Title :
Minimum-energy neural-fuzzy approach for current/voltage-controlled electromagnetic suspension system
Author :
Chang, Yen-Chen ; Wu, Shinq-Jen ; Lee, Tsu-Tian
Author_Institution :
Dept. of Electr. Eng., Da-Yeh Univ., Chang-Hwa, Taiwan
Abstract :
In this paper, the electromagnetic suspension system is modeled as a neural-based linear T-S fuzzy system, and then the optimal fuzzy control design scheme is proposed to control the current and voltage-controlled system with minimum current and voltage-controlled system with minimum current and voltage consumption, respectively. The proposed linear self-constructing neural fuzzy inference network is a six layer neural network (linear SONFIN) modified form the well-known SONFIN network, which can construct a linear T-S fuzzy model of the system just by the input and output (I/O) information. Based on the linear T-S model, we can construct the optimal fuzzy control scheme to efficiently regulate the highly nonlinear complex and uncertain electromagnetic suspension system to the equilibrium state.
Keywords :
control system synthesis; electric current control; fuzzy control; magnetic levitation; multilayer perceptrons; neurocontrollers; optimal control; suspensions; voltage control; SONFIN network; current control; electromagnetic suspension system; fuzzy control design; linear T-S fuzzy system; minimum-energy neural fuzzy approach; optimal fuzzy control; self-constructing neural fuzzy inference network; six layer neural network; voltage consumption; voltage control; Design engineering; Electromagnetic forces; Electromagnetic modeling; Fuzzy systems; Iron; Magnetic levitation; Nonlinear control systems; Nonlinear systems; Sliding mode control; Voltage;
Conference_Titel :
Computational Intelligence in Robotics and Automation, 2003. Proceedings. 2003 IEEE International Symposium on
Print_ISBN :
0-7803-7866-0
DOI :
10.1109/CIRA.2003.1222203
