Improved Bounds for Fully Dynamic Matching via Ordered Ruzsa-Szemeredi Graphs

Abstract

In a very recent breakthrough, Behnezhad and Ghafari [FOCS'24] developed a novel fully dynamic randomized algorithm for maintaining a (1-ε)-approximation of maximum matching with amortized update time potentially much better than the trivial O(n) update time. The runtime of the BG algorithm is parameterized via the following graph theoretical concept: * For any n, define ORS(n) -- standing for Ordered RS Graph -- to be the largest number of edge-disjoint matchings M1,…,Mt of size (n) in an n-vertex graph such that for every i ∈ [t], Mi is an induced matching in the subgraph Mi Mi+1 … Mt. Then, for any fixed ε > 0, the BG algorithm runs in \[ O( n1+O(ε) · ORS(n) ) \] amortized update time with high probability, even against an adaptive adversary. ORS(n) is a close variant of a more well-known quantity regarding RS graphs (which require every matching to be induced regardless of the ordering). It is currently only known that no(1) ≤slant ORS(n) ≤slant n1-o(1), and closing this gap appears to be a notoriously challenging problem. In this work, we further strengthen the result of Behnezhad and Ghafari and push it to limit to obtain a randomized algorithm with amortized update time of \[ no(1) · ORS(n) \] with high probability, even against an adaptive adversary. In the limit, i.e., if current lower bounds for ORS(n) = no(1) are almost optimal, our algorithm achieves an no(1) update time for (1-ε)-approximation of maximum matching, almost fully resolving this fundamental question. In its current stage also, this fully reduces the algorithmic problem of designing dynamic matching algorithms to a purely combinatorial problem of upper bounding ORS(n) with no algorithmic considerations.