Maximum k- vs. -colourings of graphs
Abstract
We present polynomial-time SDP-based algorithms for the following problem: For fixed k ≤ , given a real number ε>0 and a graph G that admits a k-colouring with a -fraction of the edges coloured properly, it returns an -colouring of G with an (α - ε)-fraction of the edges coloured properly in polynomial time in G and 1 / ε. Our algorithms are based on the algorithms of Frieze and Jerrum [Algorithmica'97] and of Karger, Motwani and Sudan [JACM'98]. When k is fixed and grows large, our algorithm achieves an approximation ratio of α = 1 - o(1 / ). When k, are both large, our algorithm achieves an approximation ratio of α = 1 - 1 / + 2 / k - o( / k ) - O(1 / k2); if we fix d = - k and allow k, to grow large, this is α = 1 - 1 / + 2 / k - o( / k ). By extending the results of Khot, Kindler, Mossel and O'Donnell [SICOMP'07] to the promise setting, we show that for large k and , assuming Khot's Unique Games Conjecture (), it is -hard to achieve an approximation ratio α greater than 1 - 1 / + 2 / k + o( / k ), provided that is bounded by a function that is o(([3]k)). For the case where d = - k is fixed, this bound matches the performance of our algorithm up to o( / k ). Furthermore, by extending the results of Guruswami and Sinop [ToC'13] to the promise setting, we prove that it is -hard to achieve an approximation ratio greater than 1 - 1 / + 8 / k + o( / k ), provided again that is bounded as before (but this time without assuming the ).
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