English

Bridge-Depth Characterizes which Structural Parameterizations of Vertex Cover Admit a Polynomial Kernel

Data Structures and Algorithms 2023-07-25 v2 Computational Complexity Combinatorics

Abstract

We study the kernelization complexity of structural parameterizations of the Vertex Cover problem. Here, the goal is to find a polynomial-time preprocessing algorithm that can reduce any instance (G,k)(G,k) of the Vertex Cover problem to an equivalent one, whose size is polynomial in the size of a pre-determined complexity parameter of GG. A long line of previous research deals with parameterizations based on the number of vertex deletions needed to reduce GG to a member of a simple graph class F\mathcal{F}, such as forests, graphs of bounded tree-depth, and graphs of maximum degree two. We set out to find the most general graph classes F\mathcal{F} for which Vertex Cover parameterized by the vertex-deletion distance of the input graph to F\mathcal{F}, admits a polynomial kernelization. We give a complete characterization of the minor-closed graph families F\mathcal{F} for which such a kernelization exists. We introduce a new graph parameter called bridge-depth, and prove that a polynomial kernelization exists if and only if F\mathcal{F} has bounded bridge-depth. The proof is based on an interesting connection between bridge-depth and the size of minimal blocking sets in graphs, which are vertex sets whose removal decreases the independence number.

Keywords

Cite

@article{arxiv.2004.12865,
  title  = {Bridge-Depth Characterizes which Structural Parameterizations of Vertex Cover Admit a Polynomial Kernel},
  author = {Marin Bougeret and Bart M. P. Jansen and Ignasi Sau},
  journal= {arXiv preprint arXiv:2004.12865},
  year   = {2023}
}

Comments

Author-accepted version of SIDMA publication

R2 v1 2026-06-23T15:07:32.160Z