Threshold Minimum Cut with Terminal Quotas: Logarithmic and Planar Approximation Algorithms

Abstract

We study threshold minimum cut problems with a distinguished root vertex, a set of terminals, and a quota. In the threshold minimum edge cut problem (), the goal is to find a minimum-cost edge cut that disconnects at least k terminals from the root. In the threshold minimum node cut problem (), the goal is to delete a minimum-cost set of nonterminal, nonroot vertices so that at least k terminals become disconnected from the root. We prove three approximation guarantees. First, undirected general-graph admits a randomized polynomial-time expected O( n) approximation via a Räcke-style cut-dominating tree decomposition and an exact dynamic program on trees. A standard repetition argument gives the same asymptotic ratio with high probability. Second, planar admits a factor-2 approximation by reducing the threshold condition to planar weighted balanced cut. Third, bounded-degree planar admits a 2Δ-approximation, where Δ is the maximum degree of a deletable vertex, by reducing the node-cost problem to the planar edge-cut problem on the same graph. The results separate exact-quota guarantees from bicriteria small-set-expansion-type guarantees and identify the unbounded-degree planar node-cut case as the main remaining obstacle.