Influence of Asymmetric Sampling Delay on PMSM FOC Drives with Varying Rotor Position

2022 IEEE Transportation Electrification Conference & Expo (ITEC) Pub Date : 2022-06-15 DOI:10.1109/ITEC53557.2022.9813747

Garret Ray, M. Acosta, S. Kuruppu

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Abstract

This paper investigates the behavior of permanent magnet synchronous machines paired with field-oriented control under the effects of asymmetric delay in per-phase current measurement and position measurement delay effect. A mathematical model for field-oriented control with asymmetric 3-phase feedback delay was developed and used to obtain theoretical current step responses in the quadrature and direct axes, as well as obtain root locus results of the dynamic system. Step responses were also obtained in a simulated model using Simulink, and through experiments, while injecting varying levels of per-phase feedback delay. Increasing levels of asymmetric delay and increasing controller bandwidth, increased the systems’ sensitivity to instability. Delay in phase A and phase B were found to primarily affect responses in the q-axis and d-axis respectively. Unequal amounts of delay (asymmetric delay) on phase A and Phase B create substantial instability when compared with equal delay (symmetric delay). Asymmetric delay in current measurement also resulted in varying amplitudes in current response at varying rotor positions.

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非对称采样延迟对变转子位置PMSM FOC驱动的影响

本文研究了磁场定向控制下的永磁同步电机在非对称相位电流测量延时和位置测量延时效应下的性能。建立了具有非对称三相反馈时滞的磁场定向控制数学模型，并利用该模型得到了系统在正交轴和直轴上的理论电流阶跃响应，以及系统的根轨迹结果。利用Simulink仿真模型，并通过实验，在注入不同水平的每相位反馈延迟的情况下，得到阶跃响应。增加非对称延迟水平和增加控制器带宽，增加了系统对不稳定的敏感性。发现A相和B相的延迟分别主要影响q轴和d轴的反应。与等延迟(对称延迟)相比，阶段A和阶段B上的不等延迟(非对称延迟)会产生大量的不稳定性。电流测量中的不对称延迟也导致在不同转子位置电流响应的幅值变化。

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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2022 IEEE Transportation Electrification Conference & Expo (ITEC)

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