English

Computing Subset Vertex Covers in $H$-Free Graphs

Combinatorics 2025-01-07 v2 Computational Complexity Discrete Mathematics Data Structures and Algorithms

Abstract

We consider a natural generalization of Vertex Cover: the Subset Vertex Cover problem, which is to decide for a graph G=(V,E)G=(V,E), a subset TVT\subseteq V and integer kk, if VV has a subset SS of size at most kk, such that SS contains at least one end-vertex of every edge incident to a vertex of TT. A graph is HH-free if it does not contain HH as an induced subgraph. We solve two open problems from the literature by proving that Subset Vertex Cover is NP-complete on subcubic (claw,diamond)-free planar graphs and on 22-unipolar graphs, a subclass of 2P32P_3-free weakly chordal graphs. Our results show for the first time that Subset Vertex Cover is computationally harder than Vertex Cover (under P \neq NP). We also prove new polynomial time results, some of which follow from a reduction to Vertex Cover restricted to classes of probe graphs. We first give a dichotomy on graphs where G[T]G[T] is HH-free. Namely, we show that Subset Vertex Cover is polynomial-time solvable on graphs GG, for which G[T]G[T] is HH-free, if H=sP1+tP2H=sP_1+tP_2 and NP-complete otherwise. Moreover, we prove that Subset Vertex Cover is polynomial-time solvable for (sP1+P2+P3)(sP_1+P_2+P_3)-free graphs and bounded mim-width graphs. By combining our new results with known results we obtain a partial complexity classification for Subset Vertex Cover on HH-free graphs.

Keywords

Cite

@article{arxiv.2307.05701,
  title  = {Computing Subset Vertex Covers in $H$-Free Graphs},
  author = {Nick Brettell and Jelle J. Oostveen and Sukanya Pandey and Daniël Paulusma and Johannes Rauch and Erik Jan van Leeuwen},
  journal= {arXiv preprint arXiv:2307.05701},
  year   = {2025}
}
R2 v1 2026-06-28T11:27:48.296Z