English

Covering line graphs with equivalence relations

Combinatorics 2011-02-16 v1

Abstract

An equivalence graph is a disjoint union of cliques, and the equivalence number eq(G)\mathit{eq}(G) of a graph GG is the minimum number of equivalence subgraphs needed to cover the edges of GG. We consider the equivalence number of a line graph, giving improved upper and lower bounds: 13log2log2χ(G)<eq(L(G))2log2log2χ(G)+2\frac 13 \log_2\log_2 \chi(G) < \mathit{eq}(L(G)) \leq 2\log_2\log_2 \chi(G) + 2. This disproves a recent conjecture that eq(L(G))\mathit{eq}(L(G)) is at most three for triangle-free GG; indeed it can be arbitrarily large. To bound eq(L(G))\mathit{eq}(L(G)) we bound the closely-related invariant σ(G)\sigma(G), which is the minimum number of orientations of GG such that for any two edges e,fe,f incident to some vertex vv, both ee and ff are oriented out of vv in some orientation. When GG is triangle-free, σ(G)=eq(L(G))\sigma(G)=\mathit{eq}(L(G)). We prove that even when GG is triangle-free, it is NP-complete to decide whether or not σ(G)3\sigma(G)\leq 3.

Keywords

Cite

@article{arxiv.1006.3692,
  title  = {Covering line graphs with equivalence relations},
  author = {L. Esperet and J. Gimbel and A. King},
  journal= {arXiv preprint arXiv:1006.3692},
  year   = {2011}
}

Comments

10 pages, submitted in July 2009

R2 v1 2026-06-21T15:38:10.777Z