Beyond the Vizing's bound for at most seven colors

Abstract

Let G=(V,E) be a simple graph of maximum degree . The edges of G can be colored with at most +1 colors by Vizing's theorem. We study lower bounds on the size of subgraphs of G that can be colored with colors. Vizing's Theorem gives a bound of +1|E|. This is known to be tight for cliques K+1 when is even. However, for =3 it was improved to 26/31|E| by Albertson and Haas [Parsimonious edge colorings, Disc. Math. 148, 1996] and later to 6/7|E| by Rizzi [Approximating the maximum 3-edge-colorable subgraph problem, Disc. Math. 309, 2009]. It is tight for B3, the graph isomorphic to a K4 with one edge subdivided. We improve previously known bounds for ∈3,...,7, under the assumption that for =3,4,6 graph G is not isomorphic to B3, K5 and K7, respectively. For ≥ 4 these are the first results which improve over the Vizing's bound. We also show a new bound for subcubic multigraphs not isomorphic to K3 with one edge doubled. In the second part, we give approximation algorithms for the Maximum k-Edge-Colorable Subgraph problem, where given a graph G (without any bound on its maximum degree or other restrictions) one has to find a k-edge-colorable subgraph with maximum number of edges. In particular, when G is simple for k=3,4,5,6,7 we obtain approximation ratios of 13/15, 9/11, 19/22, 23/27 and 22/25, respectively. We also present a 7/9-approximation for k=3 when G is a multigraph. The approximation algorithms follow from a new general framework that can be used for any value of k.