A Generalized Observer-Based Robust Predictive Current Control Strategy for PMSM Drive System

A predictive current controller is established based on the system model and, therefore, suffers from the problems, such as parameter mismatches, digital delay, and external disturbances. In order to tackle these problems, an observer-based robust predictive current control strategy is proposed in this article, which employs an extended state observer to estimate the disturbances, currents, and applies the augmented system model for the design of the controller. It is generally formulated and applicable to any ac motor drive system as long as the prerequisites are satisfied. Furthermore, the proposed control scheme is proven to be input-to-state stable with a proper design of the controller and the observer. The effectiveness of the proposed control strategy is moreover verified with numerous experiments on a dSPACE system under various test scenarios. The comparative studies between the proposed method and the predictive current control approaches, i.e., the conventional deadbeat control and the continuous control set model predictive control, are conducted at different operating conditions.

Automated summary

An observer-based robust predictive current control strategy is proposed in this article, which utilizes an extended state observer to estimate disturbances and currents, and applies an augmented system model for controller design to address parameter mismatches, digital delay, and external disturbances.