1, -3, 3}, {-1, -3, 3, 3, 1, 3, 3, -3, 1, -1, 3, 3, 1, 3, -1, 1, -3, -3}, {-1, 1, 3, 3, -3, 3, 3, 1, -3, -1, 3, 3, -3, 3, -1, -3, 1, 1}, {1, 3, 3, 3, 1, 3, 3, -3, 1, -1, 3, 3, 1, 3, -1, -1, -3, -3}, {-3, 3, 3, 3, -3, 3, 3, 1, -3, -1, 3, 3, -3, 3, -1, -1, 1, 1}, {3, -1, 1, -3, -1, -1, -1, -3, -1, -1, 3, 3, 1, -3, -1, -3, 3, 1}, {3, -1, -3, 1, -1, -1, -1, 1, -1, -1, 3, 3, -3, 1, -1, 1, 3, -3}, {-1, -3, 3, -1, -1, 3, 3, -1, 3, 3, 3, 3, -1, -3, -1, 3, 3, 3}, {-1, 1, 3, -1, -1, 3, 3, -1, 3, 3, 3, 3, -1, 1, -1, 3, 3, 3}, {-1, -1, 3, 3, -1, -1, 3, -1, -1, 3, 3, 3, 3, -1, 3, -1, 3, -1}, {-1, 3, -3, -1, -3, 1, -1, 3, -1, 1, 3, 3, 3, 1, 1, -1, 1, 3}, {-1, 3, 1, -1, 1, -3, -1, 3, -1, -3, 3, 3, 3, -3, -3, -1, -3, 3}, {1, -3, -1, 1, 3, -1, -1, -3, 3, 1, 3, 3, 3, -3, 1, -3, 1,-3}, {-3, 1, -1, -3, 3, -1, -1, 1, 3, -3, 3, 3, 3, 1, -3, 1, -3, 1}, {3, -3, -1, 1, 3, 3, -3, 3, -1, -3, 3, 3, 1, 3, -1, 1, -3, -1}, {3, 1, -1, -3, 3, 3, 1, 3, -1, 1, 3, 3, -3, 3, -1, -3, 1, -1}, {3, -1, 3, 1, -3, 1, -3, -3, -3, -1, 3, 3, 1, -3, -3, 3, 3, -3}, {3, -1, 3, -3, 1, -3, 1, 1, 1, -1, 3, 3, -3, 1, 1, 3, 3, 1}, {-3, 1, -1, 1, -1, -3, -3, 3, -1, 3, 3, 3, -3, -1, 3, -3, -1, 1}, {1, -3, -1, -3, -1, 1, 1, 3, -1, 3, 3, 3, 1, -1, 3, 1, -1, -3}, {3, 1, -3, -3, 3, 1, 1, -3, 3, -3, 3, 3, -3, 1, 3, -1, -1, 1}, {3, -3, 1, 1, 3, -3, -3, 1, 3, 1, 3, 3, 1, -3, 3, -1, -1, -3}, {3, -1, 1, 3, 1, -1, 1, 1, 1, -1, 3, 3, -3, 1, -1, -1, 3, -3}, {3, -1, -3, 3, -3, -1, -3, -3, -3, -1, 3, 3, 1, -3, -1, -1, 3, 1}, {3, 1, 3, -1, 3, -3, 3, -1, -3, 3, 3, 3, -3, -1, 1, -3, -1, 1}, {3, -3, 3, -1, 3, 1, 3, -1, 1, 3, 3, 3, 1, -1, -3, 1, -1, -3}, {-1, -1, -1, 3, 3, -1, 3, -1, -1, 3, 3, 3, -3, 3, 3, 3, -1, -1}, {-1, -1, -1, 3, 3, -1, 3, -1, -1, 3, 3, 3, 1, 3, 3, 3, -1, -1}, {-1, 1, 3, -3, -1, 1, -3, -3, 3, -1, 3, 3, 3, 3, -3, -3, -1, -3}, {-1, -3, 3, 1, -1, -3, 1, 1, 3, -1, 3, 3, 3, 3, 1, 1, -1, 1}, {1, -1, 3, 1, -3, -1, 1, 1, 3, -1, 3, 3, 1, 1, -1, 1, -1, -3}, {-3, -1, 3, -3, 1, -1, -3, -3, 3, -1, 3, 3, -3, -3, -1, -3, -1, 1}, {1, -3, -1, 1, 3, 3, -3, 3, -3, 1, 3, 3, 1, -1, -3, 3, -3, 1}, {-3, 1, -1, -3, 3, 3, 1, 3, 1, -3, 3, 3, -3, -1, 1, 3, 1, -3}, {3, -1, 1, -3, -1, 3, -3, 3, 1, -3, 3, 3, 3, -3, -1, -1, 1, -3}, {3, -1, -3, 1, -1, 3, 1, 3, -3, 1, 3, 3, 3, 1, -1, -1, -3, 1}, {1, -3, -3, 1, -3, 1, -3, 1, 3, 3, 3, 3, -1, -1, 3, -3, -3, 3}, {-3, 1, 1, -3, 1, -3, 1, -3, 3, 3, 3, 3, -1, -1, 3, 1, 1, 3}, {-1, -1, -1, 3, 3, -1, 3, -3, 3, -1, 3, 3, -1, -1, -1, -1, 3, 3}, {-1, -1, -1, 3, 3, -1, 3, 1, 3, -1, 3, 3, -1, -1, -1, -1, 3, 3}, {1, 3, -1, 1, 3, -1, -3, -3, 1, 1, 3, 3, 1, 3, 1, -3, 1, 3}, {-3, 3, -1, -3, 3, -1, 1, 1, -3, -3, 3, 3, -3, 3, -3, 1, -3, 3}, {1, -3, 1, -1, -1, -1, -1, 1, -1, -1, 3, 3, -3, 1, -1, 1, -3, -3}, {-3, 1, -3, -1, -1, -1, -1, -3, -1, -1, 3, 3, 1, -3, -1, -3, 1, 1}, {-3, 1, -3, 3, -1, -1, 3, -1, -3, -3, 3, 3, -3, -1, -3, -1, 1, 1}, {1,-3, 1, 3, -1, -1, 3, -1, 1, 1, 3, 3, 1, -1, 1, -1, -3, -3}, {3, 1, -1, 1, -3, -1, 3, -1, -3, 3, 3, 3, -3, -3, -1, -3, 3, 3}, {3, -3, -1, -3, 1, -1, 3, -1, 1, 3, 3, 3, 1, 1, -1, 1, 3, 3}, {-3, 3, -1, 3, -1, -1, 1, -1, -1, -1, 3, 3, -1, -3, -1, 1, -3, 3}, {1, 3, -1, 3, -1, -1, -3, -1, -1, -1, 3, 3, -1, 1, -1, -3, 1, 3}, {1, 1, -1, 1, -3, -1, 1, -1, -1, 3, 3, 3, -1, 3, 1, -3, -3, -1}, {-3, -3, -1, -3, 1, -1, -3, -1, -1, 3, 3, 3, -1, 3, -3, 1, 1, -1}, {-3, -1, 3, 1, -1, 3, 3, -1, 3, 3, 3, 3, -1, 1, -1, 3, -1, 3}, {1, -1, 3, -3, -1, 3, 3, -1, 3, 3, 3, 3, -1, -3, -1, 3, -1, 3}, {-1, 1, 3, 3, -3, 3, -1, -1, 1, -3, 3, 3, 1, 3, 3, 3, 1, 3}, {-1, -3, 3, 3, 1, 3, -1, -1, -3, 1, 3, 3, -3, 3, 3, 3, -3, 3}, {3, -1, 3, -1, -3, 1, -3, 3, 1, 1, 3, 3, 3, -1, 1, -3, 1, 3}, {3, -1, 3, -1, 1, -3, 1, 3, -3, -3, 3, 3, 3, -1, -3, 1, -3, 3}, {1, 3, -1, -1, 3, -3, -1, -3, 3, 1, 3, 3, 3, -3, 1, -3, 3, -3}, {-3, 3, -1, -1, 3, 1, -1, 1, 3, -3, 3, 3, 3, 1, -3, 1, 3, 1}, {1, 3, -3, 3, 3, 1, 3, 1, 1, -1, 3, 3, -3, 1, -3, -3, -1, 1}, {-3, 3, 1, 3, 3, -3, 3, -3, -3, -1, 3, 3, 1, -3, 1, 1, -1, -3}, {-1, 3, 3, -1, 3, 3, -1, -1, 3, 3, 3, 3, -1, 3, -1, 3, -1, -1}, {-3, 3, -3, 1, -3, -1, 3, 3, 1, 1, 3, 3, -1, -3, 1, -3, 3, -3}, {1, 3, 1, -3, 1, -1, 3, 3, -3, -3, 3, 3, -1, 1, -3, 1, 3, 1}, {-3, -1, 3, 3, 1, -3, -1, -3, 3, 1, 3, 3, 3, -1, 3, 3, -3, -1}, {1, -1, 3, 3, -3, 1, -1, 1, 3, -3, 3, 3, 3, -1, 3, 3, 1, -1}, {3, 1, -1, 1, -1, -3, 3, 1, 3, -1, 3, 3, -3, -3, -3, 1, 3, 3}, {3, -3, -1, -3, -1, 1, 3, -3, 3, -1, 3, 3, 1, 1, 1, -3, 3, 3}, {-1, 3, 1, -1, -1, 3, -1, -3, -3, 1, 3, 3, -3, 3, -3, -3, -1, -3}, {-1, 3, -3, -1, -1, 3, -1, 1, 1, -3, 3, 3, 1, 3, 1, 1, -1, 1}, {-1, 1, 3, -1, -1, 3, -1, -1, 3, 3, 3, 3, -1, 3, -1, 3, -1, 1}, {-1, -3, 3, -1, -1, 3, -1, -1, 3, 3, 3, 3, -1, 3, -1, 3, -1, -3}, {-1, -3, -1, -3, -1, 1, 1, 3, 3, -1, 3, 3, 1, 1, -1, -3, 1, -3}, and {-1, 1, -1, 1, -1, -3, -3, 3, 3, -1, 3, 3, -3, -3, -1, 1, -3, 1}, and the sequence set 3B comprises some or all of the following sequences, and M is 4: {-3, -3, -3, 1, 1, -3, -3, 1, 1, -3, -3, -3, -3, -3, 1, -3, 1, -3, -3, 1, -3, 1, 1, 1}, {-3, 1, 1, 1, 1, -3, 1, -3, 1, -3, -3, -3, -3, 1, 1, -3, -3, 1, -3, -3, 1, 1, 1, 1}, {1, 1, -3, 1, -3, -3, 1, -3, 1, 1, -3, 1, 1, 1, -3, 1, 1, 1, -3, -3, -3, -3, 1, 1}, {1, -3, -3, -3, 1, 1, -3, -3, 1, 1, -3, -3, -3, -3, -3, 1, -3, 1, -3, -3, 1, -3, 1, 1}, {3, 3, -3, -3, 1, 3, 3, -3, -3, 3, -1, 3, -1, 3, 3, 1, 1, -3, -1, -1, -3, -3, 1, 1}, {-1, -1, -3, -3, 1, -1, -1, -3, -3, -1, 3, -1, 3, -1, -1, 1, 1, -3, 3, 3, -3, -3, 1, 1}, {3, 3, -1, -3, 1, 3, 1, 1, -1, 3, 3, -3, -3, 3, -3, 1, 3, 3, -1, -3, 1, 3, 1, 1}, {-1, -1, 3, -3, 1, -1, 1, 1, 3, -1, -1, -3, -3, -1, -3, 1, -1, -1, 3, -3, 1, -1, 1, 1}, {-1, 1, -1, 1, -3, -3, 1, 1, 3, 1, 3, 1, 1, -3, -3, 1, -1, 1, -1, 1, -3, -3, 1, 1}, {3, 1, 3, 1, -3, -3, 1, 1, -1, 1, -1, 1, 1, -3, -3, 1, 3, 1, 3, 1, -3, -3, 1, 1}, {1,3, 3, -1, 1, -1, 1, 1, 1, 3, -1, 3, 1, -1, -3, -3, 1, 3, 3, -1, 1, -1, 1, 1}, {1,-1,-1,3, 1, 3, 1, 1, 1, -1, 3, -1, 1, 3, -3, -3, 1, -1, -1, 3, 1, 3, 1, 1}, {1, 1, -1, -1, 3, 3, 1, 1, -3, -1, 3, -1, 3, 1, 3, 3, -1, -1, 1, 1, -1, -1, 1, 1}, {1, 1, 3, 3, -1, -1, 1, 1, -3, 3, -1, 3, -1, 1, -1, -1, 3, 3, 1, 1, 3, 3, 1, 1}, {-3, -3, 3, -3, -1, -3, 1, 1, 1, -3, -1, -3, 3, -3, -3, 1, -3, -3, 3, -3, -1, -3, 1, 1}, {-3, -3, -1, -3, 3, -3, 1, 1, 1, -3, 3, -3, -1, -3, -3, 1, -3, -3, -1, -3, 3, -3, 1, 1}, {3, 1, -3, -1, 3, -1, 1, 1, 3, -3, -3, 3, 3, 3, 1, -3, 3, 1, -3, -1, 3, -1, 1, 1}, {-1, 1, -3, 3, -1, 3, 1, 1, -1, -3, -3, -1, -1, -1, 1, -3, -1, 1, -3, 3, -1, 3, 1, 1}, {3, -3, -3, -1, -3, 1, -3, -1, 3, -1, 3, 3, -3, -1, -1, -3, -3, 3, 1, -3, 3, 1, 1, 1}, {-1, -3, -3, 3, -3, 1, -3, 3, -1, 3, -1, -1, -3, 3, 3, -3, -3, -1, 1, -3, -1, 1, 1, 1}, {3, -3, -1, 1, 3, -1, 1, 3, -3, 1, 1, 1, 1, -3, 1, -3, 3, 3, -1, -3, 1, 1, 1, 1}, {-1, -3, 3, 1, -1, 3, 1, -1, -3, 1, 1, 1, 1, -3, 1, -3, -1, -1, 3, -3, 1, 1, 1, 1}, {-1, -1, -3, -3, 3, 3, 3, 3, 1, 3, -3, -3, 3, -1, 1, -3, 3, -1, 3, 3, -1, -3, 1, 1}, {3, 3, -3, -3, -1, -1, -1, -1, 1, -1, -3, -3, -1, 3, 1, -3, -1, 3, -1, -1, 3, -3, 1, 1}, {1, 3, 3, -1, 3, -3, -1, -3, -1, 3, -1, -3, 1, 1, 3, 3, 1, 1, -1, -1, 3, 3, 1, 1}, {1, -1, -1, 3, -1, -3, 3, -3, 3, -1, 3, -3, 1, 1, -1, -1, 1, 1, 3, 3, -1, -1, 1, 1}, {-1, 3, -3, -3, 1, -3, 3, -3, -3, 1, -3, -3, 3, -1, -1, -1, 3, -3, 3, 3, 3, -1, 1, 1}, {3, -1, -3, -3, 1, -3, -1, -3, -3, 1, -3, -3, -1, 3, 3, 3, -1, -3, -1, -1, -1, 3, 1, 1}, {-1, 3, 3, -3, -1, -3, 1, 1, -1, -1, -1, -3, -1, 1, -3, 1, -1, 3, 3, -3, -1, -3, 1, 1}, {3, -1, -1, -3, 3, -3, 1, 1, 3, 3, 3, -3, 3, 1, -3, 1, 3, -1, -1, -3, 3, -3, 1, 1}, {-3, 1, -1, 3, 1, 1, 1, 1, -3, 1, 3, -1, 1, 1, -3, -3, -3, 1, -1, 3, 1, 1, 1, 1}, {-3, 1, 3, -1, 1, 1, 1, 1, -3, 1, -1, 3, 1, 1, -3, -3, -3, 1, 3, -1, 1, 1, 1, 1}, {1, -3, -1, 3, -3, 3, -3, 1, 3, -1, 1, 1, 3, 1, -3, 3, 1, 1, -3, -3, -3, 3, 1, 1}, {1, -3, 3, -1, -3, -1, -3, 1, -1, 3, 1, 1, -1, 1, -3, -1, 1, 1, -3, -3, -3, -1, 1, 1}, {-3, 1, -1, 3, -3, -3, 1, 1, -3, 1, 3, -1, -3, -3, -3, -3, -3, 1, -1, 3, -3, -3, 1, 1}, {-3, 1, 3, -1, -3, -3, 1, 1, -3, 1, -1, 3, -3, -3, -3, -3, -3, 1, 3, -1, -3, -3, 1, 1}, {1, 3, -3, 1, -3, -1, 3, -3, 1, 1, 3, 3, 1, -3, 3, -1, 1, -1, -3, -3, -3, 1, 1, 1}, {1, -1, -3, 1, -3, 3, -1, -3, 1, 1, -1, -1, 1, -3, -1, 3, 1, 3, -3, -3, -3, 1, 1, 1}, {-1, 1, -1, -1, 3, -1, 3, -3, -3, -1, -3, 1, 1, -3, 1, 1, 1, -1, -1, 3, 3, -1, 1, 1}, {3, 1, 3, 3, -1, 3, -1, -3, -3, 3, -3, 1, 1, -3, 1, 1, 1, 3, 3, -1, -1, 3, 1, 1}, {1, -1, -3, -1, 3, -1, 3, 1, -1, 1, -3, 1, 1, -1, 1, 1, 3, -3, -1, -3, -3, -3, 1, 1}, {1, 3, -3, 3, -1, 3, -1, 1, 3, 1, -3, 1, 1, 3, 1, 1, -1, -3, 3, -3, -3, -3, 1, 1}, {-3, -1, -1, 3, -3, 1, 1, 3, -3, 1, 1, 1, 3, 3, 1, -3, 1, -1, -3, -3, 3, 3, 1, 1}, {-3, 3, 3, -1, -3, 1, 1, -1, -3, 1, 1, 1, -1, -1, 1, -3, 1, 3, -3, -3, -1, -1, 1, 1}, {3, -1, -3, -3, 1, 1, -1, 3, -3, 1, -3, -3, -3, 3, -3, 3, 1, -3, -3, -1, -3, 1, 1, 1}, {-1, 3, -3, -3, 1, 1, 3, -1, -3, 1, -3, -3, -3, -1, -3, -1, 1, -3, -3, 3, -3, 1, 1, 1}, {-3, -1, 3, 3, 1, 1, -1, 3, -3, 1, -3, -3, -3, 3, -3, -3, 1, -1, 3, 3, -3, -3, 1, 1}, {-3, 3, -1, -1, 1, 1, 3, -1, -3, 1, -3, -3, -3, -1, -3, -3, 1, 3, -1, -1, -3, -3, 1, 1}, {1, -3, 1, 1, -3, 1, 1, 3, 1, -1, 1, -3, -3, -3, 1, -1, 1, 3, 1, 1, -3, 1, 1, 1}, {1, -3, 1, 1, -3, 1, 1, -1, 1, 3, 1, -3, -3, -3, 1, 3, 1, -1, 1, 1, -3, 1, 1, 1}, {1, -3, -3, -3, 1, 1, -3, -3, -3, 1, -3, -3, -3, -3, 1, -3, 1, 1, -3, -3, 1, -3, 1, 1}, {-1, -1, -1, -3, -1, -3, 3, -3, 3, 3, 3, -1, -3, 1, 3, -3, 3, -3, -1, -1, -3, -3, 1, 1}, {3, 3, 3, -3, 3, -3, -1, -3, -1, -1, -1, 3, -3, 1, -1, -3, -1, -3, 3, 3, -3, -3, 1, 1}, {-3, -3, -3, 1, -3, 1, 1, -3, 1, -3, 1, 1, 1, 1, 1, -3, -3, 1, 1, -3, -3, 1, 1, 1}, {-1, -3, -3, 3, -1, -1, 1, 1, -1, 1, -3, -1, -1, 3, 1, -3, -1, -3, -3, 3, -1, -1, 1, 1}, {3, -3, -3, -1, 3, 3, 1, 1, 3, 1, -3, 3, 3, -1, 1, -3, 3, -3, -3, -1, 3, 3, 1, 1}, {-1, 3, -3, 3, 3, 1, 1, 1, 1, -1, -3, 1, -1, 1, 1, 3, -3, 1, 3, -1, -3, -3, 1, 1}, {3, -1, -3, -1, -1, 1, 1, 1, 1, 3, -3, 1, 3, 1, 1, -1, -3, 1, -1, 3, -3, -3, 1, 1}, {1, 1, -3, 1, -3, -3, -3, -3, 1, -3, 1, 1, 1, -3, 1, 1, 1, 1, -3, -3, 1, 1, 1, 1}, {-1, 3, 3, -3, 3, 3, -3, -1, 3, -1, -1, 3, -1, -3, -1, 3, 3, 3, -1, -1, -1, 3, 1, 1}, {3, -1, -1, -3, -1, -1, -3, 3, -1, 3, 3, -1, 3, -3, 3, -1, -1, -1, 3, 3, 3, -1, 1, 1}, {3, -1, 1, -3, -1, -1, 1, -3, -1, 1, -1, -3, 1, -1, 1, -3, -3, -3, -3, 1, 1, 1, 1, 1}, {-1, 3, 1, -3, 3, 3, 1, -3, 3, 1, 3, -3, 1, 3, 1, -3, -3, -3, -3, 1, 1, 1, 1, 1}, {1, -1, 1, -3, -3, 1, -3, 1, -3, 1, -3, -3, 1, 1, -3, -3, -3, -3, -3, -3, -3, -1, 1, 1}, {1, 3, 1, -3, -3, 1, -3, 1, -3, 1, -3, -3, 1, 1, -3, -3, -3, -3, -3, -3, -3, 3, 1, 1}, {-1, -1, 1, 1, 1, -3, 3, 3, -1, -1, -1, 1, -3, -1, 1, -1, -3, 1, -3, 3, 1, 3, 1, 1}, {3, 3, 1, 1, 1, -3, -1, -1, 3, 3, 3, 1, -3, 3, 1, 3, -3, 1, -3, -1, 1, -1, 1, 1}, {1, -3, 1, 3, -1, -1, 3, 3, 3, -1, 1, 1, -3, 3, 3, -3, 3, -3, 3, -1, 1, -3, 1, 1}, {1, -3, 1, -1, 3, 3, -1, -1, -1, 3, 1, 1, -3, -1, -1, -3, -1, -3, -1, 3, 1, -3, 1, 1}, {3, -1, -1, -1, 1, -1, -1, -3, -1, 3, 3, 1, -3, -3, -1, 3, -1, -3, 1, 3, -3, -3, 1, 1}, {-1, 3, 3, 3, 1, 3, 3, -3, 3, -1, -1, 1, -3, -3, 3, -1, 3, -3, 1, -1, -3, -3, 1, 1}, {1, 3, -3, -3, 3, -3, -3, -3, 1, -3, -3, 3, -1, 3, 3, -3, 1, -1, -1, -1, 3, 3, 1, 1}, {1, -1, -3, -3, -1, -3, -3, -3, 1, -3, -3, -1, 3, -1, -1, -3, 1, 3, 3, 3, -1, -1, 1, 1}, {-3, 1, -3, -3, 3, -3, 3, -1, -1, -1, -1, -3, 1, 3, -1, -3, 3, -1, 1, 3, 3, -1, 1, 1}, {-3, 1, -3, -3, -1, -3, -1, 3, 3, 3, 3, -3, 1, -1, 3, -3, -1, 3, 1, -1, -1, 3, 1, 1}, {3, 1, 3, -1, 3, -3, -1, -1, -1, 1, 3, -3, 3, 1, 3, 1, -1, 3, 3, 1, 1, 3, 1, 1}, {-1, 1, -1, 3, -1, -3, 3, 3, 3, 1, -1, -3, -1, 1,-1, 1, 3, -1, -1, 1, 1, -1, 1, 1}, {1, 1, -1, -1, 3, 3, -1, 1, 3, -3, 3, 1, 1, 3, 1, -3, -1, -3, 1, -1, 1, 1, 1, 1}, {1, 1, 3, 3, -1, -1, 3, 1, -1, -3, -1, 1, 1, -1, 1, -3, 3, -3, 1, 3, 1, 1, 1, 1}, {1, -3, 1, -3, 1, 1, -3, 1, 1, 1, -3, 1, 1, 1, 1, -3, -3, -3, -3, 1, 1, -3, 1, 1}, {-1, 3, 1, -1, 1, 3, 1, 1, -1, 3, 1, -3, -1, 3, 3, 3, 3, -1, -3, -1, 1, 3, 1, 1}, {3, -1, 1, 3, 1, -1, 1, 1, 3, -1, 1, -3, 3, -1, -1, -1, -1, 3, -3, 3, 1, -1, 1, 1}, {-3, -1, -3, 1, -3, 3, -1, 1, 3, -1, 1, 1, 1, 3, 3, 1, -1, -1, -3, 1, -3, 3, 1, 1}, {-3, 3, -3, 1, -3, -1, 3, 1, -1, 3, 1, 1, 1, -1, -1, 1, 3, 3, -3, 1, -3, -1, 1, 1}, {1, -3, -3, 1, -1, -1, 1, 1, -3, 1, -3, 1, 3, 3, 1, 1, 1, -3, -3, 1, -1, -1, 1, 1}, {1, -3, -3, 1, 3, 3, 1, 1, -3, 1, -3, 1, -1, -1, 1, 1, 1, -3, -3, 1, 3, 3, 1, 1}, {3, -1, -1, -3, -3, -3, 1, 1, 3, -1, 1, 3, -1, -3, -1, -1, -1, 3, 1, -1, -1, -1, 1, 1}, {-1, 3, 3, -3, -3, -3, 1, 1, -1, 3, 1, -1, 3, -3, 3, 3, 3, -1, 1, 3, 3, 3, 1, 1}, {-1, 1, -3, 1, -1, -3, 1, -3, -3, 1, -1, -1, -3, -3, -1, -1, 1, -3, 1, 3, 3, -3, 1, 1}, {3, 1, -3, 1, 3, -3, 1, -3, -3, 1, 3, 3, -3, -3, 3, 3, 1, -3, 1, -1, -1, -3, 1, 1}, {3, 3, 1, -3, -1, -3, 1, -1, 1, -1, 3, -3, -3, 1, 1, -3, 1, 1, -1, 1, 1, 1, 1, 1}, {-1, -1, 1, -3, 3, -3, 1, 3, 1, 3, -1, -3, -3, 1, 1, -3, 1, 1, 3, 1, 1, 1, 1, 1}, {-1, 1, 3, 1, 3, -3, -1, 3, -1, -1, -1, 1, 3, -1, -3, 1, -1, -1, -3, -3, -3, 3, 1, 1}, {3, 1, -1, 1, -1, -3, 3, -1, 3, 3, 3, 1, -1, 3, -3, 1, 3, 3, -3, -3, -3, -1, 1, 1}, {1, -1, -3, -3, 1, -1, 3, 3, 1, -1, -3, -1, -3, 1, 3, -3, 1, 3, 3, 3, 3, -3, 1, 1}, {1, 3, -3, -3, 1, 3, -1, -1, 1, 3, -3, 3, -3, 1, -1, -3, 1, -1, -1, -1, -1, -3, 1, 1}, {3, -1, -3, -3, -3, 3, -3, 3, 3, 3, 1, -3, 1, -3, -3, 3, -1, -1, 1, 3, -3, -1, 1, 1}, {-1, 3, -3, -3, -3, -1, -3, -1, -1, -1, 1, -3, 1, -3, -3, -1, 3, 3, 1, -1, -3, 3, 1, 1}, {3, -3, -3, 1, -3, 1, 1, -3, 1, -1, 3, -3, -3, -3, 3, -1, -1, -3, 3, 3, -3, -1, 1, 1}, {-1, -3, -3, 1, -3, 1, 1, -3, 1, 3, -1, -3, -3, -3, -1, 3, 3, -3, -1, -1, -3, 3, 1, 1}, {1, 3, 3, 1, -3, 3, 1, 3, 3, 3, -3, -3, 1, 3, 1, -1, -1, 3, -3, 1, -3, 3, 1, 1}, {1, -1, -1, 1, -3, -1, 1, -1, -1, -1, -3, -3, 1, -1, 1, 3, 3, -1, -3, 1, -3, -1, 1, 1}, {-3, -3, -1, 3, -3, -1, -1, 3, -3, -1, 3, 1, -1, -3, -1, 3, 1, 3, 3, 3, 1, 1, 1, 1}, {-3, -3, 3, -1, -3, 3, 3, -1, -3, 3, -1, 1, 3, -3, 3, -1, 1, -1, -1, -1, 1, 1, 1, 1}, {3, 3, 3, -1, 1, 3, 3, 3, 3, 1, -3, -1, -3, 1, -3, -3, 1, 3, 3, 1, -3, -3, 1, 1}, {-1, -1, -1, 3, 1, -1, -1, -1, -1, 1, -3, 3, -3, 1, -3, -3, 1, -1, -1, 1, -3, -3, 1, 1}, {-3, -3, -1, 3, -3, -1, 1, -3, -1, 3, -1, -3, 1, 1, 3, 3, 3, 1, 1, -1, -3, 3, 1, 1}, {-3, -3, 3, -1, -3, 3, 1, -3, 3, -1, 3, -3, 1, 1, -1, -1, -1, 1, 1, 3, -3, -1, 1, 1}, {3, 1, 1, 1, -1, 1, 1, -1, -3, 1, 1, 3, -1, 1, -1, 3, 3, 3, -3, -1, -3, -1, 1, 1}, {-1, 1, 1, 1, 3, 1, 1, 3, -3, 1, 1, -1, 3, 1, 3, -1, -1, -1, -3, 3, -3, 3, 1, 1}, {1, 1, 1, -1, -1, 1, -1, -3, -3, 1, -3, 3, -1, 1, -3, -3, 3, -3, -1, -1, -1, 1, 1, 1}, {1, 1, 1, 3, 3, 1, 3, -3, -3, 1, -3, -1, 3, 1, -3, -3, -1, -3, 3, 3, 3, 1, 1, 1}, {1, 1, 3, 1, 1, -1, 1, -1, 1, -1, 3, -1, 1, 3, -3, 3, 1, -1, -3, -3, -3, -3, 1, 1}, {1, 1, -1, 1, 1, 3, 1, 3, 1, 3, -1, 3, 1, -1, -3, -1, 1, 3, -3, -3, -3, -3, 1, 1}, {1, 3, -3, -3, 3, -3, -1, 3, 3, 1, 3, -3, 3, -1, 1, -1, -3, -1, -1, 3, 1, -1, 1, 1}, {1, -1, -3, -3, -1, -3, 3, -1, -1, 1, -1, -3, -1, 3, 1, 3, -3, 3, 3, -1, 1, 3, 1, 1}, {-1, -1, 3, -1, -1, -3, 1, 3, -3, -1, 3, 1, -3, 1, 1, 1, 1, 1, -3, -3, 3, 1, 1, 1}, {3, 3, -1, 3, 3, -3, 1, -1, -3, 3, -1, 1, -3, 1, 1, 1, 1, 1, -3, -3, -1, 1, 1, 1}, {3, -3, -1, 1, -1, 3, 1, 1, 3, 1, 3, 1, -1, -1, -3, 1, 3, -3, -1, 1, -1, 3, 1, 1}, {-1, -3, 3, 1, 3, -1, 1, 1, -1, 1, -1, 1, 3, 3, -3, 1, -1, -3, 3, 1, 3, -1, 1, 1}, {3, -1, 3, -1, -3, 1, -3, -3, -1, 1, -1, 1, 3, -1, -3, 3, 3, 3, 1, 1, 3, 3, 1, 1}, {-1, 3, -1, 3, -3, 1, -3, -3, 3, 1, 3, 1, -1, 3, -3, -1, -1, -1, 1, 1, -1, -1, 1, 1}, {-3, 3, -1, 3, 3, -1, -3, 3, -1, 1, 3, 1, 1, -1, 3, -3, 3, 1, 3, 3, -3, 1, 1, 1}, {-3, -1, 3, -1, -1, 3, -3, -1, 3, 1, -1, 1, 1, 3, -1, -3, -1, 1, -1, -1, -3, 1, 1, 1}, {3, -1, 3, -1, -3, 1, -1, -3, 1, -3, -1, 3, -3, -3, -1, -1, -1, -3, 3, 3, 1, 1, 1, 1}, {-1, 3, -1, 3, -3, 1, 3, -3, 1, -3, 3, -1, -3, -3, 3, 3, 3, -3, -1, -1, 1, 1, 1, 1}, {-1, -3, -1, 3, -1, -1, 3, 1, 3, -1, 3, 1, -1, 1, 3, -3, 3, 1, 1, 1, -1, -1, 1, 1}, {3, -3, 3, -1, 3, 3, -1, 1, -1, 3, -1, 1, 3, 1, -1, -3, -1, 1, 1, 1, 3, 3, 1, 1}, {1, -1, -3, 3, 3, -3, 3, -3, 3, 3, 1, -3, -3, -1, -3, 1, 3, 3, -1, 1, 3, -3, 1, 1}, {1, 3, -3, -1, -1, -3, -1, -3, -1, -1, 1, -3, -3, 3, -3, 1, -1, -1, 3, 1, -1, -3, 1, 1}, {1, -3, 1, 3, -3, -1, 1, 1, 1, 1, 1, -1, -3, 3, 1, -3, 1, -3, 1, 3, -3, -1, 1, 1}, {1, -3, 1, -1, -3, 3, 1, 1, 1, 1, 1, 3, -3, -1, 1, -3, 1, -3, 1, -1, -3, 3, 1, 1}, {1, 3, -1, -3, -1, 1, 3, -1, 3, -1, 3, -3, -3, 1, 1, -1, 1, 1, -1, -1, 1, 1, 1, 1}, {1, -1, 3, -3, 3, 1, -1, 3, -1, 3, -1, -3, -3, 1, 1, 3, 1, 1, 3, 3, 1, 1, 1, 1}, {1, 3, -3, -1, -1, 3, 1, 1, -3, 3, -3, 3, 3, 3, 1, -3, 1, 3, -3, -1, -1, 3, 1, 1}, {1, -1, -3, 3, 3, -1, 1, 1, -3, -1, -3, -1, -1, -1, 1, -3, 1, -1, -3, 3, 3, -1, 1, 1}, {3, -1, -3, 1, -1, -3, 1, 3, -1, 1, 3, 3, -3, 3, -1, -3, -3, 3, 3, 3, 3, -3, 1, 1}, {-1, 3, -3, 1, 3, -3, 1, -1, 3, 1, -1, -1, -3, -1, 3, -3, -3, -1, -1, -1, -1, -3, 1, 1}, {-3, -3, 1, 3, 1, -1, 1, -3, -3, -3, 1, -1, 1, 3, 1, 1, -3, 1, 1, 3, 1, -1, 1, 1}, {-3, -3, 1, -1, 1, 3, 1, -3, -3, -3, 1, 3, 1, -1, 1, 1, -3, 1, 1, -1, 1, 3, 1, 1}, {-1, 1, 3, 3, 1, -3, 3, -3, 3, -1, -1, 1, 3, 1, 1, -1, 1, -1, -1, 3, 3, -3, 1, 1}, {3, 1, -1, -1, 1, -3, -1, -3, -1, 3, 3, 1, -1, 1, 1, 3, 1, 3, 3, -1, -1, -3, 1, 1}, {-3, 1, 1, 3, 3, 1, -3, -3, 1, 3, -1, 3, 3, 3, -3, -1, -3, 3, -3, 3, 1, 1, 1, 1}, {-3, 1, 1, -1, -1, 1, -3, -3, 1, -1, 3, -1, -1, -1, -3, 3, -3, -1, -3, -1, 1, 1, 1, 1}, {1, 3, 3, -1, 1, -1, -3, 3, 1, 3, -1, -3, 1, 3, -3, 3, 3, -3, 3, -3, -1, -1, 1, 1}, {1, -1, -1, 3, 1, 3, -3, -1, 1, -1, 3, -3, 1, -1, -3, -1, -1, -3, -1, -3, 3, 3, 1, 1}, {-3, -3, -3, -3, 1, 1, -1, 1, -3, 1, 3, 1, -1, -3, -1, -1, 1, -3, -3, 1, 1, -3, 1, 1}, {-3, -3, -3, -3, 1, 1, 3, 1, -3, 1, -1, 1, 3, -3, 3, 3, 1, -3, -3, 1, 1, -3, 1, 1}, {-1, 3, 1, 1, -1, 3, 3, 1, 3, -3, -3, -1, 1, -3, 1, -1, -3, -1, -3, -3, 3, 3, 1, 1}, {3, -1, 1, 1, 3, -1, -1, 1, -1, -3, -3, 3, 1, -3, 1, 3, -3, 3, -3, -3, -1, -1, 1, 1}, {3, -3, -1, 3, 3, 3, -1, -1, -3, 1, 3, 1, -3, -1, -1, -3, -1, -1, -3, 1, 1, -3, 1, 1}, {-1, -3, 3, -1, -1, -1, 3, 3, -3, 1, -1, 1, -3, 3, 3, -3, 3, 3, -3, 1, 1, -3, 1, 1}, {-1, 1, 1, -1, -3, -3, 1, 1, 3, 1, 1, 3, 1, -3, 1, -3, -1, 1, 1, -1, -3, -3, 1, 1}, {3, 1, 1, 3, -3, -3, 1, 1, -1, 1, 1, -1, 1, -3, 1, -3, 3, 1, 1, 3, -3, -3, 1, 1}, {3, 1, -3, 3, 1, 1, -3, -3, -1, 1, -1, -3, 1, 3, -1, 1, -1, -1, -3, -1, -1, 1, 1, 1}, {-1, 1, -3, -1, 1, 1, -3, -3, 3, 1, 3, -3, 1, -1, 3, 1, 3, 3, -3, 3, 3, 1, 1, 1}, {1, -3, -3, 1, 3, 3, 1, 3, 1, 1, -3, 1, 1, -3, -3, -3, 1, -1, 1, -1, -3, -1, 1, 1}, {1, -3, -3, 1, -1, -1, 1, -1, 1, 1, -3, 1, 1, -3, -3, -3, 1, 3, 1, 3, -3, 3, 1, 1}, {3, -3, -1, 3, -1, -3, 1, 1, 3, -3, 3, -1, -1, -3, -3, -3, 3, -3, -1, 3, -1, -3, 1, 1}, {-1, -3, 3, -1, 3, -3, 1, 1, -1, -3, -1, 3, 3, -3, -3, -3, -1, -3, 3, -1, 3, -3, 1, 1}, {-3, 1, -3, -1, -1, 3, -1, -1, -1, -3, -1, -1, 1, -3, 3, 3, -1, 3, -1, -1, -3, 3, 1, 1}, {-3, 1, -3, 3, 3, -1, 3, 3, 3, -3, 3, 3, 1, -3, -1, -1, 3, -1, 3, 3, -3, -1, 1, 1}, {-3, 3, -3, -1, 3, -1, 3, 1, 1, -3, 1, -3, -3, -1, 1, -1, -3, -1, -1, -1, -3, 3, 1, 1}, {-3, -1, -3, 3, -1, 3, -1, 1, 1, -3, 1, -3, -3, 3, 1, 3, -3, 3, 3, 3, -3, -1, 1, 1}, {-1, -3, -3, -1, -1, 3, 1, 1, -1, 1, -3, 3, -1, -1, 1, -3, -1, -3, -3, -1, -1, 3, 1, 1}, {3, -3, -3, 3, 3, -1, 1, 1, 3, 1, -3, -1, 3, 3, 1, -3, 3, -3, -3, 3, 3, -1, 1, 1}, {3, -1, -1, -3, -3, -3, 1, 3, -1, 1, -3, -3, -3, -1, -1, -3, 3, -1, -3, 1, 3, 3, 1, 1}, {-1, 3, 3, -3, -3, -3, 1, -1, 3, 1, -3, -3, -3, 3, 3, -3, -1, 3, -3, 1, -1, -1, 1, 1}, {3, -1, -1, 1, 1, 3, 1, 1, -1, -1, 3, 1, -3, 3, -3, 1, 3, -1, -1, 1, 1, 3, 1, 1}, {-1, 3, 3, 1, 1, -1, 1, 1, 3, 3, -1, 1, -3, -1, -3, 1, -1, 3, 3, 1, 1, -1, 1, 1}, {1, 3, 1, 1, 3, -1, 3, 3, 1, -3, 1, -3, -1, -1, -3, -3, 1, 1, 3, 3, -3, -1, 1, 1}, and {1, -1, 1, 1, -1, 3, -1, -1, 1, -3, 1, -3, 3, 3, -3, -3, 1, 1, -1, -1, -3, 3, 1, 1}; and a sending unit, configured to send a signal generated based on the sequence { f n }, wherein the sequence { f n } is mapped to N subcarriers.', '22. A signal processing apparatus, wherein the apparatus comprises a processor and a storage medium, the storage medium stores an instruction, and when the instruction is run by the processor, the processor is enabled to perform the signal processing method according to any one of claims 1 to 6 and 13 to']",True,"['801', '802', '800', '8', '901', '902', '903', '900', '9', '1001', '1002', '1000', '10', '53']" 862,EP_3605996_A1 (4).png,EP3605996A1,"AUTHENTICATION METHOD, DEVICE, VR TERMINAL AND VR SERVER BASED ON VR SCENE",['FIG5'],"['FIG5 is a structural hardware diagram illustrating a VR terminal that a VR scenario-based authentication apparatus is mounted on, according to an implementation of the present specification']","['The implementation of the VR scenario-based authentication apparatus in the present specification can be applied to a VR terminal. The apparatus implementation can be implemented by using software, hardware, or a combination of hardware and software. Software implementation is used as an example. As a logical apparatus, the software is formed by reading a corresponding computer program instruction from a nonvolatile storage to a memory for running by a processor in a VR terminal that the software belongs to. In terms of hardware, FIG5 is a structural hardware diagram illustrating a VR terminal that a VR scenario-based authentication apparatus belongs to, according to an implementation of the present specification. In addition to a processor, a memory, a network interface, and a nonvolatile storage shown in FIG5, the VR terminal that the apparatus belongs to in this implementation can usually further include other hardware based on an actual function of the VR terminal. Details are omitted.']",30,175,structural diagram,H,"[{'element_identifier': '601', 'terms': ['calculation module']}, {'element_identifier': '60', 'terms': ['reality scenario-based authentication apparatus']}, {'element_identifier': '602', 'terms': ['first acquisition module']}, {'element_identifier': '603', 'terms': ['sending module']}]","['13. A virtual reality scenario-based authentication apparatus, wherein the apparatus comprises: a calculation module, configured to calculate interactive environment authentication information based on random information delivered by a virtual reality server; a first acquisition module, configured to obtain password information entered by a user in a virtual reality scenario; and a sending module, configured to send the password information and the interactive environment authentication information to the virtual reality server, so that the virtual reality server obtains random information through reverse calculation based on the interactive environment authentication information after the password information is verified, and matches the random information obtained through reverse calculation against the random information delivered to a virtual reality client, to perform security authentication on an interactive environment of the virtual reality scenario.']",True,"['5', '60', '601', '602', '6', '603', '23']" 863,EP_3605996_A1 (5).png,EP3605996A1,"AUTHENTICATION METHOD, DEVICE, VR TERMINAL AND VR SERVER BASED ON VR SCENE",['FIG7'],"['FIG7 is a structural hardware diagram illustrating a VR server that another VR scenario-based authentication apparatus is mounted on, according to an implementation of the present specification']","['The implementation of the VR scenario-based authentication apparatus in the present specification can be applied to a VR server. The apparatus implementation can be implemented by using software, hardware, or a combination of hardware and software. Software implementation is used as an example. As a logical apparatus, the software is formed by reading a corresponding computer program instruction from a nonvolatile storage to a memory for running by a processor in a VR server that the software belongs to. In terms of hardware, FIG7 is a structural hardware diagram illustrating a VR terminal that a VR scenario-based authentication apparatus belongs to, according to an implementation of the present specification. In addition to a processor, a memory, a network interface, and a nonvolatile storage shown in FIG7, the VR terminal that the apparatus belongs to in this implementation can usually further include other hardware based on an actual function of the VR terminal. Details are omitted.']",30,175,structural diagram,H,"[{'element_identifier': '802', 'terms': ['verification module']}, {'element_identifier': '801', 'terms': []}, {'element_identifier': '80', 'terms': ['reality scenario-based authentication apparatus']}, {'element_identifier': '803', 'terms': ['determining module']}]","['13. A virtual reality scenario-based authentication apparatus, wherein the apparatus comprises: a calculation module, configured to calculate interactive environment authentication information based on random information delivered by a virtual reality server; a first acquisition module, configured to obtain password information entered by a user in a virtual reality scenario; and a sending module, configured to send the password information and the interactive environment authentication information to the virtual reality server, so that the virtual reality server obtains random information through reverse calculation based on the interactive environment authentication information after the password information is verified, and matches the random information obtained through reverse calculation against the random information delivered to a virtual reality client, to perform security authentication on an interactive environment of the virtual reality scenario.', '17. A virtual reality scenario-based authentication apparatus, applied to a virtual reality server, wherein the apparatus comprises: a second acquisition module, configured to obtain interactive environment authentication information and password information entered by a user in a virtual reality scenario that are sent by a virtual reality terminal, wherein the interactive environment authentication information is generated through calculation based on random information delivered to the virtual reality terminal; a verification module, configured to verify the password information; and if the password information is verified, obtain random information through reverse calculation based on the interactive environment authentication information, and verify whether the random information obtained through reverse calculation matches the random information delivered by the virtual reality server; and a determining module, configured to determine that security authentication on an interactive environment of the virtual reality scenario succeeds if the random information obtained through reverse calculation matches the random information delivered to the virtual reality terminal.']",True,"['80', '801', '802', '00', '803', '24']" 864,EP_3606013_A1 (1).png,EP3606013A1,INTEROPERABILITY OF DISCOVERY AND CONNECTION PROTOCOLS BETWEEN CLIENT DEVICES AND FIRST SCREEN DEVICES,['FIG2'],['FIG2 is an interaction diagram of a method for discovering and deduplication of a first screen device according to an embodiment'],"['FIG2 is an interaction diagram showing the discovery process in more detail, specifically, FIG2 is an interaction diagram of one embodiment of a method for discovering and deduplication of a first screen device. In various embodiments, the method may include different and/or additional steps than those described in conjunction with FIG2. Additionally, in some embodiments, the steps may be performed in a different order than described in conjunction with FIG2.', 'A second screen application 160 on a second screen device 105 presents 305 discovered devices that are local to the second screen device 105. For example, the second screen application 160 may present a session interface that shows a single device entry for each discovered device. The listing of device entries may be generated using the process described above with reference to FIG2. The second screen application 160 receives 310 a selection of a device entry that is associated with a first screen application 140. For example, the user may select a device entry for a first screen device 120, and the first screen application 140 is an application operating on the first screen device 120.']",21,203,diagram,G,"[{'element_identifier': '235', 'terms': ['retrieves']}, {'element_identifier': '210', 'terms': ['makes']}, {'element_identifier': '230', 'terms': ['requests']}, {'element_identifier': '245', 'terms': ['updates']}, {'element_identifier': '130', 'terms': ['control server', 'control servers']}, {'element_identifier': '215', 'terms': ['sends']}, {'element_identifier': '220', 'terms': ['provides']}, {'element_identifier': '250', 'terms': ['performs']}, {'element_identifier': '240', 'terms': ['provides']}, {'element_identifier': '255', 'terms': ['presents']}, {'element_identifier': '140', 'terms': ['first screen application', 'first screen applications']}, {'element_identifier': '205', 'terms': ['generates']}, {'element_identifier': '150', 'terms': ['screen application', 'screen applications']}]","['1. A computer-implemented method for facilitating interoperability between a first screen device and a second screen device, the method comprising: discovering, by the second screen device, a first screen application operating on the first screen device and a plurality of coupling protocols available to connect to the first screen device; providing, by the second screen device, a device list based on the discovering, the device list including a plurality of entries each associated with the first screen application and a respective coupling protocol of the plurality of coupling protocols; obtaining, by the second screen device, pairing information for the first screen application from a control server; updating, by the second screen device, the device list using the pairing information from the control server; performing, by the second screen device, device deduplication using the updated device list to generate a deduplicated entry for the first screen application; and presenting, by the second screen device, the deduplicated entry for the first screen application in a user interface.']",False,"['150', '140', '205', '210', '130', '215', '220', '225', '230', '235', '240', '245', '250', '255', '2', '17']" 865,EP_3606013_A1 (2).png,EP3606013A1,INTEROPERABILITY OF DISCOVERY AND CONNECTION PROTOCOLS BETWEEN CLIENT DEVICES AND FIRST SCREEN DEVICES,['FIG3'],['FIG3 is an interaction diagram of a method for establishing a session between a first screen application and one or more second screen applications according to an embodiment'],"['Turning now to a discussion of establishing sessions between devices, FIG3 is an interaction diagram of one embodiment of a method for establishing a session between a first screen application and one or more second screen applications. In various embodiments, the method may include different and/or additional steps than those described in conjunction with FIG3. Additionally, in some embodiments, the steps may be performed in a different order than described in conjunction with FIG3.', 'In some instances (not shown in FIG3) there are no existing sessions between the first screen application 140 and another client device and the coupling protocols available to the client device 105 are different from the coupling protocols available to the first screen device 120. Accordingly, the client device 105 is not able to directly couple to and establish a session with the first screen application 140. In some embodiments, the client device 105 couples to the first screen application 140 indirectly through the control server 130. For example, the client device 105 communicates with the control server 130 using a coupling protocol available to the client device 105 and the control server 130, the control server 130 translates the information received from the client device 105 into a format compatible with a coupling protocol that is supported by the first screen device, and communicates with the first screen application using the coupling protocol.']",28,247,diagram,G,"[{'element_identifier': '310', 'terms': ['receives']}, {'element_identifier': '325', 'terms': ['determines']}, {'element_identifier': '160', 'terms': ['second screen application']}, {'element_identifier': '335', 'terms': ['provides']}, {'element_identifier': '130', 'terms': ['control server', 'control servers']}, {'element_identifier': '350', 'terms': ['coupling module']}, {'element_identifier': '345', 'terms': ['existing session']}, {'element_identifier': '360', 'terms': ['coupling']}, {'element_identifier': '355', 'terms': ['couples', 'couple']}, {'element_identifier': '315', 'terms': ['requests']}, {'element_identifier': '320', 'terms': ['provides']}, {'element_identifier': '330', 'terms': ['establishes']}, {'element_identifier': '340', 'terms': ['then updates']}, {'element_identifier': '140', 'terms': ['first screen application', 'first screen applications']}, {'element_identifier': '150', 'terms': ['screen application', 'screen applications']}, {'element_identifier': '305', 'terms': ['presents']}]","['1. A computer-implemented method for facilitating interoperability between a first screen device and a second screen device, the method comprising: discovering, by the second screen device, a first screen application operating on the first screen device and a plurality of coupling protocols available to connect to the first screen device; providing, by the second screen device, a device list based on the discovering, the device list including a plurality of entries each associated with the first screen application and a respective coupling protocol of the plurality of coupling protocols; obtaining, by the second screen device, pairing information for the first screen application from a control server; updating, by the second screen device, the device list using the pairing information from the control server; performing, by the second screen device, device deduplication using the updated device list to generate a deduplicated entry for the first screen application; and presenting, by the second screen device, the deduplicated entry for the first screen application in a user interface.', '7. The method of claim 1, further comprising: receiving a user selection of the deduplicated entry for the first screen application; requesting application status information associated with the first screen application from the control server; receiving the application status information associated with the first screen application from the control server; and determining, based on the application status information, whether the first screen application has an existing session with any other client devices.']",False,"['150', '160', '305', '310', '130', '140', '315', '320', '325', '330', '335', '340', '350', '355', '360', '365', '345', '3', '18']" 866,EP_3606013_A1 (3).png,EP3606013A1,INTEROPERABILITY OF DISCOVERY AND CONNECTION PROTOCOLS BETWEEN CLIENT DEVICES AND FIRST SCREEN DEVICES,['FIG4'],"['FIG4 is a block diagram illustrating a detailed view of a second screen application of FIG1, according to one embodiment']","['Turning now to a discussion of the structure of the second screen application 150, FIG4 is a block diagram illustrating a detailed view of modules within the second screen application 150 according to one embodiment. Some embodiments of the second screen application 150 have different modules than those described here. Similarly, the functions can be distributed among the modules in a different manner than is described here. The second screen application 150 are comprised of modules including a device database 410, a discovery module 420, a deduplication module 430, an interface module 440, and a coupling module 450. Moreover, while the discussion below is in the context of the second screen application 150, it also equally applies to the second screen application 160.']",21,136,block diagram,G,"[{'element_identifier': '150', 'terms': ['screen application', 'screen applications']}, {'element_identifier': '430', 'terms': ['deduplication module']}, {'element_identifier': '420', 'terms': ['discovery module']}, {'element_identifier': '440', 'terms': ['interface module']}, {'element_identifier': '4', 'terms': ['clause']}, {'element_identifier': '410', 'terms': ['device database']}, {'element_identifier': '450', 'terms': ['coupling module']}]","['1. A computer-implemented method for facilitating interoperability between a first screen device and a second screen device, the method comprising: discovering, by the second screen device, a first screen application operating on the first screen device and a plurality of coupling protocols available to connect to the first screen device; providing, by the second screen device, a device list based on the discovering, the device list including a plurality of entries each associated with the first screen application and a respective coupling protocol of the plurality of coupling protocols; obtaining, by the second screen device, pairing information for the first screen application from a control server; updating, by the second screen device, the device list using the pairing information from the control server; performing, by the second screen device, device deduplication using the updated device list to generate a deduplicated entry for the first screen application; and presenting, by the second screen device, the deduplicated entry for the first screen application in a user interface.']",False,"['150', '410', '420', '430', '440', '450', '4', '19']" 867,EP_3606013_A1 (6).png,EP3606013A1,INTEROPERABILITY OF DISCOVERY AND CONNECTION PROTOCOLS BETWEEN CLIENT DEVICES AND FIRST SCREEN DEVICES,['FIG7'],['FIG7 is a block diagram illustrating an example computer for implementing the entities shown in FIG1 '],"['Turning now to a discussion of the implementation of client devices 100, 105, the first screen device 120, and/or the control server 130, FIG7 is a block diagram illustrating an example computer 700 for implementing the entities shown in FIG1. The computer 700 includes at least one processor 702 coupled to a chipset 704. The chipset 704 includes a memory controller hub 720 and an input/output (I/O) controller hub 722. A memory 706 and a graphics adapter 712 are coupled to the memory controller hub 720, and a display 718 is coupled to the graphics adapter 712. A storage device 708, an input device 714, and network adapter 716 are coupled to the I/O controller hub 722. Other embodiments of the computer 700 have different architectures.']",16,147,block diagram,G,"[{'element_identifier': '704', 'terms': ['chipset']}, {'element_identifier': '712', 'terms': ['graphics adapter', 'graphics adapters']}, {'element_identifier': '722', 'terms': ['controller hub']}, {'element_identifier': '706', 'terms': ['memory']}, {'element_identifier': '708', 'terms': ['storage device']}, {'element_identifier': '702', 'terms': ['processor']}, {'element_identifier': '716', 'terms': ['network adapter']}, {'element_identifier': '720', 'terms': ['memory controller hub']}, {'element_identifier': '718', 'terms': ['display', 'displays']}, {'element_identifier': '714', 'terms': ['input interface']}, {'element_identifier': '700', 'terms': ['computer', 'computers']}]","['1. A computer-implemented method for facilitating interoperability between a first screen device and a second screen device, the method comprising: discovering, by the second screen device, a first screen application operating on the first screen device and a plurality of coupling protocols available to connect to the first screen device; providing, by the second screen device, a device list based on the discovering, the device list including a plurality of entries each associated with the first screen application and a respective coupling protocol of the plurality of coupling protocols; obtaining, by the second screen device, pairing information for the first screen application from a control server; updating, by the second screen device, the device list using the pairing information from the control server; performing, by the second screen device, device deduplication using the updated device list to generate a deduplicated entry for the first screen application; and presenting, by the second screen device, the deduplicated entry for the first screen application in a user interface.', '15. A system to facilitate interoperability between a first screen device and a second screen device, the system comprising: a memory; and a processor, coupled to the memory, to: discover a first screen application operating on the first screen device and a plurality of coupling protocols available to connect to the first screen device; provide a device list based on the discovering, the device list including a plurality of entries each associated with the first screen application and a respective coupling protocol of the plurality of coupling protocols; obtain pairing information for the first screen application from a control server; update the device list using the pairing information from the control server; perform device deduplication using the updated device list to generate a deduplicated entry for the first screen application; and present the deduplicated entry for the first screen application in a user interface.']",False,"['702', '718', '704', '712', '720', '706', '708', '716', '722', '714', '700', '7', '22']" 868,EP_3606013_A1.png,EP3606013A1,INTEROPERABILITY OF DISCOVERY AND CONNECTION PROTOCOLS BETWEEN CLIENT DEVICES AND FIRST SCREEN DEVICES,['FIG1'],['FIG1 is a block diagram illustrating an embodiment of an environment for facilitating client device interoperability with a first screen device'],"['FIG1 is a block diagram illustrating an embodiment of an environment for facilitating client device 100, 105 interoperability with a first screen device 120. The environment includes a client device 100 and a client device 105, each coupled by a network 110 to a first screen device 120 and control server 130. Here, only two client devices, one screen device and one control server are illustrated, but there may be multiple instances of each of these entities. For example, there may be thousands or millions of client devices 100, 105 and first screen devices 120 in communication with one or more control servers 130.', 'The types of computers 700 used by the entities of FIG1 can vary depending upon the embodiment and the processing power required by the entity. In some embodiments, the client device 100 may interact with one or more servers working together to provide the functionality described herein. For example, the control server 130 may include multiple computers 700 communicating with each other through a network such as in a server farm to provide the functionality described herein. The computers 700 can lack some of the components described above, such as graphics adapters 712, and displays 718.']",21,220,block diagram,G,"[{'element_identifier': '160', 'terms': ['second screen application']}, {'element_identifier': '130', 'terms': ['control server', 'control servers']}, {'element_identifier': '1', 'terms': ['clause']}, {'element_identifier': '100', 'terms': ['device', 'devices']}, {'element_identifier': '105', 'terms': ['device', 'devices']}, {'element_identifier': '140', 'terms': ['first screen application', 'first screen applications']}, {'element_identifier': '110', 'terms': ['network']}, {'element_identifier': '150', 'terms': ['screen application', 'screen applications']}, {'element_identifier': '120', 'terms': ['first screen device', 'first screen devices']}]","['1. A computer-implemented method for facilitating interoperability between a first screen device and a second screen device, the method comprising: discovering, by the second screen device, a first screen application operating on the first screen device and a plurality of coupling protocols available to connect to the first screen device; providing, by the second screen device, a device list based on the discovering, the device list including a plurality of entries each associated with the first screen application and a respective coupling protocol of the plurality of coupling protocols; obtaining, by the second screen device, pairing information for the first screen application from a control server; updating, by the second screen device, the device list using the pairing information from the control server; performing, by the second screen device, device deduplication using the updated device list to generate a deduplicated entry for the first screen application; and presenting, by the second screen device, the deduplicated entry for the first screen application in a user interface.']",False,"['100', '150', '120', '140', '105', '110', '160', '130', '1', '16']" 869,EP_3606017_A1 (5).png,EP3606017A1,"ELECTRONIC DEVICE, ELECTRONIC DEVICE CONTROL METHOD, AND RECORDING MEDIUM",['FIG1'],"['FIG1 is a diagram schematically illustrating an example system in which an electronic apparatus is used ', 'FIG1 is a diagram schematically illustrating an example system in which an electronic apparatus is used']","['FIG1 is a diagram illustrating an example system in which an electronic apparatus 10 is used. The electronic apparatus 10 is a portable electronic apparatus, such as a smartphone, for instance. The electronic apparatus 10 can be used in intelligent transport systems (ITS), specifically, in a safe-driving assistance communication system 1. The safe-driving assistance communication system 1 is called a safe-driving assistance system or a safe-driving assistance wireless system.', ""As illustrated in FIG1, the safe-driving assistance communication system 1 enables mutual wireless communication between each roadside unit 5 at an intersection 2 or other places, each vehicle 6 (e.g., an automobile) traveling along a roadway 7, and the electronic apparatus 10 carried by each user 9 who is a pedestrian. The roadside unit 5, the vehicle 6, and the electronic apparatus 10 can thus exchange information with one another. The multiple vehicles 6 can perform wireless communication with one another. The vehicles 6 can thus exchange information with one another. The communication between the roadside unit 5 and the vehicle 6, the communication between the vehicles 6, the communication between the roadside unit 5 and the pedestrian's electronic apparatus 10, and the communication between the pedestrian's electronic apparatus 10 and the vehicle 6 are respectively called vehicle-to-roadside-infrastructure communication, vehicle-to-vehicle communication, pedestrian-to-roadside-infrastructure communication, and vehicle-to-pedestrian communication. "", 'FIG1 is a diagram illustrating an example system in which an electronic apparatus 10 is used. The electronic apparatus 10 is a portable electronic apparatus, such as a smartphone, for instance. The electronic apparatus 10 can be used in intelligent transport systems (ITS), specifically, in a safe-driving assistance communication system 1. The safe-driving assistance communication system 1 is called a safe-driving assistance system or a safe-driving assistance wireless system.', ""As illustrated in FIG1, the safe-driving assistance communication system 1 enables mutual wireless communication between each roadside unit 5 at an intersection 2 or other places, each vehicle 6 (e.g., an automobile) traveling along a roadway 7, and the electronic apparatus 10 carried by each user 9 who is a pedestrian. The roadside unit 5, the vehicle 6, and the electronic apparatus 10 can thus exchange information with one another. The multiple vehicles 6 can perform wireless communication with one another. The vehicles 6 can thus exchange information with one another. The communication between the roadside unit 5 and the vehicle 6, the communication between the vehicles 6, the communication between the roadside unit 5 and the pedestrian's electronic apparatus 10, and the communication between the pedestrian's electronic apparatus 10 and the vehicle 6 are respectively called vehicle-to-roadside-infrastructure communication, vehicle-to-vehicle communication, pedestrian-to-roadside-infrastructure communication, and vehicle-to-pedestrian communication.""]",32,554,diagram,G,"[{'element_identifier': '100', 'terms': ['controller']}, {'element_identifier': '1', 'terms': ['system']}]","['1. An electronic apparatus comprising: a communication unit configured to perform wireless communication with an external device and a vehicle and; a controller configured to, (i) upon receiving, via the communication unit, a reception signal transmitted from the external device through one-to-many communication, make a determination based on the reception signal, about whether a first distance between the electronic apparatus and the external device is shorter than a distance reference value, and (ii) upon determining that the first distance is shorter than the distance reference value, perform a restricting process of restricting transmission of a transmission signal via the communication unit.']",True,"['1', '1', '1', '100', '25']" 870,EP_3606017_A1 (6).png,EP3606017A1,"ELECTRONIC DEVICE, ELECTRONIC DEVICE CONTROL METHOD, AND RECORDING MEDIUM","['FIG1', ' FIG15']","['FIG1 is a diagram schematically illustrating an example system in which an electronic apparatus is used ', 'FIG1 is a diagram schematically illustrating an example system in which an electronic apparatus is used ', 'FIG1 is a diagram schematically illustrating an example system in which an electronic apparatus is used ', 'FIG15 is a diagram schematically illustrating an example configuration of the controller that sets a distance reference value']","['FIG1 is a diagram illustrating an example system in which an electronic apparatus 10 is used. The electronic apparatus 10 is a portable electronic apparatus, such as a smartphone, for instance. The electronic apparatus 10 can be used in intelligent transport systems (ITS), specifically, in a safe-driving assistance communication system 1. The safe-driving assistance communication system 1 is called a safe-driving assistance system or a safe-driving assistance wireless system.', ""As illustrated in FIG1, the safe-driving assistance communication system 1 enables mutual wireless communication between each roadside unit 5 at an intersection 2 or other places, each vehicle 6 (e.g., an automobile) traveling along a roadway 7, and the electronic apparatus 10 carried by each user 9 who is a pedestrian. The roadside unit 5, the vehicle 6, and the electronic apparatus 10 can thus exchange information with one another. The multiple vehicles 6 can perform wireless communication with one another. The vehicles 6 can thus exchange information with one another. The communication between the roadside unit 5 and the vehicle 6, the communication between the vehicles 6, the communication between the roadside unit 5 and the pedestrian's electronic apparatus 10, and the communication between the pedestrian's electronic apparatus 10 and the vehicle 6 are respectively called vehicle-to-roadside-infrastructure communication, vehicle-to-vehicle communication, pedestrian-to-roadside-infrastructure communication, and vehicle-to-pedestrian communication. "", 'FIG1 is a diagram illustrating an example system in which an electronic apparatus 10 is used. The electronic apparatus 10 is a portable electronic apparatus, such as a smartphone, for instance. The electronic apparatus 10 can be used in intelligent transport systems (ITS), specifically, in a safe-driving assistance communication system 1. The safe-driving assistance communication system 1 is called a safe-driving assistance system or a safe-driving assistance wireless system.', ""As illustrated in FIG1, the safe-driving assistance communication system 1 enables mutual wireless communication between each roadside unit 5 at an intersection 2 or other places, each vehicle 6 (e.g., an automobile) traveling along a roadway 7, and the electronic apparatus 10 carried by each user 9 who is a pedestrian. The roadside unit 5, the vehicle 6, and the electronic apparatus 10 can thus exchange information with one another. The multiple vehicles 6 can perform wireless communication with one another. The vehicles 6 can thus exchange information with one another. The communication between the roadside unit 5 and the vehicle 6, the communication between the vehicles 6, the communication between the roadside unit 5 and the pedestrian's electronic apparatus 10, and the communication between the pedestrian's electronic apparatus 10 and the vehicle 6 are respectively called vehicle-to-roadside-infrastructure communication, vehicle-to-vehicle communication, pedestrian-to-roadside-infrastructure communication, and vehicle-to-pedestrian communication. "", 'FIG1 is a diagram illustrating an example system in which an electronic apparatus 10 is used. The electronic apparatus 10 is a portable electronic apparatus, such as a smartphone, for instance. The electronic apparatus 10 can be used in intelligent transport systems (ITS), specifically, in a safe-driving assistance communication system 1. The safe-driving assistance communication system 1 is called a safe-driving assistance system or a safe-driving assistance wireless system.', ""As illustrated in FIG1, the safe-driving assistance communication system 1 enables mutual wireless communication between each roadside unit 5 at an intersection 2 or other places, each vehicle 6 (e.g., an automobile) traveling along a roadway 7, and the electronic apparatus 10 carried by each user 9 who is a pedestrian. The roadside unit 5, the vehicle 6, and the electronic apparatus 10 can thus exchange information with one another. The multiple vehicles 6 can perform wireless communication with one another. The vehicles 6 can thus exchange information with one another. The communication between the roadside unit 5 and the vehicle 6, the communication between the vehicles 6, the communication between the roadside unit 5 and the pedestrian's electronic apparatus 10, and the communication between the pedestrian's electronic apparatus 10 and the vehicle 6 are respectively called vehicle-to-roadside-infrastructure communication, vehicle-to-vehicle communication, pedestrian-to-roadside-infrastructure communication, and vehicle-to-pedestrian communication. "", 'FIG15 is a diagram schematically illustrating an example configuration of the controller 100 that sets the distance reference value Dref based on the vehicle information. The controller 100 comprises an information selector 106a and the multiplier 105a. The information selector 106a receives the vehicle information. In the example of FIG15, the information selector 106a receives the distances D21 and D22. The information selector 106a selects and then outputs the vehicle information that provides the smallest distance reference value Dref. In the example of FIG15, the information selector 106a outputs the distance D21, which is smaller than the distance D22, to the multiplier 105a. The multiplier 105a outputs the product of the distance D21 and predetermined value K1 as the distance reference value Dref, as earlier described.']",66,969,diagram,G,"[{'element_identifier': '1', 'terms': ['system']}, {'element_identifier': '100', 'terms': ['controller']}, {'element_identifier': '4', 'terms': ['traffic light']}, {'element_identifier': '2', 'terms': ['restriction notification information']}, {'element_identifier': '15', 'terms': ['microphone hole']}, {'element_identifier': '3', 'terms': ['crosswalk', 'Level']}]","['1. An electronic apparatus comprising: a communication unit configured to perform wireless communication with an external device and a vehicle and; a controller configured to, (i) upon receiving, via the communication unit, a reception signal transmitted from the external device through one-to-many communication, make a determination based on the reception signal, about whether a first distance between the electronic apparatus and the external device is shorter than a distance reference value, and (ii) upon determining that the first distance is shorter than the distance reference value, perform a restricting process of restricting transmission of a transmission signal via the communication unit.']",True,"['1', '2', '100', '1', '3', '100', '1', '4', '100', '15', '100', '26']" 871,EP_3606025_A1 (1).png,EP3606025A1,CAMERA MODULE AND AUTOMOBILE,['FIG3'],['FIG3 is an exploded view of the camera module of the present embodiment'],"['Hereinafter, the ""z-axis direction"" shown in FIG3 is defined as ""vertical direction."" In this case, the ""z-axis arrow direction"" is the ""upper direction."" The ""z-axis direction"" can be mixed with the ""optical axis direction,"" and the ""optical axis"" means the optical axis of the lens module 100.', 'Hereinafter, the second housing 300 of the present embodiment will be described with reference to FIG3, 4, 5, and 6. The second housing 300 may be an exterior member of the camera module 1000. The second housing 300 may be a plastic injection mold. The substrate 400 may be disposed on the upper portion of the second housing 300. The substrate 400 may be fixed to the upper portion of the second housing 300. In this case, the substrate 400 can be insertion coupled with the second housing 300. In addition, an adhesive may be applied to the coupled portions of the second housing 300 and/or the substrate 400.']",13,196,exploded view,H,"[{'element_identifier': '210', 'terms': ['lens holder']}, {'element_identifier': '310', 'terms': ['support portion']}, {'element_identifier': '100', 'terms': ['lens module']}, {'element_identifier': '400', 'terms': ['substrate']}, {'element_identifier': '220', 'terms': ['body']}, {'element_identifier': '300', 'terms': ['second housing']}, {'element_identifier': '311', 'terms': ['first support plate']}, {'element_identifier': '320', 'terms': ['base']}, {'element_identifier': '500', 'terms': ['image sensor']}, {'element_identifier': '10', 'terms': ['gasket']}, {'element_identifier': '330', 'terms': ['cable accommodating portion']}, {'element_identifier': '1000', 'terms': ['camera module']}, {'element_identifier': '200', 'terms': ['first housing']}]","['1. A camera module comprising: a first housing in which a lens module is disposed; and a second housing including a base and a support portion extending upward from the base, wherein the substrate and the support portion are disposed in the first housing, and a lower surface of the first housing is coupled with an upper surface of the base.', '3. The camera module according to claim 1, wherein the support portion comprises: a first support plate extending from the base to one side; a second support plate disposed perpendicularly to the first support plate and extending to one side from the base; and a corner part connecting the first support plate and the second support plate.', '8. The camera module according to claim 1, wherein the second housing comprises a cable accommodating portion protruding toward the other side of the base.']",False,"['1000', '100', '10', '210', '200', '220', '500', '400', '311', '310', '320', '300', '330', '13']" 872,EP_3606025_A1 (4).png,EP3606025A1,CAMERA MODULE AND AUTOMOBILE,['FIG6'],"['FIG6 is a perspective view of the second housing, the substrate, and the image sensor of the present embodiment']","['Hereinafter, referring to FIG6, guide portions 315-1, 315-2, 316-1, 316-2, 317-1, 317-2, 318-1, and 318-2 will be described.']",21,44,perspective view,H,"[{'element_identifier': '400', 'terms': ['substrate']}, {'element_identifier': '318', 'terms': ['fourth edge']}, {'element_identifier': '315', 'terms': ['first edge']}, {'element_identifier': '500', 'terms': ['image sensor']}, {'element_identifier': '316', 'terms': ['second edge']}, {'element_identifier': '317', 'terms': ['third edge']}]","['1. A camera module comprising: a first housing in which a lens module is disposed; and a second housing including a base and a support portion extending upward from the base, wherein the substrate and the support portion are disposed in the first housing, and a lower surface of the first housing is coupled with an upper surface of the base.']",False,"['318', '500', '400', '317', '315', '316', '16']" 873,EP_3606025_A1 (5).png,EP3606025A1,CAMERA MODULE AND AUTOMOBILE,['FIG7'],['FIG7 is a conceptual view showing the camera module of the present embodiment being fusion welded '],"['The arrangement and spacing between the ribs 221 and the side walls 321 are important for laser welding. The length of the rib 221 in the vertical direction (a in FIG7) is preferably 0.8 mm, and the tolerance between the rib 221 and the side wall 321 (b in FIG7) is preferably 0.3 mm. This is because the ribs 221 melt and shrink as a whole. The thickness of the base 320 (c in FIG7) is preferably 1.2 mm, and the width of the side wall 321 (d in FIG7) is preferably 0.5 mm considering the laser permeability and durability. It is preferable that the tolerance (e in FIG7) between the inner side surface of the side wall 321 and the outer side surface of the rib 221 is 0.2 mm in order to stably accommodate the molten rib 221 and the base 320 during the fusion process. It is preferable that the width of the contact portion between the rib 221 and the base 320 (f in FIG7) is secured to 1 mm for the bonding strength and airtightness. It is preferable that the assembly tolerance (g in FIG7) between the first housing 200 and the second housing 300 is 0.1 mm.']",16,226,conceptual view,H,"[{'element_identifier': '220', 'terms': ['body']}, {'element_identifier': '221', 'terms': ['opening', 'ribs', 'rib']}, {'element_identifier': '321', 'terms': ['side wall', 'side walls']}, {'element_identifier': '320', 'terms': ['base']}]","['1. A camera module comprising: a first housing in which a lens module is disposed; and a second housing including a base and a support portion extending upward from the base, wherein the substrate and the support portion are disposed in the first housing, and a lower surface of the first housing is coupled with an upper surface of the base.']",False,"['220', '221', '321', '320', '17']" 874,EP_3606058_A1 (2).png,EP3606058A1,"IMAGE CORRECTION METHOD AND APPARATUS, STORAGE MEDIUM, AND PROJECTION DEVICE",['FIG2'],['FIG2 is a spatial positional relationship diagram of adjacent diffraction spots according to some embodiments of the present disclosure'],"['In an example, FIG2 is a spatial positional relationship diagram of adjacent diffraction spots according to some embodiments of the present disclosure. As shown in FIG2, L1 is the ith diffraction spot, and L2 is the (i + 1)th diffraction spot. Line segment AB is the first line segment, line segment AC is the second line segment, and point B is the projection point of point C on the plane of the ith diffraction spot, so angle B is a right angle, and triangle ABC is a right-angled triangle. The angle between line segment AB and line segment AC is angle A, and angle A is also an angle between the plane of the ith diffraction spot and the plane of the (i + 1)th diffraction spot.']",19,143,diagram,G,"[{'element_identifier': '21', 'terms': []}, {'element_identifier': '2', 'terms': ['line segment']}]","['2. The method according to claim 1, wherein the determining (S103) an angle α i between a plane of an i th diffraction spot and a plane of an (i + 1) th diffraction spot that are adjacent in the horizontal or vertical direction in the region to be corrected comprises: determining a line segment having a first circle center and a second circle center as end points as a first line segment, wherein the first circle center is a circle center of the i th diffraction spot, and the second circle center is a circle center of the (i + 1) th diffraction spot; determining a line segment having the first circle center and a first projection point as end points as a third line segment, the first projection point being a projection point of the second circle center on a plane of the i th diffraction spot; and determining an angle between the first line segment and the third line segment as the angle α i .']",False,"['2', '21']" 875,EP_3606065_A1 (1).png,EP3606065A1,"MEDIA MODULE FOR TESTING CAMERA MODULE, TESTING PANEL AND TESTING BOARD",['FIG2'],['FIG2 is an exploded schematic view of the testing jointed board and the medium module in accordance with the above-described preferred embodiment of the present invention'],"['Specifically, as shown in FIG2, the board body 10 of the testing jointed board further includes a supporting board 11, wherein the supporting board 11 is disposed on the medium module 20, so that the medium module 20 can be fixed in the board body 10 in a certain arrangement and operated through the board body 10. The supporting board 11 of the board body 10 is detachably connected to the medium module 20, so that the medium module 20 placed in the board body 10 can be in a consistent test environment. Preferably, each of the medium modules 20 is detachably connected to the supporting board 11, so that the medium module 20 is disposed or taken out as needed. The medium module 20 is preferably snapped to the supporting board. The medium module 20 is preferably adapted to be adhesively connected to the supporting board in a host-and-slave manner. The medium module 20 is preferably adapted to be magnetically attracted to the supporting board. The medium module 20 is preferably adapted to be connected to the supporting board by a post and an aperture. The board body 10 further includes a cover 12 and a snapping assembly 13, wherein the cover 12 detachably covers the supporting board 11 to protect the medium module 20 disposed on the supporting board 11, wherein the snapping assembly 13 is disposed on the supporting board 11 and the cover 12 to detachably connect the cover 12 to the supporting board 11. It is obvious that when the medium module 20 is disposed on the supporting board 11 and the snapping assembly 13 fixes the cover 12 to the supporting board 11, the medium module 20 cannot be fetched from the board body 10. Correspondingly, when the medium module 20 needs to be taken out from the board body 10, the snapping assembly 13 is opened, so that the cover 12 can be detached from the supporting board 11, so that the medium module 20 can be taken out.']",28,365,exploded schematic view,H,"[{'element_identifier': '122', 'terms': ['calibrating position']}, {'element_identifier': '30', 'terms': ['camera module', 'camera modules']}, {'element_identifier': '12', 'terms': ['cover']}, {'element_identifier': '20', 'terms': ['module', 'modules']}, {'element_identifier': '112', 'terms': ['calibrating position']}, {'element_identifier': '111', 'terms': ['testing position', 'testing positions']}, {'element_identifier': '120', 'terms': ['opening']}]","['1. A medium module for testing optical performance of a camera module, characterized in that it comprises: a substrate; and an expansion circuit disposed on the substrate and adapted to be connected to the camera module, to provide an adaptive circuit switching for the camera module.', '28. The testing jointed board according to claim 21, wherein the board body further comprises a cover and a snapping assembly, and the cover detachably covers the supporting board to protect the medium module disposed on the supporting board, and the snapping assembly is disposed on the supporting board and the cover to detachably connect the cover to the supporting board.', '29. The testing jointed board according to claim 21, wherein the supporting board provides at least four testing positions to be correspondingly disposed with the medium module, so that the camera module carried by the medium module is placed in the testing position.', '34. The testing jointed board according to claim 21 wherein the supporting board has at least one calibrating position, and the calibrating position provides a calibration of the position of the supporting board.']",False,"['120', '12', '20', '122', '30', '111', '112', '131', '18']" 876,EP_3606065_A1.png,EP3606065A1,"MEDIA MODULE FOR TESTING CAMERA MODULE, TESTING PANEL AND TESTING BOARD",['FIG1'],['FIG1 is a schematic view of a testing jointed board and a medium module in accordance with a preferred embodiment of the present invention'],"['The invention provides a camera module testing medium module, a testing jointed board and a testing board for testing at least one camera module. As shown in FIG1, the preferred embodiment provides a testing jointed board comprising: a board body 10 and at least one medium module 20, wherein the medium module 20 is connected to a camera module 30, wherein the camera module 30 is a finished product to be tested, and the camera module 30 is connected to the medium module 20 for performing various performance tests on of camera module 30. The camera module 30 can be connected and detachably fixed to the medium module 20, and the medium module 20 can carry the camera module 30 to perform all testing operations. It is to be noted that the connection between the medium module 20 and the camera module 30 is one by one. That is, the camera module 30 can complete all testing operations through the medium module 20 without having to be repeatedly connected and fetched relative to the medium module 20. For example, the camera module 30 to be tested is connected and fixed to the medium module 20 before starting the testing operation. The medium module 20 will carry the camera module 30 for all the tests. The medium module 20 will be always connected to the camera module 30 regardless of whether the camera module 30 passes the test. That is, the medium module 20 can also assist the camera module 30 in performing the corresponding operation without passing the test for the camera module 30 that has not passed the test. For the camera module 30 that passes the test, the medium module 20 will also accompany the camera module 30 to complete other tests. With the medium module 20, the camera module 30 can avoid repeated connection and disconnection and fetch during all tests, including the flow process, to reduce adverse effects of the test on the camera module 30, reduce the time required for each of the camera modules 30 to be tested, and improve the overall efficiency of the test.']",24,379,schematic view,H,"[{'element_identifier': '30', 'terms': ['camera module', 'camera modules']}, {'element_identifier': '10', 'terms': ['board body', 'board bodies']}, {'element_identifier': '20', 'terms': ['module', 'modules']}]","['1. A medium module for testing optical performance of a camera module, characterized in that it comprises: a substrate; and an expansion circuit disposed on the substrate and adapted to be connected to the camera module, to provide an adaptive circuit switching for the camera module.', '15. A testing jointed board for testing optical performance of a camera module, characterized in that it comprises: a board body; and at least two medium modules disposed on the board body, wherein each medium module is connected to a camera module to perform test of the optical performance of the camera module through the board body.']",False,"['30', '30', '10', '30', '20', '30', '20', '17']" 877,EP_3606101_A1 (3).png,EP3606101A1,SIGNAL PROCESSING DEVICE,['FIG5'],['FIG5 is a block diagram showing another application example of the signal processing device'],"['FIG5 is a block diagram showing another application example of the signal processing device 1. As shown in FIG5, each of speakers 21L and 21R includes a tweeter TW serving as a speaker for high pitched sounds, and a woofer WF serving as a speaker for low pitched sounds. The tweeter TW and the woofer WF may be connected to the signal processing device 1, using a bi-wiring method. FIG5 shows the case where the tweeter TW is connected to the A-channel, and the woofer WF is connected to the B-channel. Switching of the speaker using such a bi-wiring method is also included in one aspect of the switching of the speaker in the present invention.']",14,133,block diagram,H,"[{'element_identifier': '171', 'terms': ['switching reception portion']}, {'element_identifier': '12', 'terms': ['obtaining portion']}, {'element_identifier': '11', 'terms': ['input portion']}, {'element_identifier': '1', 'terms': ['signal processing device']}, {'element_identifier': '18', 'terms': ['control portion']}, {'element_identifier': '16', 'terms': ['signal processing portion']}, {'element_identifier': '15', 'terms': ['storage portion']}, {'element_identifier': '13', 'terms': ['output portion']}]","['1. A signal processing device comprising: a switching reception portion that receives switching of a speaker arranged as a supply destination of a signal; a storage portion that stores an optimal setting in association with the switching, the optimal setting being obtained by measuring characteristics of the speaker selected by the switching; and a signal processing portion that reads out the optimal setting from the storage portion and uses the optimal setting to process a signal to be supplied to the speaker, the optimal setting being associated with the switching received by the switching reception portion.']",False,"['15', '13', '11', '16', '4', '12', '12', '171', '1', '18']" 878,EP_3606101_A1 (4).png,EP3606101A1,SIGNAL PROCESSING DEVICE,['FIG6'],['FIG6 is a block diagram conceptually showing a configuration of a signal processing device in accordance with a second preferred embodiment'],"['FIG6 is a block diagram conceptually showing a configuration of a signal processing device 1 in accordance with a second preferred embodiment. As shown in FIG6, the switching execution portion 14 may include an A/B switching portion 141 that performs switching regarding to the A-channel and the B-channel, and an ON/OFF switching portion 142 that is connected to a sub-woofer SW and switches between use and non-use of the sub-woofer SW serving as a speaker for super-low pitched sounds.']",21,99,block diagram,H,"[{'element_identifier': '171', 'terms': ['switching reception portion']}, {'element_identifier': '17', 'terms': ['operation reception portion']}, {'element_identifier': '14', 'terms': ['switching execution portion']}, {'element_identifier': '12', 'terms': ['obtaining portion']}, {'element_identifier': '141', 'terms': ['switching portion']}, {'element_identifier': '142', 'terms': ['switching portion']}, {'element_identifier': '1', 'terms': ['signal processing device']}, {'element_identifier': '18', 'terms': ['control portion']}, {'element_identifier': '16', 'terms': ['signal processing portion']}, {'element_identifier': '15', 'terms': ['storage portion']}, {'element_identifier': '13', 'terms': ['output portion']}]","['1. A signal processing device comprising: a switching reception portion that receives switching of a speaker arranged as a supply destination of a signal; a storage portion that stores an optimal setting in association with the switching, the optimal setting being obtained by measuring characteristics of the speaker selected by the switching; and a signal processing portion that reads out the optimal setting from the storage portion and uses the optimal setting to process a signal to be supplied to the speaker, the optimal setting being associated with the switching received by the switching reception portion.']",False,"['15', '16', '1', '13', '14', '141', '142', '12', '13', '17', '2', '171', '18', '17']" 879,EP_3606101_A1 (6).png,EP3606101A1,SIGNAL PROCESSING DEVICE,['FIG8'],['FIG8 is a block diagram conceptually showing a configuration of a signal processing device in accordance with a fourth preferred embodiment'],"['FIG8 is a block diagram conceptually showing a configuration of a signal processing device 1 in accordance with a fourth preferred embodiment. As shown in FIG8, in the signal processing device 1, the operation reception portion 17 may include a selection reception portion 172 that receives a selection about whether or not to perform the signal processing using the optimal setting Ia. In other words, the selection reception portion 172 receives, from a user, a selection instruction about whether or not to optimize speaker characteristics.']",21,92,block diagram,H,"[{'element_identifier': '171', 'terms': ['switching reception portion']}, {'element_identifier': '17', 'terms': ['operation reception portion']}, {'element_identifier': '14', 'terms': ['switching execution portion']}, {'element_identifier': '12', 'terms': ['obtaining portion']}, {'element_identifier': '172', 'terms': ['selection reception portion']}, {'element_identifier': '11', 'terms': ['input portion']}, {'element_identifier': '18', 'terms': ['control portion']}, {'element_identifier': '16', 'terms': ['signal processing portion']}, {'element_identifier': '15', 'terms': ['storage portion']}, {'element_identifier': '13', 'terms': ['output portion']}]","['1. A signal processing device comprising: a switching reception portion that receives switching of a speaker arranged as a supply destination of a signal; a storage portion that stores an optimal setting in association with the switching, the optimal setting being obtained by measuring characteristics of the speaker selected by the switching; and a signal processing portion that reads out the optimal setting from the storage portion and uses the optimal setting to process a signal to be supplied to the speaker, the optimal setting being associated with the switching received by the switching reception portion.', '5. The signal processing device according to any one of claims 1 to 4, further comprising a selection reception portion that receives a selection about whether or not to use the optimal setting in the signal processing, wherein, when the selection reception portion receives the selection in which the optimal setting is not used, the signal processing portion processes the signal by using a default setting.']",False,"['15', '11', '16', '13', '14', '12', '15', '171', '172', '18', '17']" 880,EP_3606123_A1 (2).png,EP3606123A1,"DATA DISTRIBUTION METHOD, AUTHENTICATION SERVER, AND DATA STRUCTURE",['FIG3'],['FIG3 is a block diagram illustrating an example of the functional configuration of a controller illustrated in FIG2'],"['FIG3 is a block diagram illustrating an example of the functional configuration of controller 101 illustrated in FIG2.', 'Controller 101 includes a processor and memory having a program stored therein for causing the processor to execute predetermined processing. In other words, controller 101 is realized as a result of the processor executing a given program using the memory. In the present embodiment, controller 101 includes, as illustrated in FIG3, transaction data generator 1011, secure computation calculator 1012, recorder 1013, and communication unit 1014.']",18,95,block diagram,G,"[{'element_identifier': '1012', 'terms': ['secure computation calculator']}, {'element_identifier': '1013', 'terms': ['recorder']}, {'element_identifier': '1011', 'terms': ['transaction data generator']}, {'element_identifier': '101', 'terms': ['controller']}, {'element_identifier': '1014', 'terms': ['communication unit']}, {'element_identifier': '3', 'terms': ['NPL']}]","['7. An authentication server in a data distribution system which includes a device and a plurality of authentication servers including the authentication server, the authentication server comprising: a communication unit configured to receive transaction data including encrypted history information which is history information of the device encrypted using a secure computation method which enables computation without decrypting the encrypted history information; a recorder which records, in a distributed ledger, the transaction data received from the device, when a validity of the transaction data is verified; and a secure computation calculator which performs secure computation on the encrypted history information included in the transaction data, the secure computation being computation processing performed without decrypting the encrypted history information.']",False,"['3', '101', '1011', '1014', '1012', '1013', '22']" 881,EP_3606123_A1 (4).png,EP3606123A1,"DATA DISTRIBUTION METHOD, AUTHENTICATION SERVER, AND DATA STRUCTURE",['FIG8'],['FIG8 is a block diagram illustrating an example of the functional configuration of an authentication server according to the embodiment'],"['FIG8 is a block diagram illustrating an example of the functional configuration of authentication server 200a according to the present embodiment. Authentication servers 200b and 200c have the same configuration as authentication server 200a, and thus authentication server 200a is taken as an example in the following description.', 'As illustrated in FIG8, authentication server 200a includes transaction data verifier 211, block generator 212, synchronizing unit 213, data verifier 214, recorder 215, and communication unit 216. Authentication server 200a can be realized as a result of a processor executing a given program using memory. Hereinafter, each structural element will be described.']",20,114,block diagram,G,"[{'element_identifier': '8', 'terms': ['machine learning.']}, {'element_identifier': '211', 'terms': ['transaction data verifier']}, {'element_identifier': '214', 'terms': ['secure computation calculator']}, {'element_identifier': '216', 'terms': ['recorder']}, {'element_identifier': '217', 'terms': ['communication unit']}, {'element_identifier': '213', 'terms': ['synchronizing unit']}, {'element_identifier': '215', 'terms': ['token generator']}, {'element_identifier': '212', 'terms': ['block generator']}]","['7. An authentication server in a data distribution system which includes a device and a plurality of authentication servers including the authentication server, the authentication server comprising: a communication unit configured to receive transaction data including encrypted history information which is history information of the device encrypted using a secure computation method which enables computation without decrypting the encrypted history information; a recorder which records, in a distributed ledger, the transaction data received from the device, when a validity of the transaction data is verified; and a secure computation calculator which performs secure computation on the encrypted history information included in the transaction data, the secure computation being computation processing performed without decrypting the encrypted history information.']",False,"['8', '211', '212', '213', '214', '215', '216', '217', '27']" 882,EP_3606123_A1 (6).png,EP3606123A1,"DATA DISTRIBUTION METHOD, AUTHENTICATION SERVER, AND DATA STRUCTURE",['FIG10'],['FIG10 is a block diagram illustrating an example of the functional configuration of a service server according to the embodiment'],"['FIG10 is a block diagram illustrating an example of the functional configuration of service server 300 according to the present embodiment.', 'As illustrated in FIG10, service server 300 includes service manager 311 and communication unit 312.']",20,40,block diagram,G,"[{'element_identifier': '300', 'terms': ['service server']}, {'element_identifier': '311', 'terms': ['service manager']}, {'element_identifier': '312', 'terms': ['communication unit']}, {'element_identifier': '10', 'terms': ['data distribution system']}]","['3. The data distribution method according to claim 1 or claim 2, wherein the data distribution system further includes a service server, the data distribution method further comprising: generating, by the service server, third transaction data indicating a data analysis request, and transmitting, by the service server, the third transaction data to the first authentication server; recording, by the plurality of authentication servers, the third transaction data in distributed ledgers when a validity of the third transaction data received from the service server is verified by the first authentication server; performing, by the first authentication server, the secure computation on the encrypted history information, and transmitting, by the first authentication server, a computation result of the secure computation to the service server, the encrypted history information being subjected to the computation processing according to the data analysis request and being included in first transaction data among one or more items of transaction data recorded in the distributed ledger; and receiving, by the service server, the computation result of the secure computation from the first authentication server.', '7. An authentication server in a data distribution system which includes a device and a plurality of authentication servers including the authentication server, the authentication server comprising: a communication unit configured to receive transaction data including encrypted history information which is history information of the device encrypted using a secure computation method which enables computation without decrypting the encrypted history information; a recorder which records, in a distributed ledger, the transaction data received from the device, when a validity of the transaction data is verified; and a secure computation calculator which performs secure computation on the encrypted history information included in the transaction data, the secure computation being computation processing performed without decrypting the encrypted history information.']",False,"['10', '300', '312', '311', '29']" 883,EP_3606134_A1 (1).png,EP3606134A1,"METHOD FOR PROCESSING RADIO LINK FAILURE, AND TERMINAL DEVICE AND NETWORK DEVICE",['FIG3'],['FIG3 is another schematic flowchart of a method for processing an RLF according to an embodiment of the present disclosure'],"['FIG3 shows a schematic flow diagram of a method 200 for processing an RLF according to an embodiment of the present disclosure. The method 200 can be performed by a network device.', 'As shown in FIG3, the method 200 includes the following contents:In S210, the network device receives same Packet Data Convergence Protocol (PDCP) layer data which is sent by a terminal device using a primary carrier and a secondary carrier.']",20,81,schematic flowchart,H,"[{'element_identifier': '310', 'terms': ['sending unit']}, {'element_identifier': '4', 'terms': ['generation']}, {'element_identifier': '300', 'terms': ['terminal device']}, {'element_identifier': '320', 'terms': ['determination unit']}, {'element_identifier': '200', 'terms': ['method']}]","['1. A method for processing a Radio Link Failure (RLF), comprising: sending, by a terminal device, same Packet Data Convergence Protocol (PDCP) layer data to a network device using a primary carrier and a secondary carrier; if the number of transmissions of Acknowledged Mode Protocol Data Unit (AMD PDU) reaches the maximum number of transmissions in a Radio Link Control (RLC) entity corresponding to the secondary carrier, determining by the terminal device that an RLF event occurs in the secondary carrier; and sending, by the terminal device, first RLF type indication information to the network device, wherein the first RLF type indication information is used to indicate that a carrier where the RLF event occurs is the secondary carrier.', '15. A terminal device, comprising: a sending unit configured to send same Packet Data Convergence Protocol (PDCP) layer data to a network device using a primary carrier and a secondary carrier; a determination unit configured to, if the number of transmissions of Acknowledged Mode Protocol Data Unit (AMD PDU) reaches the maximum number of transmissions in a Radio Link Control (RLC) entity corresponding to the secondary carrier, determine that a Radio Link Failure (RLF) event occurs in the secondary carrier; and wherein the sending unit is configured to send first RLF type indication information to the network device, wherein the first RLF type indication information is used to indicate that a carrier where the RLF event occurs is the secondary carrier.']",True,"['200', '300', '310', '320', '4', '19']" 884,EP_3606134_A1 (2).png,EP3606134A1,"METHOD FOR PROCESSING RADIO LINK FAILURE, AND TERMINAL DEVICE AND NETWORK DEVICE",['FIG5'],['FIG5 is a schematic block diagram of a network device according to an embodiment of the present disclosure'],"['As shown in FIG5, a network device 400 according to an embodiment of the present disclosure includes a receiving unit 410 and a determination unit 420. According to an exemplary embodiment, the network device may further include a sending unit 430.']",18,45,schematic block diagram,H,"[{'element_identifier': '430', 'terms': ['sending unit']}, {'element_identifier': '420', 'terms': ['determination unit']}, {'element_identifier': '500', 'terms': ['device']}, {'element_identifier': '530', 'terms': ['memory']}, {'element_identifier': '510', 'terms': ['processor']}, {'element_identifier': '410', 'terms': ['receiving unit']}, {'element_identifier': '520', 'terms': ['transceiver']}]","['1. A method for processing a Radio Link Failure (RLF), comprising: sending, by a terminal device, same Packet Data Convergence Protocol (PDCP) layer data to a network device using a primary carrier and a secondary carrier; if the number of transmissions of Acknowledged Mode Protocol Data Unit (AMD PDU) reaches the maximum number of transmissions in a Radio Link Control (RLC) entity corresponding to the secondary carrier, determining by the terminal device that an RLF event occurs in the secondary carrier; and sending, by the terminal device, first RLF type indication information to the network device, wherein the first RLF type indication information is used to indicate that a carrier where the RLF event occurs is the secondary carrier.', '15. A terminal device, comprising: a sending unit configured to send same Packet Data Convergence Protocol (PDCP) layer data to a network device using a primary carrier and a secondary carrier; a determination unit configured to, if the number of transmissions of Acknowledged Mode Protocol Data Unit (AMD PDU) reaches the maximum number of transmissions in a Radio Link Control (RLC) entity corresponding to the secondary carrier, determine that a Radio Link Failure (RLF) event occurs in the secondary carrier; and wherein the sending unit is configured to send first RLF type indication information to the network device, wherein the first RLF type indication information is used to indicate that a carrier where the RLF event occurs is the secondary carrier.', '22. A network device, comprising: a receiving unit configured to receive same Packet Data Convergence Protocol (PDCP) layer data which is sent by a terminal device using a primary carrier and a secondary carrier; wherein the receiving unit is configured to receive first RLF type indication information sent by the terminal device, wherein the first RLF type indication information is used to indicate that a carrier where a Radio Link Failure (RLF) event occurs is the secondary carrier, and the number of transmissions of Acknowledged Mode Protocol Data Unit (AMD PDU) reaches the maximum number of transmissions in a Radio Link Control (RLC) entity corresponding to the secondary carrier where the RLF event occurs; and a determination unit configured to determine that the carrier where the RLF event occurs is the secondary carrier according to the first RLF type indication information.']",True,"['410', '420', '430', '5', '500', '510', '520', '530', '9', '20']" 885,EP_3606140_A1 (3).png,EP3606140A1,USER TERMINAL AND RADIO COMMUNICATION METHOD,['FIG5'],['FIG5 is a diagram illustrating one example of an entire configuration of a radio base station according to one embodiment of the present invention'],"['FIG5 is a diagram illustrating one example of an entire configuration of the radio base station according to the one embodiment of the present invention. The radio base station 10 includes pluralities of transmitting/receiving antennas 101, amplifying sections 102 and transmitting/receiving sections 103, a baseband signal processing section 104, a call processing section 105 and a channel interface 106. In this regard, the radio base station 10 only needs to be configured to include one or more of each of the transmitting/receiving antennas 101, the amplifying sections 102 and the transmitting/receiving sections 103.']",24,109,diagram,H,"[{'element_identifier': '103', 'terms': ['each transmitting/receiving section']}, {'element_identifier': '30', 'terms': ['higher station apparatus']}, {'element_identifier': '104', 'terms': ['baseband signal processing section']}, {'element_identifier': '105', 'terms': ['call processing section']}, {'element_identifier': '102', 'terms': ['each amplifying section']}, {'element_identifier': '101', 'terms': ['each transmitting/receiving antenna']}, {'element_identifier': '10', 'terms': ['radio base station']}, {'element_identifier': '106', 'terms': ['channel interface']}]","['1. A user terminal comprising: a receiving section that receives a DL signal; and a control section that controls reporting of a measurement report associated with a predetermined reception beam based on the received DL signal, wherein the control section determines the predetermined reception beam based on information notified from a radio base station or autonomously.']",False,"['101', '102', '01', '102', '106', '104', '105', '103', '103', '30', '10', '24']" 886,EP_3606140_A1 (4).png,EP3606140A1,USER TERMINAL AND RADIO COMMUNICATION METHOD,['FIG9'],['FIG9 is a diagram illustrating one example of hardware configurations of the radio base station and the user terminal according to one embodiment of the present invention '],"['For example, the radio base station and the user terminal according to the one embodiment of the present invention may function as computers that perform processing of the radio communication method according to the present invention. FIG9 is a diagram illustrating one example of hardware configurations of the radio base station and the user terminal according to the one embodiment of the present invention. The above radio base station 10 and user terminal 20 may be each physically configured as a computer apparatus that includes a processor 1001, a memory 1002, a storage 1003, a communication apparatus 1004, an input apparatus 1005, an output apparatus 1006 and a bus 1007.', 'In this regard, a word ""apparatus"" in the following description can be read as a circuit, a device or a unit. The hardware configurations of the radio base station 10 and the user terminal 20 may be configured to include one or a plurality of apparatuses illustrated in FIG9 or may be configured without including part of the apparatuses.', 'For example, FIG9 illustrates only the one processor 1001. However, there may be a plurality of processors. Furthermore, processing may be executed by one processor or may be executed by one or more processors concurrently, successively or by another method. In addition, the processor 1001 may be implemented by one or more chips.']",27,248,diagram,H,"[{'element_identifier': '103', 'terms': ['each transmitting/receiving section']}, {'element_identifier': '304', 'terms': ['received signal processing section']}, {'element_identifier': '303', 'terms': ['mapping section']}, {'element_identifier': '302', 'terms': ['transmission signal generation section']}, {'element_identifier': '301', 'terms': ['control section']}, {'element_identifier': '106', 'terms': ['channel interface']}, {'element_identifier': '305', 'terms': ['measurement section']}]","['1. A user terminal comprising: a receiving section that receives a DL signal; and a control section that controls reporting of a measurement report associated with a predetermined reception beam based on the received DL signal, wherein the control section determines the predetermined reception beam based on information notified from a radio base station or autonomously.']",False,"['301', '302', '303', '103', '106', '304', '25', '305', '9']" 887,EP_3606140_A1 (5).png,EP3606140A1,USER TERMINAL AND RADIO COMMUNICATION METHOD,['FIG7'],['FIG7 is a diagram illustrating one example of an entire configuration of a user terminal according to one embodiment of the present invention'],"['FIG7 is a diagram illustrating one example of an entire configuration of the user terminal according to the one embodiment of the present invention. The user terminal 20 includes pluralities of transmitting/receiving antennas 201, amplifying sections 202 and transmitting/receiving sections 203, a baseband signal processing section 204 and an application section 205. In this regard, the user terminal 20 only needs to be configured to include one or more of each of the transmitting/receiving antennas 201, the amplifying sections 202 and the transmitting/receiving sections 203.']",23,100,diagram,H,"[{'element_identifier': '201', 'terms': ['each transmitting/receiving antenna']}, {'element_identifier': '202', 'terms': ['each amplifying section']}, {'element_identifier': '203', 'terms': ['each transmitting/receiving section']}, {'element_identifier': '204', 'terms': ['baseband signal processing section']}, {'element_identifier': '20', 'terms': ['user terminal', 'user terminals']}, {'element_identifier': '205', 'terms': ['application section']}]","['1. A user terminal comprising: a receiving section that receives a DL signal; and a control section that controls reporting of a measurement report associated with a predetermined reception beam based on the received DL signal, wherein the control section determines the predetermined reception beam based on information notified from a radio base station or autonomously.']",False,"['201', '20', '203', '205', '204', '202', '26', '203', '202']" 888,EP_3606181_A1 (1).png,EP3606181A1,"METHOD FOR TERMINAL DEVICE TO ACCESS NETWORK, TERMINAL DEVICE AND NETWORK DEVICE",['FIG4'],['FIG4 is a schematic block diagram of a terminal device according to an embodiment of the present application'],"['FIG4 is a schematic block diagram of a terminal device 400 according to an embodiment of the present application. As shown in FIG4, the terminal device 400 includes a transceiver unit 410 and a determining unit 420.']",18,40,schematic block diagram,H,"[{'element_identifier': '420', 'terms': ['receiving unit']}, {'element_identifier': '430', 'terms': ['unit']}, {'element_identifier': '400', 'terms': ['terminal device']}, {'element_identifier': '4', 'terms': ['message']}, {'element_identifier': '300', 'terms': ['method']}, {'element_identifier': '3', 'terms': ['message']}, {'element_identifier': '410', 'terms': ['sending unit']}]","['4. The method according to any one of claims 1 to 3, wherein after the terminal device receives the random access response information sent by the at least one network device according to the indication information, the method further comprises: determining, by the terminal device, a target network device among the at least one network device; and sending, by the terminal device, a message 3 to the target network device.', '14. A terminal device, comprising: a sending unit, used for sending a random access preamble; and a receiving unit, used for receiving indication information sent by a first network device; wherein the receiving unit is further used for receiving random access response information sent by at least one network device according to the indication information, wherein the at least one network device comprises the first network device.']",True,"['300', '3', '3', '4', '400', '410', '420', '430', '4', '18']" 889,EP_3606181_A1 (2).png,EP3606181A1,"METHOD FOR TERMINAL DEVICE TO ACCESS NETWORK, TERMINAL DEVICE AND NETWORK DEVICE",['FIG9'],['FIG9 is yet another schematic block diagram of a network device according to an embodiment of the present application '],"['FIG9 shows a schematic block diagram of a network device 900 according to an embodiment of the present application. As shown in FIG9, the network device 900 includes a processor 910 and a transceiver 920, and the processor 910 is connected to the transceiver 920. Optionally, the network device 900 further includes a memory 930, and the memory 930 is connected to the processor 910. Herein, the processor 910, the memory 930 and the transceiver 920 communicate with each other through an internal connection path to transfer control and/or data signals. The memory 930 may be used to store instructions, and the processor 910 may be used to execute instructions stored in the memory 930 to control the transceiver 920 to transmit information or signals. The transceiver 920 is used for receiving a random access preamble sent by a terminal device, sending second random access response information to the terminal device according to the random access preamble, and receiving a message 3 sent by the terminal device. The message 3 includes identifications of at least two network devices. The processor 910 is used for negotiating with other network devices except the network device among the at least two network devices according to the identifications of the at least two network devices, and determining a target network device that sends a message 4 to the terminal device.']",19,244,schematic block diagram,H,"[{'element_identifier': '620', 'terms': ['sending unit']}, {'element_identifier': '600', 'terms': ['network device']}, {'element_identifier': '500', 'terms': ['network device']}, {'element_identifier': '630', 'terms': ['determination unit']}, {'element_identifier': '610', 'terms': ['receiving unit']}, {'element_identifier': '510', 'terms': ['receiving unit']}, {'element_identifier': '520', 'terms': ['sending unit']}]","['1. A method for a terminal device to access a network, comprising: sending, by a terminal device, a random access preamble; receiving, by the terminal device, indication information sent by a first network device; and receiving, by the terminal device, random access response information sent by at least one network device according to the indication information, wherein the at least one network device comprises the first network device.', '17. The terminal device according to any one of claims 14 to 16, wherein the terminal device further comprises: a determination unit, used for determining a target network device among the at least one network device after the receiving unit receives the random access response information sent by the at least one network device according to the indication information; and the sending unit is further used for sending a message 3 to the target network device.']",True,"['500', '510', '520', '5', '600', '610', '620', '630', '9', '19']" 890,EP_3606181_A1 (3).png,EP3606181A1,"METHOD FOR TERMINAL DEVICE TO ACCESS NETWORK, TERMINAL DEVICE AND NETWORK DEVICE","['FIG7', ' FIG8']","['FIG7 is another schematic block diagram of a terminal device according to an embodiment of the present application ', 'FIG8 is yet another schematic block diagram of a network device according to an embodiment of the present application']","['FIG7 shows a schematic block diagram of a terminal device 700 according to an embodiment of the present application. As shown in FIG7, the terminal device 700 includes a processor 710 and a transceiver 720, and the processor 710 is connected to the transceiver 720. Optionally, the terminal device 700 further includes a memory 730, and the memory 730 is connected to the processor 710. Herein, the processor 710, the memory 730 and the transceiver 720 communicate with each other through an internal connection path to transfer control and/or data signals. The memory 730 may be used to store instructions, and the processor 710 may be used to execute instructions stored in the memory 730 to control the transceiver 720 to transmit information or signals. The transceiver 720 is used for sending a random access preamble, receiving indication information sent by a first network device, and receiving random access response information sent by at least one network device according to the indication information. The at least one network device includes the first network device. ', 'FIG8 shows a schematic block diagram of a network device 800 according to an embodiment of the present application. As shown in FIG8, the network device 800 includes a processor 810 and a transceiver 820, and the processor 810 is connected to the transceiver 820. Optionally, the network device 800 further includes a memory 830, and the memory 830 is connected to the processor 810. Herein, the processor 810, the memory 830 and the transceiver 820 communicate with each other through an internal connection path to transfer control and/or data signals. The memory 830 may be used to store instructions, and the processor 810 may be used to execute instructions stored in the memory 830 to control the transceiver 820 to transmit information or signals. The transceiver 820 is used for receiving a random access preamble sent by a terminal device, and sending indication information to the terminal device. The indication information is used for indicating the terminal device to receive random access response information sent by at least one network device. The at least one network device includes the network device. The transceiver 820 is further used for sending first random access response information to the terminal device according to the random access preamble.']",37,412,schematic block diagram,H,"[{'element_identifier': '830', 'terms': ['memory']}, {'element_identifier': '810', 'terms': ['processor']}, {'element_identifier': '710', 'terms': ['processor']}, {'element_identifier': '820', 'terms': ['transceiver']}, {'element_identifier': '720', 'terms': ['transceiver']}, {'element_identifier': '730', 'terms': ['memory']}, {'element_identifier': '800', 'terms': ['network device']}, {'element_identifier': '700', 'terms': ['terminal device']}]","['1. A method for a terminal device to access a network, comprising: sending, by a terminal device, a random access preamble; receiving, by the terminal device, indication information sent by a first network device; and receiving, by the terminal device, random access response information sent by at least one network device according to the indication information, wherein the at least one network device comprises the first network device.']",True,"['700', '710', '720', '730', '7', '800', '810', '1', '820', '830', '8', '20']" 891,EP_3606218_A1 (2).png,EP3606218A1,"USER EQUIPMENT, BASE STATION, AND RELATED METHOD",['FIG3'],['FIG3 is a flowchart of a method used in a base station according to an embodiment of the present disclosure'],"['In accordance with the method 100 described above, the present disclosure further provides a method used in a base station. FIG3 is a flowchart of a method 300 used in a base station according to an embodiment of the present disclosure. As shown in the figure, the method 300 includes the following steps.']",20,58,flowchart,H,"[{'element_identifier': '300', 'terms': ['method']}]","['1. A method in user equipment, comprising: receiving an indication for enabling a sub-physical resource block enhancement mode from a base station through a media access control (MAC) random access response (RAR) or radio resource control signaling, wherein one or more bits in the MAC RAR indicate that the sub-physical resource block enhancement mode is to be applied to transmission of a random access message 3 ""Msg3"" and subsequent physical uplink shared channels (PUSCHs); enabling the sub-physical resource block enhancement mode in response to the indication, and receiving downlink control information (DCI) from the base station, the DCI comprising a subcarrier indication field indicating the number of subcarriers used for a PUSCH and locations of the subcarriers; and transmitting the PUSCH according to the subcarrier indication field.']",False,"['300', '17']" 892,EP_3606233_A1 (1).png,EP3606233A1,METHOD AND DEVICE FOR DETERMINING TRANSMISSION PARAMETERS AND STORAGE MEDIUM,['FIG4'],['FIG4 is a structural block diagram of a transmission parameter determination device according to an embodiment of the present disclosure'],"['A transmission parameter determination device is further provided in this embodiment. FIG4 is a structural block diagram of the transmission parameter determination device according to an embodiment of the present disclosure. As shown in FIG4, the device includes:']",20,42,structural block diagram,H,"[{'element_identifier': '46', 'terms': ['second determination module']}, {'element_identifier': '4', 'terms': ['symbol']}, {'element_identifier': '34', 'terms': ['first determination module']}, {'element_identifier': '42', 'terms': ['determination module']}, {'element_identifier': '44', 'terms': []}, {'element_identifier': '36', 'terms': ['processing module']}, {'element_identifier': '32', 'terms': ['first acquisition module']}]","['38. A transmission parameter determination device, comprising: a first acquisition module, which is configured to acquire a plurality of transmission parameter sets, wherein the plurality of transmission parameter sets at least comprise: a first transmission parameter set, a second transmission parameter set, and transmission parameters having a same type; a first determination module, which is configured to determine a plurality of resource areas, wherein the plurality of resource areas at least comprise: a first resource area, a second resource area; and each resource area comprises at least one of: a time domain resource area, a code domain resource area, a frequency domain resource area, a spatial domain resource area, a reference signal resource area; and a processing module, which is configured to send information or receive information on the plurality of resource areas according to the plurality of transmission parameter sets, which at least comprises: sending information or receiving information on the first resource area according to the first transmission parameter set; and sending information or receiving information on the second resource area according to the second transmission parameter set.', '41. A transmission parameter determination device, comprising: a determination module, which is configured to determine a number of parameter configurations X corresponding to a parameter type, wherein X is a natural number, and there at least exist a first parameter configuration and a first time domain resource area on which a first parameter acts; a second acquisition module, which is configured to acquire a configuration of the parameter type according to a determination result; a second determination module, which is configured to in a case that the X is greater than 1, determine that there at least exist a second parameter configuration and a second time domain resource area on which a second parameter acts.']",True,"['32', '34', '36', '42', '44', '46', '4', '41']" 893,EP_3606254_A1 (3).png,EP3606254A1,METHOD AND DEVICE FOR ACQUIRING CONTROL INFORMATION,['FIG6'],['FIG6 is a schematic communication diagram of another type of control information processing according to an embodiment of the present invention'],"['An embodiment of the present invention provides another control information processing method and a network device and a terminal based on the method. Different from Embodiment 4 in which scheduling information and waveform information are sent by using different messages, in this embodiment, the scheduling information and the waveform information are carried in same DCI. For a DCI format, the examples provided in Table 2 are used in this embodiment. The following describes this embodiment of the present invention in detail with reference to FIG6.']",21,92,schematic diagram,H,"[{'element_identifier': '6', 'terms': ['DCI']}]","['2. The method according to claim 1, wherein the control information is radio resource control RRC signaling, a media access control-control element MAC CE, or downlink control information DCI.']",False,"['6', '28']" 894,EP_3606254_A1 (5).png,EP3606254A1,METHOD AND DEVICE FOR ACQUIRING CONTROL INFORMATION,['FIG9'],['FIG9 is a schematic structural diagram of a terminal according to an embodiment of the present invention '],"['FIG9 is a simplified schematic diagram of a possible design structure of a terminal in the foregoing embodiments. The terminal device 900 includes a processor 901 and a transceiver 902.', 'As shown in FIG9, the terminal 900 may further include a power supply 903, configured to supply power to various components or circuits in the terminal. The terminal may further include an antenna 904, configured to send, by using a radio signal, uplink data output by the transceiver, or output a received radio signal to the transceiver. In addition, to implement more functions of the terminal, the terminal may further include one or more of an input unit 906, a display unit 907, an audio circuit 909, a camera 905, a sensor 908, and the like. The audio circuit 909 may include a loudspeaker 9091, a microphone 9092, and the like.']",17,163,schematic structural diagram,H,"[{'element_identifier': '9092', 'terms': ['microphone']}, {'element_identifier': '909', 'terms': ['audio circuit']}, {'element_identifier': '900', 'terms': ['terminal']}, {'element_identifier': '908', 'terms': ['sensor']}, {'element_identifier': '904', 'terms': ['antenna']}, {'element_identifier': '901', 'terms': ['processor']}, {'element_identifier': '9', 'terms': ['andFIG.']}, {'element_identifier': '907', 'terms': ['display unit']}, {'element_identifier': '902', 'terms': ['transceiver']}, {'element_identifier': '9091', 'terms': ['loudspeaker']}, {'element_identifier': '905', 'terms': ['camera']}, {'element_identifier': '903', 'terms': ['power supply']}, {'element_identifier': '906', 'terms': ['input unit']}, {'element_identifier': '910', 'terms': ['memory']}]","['17. A network device, wherein the network device comprises a processor and a transmitter, wherein the processor is configured to generate control information, wherein the control information comprises information indicating an uplink transmission waveform of a terminal; and the transmitter is configured to send the control information to the terminal.']",False,"['904', '902', '903', '910', '905', '906', '900', '901', '909', '9091', '9092', '908', '907', '9', '30']" 895,EP_3606268_A1 (2).png,EP3606268A1,METHOD AND DEVICE FOR DETERMINING PREAMBLE SEQUENCE OF PHYSICAL RANDOM ACCESS CHANNEL,['FIG5'],['FIG5 is a schematic structural diagram of a network-side device according to some embodiments of the application '],"['FIG5 is a schematic structural diagram of a network-side device according to embodiments of the application, and as illustrated, the device includes:', 'Here in FIG5, the bus architecture can include any number of any number of interconnecting buses and bridges to particularly link together various circuits including one or more processors represented by the processor 500, and one or more memories represented by the memory 520. The bus architecture can further link together various other circuits, e.g., a peripheral device, a manostat, a power management circuit, etc., all of which are well known in the art, so a further description thereof will be omitted in this context. The bus interface serves as an interface. The transceiver 510 can be a number of elements, e.g., a transmitter and a receiver, which are units for communication with various other devices over a transmission medium. The processor 500 is responsible for managing the bus architecture and performing normal processes, and the memory 520 can store data for use by the processor 500 in performing the operations.']",19,198,schematic structural diagram,H,"[{'element_identifier': '402', 'terms': ['anda sequence determining module']}, {'element_identifier': '500', 'terms': ['processor']}, {'element_identifier': '510', 'terms': ['transceiver']}, {'element_identifier': '401', 'terms': []}, {'element_identifier': '520', 'terms': ['memory']}]","['11. A device for determining a preamble sequence on a Physical Random Access Channel (PRACH), the device comprising: a processor configured to read and execute program in a memory to: determine instances of time at which respective preamble sub-sequences are detected in a detection window; and determine preamble sub-sequences belonging to a same preamble sequence according to the instances of time at which the respective preamble sub-sequences are detected in a current stage, and the instances of time at which the respective preamble sub-sequences are detected in a previous stage; and a transceiver configured to transmit and receive data under the control of the processor is configured to: receive the respective preamble sub-sequences in the previous stage; and receive the respective preamble sub-sequences in the current stage.']",True,"['401', '402', '4', '500', '510', '520', '5', '12']" 896,EP_3606286_A1 (6).png,EP3606286A1,HEATING APPARATUS AND HEATING METHOD,['FIG8'],['FIG8 is a diagram schematically illustrating a hardening pattern of a workpiece according to a test example '],"['In Test Examples 1 to 3, a quenching process was performed on both side surfaces Wa, Wb of the workpiece W using the heating apparatus 1, and a quenching coolant was sprayed to the workpiece W at a predetermined flow rate to cool the workpiece W on the downstream side of the coil 10 in the feeding direction of the workpiece W. Heating conditions of Test Examples 1 to 3 are described in Table 1, and hardening patterns of the workpiece W in Test Examples 1 to 3 are schematically illustrated in FIG8.Table 1Ex. 1Ex. 2Ex. 3Cooling fluidNot sprayedSprayedSprayedSet power (kW)505080Oscillation frequency (kHz)252525Workpiece feeding speed (mm/sec)8080120Coil coolant temperature (□C)Supply port141414Discharge port282627Hardened layer depth (mm)1.8-2.11.8-1.91.7-1.9Crystal grain size (GSNo.)11.711.811.7']",17,139,diagram,C,"[{'element_identifier': '110', 'terms': ['coil']}, {'element_identifier': '130', 'terms': ['nozzles', 'nozzle']}]",['1. A heating apparatus comprising: a coil configured to receive AC power to form a magnetic field that inductively heats a workpiece; and a spray unit configured to spray cooling fluid including a liquid to a heating target portion of the workpiece placed in the magnetic field in a form of a mist at least during a period in which the AC power is supplied to the coil.'],True,"['7', '110', '130', '130', '8', '14']" 897,EP_3607867_A1 (2).png,EP3607867A1,NEEDLE RELOAD DEVICE FOR USE WITH ENDOSTITCH DEVICE,['FIG4'],"['FIG4 is a partial, longitudinal cross-sectional view of the tool assembly of FIG2']","['With particular reference to FIG4, the blade receiving channels 130d, 132d are dimensioned to at least partially intersect needle recesses 130a, 132a. Thus, by advancing the blade 150 or 152 within the corresponding blade receiving channel 130d or 132d, the distal end 150a or 152a of the corresponding blade 150 or 152 engages or ""locks in"" a groove 104a formed in the needle 104 when at least a portion of the needle 104 is received within the corresponding recess 130a or 132a. A suture (not shown) may be secured to the needle 104. The suture may include a plurality of barbs oriented to resist movement in a direction opposite to the direction of travel.']",16,127,longitudinal cross-sectional view,A,"[{'element_identifier': '122', 'terms': ['support member']}, {'element_identifier': '130', 'terms': ['jaws', 'jaw']}, {'element_identifier': '4', 'terms': ['paragraph']}, {'element_identifier': '138', 'terms': ['camming pin']}, {'element_identifier': '134', 'terms': ['jaw pivot pin']}, {'element_identifier': '132', 'terms': ['second jaw']}, {'element_identifier': '150', 'terms': ['blades', 'blade']}]","['1. A needle reload device for use with an endoscopic stitching device comprising: a base portion including a tool receiving portion configured to receive a tool assembly of the endoscopic stitching device; and a loading assembly disposed within the base portion, the loading assembly including: a needle holder pulley rotatably supported with the base portion, the needle holder pulley including a base including first and second portions configured to detachably receive a suture needle; and a needle release arm transitionable between an engaged state, in which, the needle release arm engages the needle holder pulley to inhibit rotation of the needle holder pulley, and a disengaged state, in which, the needle release arm is disengaged from the needle holder pulley such that the needle holder pulley is rotatable, wherein when the needle release arm is in the engaged state, the first portion of the needle holder pulley is positioned between jaws of the tool assembly of the endoscopic stitching device disposed in the tool receiving portion of the base portion, and when the needle release arm is in the disengage state, the second portion of the base of the needle holder pulley is positioned between the jaws of the tool assembly disposed in the tool receiving portion of the base portion.']",False,"['130', '150', '134', '152', '132', '122', '138', '4', '12']" 898,EP_3607868_A1 (6).png,EP3607868A1,ENDOSCOPE AID AND ENDOSCOPE,['FIG11'],['FIG11 is a perspective view of another modification example of the endoscope aid of FIG4'],"['In the example illustrated in FIG11, projections 113 are provided around the distal-end-side opening of the suction pipe line 108. The distal-end-side opening of the suction pipe line 108 is provided in the distal end surface 106A of the extending part 106 of the tubular member 101, and is directed to the axial direction of the distal end part of the tubular member 101. For example, in a case where the distal-end-side opening of the suction pipe line 108 is disposed in the vicinity of the treatment target part that is bleeding and blood is suctioned, there is a case where the treatment target part sticks to the distal-end-side opening of the suction pipe line 108. However, as the projections 113 are provided around the distal-end-side opening of the suction pipe line 108, the sticking of the treatment target part is suppressed. This allows stable suction through the suction pipe line 108. The number of projections 113 is not particularly limited, may be one or plural.']",15,199,perspective view,A,"[{'element_identifier': '103', 'terms': ['distal end part']}, {'element_identifier': '11', 'terms': ['operating part']}, {'element_identifier': '113', 'terms': ['projections']}, {'element_identifier': '20', 'terms': ['light guide']}, {'element_identifier': '104', 'terms': ['smaller-diameter part']}, {'element_identifier': '105', 'terms': ['sliding contact part']}, {'element_identifier': '112', 'terms': ['tubular projection', 'tubular projections']}, {'element_identifier': '101', 'terms': ['tubular member']}, {'element_identifier': '10', 'terms': ['insertion part']}, {'element_identifier': '108', 'terms': ['suction pipe line']}, {'element_identifier': '106', 'terms': ['extending part']}, {'element_identifier': '107', 'terms': []}]","['1. An endoscope aid attachably and detachably attached to a treatment tool insertion channel of an endoscope, the endoscope aid comprising: a flexible tubular member longer than a total length of the treatment tool insertion channel, wherein the tubular member has a treatment tool insertion pipe line that extends from a proximal end part of the tubular member disposed on an inlet side of the treatment tool insertion channel to a distal end part of the tubular member, and a suction pipe line that is provided separately from the treatment tool insertion pipe line, wherein the distal end part of the tubular member has a sliding contact part that has an outer periphery coming in sliding contact with an inner peripheral surface of an outlet portion of the treatment tool insertion channel maintained in the shape of a straight pipe irrespective of bending of an endoscope bending part and is disposed in the outlet portion, and an extending part that extends from the sliding contact part to a distal end side and is disposed to protrude from an outlet of the treatment tool insertion channel, and wherein a distal-end-side opening of the suction pipe line is provided in the extending part.', '2. The endoscope aid according to claim 1, wherein a suction tube of the endoscope joins the treatment tool insertion channel, wherein the other portion excluding the distal end part of the tubular member is a smaller-diameter part thinner than the distal end part, and wherein a proximal-end-side opening of the suction pipe line is connected to a gap formed between an inner peripheral surface of the treatment tool insertion channel and an outer peripheral surface of the smaller-diameter part.', '3. The endoscope aid according to claim 2, wherein the outer periphery of the sliding contact part is formed by one or more annular projections provided on an outer peripheral surface of the sliding contact part.']",True,"['10', '101', '112', '104', '107', '105', '106', '103', '11', '108', '101', '112', '104', '107', '113', '105', '106', '103', '108', '113', '113', '20']" 899,EP_3607889_A1.png,EP3607889A1,STOMAL SUPPORT DEVICE,['FIG2'],['FIG2 is a bottom perspective view of the stomal device of FIG1'],"['In embodiments, the rod 110 may have any suitable cross-sectional shape such as, e.g., a semi-circular, circular, square, rectangular, or the like. In some embodiments, the rod 110 may be formed from pliable, semi-rigid, or rigid material, such as a plastic, a polymer, a metal, or the like. In certain embodiments, each padding portion 126 may include an adhesive (not shown) in the form of, e.g., a flat sheet, sticker, tape, or the like, to facilitate securement of the stomal device 100 on abdominal wall or the skin of the patient. In embodiments, the adhesive may include any type of biocompatible adhesive (e.g., glue). In some embodiments, the contacting surfaces 120b, 122b (FIG2) of the first and second anchoring portions 120, 122 may optionally include an adhesive coating in lieu of the adhesive on the padding portion 126.']",12,181,bottom perspective view,A,"[{'element_identifier': '1', 'terms': ['paragraph']}, {'element_identifier': '100', 'terms': ['stomal device', 'stomal devices']}, {'element_identifier': '126', 'terms': ['padding portions', 'padding portion']}, {'element_identifier': '112', 'terms': ['second ends']}, {'element_identifier': '110', 'terms': ['rod', 'rods']}, {'element_identifier': '120', 'terms': ['portions']}]","['1. A stomal device comprising: a rod configured to be positioned in a loop of a body vessel to support at least a portion of the body vessel on an abdominal wall, the rod including first and second end portions having respective first and second connecting portions; and first and second anchoring portions configured to detachably support the rod, the first and second anchoring portions including third and fourth connecting portions configured to detachably mate with the first and second connecting portions of the first and second end portions of the rod, respectively, the first and second anchoring portions transversely extending from the rod.', '6. The stomal device according to any preceding claim, wherein at least one of the first or second anchoring portions includes a padding portion.', '10. A surgical kit comprising: a rod configured to be positioned in a loop of a body vessel to support at least the loop of the body vessel on an abdominal wall, the rod including first and second end portions; a pair of first anchoring portions configured to detachably support the rod, the first anchoring portions transversely connectable with the respective first and second end portions of the rod, the first anchoring portions each defining a longitudinal axis; a pair of second anchoring portions configured to detachably support the rod, the second anchoring portions detachably connectable with the respective first and second end portions of the rod, the second anchoring portions including an arcuate profile having concavity; and a pair of third anchoring portions configured to detachably support the rod, the third anchoring portions extending transversely from the respective first and second ends of the rod, the third anchoring portions including an arcuate profile having convexity.']",True,"['110', '112', '126', '126', '1', '126', '126', '110', '100', '120', '2']" 900,EP_3607897_A1 (5).png,EP3607897A1,CARTILAGE REMOVAL TOOL,['FIG10'],['FIG10 is an exploded view of the cartilage removal instrument of FIG8'],"['FIG10 is an exploded view of the instrument 900. The shank 910 has a mounting plate 922 at the end opposite the attachment portion 940. The plate 920 can be attached to the mounting plate 922 by a screw 924, rivet, or the like inserted through the hole 923 in the mounting plate 922. In some embodiments, the plate 920 is used for one surgical procedure, removed, and replaced with a fresh plate 920. The attachment portion 940 can be secured to the housing 916 by set screws 925 or other fasteners.']",12,102,exploded view,A,"[{'element_identifier': '942', 'terms': ['cross-shaped end']}, {'element_identifier': '900', 'terms': ['instrument']}, {'element_identifier': '920', 'terms': ['plate']}, {'element_identifier': '922', 'terms': ['mounting plate']}, {'element_identifier': '923', 'terms': ['hole']}, {'element_identifier': '940', 'terms': ['attachment portion']}, {'element_identifier': '925', 'terms': ['set screws']}, {'element_identifier': '912', 'terms': ['ball']}, {'element_identifier': '924', 'terms': ['screw']}, {'element_identifier': '934', 'terms': ['blade']}, {'element_identifier': '918', 'terms': ['received in mating slots']}, {'element_identifier': '10', 'terms': ['range from']}, {'element_identifier': '914', 'terms': ['circular opening']}, {'element_identifier': '916', 'terms': ['housing']}, {'element_identifier': '910', 'terms': ['shank']}]","['1. An instrument for use in cartilage removal, the instrument comprising: an elongate body having a first end and a longitudinal axis having a longitudinal direction; and, a cartilage removal portion coupled to the elongate body at the first end, the cartilage removal portion including a plurality of serrated blades substantially perpendicular to the longitudinal axis and adapted for removing material while moving in the longitudinal direction, each serrated blade having a centroid thereof located along the longitudinal axis.', '2. The instrument of claim 1, wherein each of the blades has a circular plate with a plurality of teeth arranged around a respective circumference.']",False,"['44', '940', '918', '916', '912', '942', '914', '925', '910', '900', '16', '900', '934', '920', '10', '922', '923', '924']" 901,EP_3608021_A2.png,EP3608021A2,"ANALYTE DETECTION DEVICES, MULTIPLEX AND TABLETOP DEVICES FOR DETECTION OF ANALYTES, AND USES THEREOF",['FIG1'],['FIG1: Depicts a perspective view of a representative device according to some embodiments of the present invention'],"['Referring to the drawings, in some embodiments, FIG1 through 36 depict embodiments of devices, components of such representative devices, and various views of such embodied devices that can be used in the methods and/or in conjunction with or without other devices and/or systems described herein.', 'FIG1 depicts a device comprising a first housing member (10), a buffer container (15), a second housing member (20), a groove for the sliding button (25), a sliding button (30), an inlet opening (35), a collar (40), and a test membrane (45). FIG1 depicts a test membrane (45) comprising two capture reagents. The first (10) and second (20) housing members can also be referred to as the lower and upper housing members, respectively. In FIG1, the sample would be applied through the inlet opening (35) and can be allowed to vertically flow through to the test membrane (45). In FIG1, the groove (25) allows the sliding button to move, which when attached to the locking member moves the locking member and can, in some embodiments, move the conjugate pad and change the position of the force member.']",18,234,perspective view,B,"[{'element_identifier': '35', 'terms': ['inlet opening']}, {'element_identifier': '30', 'terms': ['button']}, {'element_identifier': '1', 'terms': ['about']}, {'element_identifier': '45', 'terms': ['test membrane']}, {'element_identifier': '20', 'terms': ['second housing member']}, {'element_identifier': '25', 'terms': ['sliding button']}, {'element_identifier': '40', 'terms': ['collar']}, {'element_identifier': '42', 'terms': ['aspect']}, {'element_identifier': '10', 'terms': ['first housing member']}, {'element_identifier': '15', 'terms': ['buffer container']}]","['15. The device of claim 1, wherein the analyte detection membrane system comprises a conjugate pad and a test membrane, wherein the conjugate pad and the test membrane are substantially parallel to each other.', '17. A method of detecting an analyte, the method comprising: contacting a sample with a device for detecting an analyte comprising, wherein the device comprises: a housing comprising a first and second housing member, wherein the housing comprises: a conjugate pad and a test membrane, wherein at least a portion of the conjugate pad and the test membrane are substantially parallel to each other; an absorbent member, wherein the absorbent member is substantially parallel to and in fluid contact with the test membrane; an inlet opening in fluid contact with the conjugate pad; a force member, wherein the force member is configured to apply pressure substantially perpendicular to the test membrane; a slidable locking member contacting the force member; and an attachment member in contact with the locking member. wherein the sample is contacted with the conjugate pad, wherein the sample vertically flows through the conjugate pad and the test membrane; and detecting the presence or absence of the analyte, wherein the detecting comprises: a) detecting an optical signal from the test membrane by a spectrometer; b) communicating the signal from the spectrometer to a signal processing unit operably connected to the spectrometer; c) analyzing the signal by using the signal processing unit to determine the presence or absence of the analyte; and d) displaying a result on the display unit.']",False,"['1', '20', '30', '25', '35', '40', '15', '45', '10', '42']" 902,EP_3608068_A1 (1).png,EP3608068A1,SAFETY DEVICE,['FIG2'],['FIG2 is a front view of the robot collaboration device illustrated in FIG1'],"['An arm controller 54 serving as a moving part controller is connected to the collision sensor 36. The arm controller 54 serves to perform deceleration or emergency stopping of the arm 22 based on a collision detection signal from the collision sensor 36, and is built in the support table 20 of the robot 14 in this embodiment as illustrated in FIG2. The arm controller 54 may be connected to the collision sensor 36 in a wired or a wireless manner.']",13,85,front view,B,"[{'element_identifier': '24', 'terms': ['link', 'links']}, {'element_identifier': '22', 'terms': ['arm']}, {'element_identifier': '18', 'terms': ['floor']}, {'element_identifier': '62', 'terms': ['light beams']}, {'element_identifier': '64', 'terms': ['sensor controller']}, {'element_identifier': '54', 'terms': ['arm controller']}, {'element_identifier': '20', 'terms': ['support table']}, {'element_identifier': '56', 'terms': ['light curtain']}, {'element_identifier': '16', 'terms': ['common work table']}, {'element_identifier': '66', 'terms': ['arm entrance area']}, {'element_identifier': '26', 'terms': ['joints']}, {'element_identifier': '58', 'terms': ['light projecting portion']}, {'element_identifier': '36', 'terms': ['collision sensor']}, {'element_identifier': '70', 'terms': ['dangerous area']}, {'element_identifier': '60', 'terms': ['light receiving portion']}, {'element_identifier': '68', 'terms': ['common area']}]","['4. The safety device according to any one of claims 1 to 3, wherein the dangerous area comprises a common area which both the moving part of the automatic device and the detection object are able to enter, and the dangerous state detecting member detects entrance of both the moving part and the detection object into the common area.']",True,"['56', '60', '36', '24', '16', '64', '54', '20', '18', '16', '70', '58', '36', '24', '22', '66', '24', '26', '68', '62', '20', '56', '60', '13']" 903,EP_3608068_A1 (6).png,EP3608068A1,SAFETY DEVICE,['FIG10'],['FIG10 is a top view of the robot collaboration device illustrated in FIG9 '],"['In this embodiment, the common area 68 which both the arm 22 of the robot 14 and the operator A can enter is constituted by a first separate area 96a and a second separate area 96b which are disposed on both sides of a boundary 94 indicated by a dot dash line in FIG10.', 'As indicated by the dot dash line in FIG10, first and second entrance prediction areas 102a and 102b may be set around the first and second separate areas 96a and 96b and it may be determined that the arm 22 and the operator A are going to enter the same separate area 96 to enable the collision sensor 36 when the imaging detector 98 has detected that both the arm 22 and the operator A enter one of the first and second entrance prediction areas 102a and 102b. In brief, the third embodiment is not limited to a configuration in which a state that both the arm 22 and the operator A have entered one separate area 96 is detected substantially at the same time as entrance, but may employ a configuration in which it is detected that both the arm 22 and the operator A are going to enter one separate area 96 before entrance.']",13,218,view,B,"[{'element_identifier': '20', 'terms': ['support table']}, {'element_identifier': '90', 'terms': ['safety device']}, {'element_identifier': '36', 'terms': ['collision sensor']}, {'element_identifier': '68', 'terms': ['common area']}, {'element_identifier': '92', 'terms': []}, {'element_identifier': '18', 'terms': ['floor']}, {'element_identifier': '94', 'terms': ['boundary']}, {'element_identifier': '10', 'terms': ['safety device']}, {'element_identifier': '99', 'terms': ['ceiling']}, {'element_identifier': '70', 'terms': ['dangerous area']}, {'element_identifier': '24', 'terms': ['link', 'links']}, {'element_identifier': '22', 'terms': ['arm']}, {'element_identifier': '16', 'terms': ['common work table']}, {'element_identifier': '62', 'terms': ['light beams']}, {'element_identifier': '54', 'terms': ['arm controller']}, {'element_identifier': '14', 'terms': ['robot']}, {'element_identifier': '100', 'terms': ['camera']}, {'element_identifier': '64', 'terms': ['sensor controller']}, {'element_identifier': '56', 'terms': ['light curtain']}, {'element_identifier': '58', 'terms': ['light projecting portion']}, {'element_identifier': '60', 'terms': ['light receiving portion']}]","['4. The safety device according to any one of claims 1 to 3, wherein the dangerous area comprises a common area which both the moving part of the automatic device and the detection object are able to enter, and the dangerous state detecting member detects entrance of both the moving part and the detection object into the common area.']",True,"['100', '99', '60', '92', '16', '64', '54', '20', '18', '16', '58', '90', '36', '24', '22', '70', '94', '99', '14', '56', '62', '20', '60', '68', '10', '18']" 904,EP_3608100_A1.png,EP3608100A1,METAL CLAD LAMINATE PLATE AND PRODUCTION METHOD THEREOF,"['FIG1', ' FIG2']","['FIG1 is a schematic view illustrating a continuous hot press apparatus used in the production process of a metal clad laminate according to one embodiment of the present invention ', 'FIG2 is a schematic view illustrating a vapor deposition apparatus used in the production process of a metal clad laminate according to one embodiment of the present invention ']","['For example, FIG1 shows a continuous hot press apparatus 10 used in the production process of a metal clad laminate according to an embodiment of the present invention. The continuous hot press apparatus 10 has a pair of heating rolls 7 which at least include a metal elastic roll 8. In FIG1, the pair of heating rolls 7 comprises a metal elastic roll 8 and a metal heating roll 9. A thermoplastic liquid crystal polymer film 2 unwound from an unwinding roll 22 and a metal sheet 6 unwound from an unwinding roll 21 are introduced to the pair of heating rolls 7.', 'Preparation of a single-sided metal clad laminate will be explained with referring to FIG1. The thermoplastic liquid crystal polymer film prepared in the previous step (1) and a rolled copper foil (produced by JX Nippon Mining & Metals Corporation under a name of BHYX-HA-V2, Rz: 0.9 µm) with a thickness of 12 µm were prepared as a thermoplastic liquid crystal polymer film 2 and a metal sheet 6, respectively. To a continuous hot roll press apparatus 10 were attached a metal elastic roll 8 and a metal heating roll 9 as a pair of heating rolls 7 for lamination. The thermoplastic liquid crystal polymer film 2 and the metal sheet 6 were introduced in such a way that the thermoplastic liquid crystal polymer film 2 came into contact with the metal elastic roll 8 and the metal sheet 6 came into contact with the metal heating roll 9. The thermoplastic liquid crystal polymer film 2 and the metal sheet 6 were thermocompression-bonded by the pair of heating rolls so as to form a single-sided metal clad laminate 19. ', 'FIG2 shows a vapor deposition apparatus used in the production process of a metal clad laminate according to one embodiment of the present invention. As illustrated in FIG2, the obtained single-sided metal clad laminate 19 is introduced from an unwinding roll 12 using a guide roll 15 such that the surface of the metal sheet 6 in the single-sided metal clad laminate comes into contact with a heating roll 13 used in vapor deposition (hereinafter sometimes refers to as ""vapor deposition-applied heating roll""). In other words, the liquid crystal polymer film 2 in the single-sided metal clad laminate does not come into contact with the vapor deposition-applied heating roll 13, but is introduced in such a way that the surface of the liquid crystal polymer film 2 is directed to the opposite side of the vapor deposition-applied heating roll 13. Thereafter, onto the single-sided metal clad laminate 19 introduced to the vapor deposition-applied heating roll 13, a metal vapor deposition layer (a copper vapor deposition layer) is formed on the liquid crystal polymer film 2 that is outward of the vapor deposition-applied heating roll 13. The formation of the metal vapor deposition layer is performed by irradiating an electron beam from an electron gun 18 onto a vapor deposition source-containing crucible 17 that is disposed below the vapor deposition-applied heating roll 13 to heat the vapor deposition source. Then the double-sided metal clad laminate 21 in which the metal vapor deposition layer is formed is guided by a guide roll 16 and is wound by a winding roll 14. The resultant double-sided metal clad laminate has a laminate structure in which the metal sheet layer, the thermoplastic liquid crystal polymer film layer, and the metal vapor deposition layer are laminated in this order.', 'Formation of a copper vapor deposition layer will be explained with referring to FIG2. A roll-to-roll processing using a vacuum vapor deposition apparatus (produced by ROCK GIKEN KOGYO Co., Ltd. under a name of RVC-W-300) was employed to form a copper vapor deposition layer (thickness: 0.3 µm) on the surface of the liquid crystal polymer film 2 of the above single-sided metal clad laminate 19.']",57,731,schematic view,B,"[{'element_identifier': '19', 'terms': ['single-sided metal clad laminate']}, {'element_identifier': '12', 'terms': ['unwinding roll']}, {'element_identifier': '22', 'terms': ['unwinding roll']}, {'element_identifier': '1', 'terms': ['Examples', 'Example']}, {'element_identifier': '2', 'terms': ['Examples', 'Example']}, {'element_identifier': '20', 'terms': ['preferably about', 'from', 'acid units']}, {'element_identifier': '15', 'terms': ['-']}, {'element_identifier': '21', 'terms': ['double-sided metal clad laminate']}, {'element_identifier': '3', 'terms': ['Examples']}]","['5. A method for producing a metal clad laminate comprising a thermoplastic liquid crystal polymer film and a metal sheet bonded to a surface of the thermoplastic liquid crystal polymer film via a roll-to-roll processing, the method at least comprising: providing a thermoplastic liquid crystal polymer film and a metal sheet; and introducing the thermoplastic liquid crystal polymer film and the metal sheet between a pair of heating rolls so as to laminate the thermoplastic liquid crystal polymer film and the metal sheet between the pair of heating roll, wherein the pair of heating rolls at least comprises a metal elastic roll on a side that comes into contact with the thermoplastic liquid crystal polymer film, and the metal elastic roll surface has a ten-point average roughness Rz of 0.2 µm or lower.', '8. The method for producing a metal clad laminate according to any one of claims 5 to 7, wherein the metal elastic roll is constituted from a roll of heat-resistant rubber and a metal surface layer formed around the roll.']",True,"['1', '22', '19', '2', '20', '12', '21', '15', '3', '21']" 905,EP_3608127_A1.png,EP3608127A1,PNEUMATIC TIRE,['FIG2'],['FIG2 shows an exemplary enlarged view of a shoulder land portion 4s of the tread portion 2 of FIG1 '],"['FIG2 shows an enlarged view of the shoulder land portion 4s. As shows in FIG2, the shoulder land portion 4s is located tire axially outward (tire widthwise outward) of the main shoulder groove 3s.', 'The tire circumferential distance between the tire circumferentially adjacent horizontal shoulder grooves 30 and 30 is in the range of 20 to 60% of the tread width in order to improve handling stability. The tire circumferential distance between the tire circumferentially adjacent horizontal shoulder grooves means the distance between the horizontal shoulder grooves adjacent to each other in the tire circumferential direction at the tread contact edge. It corresponds to l30 in FIG2.']",19,117,view,B,"[{'element_identifier': '31', 'terms': ['first portion']}, {'element_identifier': '30', 'terms': ['horizontal shoulder grooves', 'horizontal shoulder groove']}, {'element_identifier': '32', 'terms': ['second portion']}]","['1. A pneumatic tire, comprising a tread portion, the tread portion comprising at least three main circumferential grooves extending in a circumferential direction of the tire and at least four land portions separated by the main circumferential grooves and including shoulder land portions located on axially outermost sides of the tire, at least one of the shoulder land portions comprising horizontal shoulder grooves extending in an axis direction of the tire, each horizontal shoulder groove having, in a tread contact area, a tire axial length of 10 to 30% of a tread width and a tire circumferential distance between the adjacent horizontal shoulder grooves of 20 to 60% of the tread width, the shoulder land portions comprising a rubber composition containing, per 100 parts by mass of a rubber component therein, at least 40 parts by mass of carbon black and at least 30 parts by mass of silica.']",True,"['32', '30', '131', '30', '32', '30', '31', '30', '130', '30', '14']" 906,EP_3608142_A1 (1).png,EP3608142A1,FOUR-WHEEL DRIVE VEHICLE CLUTCH CONTROL METHOD AND CLUTCH CONTROL DEVICE,['FIG3'],['FIG3 is a perspective view and an action schematic view showing a cam mechanism in the electronically controlled ball-cam-type coupling'],"['An action for engaging the electronically controlled ball-cam-type coupling 10 is described below on the basis of FIG3. First, when a coil current is made to flow to the 4WD solenoid 24 by the solenoid command current from the 4WD controller 16, a magnetic field is generated around the 4WD solenoid 24 and an armature 30 is caused to be drawn toward the control clutch 31. Friction torque is generated by the control clutch 31 upon being pressed by the armature 30 drawn thereto, and the friction torque generated by the control clutch 31 is transmitted to the control cam 32 of the cam mechanism to become a circumferential-direction binding force F1. The circumferential-direction binding force F1 applied to the control cam 32 is amplified and converted to an axial-direction clutch pressing force F2 via the cam grooves 36, 36 and the balls 34, and the main cam 33 is pressed frontward. Thus, due to the clutch pressing force F2 from the main cam 33 pressing and engaging the main clutch 35, clutch engagement torque that is proportional to the solenoid command current is generated in the main clutch 35. The clutch engagement torque generated in the main clutch 35 is transmitted to the rear differential 11 through the coupling output shaft 28.']",24,236,perspective view,B,"[{'element_identifier': '28', 'terms': ['coupling output shaft']}, {'element_identifier': '17', 'terms': ['mode-switching switch']}, {'element_identifier': '35', 'terms': ['main clutch']}, {'element_identifier': '30', 'terms': ['armature']}, {'element_identifier': '34', 'terms': ['balls']}, {'element_identifier': '33', 'terms': ['main cam']}, {'element_identifier': '10', 'terms': ['coupling']}, {'element_identifier': '29', 'terms': ['coupling housing']}, {'element_identifier': '36', 'terms': ['cam grooves']}, {'element_identifier': '31', 'terms': ['control clutch']}, {'element_identifier': '32', 'terms': ['control cam']}]","['3. The four-wheel-drive vehicle clutch control method as claimed in claim 1 or 2, characterized in that the friction clutch is an electronically controlled ball-cam-type coupling; and when a shift-position-switching operation is performed between an advancing travel shift position and a reversing travel shift position while the vehicle is stopped, reducing the initial torque that had been applied before the shift-position-switching operation to or below a prescribed value.']",True,"['10', '29', '30', '31', '28', '35', '33', '34', '32', '33', '32', '33', '34', '32', '34', '36', '36', '36', '17']" 907,EP_3608178_A2 (1).png,EP3608178A2,WEBBING TAKE-UP DEVICE,['FIG2'],['FIG2 is an enlarged perspective view illustrating a locking mechanism of a webbing take-up device of an exemplary embodiment'],"['As illustrated in FIG2, the rotatable locking section 20 is formed from a metal material. The rotatable locking section 20 is formed in a substantially half-moon shape as viewed along the axial direction. A circular support hole 20A is formed penetrating a central portion, including the center of gravity, of the rotatable locking section 20 in the axial direction. The rotatable locking section 20 is fixed to one axial direction side end portion of the spool 14 at a portion at the radial direction outer side of the rotation axis (center of rotation) of the spool 14 through a support pin 28 inserted through the support hole 20A. Two main engaging teeth 20B that engage with the fixed locking section 22, described later, are formed to an outer peripheral portion of one circumferential direction side (pull-out direction side) end portion of the rotatable locking section 20. The main engaging tooth 20B on the side closer to the support pin 28 is formed with a sub engaging tooth 20C on the other axial direction side (the opposite side to the arrow Z). A portion on one circumferential direction side of the sub engaging tooth 20C projects toward the one circumferential direction side with respect to the main engaging tooth 20B on the side closer to the support pin 28. In the present exemplary embodiment, the thickness (axial direction dimension) of the main engaging teeth 20B is set thicker than the thickness (axial direction dimension) of the sub engaging tooth 20C. Moreover, the rectangular block shaped permanent magnet 24 is fixed to an inner peripheral portion of an end portion on the one circumferential direction side (pull-out direction side) of the rotatable locking section 20.', 'The rotatable locking section has a divided structure configured of the first rotatable locking section 52 and the second rotatable locking section 54, thereby enabling the respective weights of the first rotatable locking section 52 and the second rotatable locking section 54 to be reduced in comparison to the rotatable locking section 20 (see FIG2) described above. This thereby enables the kinetic energy of the first rotatable locking section 52 and the second rotatable locking section 54 as the spool 14 is rotated to be reduced. This thereby enables the impact when the second rotatable locking section 54 engages with the second fixed locking section 32 to be lessened, and also enables the impact when the first rotatable locking section 52 engages with the first fixed locking section 30 to be lessened.']",21,455,enlarged perspective view,B,"[{'element_identifier': '24', 'terms': ['permanent magnet']}, {'element_identifier': '28', 'terms': ['support pin']}, {'element_identifier': '14', 'terms': ['spool']}, {'element_identifier': '30', 'terms': ['first fixed locking section']}, {'element_identifier': '22', 'terms': ['fixed locking section']}, {'element_identifier': '18', 'terms': ['locking mechanism', 'locking mechanisms']}, {'element_identifier': '20', 'terms': ['rotatable locking section']}, {'element_identifier': '16', 'terms': ['frame']}, {'element_identifier': '32', 'terms': []}]","['1. A webbing take-up device (10) comprising: a spool (14) that takes up a webbing (12) worn by an occupant and that is rotated in a pull-out direction by the webbing being pulled out; a rotatable locking section (20) that is provided so as to be rotatable as a unit together with the spool and so as to be displaceable in a rotation-radial direction of the spool; a fixed locking section (22) that is provided at an outer side of the rotatable locking section in the rotation-radial direction of the spool, and that the rotatable locking section engages with resulting in pull-out direction rotation of the spool being locked; a restricting section (24, 26) that restricts displacement of the rotatable locking section toward the fixed locking section; and a displacement section (24, 26) that is actuated in a vehicle emergency so as to displace the rotatable locking section toward the fixed locking section against the restriction of displacement of the rotatable locking section by the restricting section, a restricting force of the rotatable locking section by the restricting section being set such that the rotatable locking section is displaced toward the fixed locking section by an inertial force that spins the rotatable locking section about its own center of rotation when the displacement section is deactivated and the spool has been rotated in the pull-out direction with an angular acceleration greater than a predetermined angular acceleration.', '2. The webbing take-up device of claim 1, wherein: the restricting section and the displacement section include: a permanent magnet (24) fixed to the rotatable locking section, and an electromagnet (26) formed from a magnetic material and including a core (24) disposed opposite the permanent magnet and a coil (36) disposed around the core; displacement of the rotatable locking section toward the fixed locking section is restricted by a magnetic force of the permanent magnet attracting the core; and the rotatable locking section is displaced toward the fixed locking section by a current being passed through the coil in one direction such that a magnetic force of repulsion from the permanent magnet is generated in the core.', '8. The webbing take-up device of claim 7, wherein: the fixed locking section includes a first fixed locking section (30) and a second fixed locking section (32) adjacent to each other in a rotation axis direction of the spool; the terminal portion is provided at the first fixed locking section; and the leading end portion is provided at the second fixed locking section.']",False,"['30', '32', '14', '22', '18', '16', '20', '28', '24']" 908,EP_3608190_A1 (5).png,EP3608190A1,VEHICLE DRIVING ASSIST APPARATUS,['FIG6'],"['FIG6 is a view for showing candidate collision avoidance paths used for avoiding a collision of the vehicle with an obstacle ', 'FIG6 is a view for showing candidate collision avoidance paths used for avoiding a collision of the vehicle with an obstacle']","['When the driving assist ECU 10 determines that there is the high possibility that the own vehicle 100 collides with the obstacle, the driving assist ECU 10 calculates a target collision avoidance path with the predetermined calculation cycle. The target collision avoidance path is a path along which the own vehicle 100 should move for avoiding the collision of the own vehicle 100 with the obstacle. For example, as shown in FIG6, the driving assist ECU 10 specifies a predicted movement path A. The predicted movement path A is a path along which the own vehicle 100 predictively moves, assuming that the own vehicle 100 moves with maintaining the movement condition of the own vehicle 100 at the present movement condition. In addition, the driving assist ECU 10 specifies a predicted movement path B1. The predicted movement path B1 is a path along which the own vehicle 100 predictively moves with a lateral acceleration acquired by adding a maximum lateral force change amount ΔGy to the present lateral acceleration Gy0 of the own vehicle 100. The maximum lateral force change amount ΔGy is a maximum change amount of a lateral force which turns the own vehicle 100 safely at the present movement speed of the own vehicle 100. In addition, the driving assist ECU 10 specifies a predicted movement path B2. The predicted movement path B2 is a path along which the own vehicle 100 predictively moves with a lateral acceleration acquired by subtracting the maximum lateral force change amount ΔGy from the present lateral acceleration Gy0 of the own vehicle 100. ', 'When the driving assist ECU 10 determines that there is the high possibility that the own vehicle 100 collides with the obstacle, the driving assist ECU 10 calculates a target collision avoidance path with the predetermined calculation cycle. The target collision avoidance path is a path along which the own vehicle 100 should move for avoiding the collision of the own vehicle 100 with the obstacle. For example, as shown in FIG6, the driving assist ECU 10 specifies a predicted movement path A. The predicted movement path A is a path along which the own vehicle 100 predictively moves, assuming that the own vehicle 100 moves with maintaining the movement condition of the own vehicle 100 at the present movement condition. In addition, the driving assist ECU 10 specifies a predicted movement path B1. The predicted movement path B1 is a path along which the own vehicle 100 predictively moves with a lateral acceleration acquired by adding a maximum lateral force change amount ΔGy to the present lateral acceleration Gy0 of the own vehicle 100. The maximum lateral force change amount ΔGy is a maximum change amount of a lateral force which turns the own vehicle 100 safely at the present movement speed of the own vehicle 100. In addition, the driving assist ECU 10 specifies a predicted movement path B2. The predicted movement path B2 is a path along which the own vehicle 100 predictively moves with a lateral acceleration acquired by subtracting the maximum lateral force change amount ΔGy from the present lateral acceleration Gy0 of the own vehicle 100.']",42,552,view,B,"[{'element_identifier': '100', 'terms': ['vehicle']}]",['1. A vehicle driving assist apparatus comprising: at least one sensor (40) to detect an obstacle existing around a vehicle (100) to which the vehicle driving assist apparatus is applied; and an electronic control unit (10) configured to: start an execution of a collision avoidance steering assist control to automatically steer the vehicle (100) to avoid a collision of the vehicle (100) with the detected obstacle in response to a driver of the vehicle (100) performing a collision avoidance steering operation for steering the vehicle (100) for avoiding the collision of the vehicle (100) with the detected obstacle when there is a possibility that the vehicle (100) collides with the detected obstacle; cancel the execution of the collision avoidance steering assist control in response to the driver performing a counter collision avoidance steering operation for steering the vehicle (100) against automatically steering the vehicle (100) intended to be achieved by the collision avoidance steering assist control after a first predetermined time elapses from starting the execution of the collision avoidance steering assist control; and continue the execution of the collision avoidance steering assist control until the first predetermined time elapses from starting the execution of the collision avoidance steering assist control even when the driver performs the counter collision avoidance steering operation.'],True,"['100', '23']" 909,EP_3608190_A1 (6).png,EP3608190A1,VEHICLE DRIVING ASSIST APPARATUS,['FIG7'],"['FIG7 is a plan view for showing white lane markings LL and LR, a side distance Ds, and a yaw angel θy used in executing a lane return steering assist control ', 'FIG7 is a plan view for showing white lane markings LL and LR, a side distance Ds, and a yaw angel θy used in executing a lane return steering assist control ']","['The driving assist ECU 10 realizes the positional relationship of the own vehicle 100 relative to the original movement lane, based on the object information sent from the at least one surrounding sensor 40. As shown in FIG7, the driving assist ECU 10 acquires a yaw angle θy and side distances Ds used for executing the lane return steering assist control. The yaw angle θy is a gap angle between the direction of the extension of the original movement lane and the movement direction of the own vehicle 100. One of the side distances Ds is a distance from a reference point P of the own vehicle 100 to the left white lane marking LL. The other side distance Ds is a distance from the reference point P of the own vehicle 100 to the right white lane marking LR. In this embodiment, the reference point P locates at the center position of the front end of the own vehicle 100. In this regard, the reference point P is not limited to the center position of the front end of the own vehicle 100. The driving assist ECU 10 selects one of the side distances Ds from the reference point P to one of the white lane markings, which the own vehicle 100 is likely to cross. In other words, the driving assist ECU 10 selects one of the side distances Ds from the reference point P to one of the white lane markings, toward which the own vehicle 100 moves. In addition, the driving assist ECU 10 acquires a curvature v of the original movement lane from the at least one surrounding sensor 40. In other words, the driving assist ECU 10 acquires an inverse number of a road radius R of the original movement lane from the at least one surrounding sensor 40. ', 'The driving assist ECU 10 realizes the positional relationship of the own vehicle 100 relative to the original movement lane, based on the object information sent from the at least one surrounding sensor 40. As shown in FIG7, the driving assist ECU 10 acquires a yaw angle θy and side distances Ds used for executing the lane return steering assist control. The yaw angle θy is a gap angle between the direction of the extension of the original movement lane and the movement direction of the own vehicle 100. One of the side distances Ds is a distance from a reference point P of the own vehicle 100 to the left white lane marking LL. The other side distance Ds is a distance from the reference point P of the own vehicle 100 to the right white lane marking LR. In this embodiment, the reference point P locates at the center position of the front end of the own vehicle 100. In this regard, the reference point P is not limited to the center position of the front end of the own vehicle 100. The driving assist ECU 10 selects one of the side distances Ds from the reference point P to one of the white lane markings, which the own vehicle 100 is likely to cross. In other words, the driving assist ECU 10 selects one of the side distances Ds from the reference point P to one of the white lane markings, toward which the own vehicle 100 moves. In addition, the driving assist ECU 10 acquires a curvature v of the original movement lane from the at least one surrounding sensor 40. In other words, the driving assist ECU 10 acquires an inverse number of a road radius R of the original movement lane from the at least one surrounding sensor 40.']",66,650,plan view,B,"[{'element_identifier': '100', 'terms': ['vehicle']}]",['1. A vehicle driving assist apparatus comprising: at least one sensor (40) to detect an obstacle existing around a vehicle (100) to which the vehicle driving assist apparatus is applied; and an electronic control unit (10) configured to: start an execution of a collision avoidance steering assist control to automatically steer the vehicle (100) to avoid a collision of the vehicle (100) with the detected obstacle in response to a driver of the vehicle (100) performing a collision avoidance steering operation for steering the vehicle (100) for avoiding the collision of the vehicle (100) with the detected obstacle when there is a possibility that the vehicle (100) collides with the detected obstacle; cancel the execution of the collision avoidance steering assist control in response to the driver performing a counter collision avoidance steering operation for steering the vehicle (100) against automatically steering the vehicle (100) intended to be achieved by the collision avoidance steering assist control after a first predetermined time elapses from starting the execution of the collision avoidance steering assist control; and continue the execution of the collision avoidance steering assist control until the first predetermined time elapses from starting the execution of the collision avoidance steering assist control even when the driver performs the counter collision avoidance steering operation.'],True,"['100', '24']" 910,EP_3608209_A1 (2).png,EP3608209A1,FASTENING STRUCTURE FOR VEHICULE,['FIG3'],['FIG3 is a bottom view of the mount portion in FIG2'],"['FIG3 is a bottom view (to the positive direction along the U axis) of FIG2. In FIG3, the upper member 40 and the weld bead 46 are omitted.', 'As shown in FIG3, the collar 50 is inserted in the insertion hole 42a formed in the lower member 42. The outer diameter of the flange 54 that extends around the cylindrical portion 52 of the collar 50 is larger than the diameter of the insertion hole 42a. The flange 54 is disposed to be partially overlapped with the lower member 42. The outer circumference of the flange 54 and the lower member 42 are secured together by arc welding such that the weld bead 62 lies between them. As shown in FIG3, the weld bead 62 is formed partially along the circumference of the flange 54. Specifically, welding is applied at two portions in angle ranges θa and θb (radians) about the cylindrical axis. The length L2 of the weld bead 62 can be approximately obtained by the following Equation (2): L2=θa+θb×D/2 where D is the outer diameter of the flange 54.', 'In the embodiment shown in FIG3, welding is applied so that the welding strength on the flange 54 side is higher than the welding strength on the cylindrical portion 52 side. In general, the welding strength increases with increasing cross sectional area of the welded portion. In the arc welding according to the present embodiment, because the cross sectional area of the welded portion is proportional to the welded length, the welded length L1 represented by Equation (1) and the welded length L2 represented by Equation (2) are set to satisfy the following relationship: L1