Interdiction of minimum spanning trees and other matroid bases

Noah Weninger, Ricardo Fukasawa
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引用次数: 0

Abstract

In the minimum spanning tree (MST) interdiction problem, we are given a graph $G=(V,E)$ with edge weights, and want to find some $X\subseteq E$ satisfying a knapsack constraint such that the MST weight in $(V,E\setminus X)$ is maximized. Since MSTs of $G$ are the minimum weight bases in the graphic matroid of $G$, this problem is a special case of matroid interdiction on a matroid $M=(E,\mathcal{I})$, in which the objective is instead to maximize the minimum weight of a basis of $M$ which is disjoint from $X$. By reduction from 0-1 knapsack, matroid interdiction is NP-complete, even for uniform matroids. We develop a new exact algorithm to solve the matroid interdiction problem. One of the key components of our algorithm is a dynamic programming upper bound which only requires that a simpler discrete derivative problem can be calculated/approximated for the given matroid. Our exact algorithm then uses this bound within a custom branch-and-bound algorithm. For different matroids, we show how this discrete derivative can be calculated/approximated. In particular, for partition matroids, this yields a pseudopolynomial time algorithm. For graphic matroids, an approximation can be obtained by solving a sequence of minimum cut problems, which we apply to the MST interdiction problem. The running time of our algorithm is asymptotically faster than the best known MST interdiction algorithm, up to polylog factors. Furthermore, our algorithm achieves state-of-the-art computational performance: we solved all available instances from the literature, and in many cases reduced the best running time from hours to seconds.
最小生成树和其他矩阵基的相互抵消
在最小生成树(MST)互斥问题中,我们给定了一个带边权重的图$G=(V,E)$,并希望找到某个满足knapsack约束的$X(Xsubseteq E$),使得$(V,E\setminus X)$中的MST权重达到最大。由于$G$的MST是$G$的图形matroid中的最小权基,这个问题是matroid interdiction在matroid $M=(E,\mathcal{I})$上的一个特例,其中的目标是最大化与$X$不相交的$M$基的最小权重。通过从 0-1 knapsack 的还原,矩阵互斥是 NP-完备的,即使对于均匀矩阵也是如此。我们开发了一种新的精确算法来解决 Matroid 互斥问题。我们算法的关键部分之一是动态编程上界,它只要求能计算/逼近给定 Matroid 的较简单离散导数问题。然后,我们的精确算法会在自定义的分支与边界算法中使用该上界。对于不同的矩阵,我们展示了如何计算/逼近离散导数。特别是对于分治矩阵,这产生了一种伪多项式时间算法。对于图形矩阵,可以通过求解一系列最小切割问题得到近似值,我们将其应用于 MST 拦截问题。我们算法的运行时间比已知的最佳 MST 互斥算法要快,快到多对数因子。此外,我们的算法达到了最先进的计算性能:我们解决了文献中所有可用的实例,并在许多情况下将最佳运行时间从数小时缩短到了数秒。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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