Title :
Affined-type Neural-Fuzzy Gap Control of Electromagnetic Suspension Systems
Author :
Wu, Shinq-Jen ; Wu, Cheng-Tao
Author_Institution :
Dept. of Electr. Eng., Da-Yeh Univ.
Abstract :
Electromagnetic suspension (EMS) systems are highly nonlinear, especially for current-controlled EMS, which is not only nonlinear to system states abut also to system inputs. And hence, theoretically approach to derive T-S fuzzy system is unsuitable. In this work, we use self-organizing neural-fuzzy technique to obtain affine-TS fuzzy models for both voltage-and current-controlled EMS systems. Based on these two models, affine-type optimal fuzzy controls for these two highly nonlinear systems are derived. The control performance and robustness to external disturbance are demonstrated and are compared with linear type. Since affine T-S fuzzy model can provide one more adjustable parameter for neural-fuzzy modelling, the derived affine TS-based controller could have better performance than linear type as system complexity increases. This phenomena obviously exists in simulation for current-controlled EMS systems
Keywords :
electric current control; electromagnetic devices; fuzzy control; fuzzy neural nets; neurocontrollers; nonlinear control systems; optimal control; robust control; self-adjusting systems; suspensions (mechanical components); voltage control; EMS current-control; T-S fuzzy system; adjustable parameter; affined-type neural-fuzzy gap control; control robustness; electromagnetic suspension systems; external disturbance; nonlinear systems; optimal fuzzy controls; system complexity; voltage control; Control systems; Fuzzy control; Fuzzy systems; Magnetic levitation; Mathematical model; Medical services; Nonlinear control systems; Nonlinear systems; Sliding mode control; Voltage;
Conference_Titel :
IEEE Industrial Electronics, IECON 2006 - 32nd Annual Conference on
Conference_Location :
Paris
Print_ISBN :
1-4244-0390-1
DOI :
10.1109/IECON.2006.347487
