The stability of adaptive synchronization of chaotic systems

TL;DR

This paper investigates the stability of adaptive synchronization in chaotic systems, extending the master stability function technique to analyze local stability and bubbling phenomena, with numerical experiments illustrating the impact of adaptation parameters.

Contribution

It introduces an extension of the master stability function method to study adaptive synchronization stability, including bubbling effects, in chaotic systems.

Findings

Stable synchronization range depends on adaptation parameters

Bubbling can destabilize synchronization in practical scenarios

Numerical experiments confirm theoretical stability analysis

Abstract

In past works, various schemes for adaptive synchronization of chaotic systems have been proposed. The stability of such schemes is central to their utilization. As an example addressing this issue, we consider a recently proposed adaptive scheme for maintaining the synchronized state of identical coupled chaotic systems in the presence of a priori unknown slow temporal drift in the couplings. For this illustrative example, we develop an extension of the master stability function technique to study synchronization stability with adaptive coupling. Using this formulation, we examine local stability of synchronization for typical chaotic orbits and for unstable periodic orbits within the synchronized chaotic attractor (bubbling). Numerical experiments illustrating the results are presented. We observe that the stable range of synchronism can be sensitively dependent on the adaption parameters, and we discuss the strong implication of bubbling for practically achievable adaptive synchronization.