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	arXiv:1001.0034v1 [math.NT] 4 Jan 2010NEW IDENTITIES INVOLVING q-EULER
	POLYNOMIALS OF HIGHER ORDER
	T. Kim AND Y. H. Kim
	Abstract. In this paper, we present new generating functions which are relat ed to
	q-Euler numbers and polynomials of higher order. From these genera ting functions, we
	give new identities involving q-Euler numbers and polynomials of higher order.
	§1. Introduction/ Preliminaries
	LetCbe the complex number ﬁeld. We assume that q∈Cwith\|q\|<1 and
	theq-number is deﬁned by [ x]q=1−qx
	1−qin this paper. The q-factorial is given by
	[n]q! = [n]q[n−1]q···[2]q[1]qand theq-binomial formulae are known that
	(x:q)n=n/productdisplay
	i=1(1−xqi−1) =n/summationdisplay
	i=0/parenleftbiggn
	i/parenrightbigg
	qq(i
	2)(−x)i,(see [3, 14, 15]) ,
	and
	1
	(x:q)n=n/productdisplay
	i=1/parenleftbigg1
	1−xqi−1/parenrightbigg
	=∞/summationdisplay
	i=0/parenleftbiggn+i−1
	i/parenrightbigg
	qxi,(see [3, 5, 14, 15]) ,
	where/parenleftbign
	i/parenrightbig
	q=[n]q!
	[n−i]q![i]q!=[n]q[n−1]q···[n−i+1]q
	[i]q!.
	The Euler polynomials are deﬁned by2
	et+1ext=/summationtext∞
	n=0En(x)tn
	n!, for\|t\|< π. In the
	special case x= 0,En(=En(0)) are called the n-th Euler numbers. In this paper, we
	consider the q-extensions of Euler numbers and polynomials of higher orde r. Barnes’
	multiple Bernoulli polynomials are also deﬁned by
	(1)
	tr
	/producttextr
	j=1(eajt−1)ext=∞/summationdisplay
	n=0Bn(x,r\|a1,···,ar)tn
	n!,where\|t\|<max
	1≤i≤r2π
	\|ai\|, (see [1, 14]).
	Key words and phrases. : multiple q-zeta function, q-Euler numbers and polynomials, higher
	order q-Euler numbers, Laurent series, Cauchy integral.
	2000 AMS Subject Classiﬁcation: 11B68, 11S80
	The present Research has been conducted by the research Grant of Kw angwoon University in 2010
	Typeset by AMS-TEX
	1In one of an impressive series of papers (see [1, 6, 14]), Barn es developed the so-called
	multiple zeta and multiple gamma function. Let a1,···,aNbe positive parameters.
	Then Barnes’ multiple zeta function is deﬁned by
	ζN(s,w\|a1,···,aN) =/summationdisplay
	m1,···,mN=0(w+m1a1+···+mNaN)−s,(see [1]),
	whereℜ(s)> N,ℜ(w)>0. Form∈Z+, we have
	ζN(−m,w\|a1,···,aN) =(−1)mm!
	(N+m)!BN+m(w,N\|a1,···,aN).
	In this paper, we consider Barnes’ type multiple q-Euler numbers and polynomials.
	The purpose of this paper is to present new generating functi ons which are related
	toq-Euler numbers and polynomials of higher order. From the Mel lin transformation
	of these generating functions, we derive the q-extensions o f Barnes’ type multiple
	zeta functions, which interpolate the q-Euler polynomials of higher order at negative
	integer. Finally, we give new identities involving q-Euler numbers and polynomials of
	higher order.
	§2.q-Euler numbers and polynomials of higher order
	In this section, we assume that q∈Cwith\|q\|<1. Letx,a1,... ,a rbe complex
	numbers with positive real parts. Barnes’ type multiple Eul er polynomialsare deﬁned
	by
	(2)2r
	/producttextr
	j=1(eajt+1)ext=∞/summationdisplay
	n=0E(r)
	n(x\|a1,... ,a r)tn
	n!,for\|t\|<max
	1≤i≤rπ
	\|wi\|,(see [6]),
	andE(r)
	n(a1,... ,a r)(=E(r)
	n(0\|a1,... ,a r)) are called the n-th Barnes’ type multiple
	Euler numbers. First, we consider the q-extension of Euler polynomials. The q-Euler
	polynomials are deﬁned by
	(3)Fq(t,x) =∞/summationdisplay
	n=0En,q(x)tn
	n!= [2]q∞/summationdisplay
	m=0(−q)me[m+x]qt,(see [8, 11, 13, 14, 15]) .
	From (3), we have
	En,q(x) =[2]q
	(1−q)nn/summationdisplay
	l=0/parenleftbiggn
	l/parenrightbigg(−1)lqlx
	(1+ql+1).
	In the special case x= 0,En,q(=En,q(0)) are called the n-thq-Euler numbers. From
	(3), we can easily derive the following relation.
	E0,q= 1,andq(qE+1)n+En,q= 0 ifn≥1,(see [8, 16, 17]) ,
	2where we use the standard convention about replacing EkbyEk,q.It is easy to show
	that
	lim
	q→1Fq(t,x) =2
	et+1ext=∞/summationdisplay
	n=0En(x)tn
	n!,(see [2, 3, 19-23]) ,
	whereEn(x) are the n-th Euler polynomials. For r∈N, the Euler polynomials of
	orderris deﬁned by
	(4)/parenleftbigg2
	et+1/parenrightbiggr
	ext=∞/summationdisplay
	n=0E(r)
	n(x)tn
	n!,for\|t\|< π.
	Now we consider the q-extension of (4).
	(5)F(r)
	q(t,x) = [2]r
	q∞/summationdisplay
	m1,...,m r=0(−q)m1+···+mre[m1+···+mr+x]qt=∞/summationdisplay
	n=0E(r)
	n,q(x)tn
	n!,
	whereE(r)
	n,q(x) are called the n-thq-Euler polynomials of order r(see [10-15]). From
	(5), we can derive
	(6) E(r)
	n,q(x) =[2]r
	q
	(1−q)nn/summationdisplay
	l=0/parenleftbiggn
	l/parenrightbigg(−1)lqlx
	(1+ql+1)r.
	By (5) and (6), we see that
	(7) F(r)
	q(t,x) = [2]r
	q∞/summationdisplay
	m=0/parenleftbiggm+r−1
	m/parenrightbigg
	(−q)me[m+x]qt.
	Thus, we note that lim q→1F(r)
	q(t,x) =/parenleftBig
	2
	et+1/parenrightBigr
	ext=/summationtext∞
	n=0E(r)
	n(x)tn
	n!.In the special
	casex= 0,E(r)
	n,q(=E(r)
	n,q(0)) are called the n-thq-Euler numbers of order r. By (5),
	(6) and (7), we obtain the following proposition.
	Proposition 1. Forr∈N, let
	F(r)
	q(t,x) = [2]r
	q/summationdisplay
	m1,...,m r=0(−q)m1+···+mre[m1+···+mr+x]qt=∞/summationdisplay
	n=0E(r)
	n,q(x)tn
	n!.
	Then we have
	E(r)
	n,q(x) =[2]r
	q
	(1−q)nn/summationdisplay
	l=0/parenleftbiggn
	l/parenrightbigg(−1)lqlx
	(1+ql+1)r= [2]r
	q∞/summationdisplay
	m=0/parenleftbiggm+r−1
	m/parenrightbigg
	(−q)m[m+x]n
	q.
	3From the Mellin transformation of F(r)
	q(t,x), we can derive the following equation.
	1
	Γ(s)/integraldisplay∞
	0F(r)
	q(−t,x)ts−1dt= [2]r
	q∞/summationdisplay
	m1,...,m r=0(−q)m1+···+mr
	[m1+···+mr+x]sq
	= [2]r
	q∞/summationdisplay
	m=0/parenleftbiggm+r−1
	m/parenrightbigg
	(−q)m1
	[m+x]sq, (8)
	wheres∈C,x/negationslash= 0,−1,−2,.... By (8), we can deﬁne the multiple q-zeta function
	related to q-Euler polynomials.
	Deﬁnition 2. Fors∈C,x∈Rwithx/negationslash= 0,−1,−2,..., we deﬁne the multiple q-zeta
	function related to q-Euler polynomials as
	ζq,r(s,x) = [2]r
	q∞/summationdisplay
	m1,...,m r=0(−q)m1+···+mr
	[m1+···+mr+x]sq.
	Note that ζq,r(s,x) is a meromorphic function in whole complex s-plane. From (8),
	we also note that
	ζq,r(s,x) = [2]r
	q∞/summationdisplay
	m=0/parenleftbiggm+r−1
	m/parenrightbigg
	(−q)m1
	[m+x]sq.
	By Laurent series and the Cauchy residue theorem in (5) and (8 ), we see that
	ζq(−n,x) =E(n)
	n,q(x),forn∈Z+.
	Therefore, we obtain the following theorem.
	Theorem 3. Forr∈N,n∈Z+, andx∈Rwithx/negationslash= 0,−1,−2,..., we have
	ζq(−n,x) =E(r)
	n,q(x).
	Letχbe the Dirichlet’s character with conductor f∈Nwithf≡1 (mod 2). Then
	the generalized q-Euler polynomial attached to χare considered by
	Fq,χ(x) =∞/summationdisplay
	n=0En,χ,q(x)tn
	n!= [2]q∞/summationdisplay
	m=0(−q)mχ(m)e[m+x]qt.
	From (3) and (9), we have
	En,χ,q(x) =[2]q
	[2]qff−1/summationdisplay
	a=0(−q)aχ(a)En,qf(x+a
	f).
	4In the special case x= 0,En,χ,q=En,χ,q(0) are called the n-th generated q-Euler
	number attached to χ.
	It is known that the generalized Euler polynomials of order rare deﬁned by
	(10) (2/summationtextf−1
	a=0(−1)aχ(a)eat
	eft+1)rext=∞/summationdisplay
	n=0E(r)
	n,χ(x)tn
	n!,
	for\|t\|<π
	f.
	We consider the q-extension of (10). The generalized q-Euler polynomials of order
	rattached to χare deﬁned by
	F(r)
	q,χ(t,x) = [2]r
	q∞/summationdisplay
	m1,...,m r=0(−q)m1+···+mr(r/productdisplay
	i=1χ(mi))e[m1+···+mr+x]qt
	=∞/summationdisplay
	n=0E(r)
	n,χ,q(x)tn
	n!,(see [14, 15]) . (11)
	Note that
	lim
	q→1F(r)
	q,χ(t,x) = (2/summationtextf−1
	a=0(−1)aχ(a)eat
	eft+1)r.
	By (11), we easily see that
	E(r)
	n,χ,q(x) =[2]r
	q
	(1−q)nn/summationdisplay
	l=0/parenleftbiggn
	l/parenrightbigg
	(−qx)lf−1/summationdisplay
	a1,...,ar=0(r/productdisplay
	j=1χ(aj))(−ql+1)/summationtextr
	i=1ai
	(1+q(l+1)f)r
	= [2]r
	q∞/summationdisplay
	m1,...,m r=0(−q)m1+···+mr(r/productdisplay
	i=1χ(mi))[m1+···+mr+x]n
	q.
	Fors∈C,x∈Rwithx/negationslash= 0,−1,−2,..., we have
	1
	Γ(s)/integraldisplay∞
	0F(r)
	q,χ(−t,x)ts−1dt
	= [2]r
	q∞/summationdisplay
	m1,...,m r=0(−q)m1+···+mr(/producttextr
	i=1χ(mi))
	[m1+···+mr+x]sq,(see [15]) . (12)
	From (12), we can consider the Dirichlet’s type multiple q-l-function as follows :
	Deﬁnition 4. Fors∈C,x∈Rwithx/negationslash= 0,−1,−2,..., we deﬁne the Dirichlet’s
	type multiple q-l-function as
	lq(s,x\|χ) = [2]r
	q∞/summationdisplay
	m1,...,m r=0(−q)m1+···+mr(/producttextr
	i=1χ(mi))
	[m1+···+mr+x]sq,(see [15]) .
	By Laurent series and the Cauchy residue theorem in (11) and ( 12), we obtain the
	following theorem.
	5Theorem 5. Forn∈Z+, we have
	lq(−n,x\|χ) =E(r)
	n,χ,q(x).
	Forh∈Zandr∈N, we consider the extended r-pleq-Euler polynomials.
	F(h,r)
	q(t,x) = [2]r
	q∞/summationdisplay
	m1,...,m r=0q/summationtextr
	j=1(h−j+1)mj(−1)/summationtextr
	j=1mje[m1+···+mr+x]qt
	=∞/summationdisplay
	n=0E(h,r)
	n,q(x)tn
	n!. (13)
	Note that
	lim
	q→1F(h,r)
	q(t,x) = (2
	et+1)rext=∞/summationdisplay
	n=0E(r)
	n(x)tn
	n!.
	From (13), we note that
	E(h,r)
	n,q(x) =[2]r
	q
	(1−q)nn/summationdisplay
	l=0/parenleftbiggn
	l/parenrightbigg(−qx)l
	(−qh−r+l+1:q)r
	= [2]r
	q∞/summationdisplay
	m=0/parenleftbiggm+r−1
	m/parenrightbigg
	q(−qh−r+1)m[m+x]n
	q. (14)
	By (14), we easily see that
	(15)F(h,r)
	q(t,x) = [2]r
	q∞/summationdisplay
	m=0/parenleftbiggm+r−1
	m/parenrightbigg
	q(−qh−r+1)me[m+x]qt,(see [11, 13, 14]) .
	Using the Mellin transform for F(h,r)
	q(t,x), we have
	1
	Γ(s)/integraldisplay∞
	0F(r)
	q(−t,x)ts−1dt
	= [2]r
	q∞/summationdisplay
	m1,...,m r=0(−1)m1+···+mrq/summationtextr
	j=1(h−j+1)mj
	[m1+···+mr+x]sq,(see [13, 14, 15]) ,(16)
	fors∈C,x∈Rwithx/negationslash= 0,−1,−2,.... Now we can deﬁne the extended q-zeta
	function associated with E(h,r)
	n,q(x).
	6Deﬁnition 6. Fors∈C,x∈Rwithx/negationslash= 0,−1,−2,..., we deﬁne the (h, q)-zeta
	function as
	ζ(h)
	q,r(s,x) = [2]r
	q∞/summationdisplay
	m1,...,m r=0(−1)m1+···+mrq/summationtextr
	j=1(h−j+1)mj
	[m1+···+mr+x]sq.
	Notethat ζ(h)
	q,r(s,x)isalsoa meromorphic function inwholecomplex s-plane. From
	(16) and (15), we note that
	(17) ζ(h)
	q,r(s,x) = [2]r
	q∞/summationdisplay
	m=0/parenleftbiggm+r−1
	m/parenrightbigg
	q(−qh−j+1)m1
	[m+x]sq.
	Using the Cauchy residue theorem and Laurent series in (16), we obtain the following
	theorem.
	Theorem 7. Forn∈Z+, we have
	ζ(h)
	q,r(−n,x) =E(h,r)
	n,q(x).
	We consider the extended r-ple generalized q-Euler polynomials as follows :
	F(h,r)
	q,χ(t,x)
	= [2]r
	q∞/summationdisplay
	m1,...,m r=0q/summationtextr
	j=1(h−j+1)mj(−1)/summationtextr
	j=1mj(r/productdisplay
	j=1χ(mj))e[m1+···+mr+x]qt(18)
	=∞/summationdisplay
	n=0E(h,r)
	n,χ,q(x)tn
	n!.
	By (18), we see that
	E(h,r)
	n,χ,q(x) =[2]r
	q
	(1−q)nf−1/summationdisplay
	a1,...,ar=0(−1)/summationtextr
	j=1aj(r/productdisplay
	j=1χ(aj))n/summationdisplay
	l=0/parenleftbiggn
	l/parenrightbigg(−1)lqlxq(h−j+l+1)aj
	(−q(h−r+l+1)f:qf)r
	=[2]r
	q
	[2]r
	qf[f]n
	qf−1/summationdisplay
	a1,...,ar=0(−1)/summationtextr
	j=1aj(r/productdisplay
	j=1χ(aj))q/summationtextr
	j=1(h−j+1)ajζ(h)
	qf,r(−n,x+/summationtextr
	j=1aj
	f).(19)
	Therefore, we obtain the following theorem.
	7Theorem 8. Forn∈Z+, we have
	E(h,r)
	n,χ,q(x)
	=[2]r
	q
	[2]r
	qf[f]n
	qf−1/summationdisplay
	a1,...,ar=0(−1)/summationtextr
	j=1aj(r/productdisplay
	j=1χ(aj))q/summationtextr
	j=1(h−j+1)ajζ(h)
	qf,r(−n,x+/summationtextr
	j=1aj
	f).
	From (18), we note that
	1
	Γ(s)/integraldisplay∞
	0F(h,r)
	q,χ(−t,x)ts−1dt
	= [2]r
	q∞/summationdisplay
	m1,...,m r=0q/summationtextr
	j=1(h−j+1)mj(/producttextr
	j=1χ(mj))(−1)m1+···+mr
	[m1+···+mr+x]sq, (20)
	wheres∈C,x∈Rwithx/negationslash= 0,−1,−2,....
	From (20), we deﬁne the Dirichlet’s type multiple ( h,q)-l-function associated with
	the generalized multiple q-Euler polynomials attached to χ.
	Deﬁnition 9. Fors∈C,x∈Rwithx/negationslash= 0,−1,−2,..., we deﬁne the Dirichlet’s
	type multiple q-l-function as follows :
	l(h)
	q(s,x\|χ) = [2]r
	q∞/summationdisplay
	m1,...,m r=0q/summationtextr
	j=1(h−j+1)mj(/producttextr
	i=1χ(mi))(−1)m1+···+mr
	[m1+···+mr+x]sq.
	Note that l(h)
	q(s,x\|χ) is a meromorphic function in whole complex plane. It is easy
	to show that
	l(h)
	q(s,x\|χ)
	=[2]r
	q
	[2]r
	qf1
	[f]sqf−1/summationdisplay
	a1,...,ar=0(−1)/summationtextr
	j=1aj(r/productdisplay
	j=1χ(aj))q/summationtextr
	j=1(h−j+1)ajζ(h)
	qf,r(s,x+/summationtextr
	j=1aj
	f).
	By (19) and (20), we obtain the following theorem.
	Theorem 10. Forn∈Z+, we have
	l(h)
	q(−n,x\|χ) =E(h,r)
	n,χ,q(x).
	Finally, we give the q-extension of Barnes’ type multiple Euler polynomials in (2 ).
	Forx,a1,... ,a r∈Cwith positive real part, let us deﬁne the Barnes’ type mutipl e
	8q-Euler polynomials in Cas follows :
	F(r)
	q(t,x\|a1,... ,a r;b1,... ,b r)
	= [2]r
	q∞/summationdisplay
	m1,...,m r=0(−1)m1+···+mrq(b1+1)m1+···+(br+1)mre[a1m1+···+armr+x]t(21)
	=∞/summationdisplay
	n=0E(r)
	n,q(x\|a1,... ,a r;b1,... ,b r)tn
	n!,
	whereb1,... ,b r∈Z. By (21), we see that
	E(r)
	n,q(x\|a1,... ,a r;b1,... ,b r)
	=[2]r
	q
	(1−q)nn/summationdisplay
	l=0/parenleftbiggn
	l/parenrightbigg(−1)lqlx
	(1+qla1+b1+1)···(1+qlar+br+1)
	= [2]r
	q∞/summationdisplay
	m1,...,m r=0(−1)m1+···+mrq(b1+1)m1+···+(br+1)mr[a1m1+···+armr+x]n
	q.
	From (21), we note that
	1
	Γ(s)/integraldisplay∞
	0F(r)
	q(−t,x\|a1,... ,a r;b1,... ,b r)ts−1dt
	= [2]r
	q∞/summationdisplay
	m1,...,m r=0(−q)m1+···+mrqb1m1+···+brmr
	[a1m1+···+armr+x]sq. (22)
	By (22), we deﬁne the Barnes’ type multiple q-zeta function as follows :
	ζq,r(s,x\|a1,... ,a r;b1,... ,b r)
	= [2]r
	q∞/summationdisplay
	m1,...,m r=0(−q)m1+···+mrqb1m1+···+brmr
	[a1m1+···+armr+x]sq,
	wheres∈C,x∈Rwithx/negationslash= 0,−1,−2,.... By (21), (22) and (23), we obtain the
	following theorem.
	Theorem 11. Forn∈Z+, we have
	ζq,r(s,x\|a1,... ,a r;b1,... ,b r) =E(r)
	n,q(x\|a1,... ,a r;b1,... ,b r).
	Letχbe the Dirichlet’s character with conductor f∈Nwithf≡1 (mod 2). Then
	the generalized Barnes’ type multiple q-Euler polynomials attached to χare deﬁned
	9by
	F(r)
	q,χ(t,x\|a1,... ,a r;b1,... ,b r)
	= [2]r
	q∞/summationdisplay
	m1,...,m r=0(−q)m1+···+mrqb1m1+···+brmr(r/productdisplay
	i=1χ(mi))e[a1m1+···+armr+x]qt(24)
	=∞/summationdisplay
	n=0E(r)
	n,χ,q(x\|a1,... ,a r;b1,... ,b r)tn
	n!,
	From (24), we note that
	1
	Γ(s)/integraldisplay∞
	0F(r)
	q,χ(−t,x\|a1,... ,a r;b1,... ,b r)ts−1dt
	= [2]r
	q∞/summationdisplay
	m1,...,m r=0(−q)m1+···+mrqb1m1+···+brmr(/producttextr
	i=1χ(mi))
	[a1m1+···+armr+x]sq. (25)
	By (25), we can deﬁne Barnes’ type multiple q-l-function in C. Fors∈C,x∈Rwith
	x/negationslash= 0,−1,−2,..., let us deﬁne the Barnes’ type multiple q-l-function as follows :
	l(r)
	q(s,x\|a1,... ,a r;b1,... ,b r)
	= [2]r
	q∞/summationdisplay
	m1,...,m r=0(−q)m1+···+mrqb1m1+···+brmr(/producttextr
	i=1χ(mi))
	[a1m1+···+armr+x]sq. (26)
	Note that l(r)
	q(s,x\|a1,... ,a r;b1,... ,b r) is a meromorphic function in whole complex
	s-plane. By (24), (25) and (26), we easily see that
	l(r)
	q(−n,x\|a1,... ,a r;b1,... ,b r) =E(r)
	n,χ,q(x\|a1,... ,a r;b1,... ,b r)
	forn∈Z+, (see [1-18]).
	References
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	196(1904), 374-425.
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	Adv. Stud. Contemp. Math. 19(2009), 39–57.
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	[4] T. Kim, On aq-analogue of the p-adic log gamma functions and related integrals , J.Number
	Theory76(1999), 320–329.
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	10[7] T. Kim, Analytic continuation of multiple q-zeta functions and their values at negative
	integers, Russ. J. Math. Phys. 11(2004), 71–76.
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	45–50.
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	by the fermionic p-adic integral on Zp, Russ. J. Math. Phys. 16(2009), 1061-9208.
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	arXiv:0912.5477v1.
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	with Daehee numbers , Russ. J. Math. Phys. 15(2008), 58–65.
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	twistedq-Euler numbers , Proc. Jangjeon Math. Soc. 12(2009), 93-100.
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	its derivatives , Mem. Fac. Sci., Kyushu University Ser. A 39(1985), 113-125.
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	Contemp. Math. 11(2005), 205–218.
	[23] Z. Zhang, Y. Zhang, Summation formulas of q-series by modiﬁed Abel’s lemma , Adv. Stud.
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	Taekyun Kim
	Division of General Education-Mathematics, Kwangwoon Uni versity,
	Seoul 139-701, S. Korea e-mail: tkkim@kw.ac.kr
	Young-Hee Kim
	Division of General Education-Mathematics,
	Kwangwoon University,
	Seoul 139-701, S. Korea e-mail: yhkim@kw.ac.kr
	11