English

Characterizing Finite Groups via Subgroup Perfect Codes

Combinatorics 2026-05-06 v1 Group Theory

Abstract

A perfect code in a graph Γ=(V,E)\Gamma = (V, E) is a subset CC of VV such that no two vertices in CC are adjacent and every vertex in VCV \setminus C is adjacent to exactly one vertex in CC. A subgroup HH of a group GG is called a subgroup perfect code of GG if it is a perfect code in some Cayley graph of GG. In this paper, we study the set Δ(G)\Delta(G) of conjugacy classes of nontrivial subgroup perfect codes of GG, with a focus on its relation to π(G)|\pi(G)|, the number of prime divisors of G|G|. We prove that Δ(G)π(G)|\Delta(G)| \ge |\pi(G)| with only three exceptional families, which leads to the natural question: when is this bound attained or nearly attained? We completely classify finite groups GG satisfying Δ(G)=π(G)|\Delta(G)| = |\pi(G)| and Δ(G)=π(G)+1|\Delta(G)| = |\pi(G)| + 1, and we further characterize all insolvable groups with Δ(G)6|\Delta(G)| \le 6. Our approach is based on the classification of primitive groups of odd degree, as well as the classification of primitive groups of square-free degree.

Keywords

Cite

@article{arxiv.2605.03284,
  title  = {Characterizing Finite Groups via Subgroup Perfect Codes},
  author = {Binbin Li and Jingjian Li and Wei Meng and Hao Yu},
  journal= {arXiv preprint arXiv:2605.03284},
  year   = {2026}
}
R2 v1 2026-07-01T12:49:42.909Z