Title :
Sliding-mode control of a chaotic pendulum: stabilization and targeting of an unstable periodic orbit
Author :
Lenz, Henning ; Berstecher, Ralph
Author_Institution :
Corp. Technol., Siemens AG, Munich, Germany
Abstract :
Using linear methods, both a stabilizing and a targeting controller have to be designed to control a chaotic system on an unstable periodic orbit. In this paper, it is shown that by applying a sliding-mode controller stabilization and targeting of periodic orbits can be achieved simultaneously. Sliding-mode controllers are nonlinear controllers. Systems controlled by sliding-mode controllers exhibit robust behavior towards model uncertainties and noise. The proposed method is proven to be suitable for chaotic systems even in the presence of model uncertainties and noise. To prevent chattering and to increase robustness, the hyperbolic tangent is applied within the boundary layer of the sliding-mode controller. The analysis is illustrated for the harmonically driven damped pendulum
Keywords :
chaos; control system synthesis; nonlinear control systems; robust control; time-varying systems; uncertain systems; variable structure systems; boundary layer; chaotic pendulum; chattering; harmonically driven damped pendulum; hyperbolic tangent; linear methods; model uncertainties; noise; nonlinear controllers; robust behavior; sliding-mode control; stabilization; targeting controller; unstable periodic orbit; Chaos; Chaotic communication; Communication system control; Control systems; Harmonic analysis; Noise robustness; Nonlinear control systems; Robust control; Sliding mode control; Uncertainty;
Conference_Titel :
Control of Oscillations and Chaos, 1997. Proceedings., 1997 1st International Conference
Conference_Location :
St. Petersburg
Print_ISBN :
0-7803-4247-X
DOI :
10.1109/COC.1997.626674
