Diameter-Constrained Reliability: Complexity, Factorization and Exact computation in Weak Graphs

International Latin American Networking Conference Pub Date : 2014-09-18 DOI:10.1145/2684083.2684095

E. Canale, J. Piccini, F. Robledo, P. Romero

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引用次数: 4

Abstract

In this paper we address a problem from the field of network reliability, called diameter-constrained reliability. Specifically, we are given a simple graph G = (V, E) with [V] = n nodes and [E] = m links, a subset K ⊆ V of terminals, a vector p = (p1,...,pm) &epsis; [0, 1]m and a positive integer d, called diameter. We assume nodes are perfect but links fail stochastically and independently, with probabilities qi = 1 --- pi. The diameter-constrained reliability (DCR for short), is the probability that the terminals of the resulting subgraph remain connected by paths composed by d links, or less. This number is denoted by RdK,G(p). The general DCR computation is inside the class of NP-Hard problems, since is subsumes the complexity that a random graph is connected. In this paper the computational complexity of DCR-subproblems is discussed in terms of the number of terminal nodes k = [K] and diameter d. A factorization formula for exact DCR computation is provided, that runs in exponential time in the worst case. Finally, a revision of graph-classes that accept DCR computation in polynomial time is then included. In this class we have graphs with bounded co-rank, graphs with bounded genus, planar graphs, and, in particular, Monma graphs, which are relevant in robust network design. We extend this class adding arborescence graphs. A discussion of trends for future work is offered in the conclusions.

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直径约束可靠性:弱图的复杂性、分解和精确计算

本文讨论了网络可靠性领域中的一个问题，即直径约束可靠性。具体地说，我们给定一个简单图G = (V, E)，其中[V] = n个节点，[E] = m个链路，一个子集K⊥V，一个向量p = (p1，…，pm) &epsis;[0,1]m和正整数d，称为直径。我们假设节点是完美的，但链接随机且独立地失效，概率qi = 1 - pi。直径约束可靠度(简称DCR)是结果子图的终端保持由d条或更少的链路组成的路径连接的概率。这个数用RdK,G(p)表示。一般的DCR计算属于NP-Hard问题，因为它包含了随机图连接的复杂性。本文从终端节点数k = [k]和直径d的角度讨论了DCR子问题的计算复杂度，并给出了精确DCR计算的分解公式，在最坏情况下以指数级时间运行。最后，对图类进行了修正，使其可以在多项式时间内进行DCR计算。在这门课中，我们学习了有界共秩图、有界属图、平面图，特别是与鲁棒网络设计相关的Monma图。我们扩展这个类，添加树形图。结论部分对今后的工作趋势进行了讨论。

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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International Latin American Networking Conference

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