A general method to stabilize unstable periodic orbits for switched dynamical systems with a periodically moving threshold

Journal 2018 International Peer-reviewed

Yuu Miino, Daisuke Ito, Hiroyuki Asahara, Takuji Kousaka, and Tetsushi Ueta

Journal
International Journal of Circuit Theory and Applications, Wiley
Volume
46 (12)
Pages
2380–2393
Date
August 2018

Abstract

In the previous study, a method to control chaos for switched dynamical systems with constant threshold value has been proposed. In this paper, we extend this method to the systems including a periodically moving threshold. The main control scheme is based on the pole placement; then, a small control perturbation added to the moving threshold value can stabilize an unstable periodic orbit embedded within a chaotic attractor. For an arbitrary periodic function of the threshold movement, we mathematically derive the variational equations, the state feedback parameters, and a control gain by composing a suitable Poincaré map. As examples, we illustrate control implementations for systems with thresholds whose movement waveforms are sinusoidal and sawtooth‐shape, and unstable one and two periodic orbits in each circuit are stabilized in numerical and circuit experiments. In these experiments, we confirm enough convergence of the control input.

DOI: 10.1002/cta.2573
Show BibTeX 
@article{miino2018general,
  author = {Miino, Yuu and Ito, Daisuke and Asahara, Hiroyuki and Kousaka, Takuji and Ueta, Tetsushi},
  title = {{A general method to stabilize unstable periodic orbits for switched dynamical systems with a periodically moving threshold}},
  journal = {International Journal of Circuit Theory and Applications},
  publisher = {John Wiley & Sons},
  year = {2018},
  month = {8},
  volume = {46},
  number = {12},
  pages = {2380--2393},
  abstract = {In the previous study, a method to control chaos for switched dynamical systems with constant threshold value has been proposed. In this paper, we extend this method to the systems including a periodically moving threshold. The main control scheme is based on the pole placement; then, a small control perturbation added to the moving threshold value can stabilize an unstable periodic orbit embedded within a chaotic attractor. For an arbitrary periodic function of the threshold movement, we mathematically derive the variational equations, the state feedback parameters, and a control gain by composing a suitable Poincaré map. As examples, we illustrate control implementations for systems with thresholds whose movement waveforms are sinusoidal and sawtooth‐shape, and unstable one and two periodic orbits in each circuit are stabilized in numerical and circuit experiments. In these experiments, we confirm enough convergence of the control input.},
  doi = {10.1002/cta.2573},
  issn = {1097007X},
  scope = {international},
  review = {reviewed},
  langid = {english}
}