Periodic orbits in the Ott-Antonsen manifold

TL;DR

This paper introduces a universal method for analyzing non-equilibrium periodic states in the Ott-Antonsen manifold, enabling efficient bifurcation analysis of complex collective dynamics in oscillator networks.

Contribution

It presents a novel approach using the Poincaré map of the Riccati equation, matching the Möbius transformation, to study periodic states beyond equilibrium in the Ott-Antonsen framework.

Findings

Developed a method for analyzing periodic states in the Ott-Antonsen manifold.

Calculated a complete bifurcation diagram of traveling chimera states.

Demonstrated the method on a ring network with asymmetric nonlocal coupling.

Abstract

In their seminal paper [Chaos 18, 037113 (2008)], E. Ott and T. M. Antonsen showed that large groups of phase oscillators driven by a certain type of common force display low dimensional long-term dynamics, which is described by a small number of ordinary differential equations. This fact was later used as a simplifying reduction technique in many studies of synchronization phenomena occurring in networks of coupled oscillators and in neural networks. Most of these studies focused mainly on partially synchronized states corresponding to the equilibrium-type dynamics in the so called Ott-Antonsen manifold. Going beyond this paradigm, here we propose a universal approach for the efficient analysis of partially synchronized states with non-equilibrium periodic collective dynamics. Our method is based on the observation that the Poincar\'e map of the complex Riccati equation, which describes the dynamics in the Ott-Antonsen manifold, coincides with the well-known M\"obius transformation. To illustrate the possibilities of our method, we use it to calculate a complete bifurcation diagram of travelling chimera states in a ring network of phase oscillators with asymmetric nonlocal coupling.