Quantized dissipative observer-based output feedback control for a class of Markovian descriptor jump systems with communication delay (Q2173701)

Summary: This paper investigates the problem of quantized dissipative observer-based output feedback control of Markovian descriptor jump systems with unavailable states, appearing networked-induced delay. The descriptor systems are presented as Markovian jump systems which give a more realistic presentation for a variety of nonlinear dynamical systems than conventional state-space representation. To accomplish the objective, a uniform framework is employed to design the delayed Markov observer-based controller and event-triggered scheme. Additionally, we provided the \(\mathcal{H}_\infty\) and \(\mathcal{L}_2 - \mathcal{L}_\infty\) and dissipative performance indices which are robust against the disturbances with time-varying delays. Moreover, a novel Lyapunov-Krasovskii functional is considered to guarantee the closed loop for stochastic stability analysis of the Markovian descriptor jump system. The solvability of Lyapunov-Krasovskii functional results in the formation of linear matrix inequalities. The controller and observer gains can be obtained by solving the linear matrix inequalities. Simulations are performed to validate the proposed scheme.