Ranking Edges by Their Impact on the Spectral Complexity of Information Diffusion over Networks

Jeremy Kazimer, Manlio De Domenico, Peter J. Mucha, Dane Taylor
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Abstract

Multiscale Modeling &Simulation, Volume 22, Issue 3, Page 925-955, September 2024.
Abstract. Despite the numerous ways now available to quantify which parts or subsystems of a network are most important, there remains a lack of centrality measures that are related to the complexity of information flows and are derived directly from entropy measures. Here, we introduce a ranking of edges based on how each edge’s removal would change a system’s von Neumann entropy (VNE), which is a spectral-entropy measure that has been adapted from quantum information theory to quantify the complexity of information dynamics over networks. We show that a direct calculation of such rankings is computationally inefficient (or unfeasible) for large networks, since the possible removal of [math] edges requires that one compute all the eigenvalues of [math] distinct matrices. To overcome this limitation, we employ spectral perturbation theory to estimate VNE perturbations and derive an approximate edge-ranking algorithm that is accurate and has a computational complexity that scales as [math] for networks with [math] nodes. Focusing on a form of VNE that is associated with a transport operator [math], where [math] is a graph Laplacian matrix and [math] is a diffusion timescale parameter, we apply this approach to diverse applications including a network encoding polarized voting patterns of the 117th U.S. Senate, a multimodal transportation system including roads and metro lines in London, and a multiplex brain network encoding correlated human brain activity. Our experiments highlight situations where the edges that are considered to be most important for information diffusion complexity can dramatically change as one considers short, intermediate, and long timescales [math] for diffusion.
根据边缘对网络信息扩散频谱复杂性的影响排序
多尺度建模与仿真》,第 22 卷第 3 期,第 925-955 页,2024 年 9 月。 摘要尽管现在有很多方法可以量化网络中最重要的部分或子系统,但仍然缺乏与信息流复杂性相关的、直接从熵度量得出的中心性度量。在这里,我们根据每条边的移除会如何改变系统的冯-诺依曼熵(Von Neumann entropy,VNE)引入了一种边的排序方法,VNE 是一种光谱熵度量,从量子信息论中改编而来,用于量化网络信息动态的复杂性。我们的研究表明,对于大型网络来说,直接计算这种排名在计算上是低效的(或不可行的),因为[数学]边的可能移除需要计算[数学]不同矩阵的所有特征值。为了克服这一限制,我们采用频谱扰动理论来估算 VNE 扰动,并推导出一种近似的边缘排序算法,该算法对于具有 [math] 个节点的网络来说,不仅准确,而且计算复杂度与 [math] 一样大。我们将重点放在与传输算子[math]相关联的 VNE 形式上,其中[math]是图拉普拉斯矩阵,[math]是扩散时标参数。我们将这种方法应用于各种不同的应用,包括编码第 117 届美国参议院极化投票模式的网络、包括伦敦道路和地铁线路在内的多式联运系统,以及编码相关人类大脑活动的多路复用大脑网络。我们的实验凸显了这样一种情况:当我们考虑信息扩散的短期、中期和长期时间尺度[数学]时,被认为对信息扩散复杂性最重要的边缘会发生巨大变化。
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