A Fast and Effective Method to Identify Relevant Sets of Variables in Complex Systems

D’Addese, Gianluca; Casari, Martina; Serra, Roberto; Villani, Marco

doi:10.3390/math9091022

Cited by 4 publications

(1 citation statement)

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“…One of the directions explored by complex systems scientists is to embed the

variables onto a low-dimensional manifold, using information contained in their time series

[ 4 , 5 ]. Recently, D’Addese et al [ 6 ] and Villani et al [ 7 ] used information-theoretic methods to identify the relevant sets of variables in random Boolean networks, gene-regulatory networks, MAPK signaling pathways in eukaryotes, and other systems, and the manifold they evolve on. Others have turned instead to topological data analysis (TDA) and persistent homology to achieve the same goal [ 8 , 9 ].…”

Section: Introductionmentioning

confidence: 99%

Laplacian Spectra of Persistent Structures in Taiwan, Singapore, and US Stock Markets

Yen

Xia

Cheong

2023

Entropy

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An important challenge in the study of complex systems is to identify appropriate effective variables at different times. In this paper, we explain why structures that are persistent with respect to changes in length and time scales are proper effective variables, and illustrate how persistent structures can be identified from the spectra and Fiedler vector of the graph Laplacian at different stages of the topological data analysis (TDA) filtration process for twelve toy models. We then investigated four market crashes, three of which were related to the COVID-19 pandemic. In all four crashes, a persistent gap opens up in the Laplacian spectra when we go from a normal phase to a crash phase. In the crash phase, the persistent structure associated with the gap remains distinguishable up to a characteristic length scale where the first non-zero Laplacian eigenvalue changes most rapidly. Before , the distribution of components in the Fiedler vector is predominantly bi-modal, and this distribution becomes uni-modal after Our findings hint at the possibility of understanding market crashs in terms of both continuous and discontinuous changes. Beyond the graph Laplacian, we can also employ Hodge Laplacians of higher order for future research.

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“…One of the directions explored by complex systems scientists is to embed the

variables onto a low-dimensional manifold, using information contained in their time series

Section: Introductionmentioning

confidence: 99%