Further results on covering codes with radius R and codimension tR + 1

Abstract

The length function q(r,R) is the smallest possible length n of a q -ary linear [n,n-r]qR code with codimension (redundancy) r and covering radius R. Let sq(N,) be the smallest size of a -saturating set in the projective space PG(N,q). There is a one-to-one correspondence between [n,n-r]qR codes and (R-1)-saturating n-sets in PG(r-1,q) that implies q(r,R)=sq(r-1,R-1). In this work, for R3, new asymptotic upper bounds on q(tR+1,R) are obtained in the following form: 0.7cm ~q(tR+1,R) =sq(tR,R-1) [R]R!RR-2· q(r-R)/R·[R] q+o(q(r-R)/R), 0.3cmr=tR+1,~t1,~ q is an arbitrary prime power,~q is large enough; 0.7cm ~ if additionally R is large enough, then [R]R!RR-21e0.3679. The new bounds are essentially better than the known ones. For t=1, a new construction of (R-1)-saturating sets in the projective space PG(R,q), providing sets of small sizes, is proposed. The [n,n-(R+1)]qR codes, obtained by the construction, have minimum distance R + 1, i.e. they are almost MDS (AMDS) codes. These codes are taken as the starting ones in the lift-constructions (so-called "qm-concatenating constructions") for covering codes to obtain infinite families of codes with growing codimension r=tR+1, t1.

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