A short proof of the Goldberg-Seymour conjecture

Abstract

For a multigraph G, '(G) denotes the chromatic index of G, (G) the maximum degree of G, and (G) = \ 2|E(H)||V(H)|-1 : H ⊂eq G and |V(H)| odd\. As a generalization of Vizing's classical coloring result for simple graphs, the Goldberg-Seymour conjecture, posed in the 1970s, states that '(G)=\(G), (G)\ or '(G)=\(G) + 1, (G)\. Hochbaum, Nishizeki, and Shmoys further conjectured in 1986 that such a coloring can be found in polynomial time. A long proof of the Goldberg-Seymour conjecture was announced in 2019 by Chen, Jing, and Zang, and one case in that proof was eliminated recently by Jing (but the proof is still long); and neither proof has been verified. In this paper, we give a proof of the Goldberg-Seymour conjecture that is significantly shorter and confirm the Hochbaum-Nishizeki-Shmoys conjecture by providing an O(|V|5|E|3) time algorithm for finding a \(G) + 1, (G)\-edge-coloring of G.

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