近似最大流量计算的高效启发式方法

arXiv - STAT - Methodology Pub Date : 2024-09-12 DOI:arxiv-2409.08350

Jingyun Qian, Georg Hahn

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引用次数: 0

摘要

为了更好地理解（人类）大脑的内部运作，人们经常使用从图论中借用的一些概念。为此，首先要建立大脑的连接网络，然后通过最短路径和最大流计算来评估信息流和信息路由等数量。由于大脑网络通常包含数千个节点和边，因此计算扩展是一个关键的研究领域。在本文中，我们将重点研究大型脑网络中的近似最大流计算。通过将图分割与最大流计算相结合，我们提出了一种计算最大流的新近似算法，其运行时间为 O(|V||E|^2/k^2)，而 Edmonds-Karp 算法的通常运行时间为 O(|V||E|^2)，其中 $V$ 是顶点集，$E$ 是边集，$k$ 是分割数。我们在模拟图以及从脑网络数据存储库（https://networkrepository.com）下载的图上评估了所提算法的准确性和运行时间。

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An efficient heuristic for approximate maximum flow computations

Several concepts borrowed from graph theory are routinely used to better understand the inner workings of the (human) brain. To this end, a connectivity network of the brain is built first, which then allows one to assess quantities such as information flow and information routing via shortest path and maximum flow computations. Since brain networks typically contain several thousand nodes and edges, computational scaling is a key research area. In this contribution, we focus on approximate maximum flow computations in large brain networks. By combining graph partitioning with maximum flow computations, we propose a new approximation algorithm for the computation of the maximum flow with runtime O(|V||E|^2/k^2) compared to the usual runtime of O(|V||E|^2) for the Edmonds-Karp algorithm, where $V$ is the set of vertices, $E$ is the set of edges, and $k$ is the number of partitions. We assess both accuracy and runtime of the proposed algorithm on simulated graphs as well as on graphs downloaded from the Brain Networks Data Repository (https://networkrepository.com).

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arXiv - STAT - Methodology

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