A Framework for ETH-Tight Algorithms and Lower Bounds in Geometric Intersection Graphs
Abstract
We give an algorithmic and lower-bound framework that facilitates the construction of subexponential algorithms and matching conditional complexity bounds. It can be applied to intersection graphs of similarly-sized fat objects, yielding algorithms with running time for any fixed dimension for many well known graph problems, including Independent Set, -Dominating Set for constant , and Steiner Tree. For most problems, we get improved running times compared to prior work; in some cases, we give the first known subexponential algorithm in geometric intersection graphs. Additionally, most of the obtained algorithms are representation-agnostic, i.e., they work on the graph itself and do not require the geometric representation. Our algorithmic framework is based on a weighted separator theorem and various treewidth techniques. The lower bound framework is based on a constructive embedding of graphs into d-dimensional grids, and it allows us to derive matching lower bounds under the Exponential Time Hypothesis even in the much more restricted class of -dimensional induced grid graphs.
Cite
@article{arxiv.1803.10633,
title = {A Framework for ETH-Tight Algorithms and Lower Bounds in Geometric Intersection Graphs},
author = {Mark de Berg and Hans L. Bodlaender and Sándor Kisfaludi-Bak and Dániel Marx and Tom C. van der Zanden},
journal= {arXiv preprint arXiv:1803.10633},
year = {2020}
}
Comments
41 pages. v4 corrects a small mistake in the conference version of Theorem 1 by slightly restricting its scope and adding Lemma 4 to its proof