Abstract EN:

In this thesis, we study two problems on stabilization of linear systems by static feedbacks which are bounded and time-delayed, namely global asymptotic stabilization and finite-gain stabilizability. Both continuous-time and discrete-time systems are considered. Regarding the problem of global asymptotic stabilization we provide, under standard necessary conditions, two different solutions for arbitrary small bound on the control and large (constant) delay. The first solution uses nested saturations, in the line of [MMN1], [MMN2], [SSY] and [YSS]. The second solution, a sort of "predictor-corrector", assumes the knowledge of a static stabilizing feedback law in the zero-delay case. For the finite-gain stabilizability issue, we assume that the system is neutrally stable. We show the existence of a linear feedback such that, for arbitrary small bound on the control and large (constant) delay, finite-gain stability holds. Moreover, the corresponding gains are delay-independent for all [dollar]p \in [1,\infty]. [dollar] Generally speaking, our treatment of the aforementioned issues on time-delay systems follows a common pattern. We always try to reformulate them as problems for perturbed delay-free systems and handle the perturbation by Lyapunov techniques or by a careful trajectory analysis. That strategy works well because the input saturation makes the perturbation uniformly bounded with respect to the delay.