Oscillatory networks: Insights from piecewise-linear modeling

TL;DR

This paper reviews methods for analyzing coupled oscillator networks, emphasizing piecewise-linear models and nonsmooth dynamics, providing insights into complex biological and mechanical systems.

Contribution

It introduces techniques combining network science and nonsmooth dynamical systems, especially saltation operators, for analyzing piecewise-linear oscillator networks.

Findings

Periodic orbits can be explicitly constructed in piecewise-linear systems.

Saltation operators effectively analyze bifurcations in nonsmooth networks.

Applications include neural, cardiac, electro-mechanical, and cooperative systems.

Abstract

There is enormous interest -- both mathematically and in diverse applications -- in understanding the dynamics of coupled oscillator networks. The real-world motivation of such networks arises from studies of the brain, the heart, ecology, and more. It is common to describe the rich emergent behavior in these systems in terms of complex patterns of network activity that reflect both the connectivity and the nonlinear dynamics of the network components. Such behavior is often organized around phase-locked periodic states and their instabilities. However, the explicit calculation of periodic orbits in nonlinear systems (even in low dimensions) is notoriously hard, so network-level insights often require the numerical construction of some underlying periodic component. In this paper, we review powerful techniques for studying coupled oscillator networks. We discuss phase reductions, phase-amplitude reductions, and the master stability function for smooth dynamical systems. We then focus in particular on the augmentation of these methods to analyze piecewise-linear systems, for which one can readily construct periodic orbits. This yields useful insights into network behavior, but the cost is that one needs to study nonsmooth dynamical systems. The study of nonsmooth systems is well-developed when focusing on the interacting units (i.e., at the node level) of a system, and we give a detailed presentation of how to use \textit{saltation operators}, which can treat the propagation of perturbations through switching manifolds, to understand dynamics and bifurcations at the network level. We illustrate this merger of tools and techniques from network science and nonsmooth dynamical systems with applications to neural systems, cardiac systems, networks of electro-mechanical oscillators, and cooperation in cattle herds.