English

Competitively tight graphs

Combinatorics 2013-12-25 v2

Abstract

The competition graph of a digraph DD is a (simple undirected) graph which has the same vertex set as DD and has an edge between two distinct vertices xx and yy if and only if there exists a vertex vv in DD such that (x,v)(x,v) and (y,v)(y,v) are arcs of DD. For any graph GG, GG together with sufficiently many isolated vertices is the competition graph of some acyclic digraph. The competition number k(G)k(G) of a graph GG is the smallest number of such isolated vertices. Computing the competition number of a graph is an NP-hard problem in general and has been one of the important research problems in the study of competition graphs. Opsut [1982] showed that the competition number of a graph GG is related to the edge clique cover number θE(G)\theta_E(G) of the graph GG via θE(G)V(G)+2k(G)θE(G)\theta_E(G)-|V(G)|+2 \leq k(G) \leq \theta_E(G). We first show that for any positive integer mm satisfying 2mV(G)2 \leq m \leq |V(G)|, there exists a graph GG with k(G)=θE(G)V(G)+mk(G)=\theta_E(G)-|V(G)|+m and characterize a graph GG satisfying k(G)=θE(G)k(G)=\theta_E(G). We then focus on what we call \emph{competitively tight graphs} GG which satisfy the lower bound, i.e., k(G)=θE(G)V(G)+2k(G)=\theta_E(G)-|V(G)|+2. We completely characterize the competitively tight graphs having at most two triangles. In addition, we provide a new upper bound for the competition number of a graph from which we derive a sufficient condition and a necessary condition for a graph to be competitively tight.

Keywords

Cite

@article{arxiv.1112.6203,
  title  = {Competitively tight graphs},
  author = {Suh-Ryung Kim and Jung Yeun Lee and Boram Park and Yoshio Sano},
  journal= {arXiv preprint arXiv:1112.6203},
  year   = {2013}
}

Comments

10 pages, 2 figures

R2 v1 2026-06-21T19:57:49.870Z