Hypergraph reconstruction from dynamics

Robin Delabays, Giulia De Pasquale, Florian Dörfler, Yuanzhao Zhang
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引用次数: 0

Abstract

A plethora of methods have been developed in the past two decades to infer the underlying network structure of an interconnected system from its collective dynamics. However, methods capable of inferring nonpairwise interactions are only starting to appear. Here, we develop an inference algorithm based on sparse identification of nonlinear dynamics (SINDy) to reconstruct hypergraphs and simplicial complexes from time-series data. Our model-free method does not require information about node dynamics or coupling functions, making it applicable to complex systems that do not have reliable mathematical descriptions. We first benchmark the new method on synthetic data generated from Kuramoto and Lorenz dynamics. We then use it to infer the effective connectivity among seven brain regions from resting-state EEG data, which reveals significant contributions from non-pairwise interactions in shaping the macroscopic brain dynamics.
从动力学重建超图
在过去的二十年里,人们开发了大量的方法来从互联系统的集体动力学推断其基本网络结构。然而,能够推断非成对交互作用的方法才刚刚开始出现。在这里,我们开发了一种基于非线性动力学稀疏识别(SINDy)的推理算法,从时间序列数据中重建超图和简单复合物。我们的无模型方法不需要节点动力学或耦合函数信息,因此适用于没有可靠数学描述的复杂系统。我们首先在由 Kuramoto 和 Lorenz 动力学生成的合成数据上对新方法进行了基准测试。然后,我们利用它从静息态脑电数据中推断出七个脑区之间的有效连接性,发现非成对相互作用在塑造宏观脑动力学方面做出了重大贡献。
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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