Solving Partition Problems Almost Always Requires Pushing Many Vertices Around
Abstract
A fundamental graph problem is to recognize whether the vertex set of a graph can be bipartitioned into sets and such that and satisfy properties and , respectively. This so-called -Recognition problem generalizes amongst others the recognition of -colorable, bipartite, split, and monopolar graphs. In this paper, we study whether certain fixed-parameter tractable -Recognition problems admit polynomial kernels. In our study, we focus on the first level above triviality, where is the set of -free graphs (disjoint unions of cliques, or cluster graphs), the parameter is the number of clusters in the cluster graph , and is characterized by a set of connected forbidden induced subgraphs. We prove that, under the assumption that NP is not a subset of coNP/poly, \textsc{-Recognition} admits a polynomial kernel if and only if contains a graph with at most vertices. In both the kernelization and the lower bound results, we exploit the properties of a pushing process, which is an algorithmic technique used recently by Heggerness et al. and by Kanj et al. to obtain fixed-parameter algorithms for many cases of -Recognition, as well as several other problems.
Cite
@article{arxiv.1808.08772,
title = {Solving Partition Problems Almost Always Requires Pushing Many Vertices Around},
author = {Iyad Kanj and Christian Komusiewicz and Manuel Sorge and Erik Jan van Leeuwen},
journal= {arXiv preprint arXiv:1808.08772},
year = {2019}
}
Comments
Full version of the corresponding article in the Proceedings of the 26th Annual European Symposium on Algorithms (ESA '18), 35 pages, 7 figures