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	arXiv:1001.0001v1 [cs.IT] 30 Dec 2009On the structure of non-full-rank perfect codes
	Olof Heden and Denis S. Krotov∗
	Abstract
	The Krotov combining construction of perfect 1-error-corr ecting binary codes
	from 2000 and a theorem of Heden saying that every non-full-r ank perfect 1-error-
	correcting binary code can be constructed by this combining construction is gener-
	alized to the q-ary case. Simply, every non-full-rank perfect code Cis the union of
	a well-deﬁned family of ¯ µ-components K¯µ, where ¯µbelongs to an “outer” perfect
	codeC⋆, and these components are at distance three from each other. Compo-
	nents from distinct codes can thus freely be combined to obta in new perfect codes.
	The Phelps general product construction of perfect binary c ode from 1984 is gen-
	eralized to obtain ¯ µ-components, and new lower bounds on the number of perfect
	1-error-correcting q-ary codes are presented.
	1. Introduction
	LetFqdenote the ﬁnite ﬁeld with qelements. A perfect1-error-correcting q-ary code of
	lengthn, for short here a perfect code , is a subset Cof the direct product Fn
	q, ofncopies of
	Fq, having the property that any element of Fn
	qdiﬀers in at most one coordinate position
	from a unique element of C.
	The family of all perfect codes is far from classiﬁed or enumerated. We will in this
	short note say something about the structure of these codes. W e need the concept of
	rank.
	We consider Fn
	qas a vector space of dimension nover the ﬁnite ﬁeld Fq. Therank
	of aq-ary codeC, here denoted rank( C), is the dimension of the linear span < C >of
	the elements of C. Trivial, and well known, counting arguments give that if there exist s
	a perfect code in Fn
	qthenn= (qm−1)/(q−1), for some integer m, and\|C\|=qn−m. So,
	for every perfect code C,
	n−m≤rank(C)≤n.
	If rank(C) =nwe will say that Chasfull rank.
	∗This research collaboration was partially supported by a grant from Swedish Institute; the work of
	the second author was partially supported by the Federal Target Program “Scientiﬁc and Educational
	PersonnelofInnovation Russia”for 2009-2013(governmentco ntract No. 02.740.11.0429)and the Russian
	Foundation for Basic Research (grant 08-01-00673).
	1We will show thatevery non-full-rankperfect code isa unionofso ca lled ¯µ-components
	K¯µ, and that these components may be enumerated by some other pe rfect codeC⋆, i.e,
	¯µ∈C⋆. Further, the distance between any two such components will be a t least three.
	This implies that we will be completely free to combine ¯ µ-components from diﬀerent
	perfect codesofsamelength, toobtainotherperfect codes. Ge neralizing aconstruction by
	Phelps of perfect 1-error correcting binary codes [8], we will obtain further ¯µ-components.
	As an application of our results we will be able to slightly improve the lowe r bound on
	the number of perfect codes given in [6].
	Our results generalize corresponding results for the binary case. In [3] it was shown
	that a binary perfect code can be constructed as the union of diﬀe rent subcodes (¯ µ-
	components) satisfying some generalized parity-check property , each of them being con-
	structed independently or taken from another perfect code. In [2] it was shown that every
	non-full-rank perfect binary code can be obtained by this combining construction.
	2. Every non-full-rank perfect code is the union of ¯µ-
	components
	We start with some notation. Assume we have positive integers n,t,n1, ...,ntsuch that
	n1+...+nt≤n. Anyq-aryword ¯xwill berepresented intheblockform ¯ x= (¯x1\|¯x2\|...\|
	¯xt\|¯x0) = (¯x∗\|¯x0), where ¯xi= (xi1,xi2,...,x ini),i= 0,1,...,t,n0=n−n1−...−nt,
	¯x∗= (¯x1\|¯x2\|...\|¯xt). For every block ¯ xi,i= 1,2,...,t, we deﬁne σi(¯xi) by
	σi(¯xi) =ni/summationdisplay
	j=1xij,
	and, for ¯x,
	¯σ(¯x) = ¯σ(¯x∗) = (σ1(¯x1),σ2(¯x2),...,σ t(¯xt))
	Recall that the Hamming distance d(¯x,¯y) between two words ¯ x, ¯yof the same length
	means the number of positions in which they diﬀer.
	Amonomial transformation is a map of the space Fn
	qthat can be composed by a
	permutation of the set of coordinate positions and the multiplication in each coordinate
	position with some non-zero element of the ﬁnite ﬁeld Fq.
	Aq-ary codeCislinearifCis a subspace of Fn
	q. A linear perfect code is called a
	Hamming code .
	Theorem 1. LetCbe any non-full-rank perfect code Cof lengthn= (qm−1)/(q−1).
	To any integer r<m, satisfying
	1≤r≤n−rank(C),
	there is aq-ary Hamming code C⋆of lengtht= (qr−1)/(q−1), such that for some
	monomial transformation ψ
	ψ(C) =/uniondisplay
	¯µ∈C⋆K¯µ,
	2where
	K¯µ={(¯x1\|¯x2\|...\|¯xt\|¯x0) : ¯σ(¯x) = ¯µ,¯x1,¯x2,...,¯xt∈Fqs
	q,¯x0∈C¯µ(¯x∗)}(1)
	for some family of perfect codes C¯µ(¯x), of length 1+q+q2+...+qs−1, wheres=m−r,
	and satisfying, for each ¯µ∈C⋆,
	d(¯x∗,¯x′
	∗)≤2 =⇒C¯µ(¯x∗)∩C¯µ(¯x′
	∗) =∅. (2)
	The codeC⋆will be called an outercode toψ(C). The subcodes K¯µwill be called
	¯µ-components ofψ(C). As the minimum distance of Cis three, the distance between any
	two distinct ¯ µ-components will be at least three.
	Proof. LetDbe any subspace of Fn
	qcontaining<C >, and of dimension n−r. By
	using a monomial transformation ψof space we may achieve that the dual space of ψ(D)
	is the nullspace of a r×n-matrix
	H=
	\| \| \| \| \| \| \| \|
	¯α11···¯α1n1¯α21···¯α2n2···¯αt1···¯αtnt¯0···¯0
	\| \| \| \| \| \| \| \|
	
	where ¯αij= ¯αi, fori= 1,2,...,t, the ﬁrst non-zero coordinate in each vector ¯ αiequals
	1, ¯αi/ne}ationslash= ¯αi′, fori/ne}ationslash=i′, and where the columns of Hare in lexicographic order, according
	to some given ordering of Fq.
	To avoid too much notation we assume that Cwas such that ψ= id.
	LetC⋆be the null space of the matrix
	H⋆=
	\| \| \|
	¯α1¯α2···¯αt
	\| \| \|
	
	Deﬁne, for ¯ µ∈C⋆,
	K¯µ={(¯x1\|¯x2\|...\|¯xt\|¯x0)∈C: (σ1(¯x1),σ2(¯x2),...,σ(¯xt)) = ¯µ}.
	Then,
	C=/uniondisplay
	¯µ∈C⋆K¯µ.
	Further, since any two columns of H⋆are linearly independent, for any two distinct words
	¯µand ¯µ′ofC⋆
	d(K¯µ,K¯µ′)≥3. (3)
	We will show that K¯µhas the properties given in Equation (1).
	Any word ¯x= (¯x1\|¯x2\|...\|¯xt\|¯x0) must be at distance at most one from a word of
	C, and hence, the word ( σ1(¯x1),σ2(¯x2),...,σ t(¯xt)) is at distance at most one from some
	word ofC⋆. It follows that C⋆is a perfect code, and as a consequence, as C⋆is linear, it
	is a Hamming code with parity-check matrix H⋆. As the number of rows of H⋆isr, we
	then get that the number tof columns of H⋆is equal to
	t=qr−1
	q−1= 1+q+q2+...+qr−1.
	3For any word ¯ x∗ofFn1+n2+...+ntq with ¯σ(¯x∗) = ¯µ∈C⋆, we now deﬁne the code C¯µ(¯x∗)
	of lengthn0by
	C¯µ(¯x∗) ={¯c∈Fn0
	q: (¯x∗\|¯c)∈C}.
	Again, using the fact that Cis a perfect code, we may deduce that for any ¯ x∗such
	that the set C¯µ(¯x∗) is non empty, the set C¯µ(¯x∗) must be a perfect code of length n0=
	(qs−1)/(q−1), for some integer s.
	From the fact that the minimum distance of Cequals three, we get the property in
	Equation (2).
	Let ¯eidenote a word of weight one with the entry 1 in the coordinate positio ni. It
	then follows that the two perfect codes C¯µ(¯x∗) andC¯µ(¯x∗+ ¯e1−¯ei), fori= 2,3,...,n 1,
	must be mutually disjoint. Hence, n1is at most equal to the number of perfect codes in
	a partition of Fn0qinto perfect codes, i.e.,
	n1≤(q−1)n0+1 =qs.
	Similarly,ni≤qs, fori= 2,3,...,t.
	Reversing these arguments, using Equation (3) and the fact that Cis a perfect code,
	we ﬁnd that ni, for eachi= 1,2,...,t, is at least equal to the number of words in an
	1-ball ofFn0q.
	We conclude that ni=qs, fori= 1,2,...,t, and ﬁnally
	n=qs(1+q+q2+...+qr−1)+1+q+q2+...+qs−1= 1+q+q2+...+qr+s−1.
	Givenr, we can then ﬁnd sfrom the equality
	n= 1+q+q2+...+qm−1.
	△
	3. Combining construction of perfect codes
	In the previous section, it was shown that a perfect code, depend ing on its rank, can
	be divided onto small or large number of so-called ¯ µ-components, which satisfy some
	equation with ¯ σ. The construction described in the following theorem realizes the ide a
	of combining independent ¯ µ-components, diﬀerently constructed or taken from diﬀerent
	perfect codes, in one perfect code.
	A functionf: Σn→Σ, where Σ is some set, is called an n-ary(ormultary)quasigroup
	of order \|Σ\|if in the equality z0=f(z1,...,z n) knowledge of any nelements of z0,z1,
	...,znuniquely speciﬁes the remaining one.
	Theorem 2. Letmandrbe integers, m>r,qbe a prime power, n= (qm−1)/(q−1)
	andt= (qr−1)/(q−1). Assume that C∗is a perfect code in Ft
	qand for every ¯µ∈C∗
	we have a distance- 3codeK¯µ⊂Fn
	qof cardinality qn−m−(t−r)that satisﬁes the following
	generalized parity-check law:
	¯σ(¯x) = (σ1(x1,...,x l),...,σ t(xlt−l+1,...,x lt)) = ¯µ
	4for every ¯x= (x1,...,x n)∈K¯µ, wherel=qm−rand¯σ= (σ1,...,σ t)is a collections of
	l-ary quasigroups of order q. Then the union
	C=/uniondisplay
	¯µ∈C∗K¯µ
	is a perfect code in Fn
	q.
	Proof. It is easy to check that Chas the cardinality of a perfect code. The distance
	at least 3 between diﬀerent words ¯ x, ¯yfromCfollows from the code distances of K¯µ(if
	¯x, ¯ybelong to the same K¯µ) andC∗(if ¯x, ¯ybelong to diﬀerent K¯µ′,K¯µ′′, ¯µ′,¯µ′′∈C∗).△
	The ¯µ-components K¯µcanbeconstructedindependentlyortakenfromdiﬀerentperfec t
	codes. In the important case when all σiare linear quasigroups (e.g., σi(y1,...,y l) =
	y1+...+yl) the components can be taken from any perfect code of rank at m ostn−r, as
	followsfromtheprevioussection(itshouldbenotedthatif ¯ σislinear, thena ¯ µ-component
	can be obtained from any ¯ µ′-component by adding a vector ¯ zsuch that ¯σ(¯z) = ¯µ−¯µ′).
	In general, the existence of ¯ µ-components that satisfy the generalized parity-check law
	for arbitrary ¯ σis questionable. But for some class of ¯ σsuch components exist, as we will
	see from the following two subsections.
	Remark. It is worth mentioning that ¯ µ-components can exist for arbitrary length tof
	¯µ(for example, in the next two subsections there are no restriction s ont), if we do not
	require the possibility to combine them into a perfect code. This is esp ecially important
	for the study of perfect codes of small ranks (close to the rank o f a linear perfect code):
	once we realize that the code is the union of ¯ µ-components of some special form, we may
	forget about the code length and consider ¯ µ-components for arbitrary length of ¯ µ, which
	allows to use recursive approaches.
	3.1. Mollard-Phelps construction
	Here we describe the way to construct ¯ µ-components derived from the product construc-
	tion discovered independently in [7] and [9]. In terms of ¯ µ-components, the construction
	in [9] is more general; it allows substitution of arbitrary multary quasig roups, and we will
	use this possibility in Section 4.
	Lemma 1. Let¯µ∈Ft
	qand letC#be a perfect code in Fk
	q. Letvandhbe(q−1)-ary
	quasigroups of order qsuch that the code {(¯y\|v(¯y)\|h(¯y)) : ¯y∈Fq−1
	q}is perfect. Let
	V1, ...,VtandH1, ...,Hkbe respectively (k+1)-ary and (t+1)-ary quasigroups of order
	q. Then the set
	K¯µ=/braceleftBig
	(¯x11\|...\|¯x1k\|y1\|¯x21\|...\|¯x2k\|y2\|...\|¯xt1\|...\|¯xtk\|yt\|z1\|z2\|...\|zk) :
	¯xij∈Fq−1
	q,
	(V1(v(¯x11),...,v(¯x1k),y1),...,V t(v(¯xt1),...,v(¯xtk),yt)) = ¯µ,
	(H1(h(¯x11),...,h(¯xt1),z1),...,H k(h(¯x1k),...,h(¯xtk),zk))∈C#/bracerightBig
	is a¯µ-component that satisﬁes the generalized parity-check law with
	σi(·,...,·,·) =Vi(v(·),...,v(·),·).
	5(The elements of F(q−1)kt+k+t
	q in this construction may be thought of as three-dimensional
	arrays where the elements of ¯xijare z-lined, every underlined block is y-lined, and the
	tuple of blocks is x-lined. Naturally, the multary quasigroups Vimay be named “vertical”
	andHi, “horizontal”.)
	The proof of the code distance is similar to that in [9], and the other pr operties of a
	¯µ-component are straightforward. The existence of admissible ( q−1)-ary quasigroups v
	andhis the only restriction on the q(this concerns the next subsection as well). If Fqis
	a ﬁnite ﬁeld, there are linear examples: v(y1,...,y q−1) =y1+...+yq−1,v(y1,...,y q−1) =
	α1y1+...+αq−1yq−1whereα1, ...,αq−1are all the non-zero elements of Fq. Ifqis not
	a prime power, the existence of a q-ary perfect code of length q+1 is an open problem
	(with the only exception q= 6, when the nonexistence follows from the nonexistence of
	two orthogonal 6 ×6 Latin squares [1, Th.6]).
	3.2. Generalized Phelps construction
	Here we describe another way to construct ¯ µ-components, which generalizes the construc-
	tion of binary perfect codes from [8].
	Lemma 2. Let¯µ∈Ft
	q. Let for every ifrom1tot+1the codesCi,j,j= 0,1,...,qk−k
	form a partition of Fk
	qinto perfect codes and γi:Fk
	q→ {0,1,...,qk−k}be the corre-
	sponding partition function:
	γi(¯y) =j⇐⇒¯y∈Ci,j.
	Letvandhbe(q−1)-ary quasigroups of order qsuch that the code {(¯y\|v(¯y)\|h(¯y)) :
	¯y∈Fq−1
	q}is perfect. Let V1, ...,Vtbe(k+ 1)-ary quasigroups of order qandQbe a
	t-ary quasigroup of order qk−k+1.
	K¯µ=/braceleftBig
	(¯x11\|...\|¯x1k\|y1\|¯x21\|...\|¯x2k\|y2\|...\|¯xt1\|...\|¯xtk\|yt\|z1\|z2\|...\|zk) :
	¯xij∈Fq−1
	q,
	(V1(v(¯x11),...,v(¯x1k),y1),...,V t(v(¯xt1),...,v(¯xtk),yt)) = ¯µ,
	Q(γ1(h(¯x11),...,h(¯x1k)),...,γ t(h(¯xt1),...,h(¯xtk))) =γt+1(z1,...,zk)/bracerightBig
	is a¯µ-component that satisﬁes the generalized parity-check law with
	σi(·,...,·,·) =Vi(v(·),...,v(·),·).
	The proof consists of trivial veriﬁcations.
	4. On the number of perfect codes
	In this section we discuss some observations, which result in the bes t known lower bound
	on the number of q-ary perfect codes, q≥3. The basic facts are already contained in
	other known results: lower bounds on the number of multary quasig roups of order q, the
	6construction [9] of perfect codes from multary quasigroups of or derq, and the possibility
	to choose the quasigroup independently for every vector of the o uter code (this possibility
	was not explicitly mentioned in [9], but used in the previous paper [8]).
	A general lower bound, in terms of the number of multary quasigrou ps, is given by
	Lemma 3. In combination with Lemma 4, it gives explicit numbers.
	Lemma 3. The number of q-ary perfect codes of length nis not less than
	Q/parenleftBiggn−1
	q,q/parenrightBiggRn−1
	q
	whereQ(m,q)is the number of m-ary quasigroups of order qand whereRn′=qn′/(n′q−
	q+1)is the cardinality of a perfect code of length n′.
	Proof. Constructing a perfect code like in Theorem 2 with t=n−1
	q, we combine
	Rn−1
	qdiﬀerent ¯µ-components.
	Constructing every such a component as in Lemma 2, k= 1,t=n−1
	q, we are free
	to choose the t-ary quasigroup Qof orderqinQ(t,q) ways. Clearly, diﬀerent t-ary
	quasigroups give diﬀerent components. (Equivalently, we can use L emma 1 and choose
	the (t+1)-ary quasigroup H1, but should note that the value of H1in the construction is
	always ﬁxed when k= 1, because C#consists of only one vertex; so we again have Q(t,q)
	diﬀerent choices, not Q(t+1,q)). △
	Lemma 4. The number Q(m,q)ofm-ary quasigroups of order qsatisﬁes:
	(a) [5]Q(m,3) = 3·2m;
	(b) [11]Q(m,4) = 3m+1·22m+1(1+o(1));
	(c) [4]Q(m,5)≥23n/3−0.072;
	(d) [10]Q(m,q)≥2((q2−4q+3)/4)n/2for oddq(the previous bound [4]wasQ(m,q)≥
	2⌊q/3⌋n);
	(e) [4]Q(m,q1q2)≥Q(m,q1)·Q(m,q2)qm
	1.
	For oddq≥5, the number of codes given by Lemmas 3 and 4(c,d) improves the
	constantcin the lower estimation of form eecn(1+o(1))for the number of perfect codes, in
	comparison with the last known lower bound [6]. Informally, this can be explained in the
	following way: the construction in [6] can be described in terms of mu tually independent
	small modiﬁcations of the linear multary quasigroup of order q, while the lower bounds
	in Lemma 4(c,d) are based on a specially-constructed nonlinear multa ry quasigroup that
	allows a lager number of independent modiﬁcations. For q= 3 andq= 2s, the number
	of codes given by Lemmas 3 and 4(a,b,e) also slightly improves the boun d in [6], but do
	not aﬀect on the constant c.
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	O. Heden
	Department of Mathematics, KTH
	S-100 44 Stockholm, Sweden
	email:olohed@math.kth.se
	D. Krotov
	Sobolev Institute of Mathematics
	and
	Mechanics and Mathematics Department, Novosibirsk State Univer sity
	Novosibirsk, Russia
	email:krotov@math.nsc.ru
	8