Critical Synchronization Dynamics of the Kuramoto Model on Connectome and Small World Graphs

Overview

Journal Sci Rep

Specialty Science

Date 2019 Dec 25

PMID 31873076

Citations 7

Authors

Geza Odor

Jeffrey Kelling

Affiliations

Soon will be listed here.

Abstract

The hypothesis, that cortical dynamics operates near criticality also suggests, that it exhibits universal critical exponents which marks the Kuramoto equation, a fundamental model for synchronization, as a prime candidate for an underlying universal model. Here, we determined the synchronization behavior of this model by solving it numerically on a large, weighted human connectome network, containing 836733 nodes, in an assumed homeostatic state. Since this graph has a topological dimension d < 4, a real synchronization phase transition is not possible in the thermodynamic limit, still we could locate a transition between partially synchronized and desynchronized states. At this crossover point we observe power-law-tailed synchronization durations, with τ ≃ 1.2(1), away from experimental values for the brain. For comparison, on a large two-dimensional lattice, having additional random, long-range links, we obtain a mean-field value: τ ≃ 1.6(1). However, below the transition of the connectome we found global coupling control-parameter dependent exponents 1 < τ ≤ 2, overlapping with the range of human brain experiments. We also studied the effects of random flipping of a small portion of link weights, mimicking a network with inhibitory interactions, and found similar results. The control-parameter dependent exponent suggests extended dynamical criticality below the transition point.

Citing Articles

Frustrated Synchronization of the Kuramoto Model on Complex Networks.

Odor G, Deng S, Kelling J Entropy (Basel). 2025; 26(12.

PMID: 39766703 PMC: 11675184. DOI: 10.3390/e26121074.

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Reaction-diffusion models in weighted and directed connectomes.

Schmitt O, Nitzsche C, Eipert P, Prathapan V, Hutt M, Hilgetag C PLoS Comput Biol. 2022; 18(10):e1010507.

PMID: 36306284 PMC: 9683624. DOI: 10.1371/journal.pcbi.1010507.

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