Analysis and synthesis of nonlinear controllers for input constrained systems using semidefinite programming optimization

Abstract

This work studies the problem of analyzing and, subsequently, optimizing the stabilization capabilities of a class of controllers for input constrained nonlinear systems. The proposed techniques apply to continuous, state feedback controllers which are defined in a subset of the state space where the time derivative of a known, candidate Control Lyapunov Function (CLF) can be made negative definite under the input constraints. This set is associated with the domain of this class of controllers and depends on the CLF. The analysis problem concerns approximating the domain and is posed via appropriately formulated set containment relationships through the generalized S-procedure with sum of squares (SOS) constraints. The optimization problem is concerned with the adjustment or enlargement of the domain and constitutes a way of controller synthesis. These objectives are pursued via optimizing over the coefficients of polynomial CLFs, through a sequence of semidefinite programming (SDP) problems with SOS constraints. By partitioning the state space based on the structure of the input value set and building upon earlier results on SOS methods, the SDP problems are subject to only convex constraints, rendering thus the proposed techniques computationally viable. The capabilities of the proposed algorithms are demonstrated through numerical examples.