English

Fully Dynamic Matching: Beating 2-Approximation in $\Delta^\epsilon$ Update Time

Data Structures and Algorithms 2019-11-06 v1

Abstract

In fully dynamic graphs, we know how to maintain a 2-approximation of maximum matching extremely fast, that is, in polylogarithmic update time or better. In a sharp contrast and despite extensive studies, all known algorithms that maintain a 2Ω(1)2-\Omega(1) approximate matching are much slower. Understanding this gap and, in particular, determining the best possible update time for algorithms providing a better-than-2 approximate matching is a major open question. In this paper, we show that for any constant ϵ>0\epsilon > 0, there is a randomized algorithm that with high probability maintains a 2Ω(1)2-\Omega(1) approximate maximum matching of a fully-dynamic general graph in worst-case update time O(Δϵ+polylog n)O(\Delta^{\epsilon}+\text{polylog } n), where Δ\Delta is the maximum degree. Previously, the fastest fully dynamic matching algorithm providing a better-than-2 approximation had O(m1/4)O(m^{1/4}) update-time [Bernstein and Stein, SODA 2016]. A faster algorithm with update-time O(nϵ)O(n^\epsilon) was known, but worked only for maintaining the size (and not the edges) of the matching in bipartite graphs [Bhattacharya, Henzinger, and Nanongkai, STOC 2016].

Keywords

Cite

@article{arxiv.1911.01839,
  title  = {Fully Dynamic Matching: Beating 2-Approximation in $\Delta^\epsilon$ Update Time},
  author = {Soheil Behnezhad and Jakub Łącki and Vahab Mirrokni},
  journal= {arXiv preprint arXiv:1911.01839},
  year   = {2019}
}

Comments

A preliminary version of this paper is to appear in proceedings of SODA 2020

R2 v1 2026-06-23T12:06:03.626Z