Finite control set MPC with high frequency injections for sensorless position and speed estimation of a PMSM

2015 IEEE International Symposium on Predictive Control of Electrical Drives and Power Electronics (PRECEDE) Pub Date : 2015-10-01 DOI:10.1109/PRECEDE.2015.7395506

V. Muzikova, T. Glasberger, V. Šmídl, Z. Peroutka

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引用次数: 9

Abstract

A new control algorithm for operation of surface mounted permanent magnet synchronous machines in very low speed and standstill using finite control set model predictive control (FCS-MPC) and high frequency signal injection for estimation of the rotor position is proposed. Estimation of the rotor position is based on the standard injections of high frequency signal into the voltage command for a PWM. It is intended to achieve the same effect using the FCS-MPC. The FCS-MPC usually operates with a short sampling period, therefore the estimation algorithm needs to be computationally cheap. Moreover, the cost function needs to be modified to secure injection of high frequency (hf) voltage signals into a given axis in a reference frame linked with the rotor position. In this paper, a method of injection of a harmonic signal using FCS-MPC is proposed, using an extension of the cost function. Rotor position and speed estimation is based on the conventional phase-locked loop. Theoretical assumptions are verified by both simulations and experiments on a laboratory prototype of PMSM drive with rated power of 250 W.

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用于永磁同步电机无传感器位置和速度估计的高频注入有限控制集MPC

提出了一种基于有限控制集模型预测控制(FCS-MPC)和高频信号注入估计转子位置的表面贴装永磁同步电机极低速静止运行控制新算法。转子位置的估计是基于标准注入高频信号到PWM的电压指令。它旨在使用FCS-MPC实现相同的效果。FCS-MPC通常在较短的采样周期内运行，因此估计算法需要计算量小。此外，还需要修改代价函数，以确保将高频电压信号注入与转子位置相连的参考系中的给定轴中。本文提出了一种利用FCS-MPC对代价函数进行扩展的谐波信号注入方法。转子位置和转速的估计是基于传统的锁相环。在额定功率为250 W的永磁同步电动机驱动样机上进行了仿真和实验，验证了理论假设。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2015 IEEE International Symposium on Predictive Control of Electrical Drives and Power Electronics (PRECEDE)

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