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利用信息流揭示网络上噪声诱导转变的级联效应。

Cascades Towards Noise-Induced Transitions on Networks Revealed Using Information Flows.

作者信息

van Elteren Casper, Quax Rick, Sloot Peter M A

机构信息

Institute of Informatics, University of Amsterdam, 1098 XH Amsterdam, The Netherlands.

Institute for Advanced Study, 1012 GC Amsterdam, The Netherlands.

出版信息

Entropy (Basel). 2024 Dec 4;26(12):1050. doi: 10.3390/e26121050.

DOI:10.3390/e26121050
PMID:39766679
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11675381/
Abstract

Complex networks, from neuronal assemblies to social systems, can exhibit abrupt, system-wide transitions without external forcing. These endogenously generated "noise-induced transitions" emerge from the intricate interplay between network structure and local dynamics, yet their underlying mechanisms remain elusive. Our study unveils two critical roles that nodes play in catalyzing these transitions within dynamical networks governed by the Boltzmann-Gibbs distribution. We introduce the concept of "initiator nodes", which absorb and propagate short-lived fluctuations, temporarily destabilizing their neighbors. This process initiates a domino effect, where the stability of a node inversely correlates with the number of destabilized neighbors required to tip it. As the system approaches a tipping point, we identify "stabilizer nodes" that encode the system's long-term memory, ultimately reversing the domino effect and settling the network into a new stable attractor. Through targeted interventions, we demonstrate how these roles can be manipulated to either promote or inhibit systemic transitions. Our findings provide a novel framework for understanding and potentially controlling endogenously generated metastable behavior in complex networks. This approach opens new avenues for predicting and managing critical transitions in diverse fields, from neuroscience to social dynamics and beyond.

摘要

从神经元集合到社会系统,复杂网络可以在没有外部强迫的情况下呈现出突然的、全系统范围的转变。这些内源性产生的“噪声诱导转变”源于网络结构与局部动力学之间复杂的相互作用,但其潜在机制仍然难以捉摸。我们的研究揭示了节点在由玻尔兹曼-吉布斯分布支配的动态网络中催化这些转变时所起的两个关键作用。我们引入了“引发节点”的概念,这些节点吸收并传播短暂的波动,暂时使其邻居失去稳定性。这个过程引发了多米诺效应,其中一个节点的稳定性与其被颠覆所需的不稳定邻居数量成反比。当系统接近临界点时,我们确定了“稳定节点”,它们编码系统的长期记忆,最终扭转多米诺效应并使网络进入一个新的稳定吸引子。通过有针对性的干预,我们展示了如何操纵这些角色来促进或抑制系统转变。我们的发现为理解并潜在地控制复杂网络中内源性产生的亚稳态行为提供了一个新的框架。这种方法为预测和管理从神经科学到社会动力学及其他领域的各种关键转变开辟了新途径。

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