Beyond the Shannon's Bound

Abstract

Let G=(V,E) be a multigraph of maximum degree . The edges of G can be colored with at most 32 colors by Shannon's theorem. We study lower bounds on the size of subgraphs of G that can be colored with colors. Shannon's Theorem gives a bound of 32|E|. However, for =3, Kami\'nski and Kowalik [SWAT'10] showed that there is a 3-edge-colorable subgraph of size at least 79|E|, unless G has a connected component isomorphic to K3+e (a K3 with an arbitrary edge doubled). Here we extend this line of research by showing that G has a -edge colorable subgraph with at least 32-1|E| edges, unless is even and G contains 2K3 or is odd and G contains -12K3+e. Moreover, the subgraph and its coloring can be found in polynomial time. Our results have applications in 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, for every even k 4 we obtain a 2k+23k+2-approximation and for every odd k 5 we get a 2k+13k-approximation. When 4 k 13 this improves over earlier algorithms due to Feige et al. [APPROX'02]