English

DP color functions versus chromatic polynomials

Combinatorics 2021-11-30 v5

Abstract

For any graph GG, the chromatic polynomial of GG is the function P(G,m)P(G,m) which counts the number of proper mm-colorings of GG for each positive integer mm. The DP color function PDP(G,m)P_{DP}(G,m) of GG, introduced by Kaul and Mudrock in 2019, is a generalization of P(G,m)P(G,m) with PDP(G,m)P(G,m)P_{DP}(G,m)\le P(G,m) for each positive integer mm. Let PDP(G)P(G)P_{DP}(G)\approx P(G) (resp. PDP(G)<P(G)P_{DP}(G)< P(G)) denote the property that PDP(G,m)=P(G,m)P_{DP}(G,m)=P(G,m) (resp. PDP(G,m)<P(G,m)P_{DP}(G,m)<P(G,m)) holds for sufficiently large integers mm.It is an interesting problem of finding graphs GG for which PDP(G)P(G)P_{DP}(G)\approx P(G) (resp. PDP(G,m)<P(G,m)P_{DP}(G,m)<P(G,m)) holds. Kaul and Mudrock showed that if GG has an even girth, then PDP(G)<P(G)P_{DP}(G)<P(G) and Mudrock and Thomason recently proved that PDP(G)P(G)P_{DP}(G)\approx P(G) holds for each graph GG which has a dominating vertex. We shall generalize their results in this article. For each edge ee in GG, let (e)=\ell(e)=\infty if ee is a bridge of GG, and let (e)\ell(e) be the length of a shortest cycle in GG containing ee otherwise. We first show that if (e)\ell(e) is even for some edge ee in GG, then PDP(G)<P(G)P_{DP}(G)<P(G) holds. However, the converse statement of this conclusion fails with infinitely many counterexamples. We then prove that PDP(G)P(G)P_{DP}(G)\approx P(G) holds for every graph GG that contains a spanning tree TT such that for each eE(G)E(T)e\in E(G)\setminus E(T), (e)\ell(e) is odd and ee contained in a cycle CC of length (e)\ell (e) with the property that (e)<(e)\ell(e')<\ell(e) for each eE(C)(E(T){e})e'\in E(C)\setminus (E(T)\cup \{e\}). Some open problems are proposed in this article.

Keywords

Cite

@article{arxiv.2105.11081,
  title  = {DP color functions versus chromatic polynomials},
  author = {Fengming Dong and Yan Yang},
  journal= {arXiv preprint arXiv:2105.11081},
  year   = {2021}
}

Comments

26 pages and 3 figures. To appear in Advance in Applied Mathematics

R2 v1 2026-06-24T02:23:39.824Z