Non-linear adaptive sliding mode observer–controller scheme for induction motors

Given measurements of rotor position, rotor velocity, and stator currents, we design an adaptive control scheme that is free of singularities, does not require rotor #ux measurements, and provides for simultaneous asymptotic rotor position/rotor #ux tracking despite the uncertainty associated with t

In this paper, a controller-observer scheme, based on passivity feedback equivalence and the sliding mode technique, is designed to achieve rotor velocity and rotor #ux norm tracking for the model of an induction motor. The passivity feedback equivalence control law design is based on a passive deco

A robust feedback control of an induction motor is proposed. The theoretical basis is a continuous-time machine model de"ned by a pair of simultaneous complex-coe$cients di!erential equations. The parameter uncertainties and load perturbations are considered in the controller design. The control met

Proposed in this paper is a new approach of design using a monovariable generalized predictive control law, with multiple reference model (GPC/MRM) to control, "rstly, rotor speed and rotor #ux amplitude of an induction machine. The control law will be extended and applied, secondly, to answer a sec

In this paper, a nonlinear indirect adaptive sensorless speed and #ux tracking controller for induction motors is proposed. In the controller, only the stator currents are assumed to be measurable. Flux observers and rotor speed estimator are designed to relax the need to #ux and speed measurement.

On the basis of a novel dynamic model obtained under a special non-linear co-ordinate transform on a d}q-axis model (w.r.t. the stationary reference frame) of an induction motor, a simple but e!ective control law for speed regulation is proposed in this paper. This controller is designed using the c