Asymptotically Optimal Inapproximability of Maxmin k-Cut Reconfiguration

Abstract

k-Coloring Reconfiguration is one of the most well-studied reconfiguration problems, which asks to transform a given proper k-coloring of a graph to another by repeatedly recoloring a single vertex. Its approximate version, Maxmin k-Cut Reconfiguration, is defined as an optimization problem of maximizing the minimum fraction of bichromatic edges during the transformation between (not necessarily proper) k-colorings. In this paper, we prove that the optimal approximation factor of this problem is 1 - (1k) for every k 2. Specifically, we show the PSPACE-hardness of approximating the objective value within a factor of 1 - k for some universal constant > 0, whereas we present a deterministic polynomial-time algorithm that achieves the approximation factor of 1 - 2k. To prove the hardness result, we develop a new probabilistic verifier that tests a ``striped'' pattern. Our polynomial-time algorithm is based on ``a random reconfiguration via a random solution,'' i.e., the transformation that goes through one random k-coloring.

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