A new method for stabilizing unstable periodic orbits of continuous-time systems. Application to control of chaos

Author

Chagas, T.P. ; Bliman, P. ; Kienitz, Karl Heinz

Author_Institution

Univ. Estadual de Santa Cruz (UESC), Ilhéus, Brazil

fYear

2012

fDate

10-13 Dec. 2012

Firstpage

2146

Lastpage

2151

Abstract

This work presents a new method of stabilization for unstable periodic orbits of continuous-time dynamical systems. The principle of this method is to use feedback term based on the difference between the actual state value and the future state value computed along the trajectories of the uncontrolled system. To compute the value of the latter, an implicit Runge-Kutta ODE integration method is used, giving rise to a time-varying dynamical controller. The stability of the control method is defined in terms of the Floquet theory and the conditions for calculation of the monodromy matrix are presented. Numerical results are obtained using the forced Van der Pol oscillator as case study and the orthogonal collocation method as implicit Runge-Kutta method.

Keywords

Runge-Kutta methods; continuous time systems; differential equations; feedback; matrix algebra; periodic control; relaxation oscillators; stability; time-varying systems; Floquet theory; Runge-Kutta ODE integration method; chaos control; continuous-time dynamical system; feedback term; forced Van der Pol oscillator; monodromy matrix; orthogonal collocation method; stabilization; time-varying dynamical controller; unstable periodic orbit; Approximation methods; Chaos; Equations; Estimation; Mathematical model; Orbits; Trajectory;

fLanguage

English

Publisher

ieee

Conference_Titel

Decision and Control (CDC), 2012 IEEE 51st Annual Conference on

Conference_Location

Maui, HI

ISSN

0743-1546

Print_ISBN

978-1-4673-2065-8

Electronic_ISBN

0743-1546

Type

conf

DOI

10.1109/CDC.2012.6426456

Filename

6426456