Designing topological cluster synchronization patterns with the Dirac operator

TL;DR

This paper introduces a novel topological synchronization model using the Dirac operator, enabling the design of stable cluster synchronization patterns involving both nodes and edges in complex networks.

Contribution

It proposes a topological approach to cluster synchronization based on the Dirac operator, extending beyond traditional node-based methods.

Findings

Successfully designed stable topological cluster synchronization patterns.

Validated the approach on real connectome data and synthetic network models.

Provided stability analysis and numerical evidence for the proposed method.

Abstract

Designing stable cluster synchronization patterns is a fundamental challenge in nonlinear dynamics of networks with great relevance to understanding neuronal and brain dynamics. So far, cluster synchronization has been studied exclusively in a node-based dynamical approach, according to which oscillators are associated only with the nodes of the network. Here, we propose a topological synchronization dynamics model based on the use of the Topological Dirac operator, which allows us to design cluster synchronization patterns for topological oscillators associated with both nodes and edges of a network. In particular, by modulating the ground state of the free energy associated with the dynamical model, we construct topological cluster synchronization patterns. These are aligned with the eigenstates of the Topological Dirac Equation that provide a very useful decomposition of the dynamical state of node and edge signals associated with the network. We use linear stability analysis to predict the stability of the topological cluster synchronization patterns and provide numerical evidence of the ability to design several stable topological cluster synchronization states on real connectome data, random graphs, and on stochastic block models.