Robust Linear Parameter Varying Output Feedback Control of Permanent Magnet Synchronous Motors

TL;DR

This paper develops a robust LPV output-feedback controller for surface permanent magnet synchronous motors, improving speed regulation performance under parameter variations, temperature effects, and disturbances through a convex LMI-based design.

Contribution

It introduces a novel robust gain-scheduled LPV control approach considering temperature effects and system perturbations for SPMSMs, validated via simulation.

Findings

Enhanced transient response with reduced settling time

Improved disturbance rejection and robustness

Superior performance compared to conventional FOC

Abstract

This paper investigates the design of a robust output-feedback linear parameter-varying (LPV) gain-scheduled controller for the speed regulation of a surface permanent magnet synchronous motor (SPMSM). Motor dynamics is defined in the $\alpha - \beta$ stationary reference frame and a parameter-varying model formulation is provided to describe the SPMSM nonlinear dynamics. In this context, a robust gain-scheduled LPV output-feedback dynamic controller is designed to satisfy the asymptotic stability of the closed-loop system and meet desired performance requirements, as well as, guarantee robustness against system parameter perturbations and torque load disturbances. The real-time impact of temperature variation on the winding resistance and magnet flux during motor operations is considered in the LPV modelling and the subsequent control design to address demagnetization effects in the motor response. The controller synthesis conditions are formulated in a convex linear matrix inequality (LMI) optimization framework. Finally, the validity of the proposed control strategy is assessed in simulation studies, and the results are compared to the results of the conventional field-oriented control (FOC) method. The closed-loop simulation studies demonstrate that the proposed LPV controller provides improved transient response with respect to settling time, overshoot, and disturbance rejection in tracking the velocity profile under the influence of parameter and temperature variations and load disturbances.