On $(1+\varepsilon)$-Approximate Flow Sparsifiers
Abstract
Given a large graph with a subset of its vertices called terminals, a quality- flow sparsifier is a small graph that contains and preserves all multicommodity flows that can be routed between terminals in , to within factor . The problem of constructing flow sparsifiers with good (small) quality and (small) size has been a central problem in graph compression for decades. A natural approach of constructing -quality flow sparsifiers, which was adopted in most previous constructions, is contraction. Andoni, Krauthgamer, and Gupta constructed a sketch of size that stores all feasible multicommodity flows up to a factor of , raised the question of constructing quality- flow sparsifiers whose size only depends on (but not the number of vertices in the input graph ), and proposed a contraction-based framework towards it using their sketch result. In this paper, we settle their question for contraction-based flow sparsifiers, by showing that quality- contraction-based flow sparsifiers with size exist for all -terminal graphs, but not for all -terminal graphs. Our hardness result on -terminal graphs improves upon a recent hardness result by Krauthgamer and Mosenzon on exact (quality-) flow sparsifiers, for contraction-based constructions. Our construction and proof utilize the notion of tight spans in metric geometry, which we believe is a powerful tool for future work.
Keywords
Cite
@article{arxiv.2310.07857,
title = {On $(1+\varepsilon)$-Approximate Flow Sparsifiers},
author = {Yu Chen and Zihan Tan},
journal= {arXiv preprint arXiv:2310.07857},
year = {2023}
}