Controlling spatiotemporal chaos and spiral turbulence in excitable media: A review

TL;DR

This review discusses recent low-amplitude control methods for managing spatiotemporal chaos and spiral turbulence in excitable media, with implications for conditions like cardiac fibrillation.

Contribution

It classifies and evaluates recent control schemes for chaos in excitable media, highlighting their advantages and limitations.

Findings

Low-amplitude control methods can effectively suppress chaos.

Control schemes are categorized into global, non-global, and local types.

Each control type has specific benefits and challenges.

Abstract

Excitable media are a generic class of models used to simulate a wide variety of natural systems including cardiac tissue. Propagation of excitation waves in this medium results in the formation of characteristic patterns such as rotating spiral waves. Instabilities in these structures may lead to spatiotemporal chaos through spiral turbulence, which has been linked to clinically diagnosed conditions such as cardiac fibrillation. Usual methods for controlling such phenomena involve very large amplitude perturbations and have several drawbacks. There have been several recent attempts to develop low-amplitude control procedures for spatiotemporal chaos in excitable media which are reviewed in this paper. The control schemes have been broadly classified by us into three types: (i) global, (ii) non-global spatially-extended and (iii) local, depending on the way the control signal is applied, and we discuss the merits and drawbacks for each.