Title :
Linear quadratic performance with worst case disturbance rejection
Author :
Lu, Wayne W. ; Balas, Gary J. ; Lee, E. Bruce
Author_Institution :
Dept. of Electr. Eng., Minnesota Univ., Minneapolis, MN, USA
Abstract :
The Lagrange multiplier method and maximum principle are proposed for the design of “LQR” controllers with the worst case disturbance rejection for a linear time-varying (LTV) plant on a finite horizon. The disturbance is bounded by either the windowed L2 -norm or the windowed L∞-norm or both. In the case of the windowed L2-norm, uncertain but norm bounded initial conditions are also considered. Certain necessary and sufficient conditions for the existence of a linear controller are derived. The results are extended to the steady state ones for the linear time-invariant (LTIV) plant on the infinite horizon. In the case of the windowed L∞-norm, the solution for the worst case disturbance turns out to be of switching (or bang-bang) type. Finally, some comparison to different problem settings in the windowed L2-norm case and an alternative approach are presented
Keywords :
control system synthesis; linear quadratic control; linear systems; maximum principle; state feedback; time-varying systems; LQR controllers; Lagrange multiplier method; finite horizon; linear quadratic performance; linear time-invariant plant; linear time-varying plant; maximum principle; necessary and sufficient conditions; windowed L∞-norm; windowed L2-norm; worst case disturbance rejection; Computer aided software engineering; Differential equations; Infinite horizon; Lagrangian functions; Minimax techniques; Performance analysis; Riccati equations; State feedback; Steady-state; Sufficient conditions;
Conference_Titel :
American Control Conference, Proceedings of the 1995
Conference_Location :
Seattle, WA
Print_ISBN :
0-7803-2445-5
DOI :
10.1109/ACC.1995.531230
