Budget and Profit Approximations for Spanning Tree Interdiction

TL;DR

This paper presents polynomial-time approximation algorithms with logarithmic guarantees for budget and profit maximization problems in minimum spanning tree interdiction, and introduces an efficient solution for a related polynomial-time solvable interdiction variant.

Contribution

It introduces new approximation guarantees for spanning tree interdiction problems and proposes a graph-theoretic relaxation and a greedy algorithm for the budget version.

Findings

Logarithmic approximation guarantees for interdiction problems.

Polynomial-time algorithm for a special interdiction case.

Super-modularity of the spanning tree weight increase function.

Abstract

We give polynomial time logarithmic approximation guarantees for the budget minimization, as well as for the profit maximization versions of minimum spanning tree interdiction. In this problem, the goal is to remove some edges of an undirected graph with edge weights and edge costs, so as to increase the weight of a minimum spanning tree. In the budget minimization version, the goal is to minimize the total cost of the removed edges, while achieving a desired increase $\Delta$ in the weight of the minimum spanning tree. An alternative objective within the same framework is to maximize the profit of interdiction, namely the increase in the weight of the minimum spanning tree, subject to a budget constraint. There are known polynomial time $O(1)$ approximation guarantees for a similar objective (maximizing the total cost of the tree, rather than the increase). However, the guarantee does not seem to apply to the increase in cost. Moreover, the same techniques do not seem to apply to the budget version. Our approximation guarantees are motivated by studying the question of minimizing the cost of increasing the minimum spanning tree by any amount. We show that in contrast to the budget and profit problems, this version of interdiction is polynomial time-solvable, and we give an efficient algorithm for solving it. The solution motivates a graph-theoretic relaxation of the NP-hard interdiction problem. The gain in minimum spanning tree weight, as a function of the set of removed edges, is super-modular. Thus, the budget problem is an instance of minimizing a linear function subject to a super-modular covering constraint. We use the graph-theoretic relaxation to design and analyze a batch greedy-based algorithm.