Tilings of Hq(n,w) with optimal (n,d,w)q-codes
Abstract
The metric space Hq(n,w) is the set of all words of length n with weight w over the alphabet Zq, under the Hamming distance metric. A q-ary constant-weight code, as a nonempty subset of Hq(n,w), has always been a fundamental topic in coding theory. This paper investigates the tiling problem of Hq(n,w) with optimal (n,d,w)q-codes, simply denoted by TOCq(n,d,w), meaning a partition of Hq(n,w) into mutually disjoint optimal q-ary constant-weight codes with distance d. When the distance d is odd, we investigate large sets of generalized Steiner systems. When d is even, we define large sets of generalized maximum H-packings. We present several general construction approaches for generating TOCq(n,d,w)s via t-resolvable Steiner systems and almost-regular edge-colorings of complete hypergraphs. For the cases d=2 and d=2w, we completely resolve the existence problem of TOCq(n,d,w)s for all parameters q,n and w. Particularly, we pay attention to tilings for weight three. For binary case and weight three, the existence problem of TOC2(n,d,3)s is totally resolved. For specific alphabet size q 3, we obtain many infinite families of TOCq(n,d,3)s for distances d=3,4,5.
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