Complex dynamics in adaptive phase oscillator networks

TL;DR

This paper investigates how adaptive coupling in Kuramoto oscillators influences collective dynamics, revealing complex bifurcation structures, multi-stability, and chaos, with implications for understanding neural plasticity.

Contribution

It introduces a minimal adaptive Kuramoto model with three parameters, systematically analyzing how adaptivity affects collective behavior and bifurcation scenarios.

Findings

Adaptive coupling enhances synchronization.

Non-trivial bifurcations emerge beyond a critical adaptivity threshold.

Rich dynamics including chaos and multi-stability are observed.

Abstract

Networks of coupled dynamical units give rise to collective dynamics such as the synchronization of oscillators or neurons in the brain. The ability of the network to adapt coupling strengths between units in accordance with their activity arises naturally in a variety of contexts, including neural plasticity in the brain, and adds an additional layer of complexity: the dynamics on the nodes influence the dynamics of the network and vice versa. We study a minimal model of Kuramoto phase oscillators including a general adaptive learning rule with three parameters (strength of adaptivity, adaptivity offset, adaptivity shift), mimicking learning paradigms based on spike-time-dependent-plasticity (STDP). Importantly, the strength of adaptivity allows to tune the system away away from the limit of the classical Kuramoto model, corresponding to stationary coupling strengths and no adaptation, and thus, to systematically study the impact of adaptivity on the collective dynamics. We carry out a detailed bifurcation analysis for the minimal model consisting of N = 2 oscillators. The non-adaptive Kuramoto model exhibits very simple dynamic behavior, drift or frequency-locking; but once the strength of adaptivity exceeds a critical threshold non-trivial bifurcation structures unravel: A symmetric adaptation rule results in multi-stability and bifurcation scenarios, and an asymmetric adaptation rule generates even more intriguing and rich dynamics, including a period doubling-cascade to chaos as well as oscillations displaying features of both librations and rotations simultaneously. Generally, adaptation improves the synchronizability of the oscillators. Finally, we also numerically investigate a larger system consisting of N = 50 oscillators and compare the resulting dynamics with the case of N = 2 oscillators.