Latest Advances of Model Predictive Control in Electrical Drives—Part II: Applications and Benchmarking With Classical Control Methods
José Rodríguez, Cristian García, Andrés Mora, S. Alireza Davari, Jorge Rodas, Diego F. Valencia, Mahmoud F. Elmorshedy, Fengxiang Wang, Kunkun Zuo, Luca Tarisciotti, Freddy Flores‐Bahamonde, Wei Xu, Zhenbin Zhang, Yongchang Zhang, Margarita Norambuena, Ali Emadi, Tobias Geyer, Ralph Kennel, Tomislav Dragičević, Davood Arab Khaburi, Zhen Zhang, Mohamed Abdelrahem, Nenad Mijatović
Abstract
This article presents the application of model predictive control (MPC) in high-performance drives. A wide variety of machines have been considered: Induction machines, synchronous machines, linear motors, switched reluctance motors, and multiphase machines. The control of these machines has been done by introducing minor and easy-to-understand modifications to the basic predictive control concept, showing the high flexibility and simplicity of the strategy. The second part of the article is dedicated to the performance comparison of MPC with classical control techniques such as field-oriented control and direct torque control. The comparison considers the dynamic behavior of the drive and steady-state performance metrics, such as inverter losses, current distortion in the motor, and acoustic noise. The main conclusion is that MPC is very competitive concerning classic control methods by reducing the inverter losses and the current distortion with comparable acoustic noise.