TY - GEN
T1 - Breaking the O(mn)-Time Barrier for Vertex-Weighted Global Minimum Cut
AU - Chuzhoy, Julia
AU - Trabelsi, Ohad
N1 - Publisher Copyright:
© 2025 Copyright held by the owner/author(s).
PY - 2025/6/15
Y1 - 2025/6/15
N2 - We consider the Global Minimum Vertex-Cut problem: given an undirected vertex-weighted graph G, compute a minimum-weight subset of its vertices whose removal disconnects G. The problem is closely related to Global Minimum Edge-Cut, where the weights are on the graph edges instead of vertices, and the goal is to compute a minimum-weight subset of edges whose removal disconnects the graph. Global Minimum Cut is one of the most basic and extensively studied problems in combinatorial optimization and graph theory. While an almost-linear time algorithm was known for the edge version of the problem for awhile (Karger, STOC 1996 and J. ACM 2000), the fastest previous algorithm for the vertex version (Henzinger, Rao and Gabow, FOCS 1996 and J. Algorithms 2000) achieves a running time of (mn), where m and n denote the number of edges and vertices in the input graph, respectively. For the special case of unit vertex weights, this bound was broken only recently (Li et al., STOC 2021); their result, combined with the recent breakthrough almost-linear time algorithm for Maximum s-t Flow (Chen et al., FOCS 2022, van den Brand et al., FOCS 2023), yields an almost-linear time algorithm for Global Minimum Vertex-Cut with unit vertex weights. In this paper we break the 28 years old bound of Henzinger et al. for the general weighted Global Minimum Vertex-Cut, by providing a randomized algorithm for the problem with running time O(min{mn0.99+o(1),m1.5+o(1)}).
AB - We consider the Global Minimum Vertex-Cut problem: given an undirected vertex-weighted graph G, compute a minimum-weight subset of its vertices whose removal disconnects G. The problem is closely related to Global Minimum Edge-Cut, where the weights are on the graph edges instead of vertices, and the goal is to compute a minimum-weight subset of edges whose removal disconnects the graph. Global Minimum Cut is one of the most basic and extensively studied problems in combinatorial optimization and graph theory. While an almost-linear time algorithm was known for the edge version of the problem for awhile (Karger, STOC 1996 and J. ACM 2000), the fastest previous algorithm for the vertex version (Henzinger, Rao and Gabow, FOCS 1996 and J. Algorithms 2000) achieves a running time of (mn), where m and n denote the number of edges and vertices in the input graph, respectively. For the special case of unit vertex weights, this bound was broken only recently (Li et al., STOC 2021); their result, combined with the recent breakthrough almost-linear time algorithm for Maximum s-t Flow (Chen et al., FOCS 2022, van den Brand et al., FOCS 2023), yields an almost-linear time algorithm for Global Minimum Vertex-Cut with unit vertex weights. In this paper we break the 28 years old bound of Henzinger et al. for the general weighted Global Minimum Vertex-Cut, by providing a randomized algorithm for the problem with running time O(min{mn0.99+o(1),m1.5+o(1)}).
KW - Global Minimum-Cut
KW - Maximum-Flow
UR - https://www.scopus.com/pages/publications/105009851800
U2 - 10.1145/3717823.3718185
DO - 10.1145/3717823.3718185
M3 - Conference contribution
AN - SCOPUS:105009851800
T3 - Proceedings of the Annual ACM Symposium on Theory of Computing
SP - 144
EP - 155
BT - STOC 2025 - Proceedings of the 57th Annual ACM Symposium on Theory of Computing
A2 - Koucky, Michal
A2 - Bansal, Nikhil
PB - Association for Computing Machinery
T2 - 57th Annual ACM Symposium on Theory of Computing, STOC 2025
Y2 - 23 June 2025 through 27 June 2025
ER -