New Complexity and Algorithmic Bounds for Minimum Consistent Subsets

Abstract

In the Minimum Consistent Subset (MCS) problem, we are presented with a connected simple undirected graph G=(V,E), consisting of a vertex set V of size n and an edge set E. Each vertex in V is assigned a color from the set \1,2,…, c\. The objective is to determine a subset V' ⊂eq V with minimum possible cardinality, such that for every vertex v ∈ V, at least one of its nearest neighbors in V' (measured in terms of the hop distance) shares the same color as v. A variant of MCS is the minimum strict consistent subset (MSCS) in which instead of requiring at least one nearest neighbor of v, all the nearest neighbors of v in V' must have the same color as v. The decision version for MCS problem as well as for MSCS problem asks whether there exists a subset V' of cardinality at most l for some positive integer l. The MCS problem is known to be NP-complete for planar graphs. In this paper, we establish that the MCS problem for trees, when the number of colors c is considered an input parameter, is NP-complete. We propose a fixed-parameter tractable (FPT) algorithm for MCS on trees running in O(26cn6) time, significantly improving the currently best-known algorithm whose running time is O(24cn2c+3). In an effort to comprehensively understand the computational complexity of the MCS problem across different graph classes, we extend our investigation to interval graphs. We show that it remains NP-complete for interval graphs, thus enriching graph classes where MCS remains intractable. We also show that the MSCS problem is log-APX-hard on general graphs and NP-complete on planar graphs.

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