An LMI approach for robust stabilization of aperiodic uncertain sampled-data systems

The aim of this paper is to investigate the problem of robust stabilization of aperiodic uncertain sampled-data linear systems. Using an impulsive system representation, synthesis conditions are proposed in terms of parameter-dependent linear matrix inequalities (LMIs). Differently from the existing approaches, the resulting state-feedback control gain is not obtained directly from the Lyapunov matrix, easing the task of imposing particular structures to the controller, such as decentralization. Moreover, using a convenient change of variables, a more efficient polynomial approximation is proposed to solve the parameter-dependent LMIs when compared to sum-of-square techniques. An extension to deal with uncertain sampled-data linear systems with periodic sampling interval based on parameter-dependent Lyapunov matrices is also proposed. Numerical examples illustrate the applicability, the advantages, and how the conservativeness of the conditions can be reduced by employing polynomial parameter-dependent decision variables in the proposed conditions when compared with standard approaches from the literature. (AU)