Title :
Adaptive control of variable reluctance motors: a spline function approach
Author :
Bortoff, Scott A. ; Kohan, Rashid R. ; Milman, Ruth
Author_Institution :
Dept. of Electr. Eng., Toronto Univ., Ont., Canada
fDate :
6/1/1998 12:00:00 AM
Abstract :
This paper considers nonlinear adaptive control of a variable reluctance motor (VRM) in a low-velocity high-torque mode of operation. A simple dynamic model for the relationship among electric torque, rotor angular position, and phase currents is proposed. The model incorporates spline functions and a set of “Fourier” sinusoids and captures several experimentally verified VRM characteristics, including flux saturation effects. Based on this model, an adaptive controller is derived using the certainty equivalence principle. The controller provides asymptotic tracking of a desired rotor position trajectory. So-called “torque-sharing functions” are employed to smooth the commutation among phases and to increase the peak torque available from the motor, when compared to “hard” commutation that energizes only one phase at a time. Experimental results from a laboratory VRM provide motivation for the model and illustrate the controller´s design and trajectory tracking performance
Keywords :
adaptive control; commutation; control system synthesis; machine control; nonlinear control systems; reluctance motors; rotors; splines (mathematics); torque; Fourier sinusoids; adaptive controller; asymptotic tracking; certainty equivalence principle; commutation smoothing; dynamic model; electric torque; flux saturation effects; hard commutation; low-velocity high-torque mode; nonlinear adaptive control; phase currents; rotor angular position; rotor position trajectory; spline function approach; torque-sharing functions; variable reluctance motors; Adaptive control; Commutation; DC motors; Feedback; Programmable control; Reluctance motors; Rotors; Spline; Torque; Trajectory;
Journal_Title :
Industrial Electronics, IEEE Transactions on
