English

k-apices of minor-closed graph classes. II. Parameterized algorithms

Data Structures and Algorithms 2021-03-03 v2 Computational Complexity Combinatorics

Abstract

Let G{\cal G} be a minor-closed graph class. We say that a graph GG is a kk-apex of G{\cal G} if GG contains a set SS of at most kk vertices such that GSG\setminus S belongs to G{\cal G}. We denote by Ak(G){\cal A}_k ({\cal G}) the set of all graphs that are kk-apices of G.{\cal G}. In the first paper of this series we obtained upper bounds on the size of the graphs in the minor-obstruction set of Ak(G){\cal A}_k ({\cal G}), i.e., the minor-minimal set of graphs not belonging to Ak(G).{\cal A}_k ({\cal G}). In this article we provide an algorithm that, given a graph GG on nn vertices, runs in 2poly(k)n32^{{\sf poly}(k)}\cdot n^3-time and either returns a set SS certifying that GAk(G)G \in {\cal A}_k ({\cal G}), or reports that GAk(G)G \notin {\cal A}_k ({\cal G}). Here poly{\sf poly} is a polynomial function whose degree depends on the maximum size of a minor-obstruction of G.{\cal G}. In the special case where G{\cal G} excludes some apex graph as a minor, we give an alternative algorithm running in 2poly(k)n22^{{\sf poly}(k)}\cdot n^2-time.

Keywords

Cite

@article{arxiv.2004.12692,
  title  = {k-apices of minor-closed graph classes. II. Parameterized algorithms},
  author = {Ignasi Sau and Giannos Stamoulis and Dimitrios M. Thilikos},
  journal= {arXiv preprint arXiv:2004.12692},
  year   = {2021}
}

Comments

37 pages, 3 figures

R2 v1 2026-06-23T15:07:06.459Z