Exact Complexity of Exact-Four-Colorability

Abstract

Let Mk be a given set that consists of k noncontiguous integers. Define Mk to be the problem of determining whether (G), the chromatic number of a given graph G, equals one of the k elements of the set Mk exactly. In 1987, Wagner wag:j:min-max proved that Mk is 2k-complete, where Mk = \6k+1, 6k+3, >..., 8k-1 \ and 2k is the 2kth level of the boolean hierarchy over . In particular, for k = 1, it is DP-complete to determine whether (G) = 7, where = 2. Wagner raised the question of how small the numbers in a k-element set Mk can be chosen such that Mk still is 2k-complete. In particular, for k = 1, he asked if it is DP-complete to determine whether (G) = 4. In this note, we solve this question of Wagner and determine the precise threshold t ∈ \4, 5, 6, 7\ for which the problem \t\ jumps from NP to DP-completeness: It is DP-complete to determine whether (G) = 4, yet \3\ is in . More generally, for each k ≥ 1, we show that Mk is 2k-complete for Mk = \3k+1, 3k+3,..., 5k-1\.

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