Reactive power model reference adaptive speed-sensorless system with direct torque control tuned with fuzzy neural networks for improved speed control in induction motor drives

Nigerian Journal of Technology Pub Date : 2023-03-14 DOI:10.4314/njt.v41i6.9

O. E. Ozoemena, E. Ashigwuike

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Abstract

This article investigates a reactive power based Model Reference Adaptive System (Q-MRAS) with Fuzzy Neural Network (FNN) facilitated Direct Torque Control for improved speed control of an Induction Motor Drive. A key component of the conventional DTC control scheme is the use of PID controllers and its derivatives. PID controllers were found to be a source of ripples. To mitigate its effect, in this work, a novel idea of replacing all the PI controls in the conventional speed control DTC models with FNN based controllers is investigated. The goal is to reduce complexity, reduce ripples in speed and boost low speed operation suitable for industrial needs. The proposed FNN controllers-based model is implemented using Matlab/Simulink. Comparisons are made between the results obtained from the proposed model and that from conventional models (Switching Table based DTC and SVM-DTC). Results showed that in the proposed FNN based DTC model, low speed operation (100 rpm) had 0.13 % speed ripple compared to 0.94 % in the conventional Switching Table based DTC and 0.23 % in the conventional SVM-DTC. This represents a reduction in speed ripple by 86.17 % in the proposed scheme compared to the Switching-Table DTC and by 43.48 % in the proposed scheme compared to the SVM-DTC scheme.

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基于模糊神经网络的无功模型参考自适应无速度传感器直接转矩控制系统用于改进异步电动机的速度控制

本文研究了一种基于无功的模型参考自适应系统(Q-MRAS)与模糊神经网络(FNN)的直接转矩控制，以改善感应电机驱动器的速度控制。传统的直接转矩控制方案的一个关键组成部分是使用PID控制器及其衍生物。PID控制器被发现是波纹的来源。为了减轻其影响，本文研究了一种将传统速度控制模型中的PI控制替换为基于FNN的控制器的新思路。目标是降低复杂性，减少速度波动，并提高适合工业需求的低速运行。利用Matlab/Simulink实现了基于FNN控制器的模型。将该模型与传统模型(基于切换表的DTC和SVM-DTC)的结果进行了比较。结果表明，在基于FNN的DTC模型中，低速运行(100转/分)的速度纹波为0.13%，而传统的基于开关表的DTC为0.94%，传统的SVM-DTC为0.23%。与开关表DTC相比，该方案的速度纹波减少了86.17%，与SVM-DTC方案相比，该方案的速度纹波减少了43.48%。

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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