Deterministic Mincut in Almost-Linear Time
Abstract
We present a deterministic (global) mincut algorithm for weighted, undirected graphs that runs in time, answering an open question of Karger from the 1990s. To obtain our result, we de-randomize the construction of the \emph{skeleton} graph in Karger's near-linear time mincut algorithm, which is its only randomized component. In particular, we partially de-randomize the well-known Benczur-Karger graph sparsification technique by random sampling, which we accomplish by the method of pessimistic estimators. Our main technical component is designing an efficient pessimistic estimator to capture the cuts of a graph, which involves harnessing the expander decomposition framework introduced in recent work by Goranci et al. (SODA 2021). As a side-effect, we obtain a structural representation of all approximate mincuts in a graph, which may have future applications.
Cite
@article{arxiv.2106.05513,
title = {Deterministic Mincut in Almost-Linear Time},
author = {Jason Li},
journal= {arXiv preprint arXiv:2106.05513},
year = {2026}
}
Comments
STOC 2021, 31 pages. Fix technical error in Theorem 1.5 resulting in an $\epsilon^{-7}$ term instead of $\epsilon^{-4}$. Also fix formatting throughout the paper