English

Cosecure Domination: Hardness Results and Algorithm

Discrete Mathematics 2023-02-28 v1 Computational Complexity Combinatorics

Abstract

For a simple graph G=(V,E)G=(V,E) without any isolated vertex, a cosecure dominating set DD of GG satisfies the following two properties (i) SS is a dominating set of GG, (ii) for every vertex vSv \in S there exists a vertex uVSu \in V \setminus S such that uvEuv \in E and (S{v}){u}(S \setminus \{v\}) \cup \{u\} is a dominating set of GG. The minimum cardinality of a cosecure dominating set of GG is called cosecure domination number of GG and is denoted by γcs(G)\gamma_{cs}(G). The Minimum Cosecure Domination problem is to find a cosecure dominating set of a graph GG of cardinality γcs(G)\gamma_{cs}(G). The decision version of the problem is known to be NP-complete for bipartite, planar, and split graphs. Also, it is known that the Minimum Cosecure Domination problem is efficiently solvable for proper interval graphs and cographs. In this paper, we work on various important graph classes in an effort to reduce the complexity gap of the Minimum Cosecure Domination problem. We show that the decision version of the problem remains NP-complete for circle graphs, doubly chordal graphs, chordal bipartite graphs, star-convex bipartite graphs and comb-convex bipartite graphs. On the positive side, we give an efficient algorithm to compute the cosecure domination number of chain graphs, which is an important subclass of bipartite graphs. In addition, we show that the problem is linear-time solvable for bounded tree-width graphs. Further, we prove that the computational complexity of this problem varies from the domination problem.

Keywords

Cite

@article{arxiv.2302.13031,
  title  = {Cosecure Domination: Hardness Results and Algorithm},
  author = {Kusum and Arti Pandey},
  journal= {arXiv preprint arXiv:2302.13031},
  year   = {2023}
}

Comments

V1, 19 pages, 2 figures

R2 v1 2026-06-28T08:49:23.304Z