Integer round-up property for the chromatic number of some h-perfect graphs

Abstract

A graph is h-perfect if its stable set polytope can be completely described by non-negativity, clique and odd-hole constraints. It is t-perfect if it furthermore has no clique of size 4. For every graph G and every c∈Z+V(G), the weighted chromatic number of (G,c) is the minimum cardinality of a multi-set F of stable sets of G such that every v∈ V(G) belongs to at least cv members of F. We prove that every h-perfect line-graph and every t-perfect claw-free graph G has the integer round-up property for the chromatic number: for every non-negative integer weight c on the vertices of G, the weighted chromatic number of (G,c) can be obtained by rounding up its fractional relaxation. In other words, the stable set polytope of G has the integer decomposition property. Our results imply the existence of a polynomial-time algorithm which computes the weighted chromatic number of t-perfect claw-free graphs and h-perfect line-graphs. Finally, they yield a new case of a conjecture of Goldberg and Seymour on edge-colorings.