English

Beyond recognizing well-covered graphs

Combinatorics 2024-04-12 v1 Discrete Mathematics

Abstract

We prove a number of results related to the computational complexity of recognizing well-covered graphs. Let kk and ss be positive integers and let GG be a graph. Then GG is said - Wk\mathbf{W_k} if for any kk pairwise disjoint independent vertex sets A1,,AkA_1, \dots, A_k in GG, there exist kk pairwise disjoint maximum independent sets S1,,SkS_1, \dots,S_k in GG such that AiSiA_i \subseteq S_i for i[k]i \in [k]. - Es\mathbf{E_s} if every independent set in GG of size at most ss is contained in a maximum independent set in GG. Chv\'atal and Slater (1993) and Sankaranarayana and Stewart (1992) famously showed that recognizing W1\mathbf{W_1} graphs or, equivalently, well-covered graphs is coNP-complete. We extend this result by showing that recognizing Wk+1\mathbf{W_{k+1}} graphs in either Wk\mathbf{W_k} or Es\mathbf{E_s} graphs is coNP-complete. This answers a question of Levit and Tankus (2023) and strengthens a theorem of Feghali and Marin (2024). We also show that recognizing Es+1\mathbf{E_{s+1}} graphs is Θ2p\Theta_2^p-complete even in Es\mathbf{E_s} graphs, where Θ2p=PNP[log]\Theta_2^p = \text{P}^{\text{NP}[\log]} is the class of problems solvable in polynomial time using a logarithmic number of calls to a SAT oracle. This strengthens a theorem of Berg\'e, Busson, Feghali and Watrigant (2023). We also obtain the complete picture of the complexity of recognizing chordal Wk\mathbf{W_k} and Es\mathbf{E_s} graphs which, in particular, simplifies and generalizes a result of Dettlaff, Henning and Topp (2023).

Keywords

Cite

@article{arxiv.2404.07853,
  title  = {Beyond recognizing well-covered graphs},
  author = {Carl Feghali and Malory Marin and Rémi Watrigant},
  journal= {arXiv preprint arXiv:2404.07853},
  year   = {2024}
}

Comments

Preliminary version

R2 v1 2026-06-28T15:51:25.819Z