Spatiotemporal stability of periodic travelling waves in a heteroclinic-cycle model

TL;DR

This study analyzes the stability of large-wavelength travelling waves in a cyclic competition model with heteroclinic cycles, revealing conditions for stability and developing methods to quantify growth rates of instabilities.

Contribution

The paper introduces a novel method for computing belts of instability and extends existing continuation schemes to analyze wave stability in heteroclinic-cycle models.

Findings

Large-wavelength travelling waves can be stable despite unstable fronts.

The developed method accurately quantifies growth rates of instabilities.

Stability transition curves are computed and verified by simulations.

Abstract

We study a Rock-Paper-Scissors model for competing populations that exhibits travelling waves in one spatial dimension and spiral waves in two spatial dimensions. A characteristic feature of the model is the presence of a robust heteroclinic cycle that involves three saddle equilibria. The model also has travelling fronts that are heteroclinic connections between two equilibria in a moving frame of reference, but these fronts are unstable. However, we find that large-wavelength travelling waves can be stable in spite of being made up of three of these unstable travelling fronts. In this paper, we focus on determining the essential spectrum (and hence, stability) of large-wavelength travelling waves in a cyclic competition model with one spatial dimension. We compute the curve of transitions from stability to instability with the continuation scheme developed by Rademacher et al. (2007 Physica D 229 166-83). We build on this scheme and develop a method for computing what we call belts of instability, which are indicators of the growth rate of unstable travelling waves. Our results from the stability analysis are verified by direct simulation for travelling waves as well as associated spiral waves. We also show how the computed growth rates accurately quantify the instabilities of the travelling waves.