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一种使用混合离散模型预测磁场定向控制来控制感应电动机的新方法。

A new method for controlling an induction motor using a hybrid discretization model predictive field orientated control.

机构信息

School of Electrical Engineering, Faculty of Engineering, Universiti Teknologi Malaysia, Johor Bahru, Malaysia.

Department of Electronic Engineering, Faculty of Engineering, The Islamia University of Bahawalpur, Bahawalpur, Pakistan.

出版信息

PLoS One. 2022 Jun 16;17(6):e0267459. doi: 10.1371/journal.pone.0267459. eCollection 2022.

DOI:10.1371/journal.pone.0267459
PMID:35709095
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9202956/
Abstract

The dynamic performance of the Model Predictive Control (MPC) of an Induction Motor (IM) relies on the accuracy and computational efficiency of the Discretisation Technique (DT). If the discretisation process is inaccurate or slow approximation, the MPC will exhibit high torque ripple and lower load handling capabilities. Traditionally, Euler's method is used to discretise the MPC, which merely relies on the predictor to yield a fast, but less accurate system approximation. In contrast, Heun's method uses a combination of predictor and corrector at alternate sampling intervals to improve the discretisation accuracy; however, the controller response becomes slow due to increased computational intensity of the algorithm. In this study, a new Hybrid Discretisation Technique (HDT) for Model Predictive Field Oriented Control (MPFOC) for IM control systems is presented to achieve robust discretisation with improved accuracy. In the proposed approach, Euler's method is used to discretise the system at the first nine samples, followed by the predictor-corrector at the tenth sampling interval, accomplishing the desired speed and accuracy of discretisation. This newly proposed HDT in MPFOC is verified with Processor-In-Loop (PIL) for a three-phase IM with bi-directional rotation under varying load conditions. The results indicate that the IM torque ripple is reduced by up to 20%, whereas, the load handling capability is increased by up to 10%. Moreover, the controller gives 20% and 23% improvement in rise time and settling time, respectively, under high loading conditions, as compared to traditional Euler and Heun methods.

摘要

感应电动机 (IM) 的模型预测控制 (MPC) 的动态性能依赖于离散技术 (DT) 的准确性和计算效率。如果离散化过程不准确或近似缓慢,MPC 将表现出高转矩纹波和较低的负载处理能力。传统上,使用 Euler 方法对 MPC 进行离散化,该方法仅依赖于预测器来产生快速但不太准确的系统近似。相比之下,Heun 方法在交替的采样间隔处使用预测器和校正器的组合来提高离散化精度;然而,由于算法的计算强度增加,控制器的响应变得缓慢。在这项研究中,提出了一种新的感应电动机控制系统模型预测磁场定向控制 (MPFOC) 的混合离散技术 (HDT),以实现具有改进准确性的鲁棒离散化。在提出的方法中,Euler 方法用于在最初的九个采样点离散系统,然后在第十个采样间隔使用预测器-校正器,实现所需的离散化速度和精度。在变负载条件下,对具有双向旋转的三相 IM 进行处理器在环 (PIL) 验证,结果表明,IM 转矩纹波降低了 20%,而负载处理能力提高了 10%。此外,与传统的 Euler 和 Heun 方法相比,在高负载条件下,控制器的上升时间和稳定时间分别提高了 20%和 23%。

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