Network Sparsification for Steiner Problems on Planar and Bounded-Genus Graphs
Abstract
We propose polynomial-time algorithms that sparsify planar and bounded-genus graphs while preserving optimal or near-optimal solutions to Steiner problems. Our main contribution is a polynomial-time algorithm that, given an unweighted graph embedded on a surface of genus and a designated face bounded by a simple cycle of length , uncovers a set of size polynomial in and that contains an optimal Steiner tree for any set of terminals that is a subset of the vertices of . We apply this general theorem to prove that: * given an unweighted graph embedded on a surface of genus and a terminal set , one can in polynomial time find a set that contains an optimal Steiner tree for and that has size polynomial in and ; * an analogous result holds for an optimal Steiner forest for a set of terminal pairs; * given an unweighted planar graph and a terminal set , one can in polynomial time find a set that contains an optimal (edge) multiway cut separating and that has size polynomial in . In the language of parameterized complexity, these results imply the first polynomial kernels for Steiner Tree and Steiner Forest on planar and bounded-genus graphs (parameterized by the size of the tree and forest, respectively) and for (Edge) Multiway Cut on planar graphs (parameterized by the size of the cutset). Additionally, we obtain a weighted variant of our main contribution.
Cite
@article{arxiv.1306.6593,
title = {Network Sparsification for Steiner Problems on Planar and Bounded-Genus Graphs},
author = {Marcin Pilipczuk and Michał Pilipczuk and Piotr Sankowski and Erik Jan van Leeuwen},
journal= {arXiv preprint arXiv:1306.6593},
year = {2017}
}