Approximating Sparsest Cut in Low-Treewidth Graphs via Combinatorial Diameter
Abstract
The fundamental sparsest cut problem takes as input a graph together with the edge costs and demands, and seeks a cut that minimizes the ratio between the costs and demands across the cuts. For -node graphs~ of treewidth~, \chlamtac, Krauthgamer, and Raghavendra (APPROX 2010) presented an algorithm that yields a factor- approximation in time . Later, Gupta, Talwar and Witmer (STOC 2013) showed how to obtain a -approximation algorithm with a blown-up run time of . An intriguing open question is whether one can simultaneously achieve the best out of the aforementioned results, that is, a factor- approximation in time . In this paper, we make significant progress towards this goal, via the following results: (i) A factor- approximation that runs in time , directly improving the work of Chlamt\'a\v{c} et al. while keeping the run time single-exponential in . (ii) For any , a factor- approximation whose run time is , implying a constant-factor approximation whose run time is nearly single-exponential in and a factor- approximation in time . Key to these results is a new measure of a tree decomposition that we call combinatorial diameter, which may be of independent interest.
Cite
@article{arxiv.2111.06299,
title = {Approximating Sparsest Cut in Low-Treewidth Graphs via Combinatorial Diameter},
author = {Parinya Chalermsook and Matthias Kaul and Matthias Mnich and Joachim Spoerhase and Sumedha Uniyal and Daniel Vaz},
journal= {arXiv preprint arXiv:2111.06299},
year = {2024}
}
Comments
15 pages, 3 figures