Title :
Worst case analysis of nonlinear systems
Author :
Fialho, Ian J. ; Georgiou, Tryphon T.
Author_Institution :
Dept. of Aerosp. Eng. & Mech., Minnesota Univ., Minneapolis, MN, USA
fDate :
6/1/1999 12:00:00 AM
Abstract :
The authors work out a framework for evaluating the performance of a continuous-time nonlinear system when this is quantified as the maximal value at an output port under bounded disturbances-the disturbance problem. This is useful in computing gain functions and L ∞-induced norms, which are often used to characterize performance and robustness of feedback systems. The approach is variational and relies on the theory of viscosity solutions of Hamilton-Jacobi equations. Convergence of Euler approximation schemes via discrete dynamic programming is established. The authors also provide an algorithm to compute upper bounds for value functions. Differences between the disturbance problem and the optimal control problem are noted, and a proof of convergence of approximation schemes for the control problem is given. Case studies are presented which assess the robustness of a feedback system and the quality of trajectory tracking in the presence of structured uncertainty
Keywords :
approximation theory; continuous time systems; convergence; dynamic programming; feedback; nonlinear control systems; nonlinear dynamical systems; optimal control; robust control; uncertain systems; variational techniques; Euler approximation schemes; Hamilton-Jacobi equations; L∞-induced norms; bounded disturbances; continuous-time nonlinear system; discrete dynamic programming; gain functions; structured uncertainty; trajectory tracking; value functions; viscosity solutions; worst case analysis; Dynamic programming; Equations; Feedback; Nonlinear systems; Optimal control; Performance gain; Robustness; Trajectory; Upper bound; Viscosity;
Journal_Title :
Automatic Control, IEEE Transactions on
