English

A group-based structure for perfect sequence covering arrays

Combinatorics 2022-02-07 v1

Abstract

An (n,k)(n,k)-perfect sequence covering array with multiplicity λ\lambda, denoted PSCA(n,k,λ)(n,k,\lambda), is a multiset whose elements are permutations of the sequence (1,2,,n)(1,2, \dots, n) and which collectively contain each ordered length kk subsequence exactly λ\lambda times. The primary objective is to determine for each pair (n,k)(n,k) the smallest value of λ\lambda, denoted g(n,k)g(n,k), for which a PSCA(n,k,λ)(n,k,\lambda) exists; and more generally, the complete set of values λ\lambda for which a PSCA(n,k,λ)(n,k,\lambda) exists. Yuster recently determined the first known value of g(n,k)g(n,k) greater than 1, namely g(5,3)=2g(5,3)=2, and suggested that finding other such values would be challenging. We show that g(6,3)=g(7,3)=2g(6,3)=g(7,3)=2, using a recursive search method inspired by an old algorithm due to Mathon. We then impose a group-based structure on a perfect sequence covering array by restricting it to be a union of distinct cosets of a prescribed nontrivial subgroup of the symmetric group SnS_n. This allows us to determine the new results that g(7,4)=2g(7,4)=2 and g(7,5){2,3,4}g(7,5) \in \{2,3,4\} and g(8,3){2,3}g(8,3) \in \{2,3\} and g(9,3){2,3,4}g(9,3) \in \{2,3,4\}. We also show that, for each (n,k){(5,3),(6,3),(7,3),(7,4)}(n,k) \in \{ (5,3), (6,3), (7,3), (7,4) \}, there exists a PSCA(n,k,λ)(n,k,\lambda) if and only if λ2\lambda \ge 2; and that there exists a PSCA(8,3,λ)(8,3,\lambda) if and only if λg(8,3)\lambda \ge g(8,3).

Keywords

Cite

@article{arxiv.2202.01948,
  title  = {A group-based structure for perfect sequence covering arrays},
  author = {Jingzhou Na and Jonathan Jedwab and Shuxing Li},
  journal= {arXiv preprint arXiv:2202.01948},
  year   = {2022}
}

Comments

21 pages

R2 v1 2026-06-24T09:19:13.968Z