Tight Bounds for Online Edge Coloring
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Vizing's celebrated theorem asserts that any graph of maximum degree Δ admits an edge coloring using at most Δ+1 colors. In contrast, Bar-Noy, Naor and Motwani showed over a quarter century that the trivial greedy algorithm, which uses 2Δ-1 colors, is optimal among online algorithms. Their lower bound has a caveat, however: it only applies to low-degree graphs, with Δ=O( n), and they conjectured the existence of online algorithms using Δ(1+o(1)) colors for Δ=ω( n). Progress towards resolving this conjecture was only made under stochastic arrivals (Aggarwal et al., FOCS'03 and Bahmani et al., SODA'10). We resolve the above conjecture for adversarial vertex arrivals in bipartite graphs, for which we present a (1+o(1))Δ-edge-coloring algorithm for Δ=ω( n) known a priori. Surprisingly, if Δ is not known ahead of time, we show that no (e/e-1 - Ω(1) ) Δ-edge-coloring algorithm exists. We then provide an optimal, (e/e-1+o(1))Δ-edge-coloring algorithm for unknown Δ=ω( n). Key to our results, and of possible independent interest, is a novel fractional relaxation for edge coloring, for which we present optimal fractional online algorithms and a near-lossless online rounding scheme, yielding our optimal randomized algorithms.
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