Title :
Numerical computation of state feedback controllers for systems with persistent outputs
Author_Institution :
Dept. of Electron. Eng., La Trobe Univ., Bundoora, Vic., Australia
Abstract :
In this paper, we consider the problem of computing a state feedback controller for a class of nonlinear plants without requiring asymptotic stability of the resulting closed loop system. A simple generalization of the L2-gain inequality which permits persistent outputs is used as the objective in the control design. By considering notions of dissipation and available storage, the controller can be computed by solving a Hamilton-Jacobi-Bellman-Isaac PDE. Although this PDE rarely admits analytical solutions, finite differences may be applied to compute an approximation to both the available storage and the desired state feedback controller. Due to problems with convergence of conventional Jacobi value space iterations, a mixed policy space/value space algorithm is applied
Keywords :
asymptotic stability; closed loop systems; control system synthesis; nonlinear control systems; partial differential equations; state feedback; HJBI partial differential equation; Hamilton-Jacobi-Bellman-Isaac PDE; L2-gain inequality; asymptotic stability; closed loop system; control design; conventional Jacobi value space iterations; convergence; dissipation; finite differences; mixed policy space/value space algorithm; nonlinear plants; persistent outputs; state feedback controller; state feedback controllers; storage availability; Asymptotic stability; Closed loop systems; Control design; Control systems; Finite difference methods; Jacobian matrices; Limit-cycles; Nonlinear control systems; Stability analysis; State feedback;
Conference_Titel :
Decision and Control, 2000. Proceedings of the 39th IEEE Conference on
Conference_Location :
Sydney, NSW
Print_ISBN :
0-7803-6638-7
DOI :
10.1109/CDC.2001.914607
