𝔖 Bobbio Scriptorium
✦   LIBER   ✦

Delay-dependent dissipative control for linear time-delay systems

✍ Scribed by Zhihu Li; Jingcheng Wang; Huihe Shao

Publisher
Elsevier Science
Year
2002
Tongue
English
Weight
151 KB
Volume
339
Category
Article
ISSN
0016-0032

No coin nor oath required. For personal study only.

✦ Synopsis

This paper deals with the problem of delay-dependent dissipative control for a class of linear time-delay systems. We develop the design methods of dissipative static state feedback and dynamic output feedback controllers such that the closed-loop system is quadratically stable and strictly ðQ; S; RÞ-dissipative. Sufficient conditions for the existence of the quadratic dissipative controllers are obtained by using linear matrix inequality (LMI) approach. Furthermore, a procedure of constructing such controllers from the solutions of LMIs is given. It is shown that the solvability of a dissipative controller design problem is implied by the feasibility of LMIs. The main results of this paper unify the existing results on H N control and passive control.

πŸ“œ SIMILAR VOLUMES

Delay-dependent nonfragile guaranteed co
Delay-dependent nonfragile guaranteed cost control for nonlinear time-delay systems
✍ Nan Xie; Gong-You Tang πŸ“‚ Article πŸ“… 2006 πŸ› Elsevier Science 🌐 English βš– 144 KB

This paper concerns the nonfragile guaranteed cost control problem for a class of nonlinear dynamic systems with multiple time delays and controller gain perturbations. Guaranteed cost control law is designed under two classes of perturbations, namely, additive form and multiplicative form. The prob

Delay-dependent H∞ control for singular
Delay-dependent H∞ control for singular Markovian jump systems with time delay
✍ Zhengguang Wu; Hongye Su; Jian Chu πŸ“‚ Article πŸ“… 2009 πŸ› John Wiley and Sons 🌐 English βš– 144 KB

## Abstract The problem of delay‐dependent __H__~∞~ control is considered for singular Markovian jump systems with time delay. The aim of the problem is to design a state feedback controller, which guarantees that the resultant closed‐loop system is not only regular, impulse free and stochastically