English

Point partition numbers: perfect graphs

Combinatorics 2020-03-17 v2

Abstract

Graphs considered in this paper are finite, undirected and without loops, but with multiple edges. For an integer t1t\geq 1, denote by MGt\mathcal{MG}_t the class of graphs whose maximum multiplicity is at most tt. A graph GG is called strictly tt-degenerate if every non-empty subgraph HH of GG contains a vertex vv whose degree in HH is at most t1t-1. The point partition number χt(G)\chi_t(G) of GG is smallest number of colors needed to color the vertices of GG so that each vertex receives a color and vertices with the same color induce a strictly tt-degenerate subgraph of GG. So χ1\chi_1 is the chromatic number, and χ2\chi_2 is known as the point aboricity. The point partition number χt\chi_t with t1t\geq 1 was introduced by Lick and White. If HH is a simple graph, then tHtH denotes the graph obtained from HH by replacing each edge of HH by tt parallel edges. Then ωt(G)\omega_t(G) is the largest integer nn such that GG contains a tKntK_n as a subgraph. Let GG be a graph belonging to MGt\mathcal{MG}_t. Then ωt(G)χt(G)\omega_t(G)\leq \chi_t(G) and we say that GG is χt\chi_t-perfect if every induced subgraph HH of GG satisfies ωt(H)=χt(H)\omega_t(H)=\chi_t(H). Based on the Strong Perfect Graph Theorem due to Chudnowsky, Robertson, Seymour and Thomas, we give a characterization of χt\chi_t-perfect graphs of MGt\mathcal{MG}_t by a set of forbidden induced subgraphs. We also discuss some complexity problems for the class of χt\chi_t-critical graphs.

Keywords

Cite

@article{arxiv.2003.04657,
  title  = {Point partition numbers: perfect graphs},
  author = {Justus von Postel and Thomas Schweser and Michael Stiebitz},
  journal= {arXiv preprint arXiv:2003.04657},
  year   = {2020}
}
R2 v1 2026-06-23T14:09:59.093Z