Phase Oscillator Networks with Nonlocal Higher-Order Interactions: Twisted States, Stability and Bifurcations

TL;DR

This paper investigates the stability and bifurcations of twisted states in phase oscillator networks with nonlocal higher-order interactions, revealing how these interactions influence synchronization patterns beyond traditional pairwise coupling.

Contribution

It introduces the analysis of higher-order nonpairwise interactions in ring-like oscillator networks, extending the understanding of twisted state stability and bifurcations.

Findings

Higher-order interactions can stabilize otherwise unstable twisted states.

Bifurcation diagrams are computed for various interaction types.

Pairwise and nonpairwise interactions have distinct effects on stability.

Abstract

The Kuramoto model provides a prototypical framework to synchronization phenomena in interacting particle systems. Apart from full phase synchrony where all oscillators behave identically, identical Kuramoto oscillators with ring-like nonlocal coupling can exhibit more elaborate patterns such as uniformly twisted states. It was discovered by Wiley, Strogatz and Girvan in 2006 that the stability of these twisted states depends on the coupling range of each oscillator. In this paper, we analyze twisted states and their bifurcations in the infinite particle limit of ring-like nonlocal coupling. We not only consider traditional pairwise interactions as in the Kuramoto model but also demonstrate the effects of higher-order nonpairwise interactions, which arise naturally in phase reductions. We elucidate how pairwise and nonpairwise interactions affect the stability of the twisted states, compute bifurcating branches, and show that higher-order interactions can stabilize twisted states that are unstable if the coupling is only pairwise.