Title :
Direct optimal vibration control
Author :
öz, Hayrani ; Yen, Gary
Author_Institution :
Dept. of Aerosp. Eng., Ohio State Univ., Columbus, OH, USA
Abstract :
The study of dynamic systems without resorting to or any knowledge of differential equations is known as the “direct method”. In this method, algebraic equations of motion characterize the system dynamics. The algebraic optimal control laws can be derived in an explicit form for general nonlinear time-varying and time-invariant systems by minimizing an algebraic performance measure. The essence of the approach is based on using assumed-time-modes expansions of generalized coordinates and inputs in conjunction with the variational work-energy principles that govern the physical system. However to implement these control laws an algebraic state estimator must be designed. The development of such an estimator is incorporated by utilizing neural networks within hybrid algebraic equations of motion for general nonlinear systems. As modeling uncertainty is concerned, both parameter uncertainty and model truncation have been considered
Keywords :
algebra; linear systems; neural nets; nonlinear control systems; optimal control; state feedback; uncertain systems; vibration control; algebraic equations of motion; algebraic optimal control laws; algebraic state estimator; assumed-time-modes expansions; direct optimal vibration control; dynamic systems; general nonlinear systems; model truncation; modeling uncertainty; neural networks; parameter uncertainty; system dynamics; variational work-energy principles; Differential equations; Motion estimation; Neural networks; Nonlinear dynamical systems; Nonlinear equations; Nonlinear systems; Optimal control; State estimation; Time varying systems; Vibration control;
Conference_Titel :
American Control Conference, 1997. Proceedings of the 1997
Conference_Location :
Albuquerque, NM
Print_ISBN :
0-7803-3832-4
DOI :
10.1109/ACC.1997.610893
