Title :
Relaxed stability conditions and systematic design of T-S fuzzy control systems
Author :
Meng, Xianyao ; Wang, Ning
Author_Institution :
Dept. of Autom.&Electr. Eng., Dalian Maritime Univ., Dalian
Abstract :
With the definition and investigation of the general fuzzy partition (GFP), the structural information of the premises and the interactions among the fuzzy subsystems were utilized sufficiently. The new relaxed stability conditions of T-S fuzzy systems were proposed for relaxing the conservatism of the previous ones. A theorem showed the relationships among the stability conditions we proposed. Based on the proposed stability conditions, we presented a systematic design method for T-S fuzzy control systems using parallel distributed compensation (PDC) principle and linear matrix inequalities (LMIs). Two computer simulations of mass-spring-damper nonlinear system demonstrate the effectiveness of the design methodology and the relaxedness of the relaxed stability conditions we proposed.
Keywords :
compensation; control system synthesis; fuzzy control; fuzzy set theory; fuzzy systems; linear matrix inequalities; stability; T-S fuzzy control system systematic design; fuzzy subsystem; general fuzzy partition; linear matrix inequality; parallel distributed compensation principle; relaxed stability condition; Computer simulation; Design automation; Design methodology; Fuzzy control; Fuzzy sets; Fuzzy systems; Lyapunov method; Nonlinear systems; Stability; Uncertainty; Fuzzy control; T-S fuzzy model; general fuzzy partition (GFP); stability; systematic design;
Conference_Titel :
Intelligent Control and Automation, 2008. WCICA 2008. 7th World Congress on
Conference_Location :
Chongqing
Print_ISBN :
978-1-4244-2113-8
Electronic_ISBN :
978-1-4244-2114-5
DOI :
10.1109/WCICA.2008.4592895
