Title :
Stabilization of Uncertain Singularly Perturbed Systems With Pole-Placement Constraints
Author :
Lin, Kuo-Jung ; Li, Tzuu-Hseng S.
Author_Institution :
Dept. of Electr. Eng., Fortune Inst. of Technol., Kaohsiung
Abstract :
This brief considers the problem of stabilization of uncertain singularly perturbed systems with pole-placement constraints by using H infin dynamic output feedback design. Based on the Lyapunov stability theorem and the tool of linear matrix inequality (LMI), we solve dynamic output feedback gain matrices and a set of common positive-definite matrices, and then some sufficient conditions are derived to stabilize the singularly perturbed systems with parametric uncertainties. Moreover, the developed Hinfin criterion guarantees that the influence of external disturbance is as small as possible and the poles of the closed-loop system are all located inside the LMI stability region. By the guaranteed epsiv-bound issue, the proposed scheme can stabilize the systems for all epsivisin(0,epsiv*). A circuit system is given to illustrate the validity of the proposed schemes
Keywords :
Hinfin control; closed loop systems; feedback; linear matrix inequalities; perturbation techniques; poles and zeros; stability; Hinfin dynamic output feedback design; LMI stability region; Lyapunov stability theorem; closed-loop system; dynamic output feedback gain matrices; linear matrix inequality; parametric uncertainties; pole-placement constraints; uncertain singularly perturbed systems; Circuit stability; Control system synthesis; Control systems; Linear matrix inequalities; Lyapunov method; Output feedback; Stability analysis; Stability criteria; Sufficient conditions; Uncertainty; Dynamic output feedback design; Lyapunov stability theorem; linear matrix inequality (LMI); singular perturbation systems;
Journal_Title :
Circuits and Systems II: Express Briefs, IEEE Transactions on
DOI :
10.1109/TCSII.2006.880016
