Weighting-Factor-Less Model Predictive Control With Multiobjectives for Three-Level Hybrid ANPC Inverter Drives
Zhenyao Sun, Shuai Xu, Guanzhou Ren, Chunxing Yao, Guangtong Ma, Juri Jatskevich
Abstract
Hybrid active neutral point clamped (HANPC) inverter has been recently considered in motor drive applications, while its control with multiple objectives remains quite complicated. The finite set model predictive control (MPC) is very attractive for multilevel inverter (MLI) drives due to its powerful ability to handle multiobjective optimization. However, tuning the weighting factors (WFs) with multiple objectives in MPC is quite challenging and time costing. In this article, a WF-less MPC method for HANPC inverter-fed permanent magnet synchronous motor (PMSM) drives is proposed. The new control strategy achieves precise current tracking, neutral point potential balance, switching frequency reduction, and switching loss minimization. The algorithm works as a three-stage procedure to achieve the best decision at each stage, and a current extrapolation method is introduced to enhance the control performance. The effectiveness of the proposed method is validated experimentally on a three-level HANPC-inverter-fed PMSM drive.