An Advanced Diagnostic Approach for Broken Rotor Bar Detection and Classification in DTC Controlled Induction Motors by Leveraging Dynamic SHAP Interaction Feature Selection (DSHAP-IFS) GBDT Methodology

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS

ACS Applied Bio Materials Pub Date : 2024-07-22 DOI:10.3390/machines12070495

Muhammad Amir Khan, B. Asad, T. Vaimann, A. Kallaste

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引用次数: 0

Abstract

This paper introduces a sophisticated approach for identifying and categorizing broken rotor bars in direct torque-controlled (DTC) induction motors. DTC is implemented in industrial drive systems as a suitable control method to preserve torque control performance, which sometimes shows its impact on fault-representing frequencies. This is because of the DTC’s closed-loop control nature, whichtriesto reduce speed and torque ripples by changing the voltage profile. The proposed model utilizes the modified Shapley Additive exPlanations (SHAP) technique in combination with gradient-boosting decision trees (GBDT) to detect and classify the abnormalities in BRBs at diverse (0%, 25%, 50%, 75%, and 100%) loading conditions. To prevent overfitting of the proposed model, we used the adaptive fold cross-validation (AF-CV) technique, which can dynamically adjust the number of folds during the optimization process. By employing extensive feature engineering in the original dataset and then applying Shapely Additive exPlanations(SHAP)-based feature selection, our methodology effectively identifies informative features from signals (three-phase current, three-phase voltage, torque, and speed) and motor characteristics. The gradient-boosting decision tree (GBDT) classifier, trained using the given characteristics, extracts consistent and reliable classification performance under different loading circumstances and enables precise and accurate detection and classification of broken rotor bars. The proposed approach (SHAP-Fusion GBDT with AF-CV) is a major advancement in the field of machine learning in detecting motor anomalies at varying loading conditions and proved to be an effective mechanism for preventative maintenance and preventing faults in DTC-controlled induction motors byattaining an accuracy rate of 99% for all loading conditions.

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利用动态 SHAP 交互特征选择（DSHAP-IFS）GBDT 方法检测和分类 DTC 控制感应电机转子断线的先进诊断方法

本文介绍了一种复杂的方法，用于识别和分类直接转矩控制（DTC）感应电机的转子断线。DTC 在工业驱动系统中作为一种合适的控制方法来保持转矩控制性能，有时会对故障频率产生影响。这是因为 DTC 的闭环控制特性，即通过改变电压曲线来降低转速和转矩纹波。所提出的模型利用改进的 Shapley Additive exPlanations（SHAP）技术与梯度提升决策树（GBDT）相结合，在不同（0%、25%、50%、75% 和 100%）负载条件下检测 BRB 的异常并进行分类。为防止所提模型的过度拟合，我们采用了自适应折叠交叉验证（AF-CV）技术，该技术可在优化过程中动态调整折叠数。通过对原始数据集进行广泛的特征工程设计，然后应用基于形状相加规划（SHAP）的特征选择，我们的方法有效地识别了信号（三相电流、三相电压、转矩和转速）和电机特性中的信息特征。使用给定特征训练的梯度提升决策树 (GBDT) 分类器可在不同负载情况下获得一致、可靠的分类性能，并能对转子断条进行精确、准确的检测和分类。所提出的方法（SHAP-Fusion GBDT with AF-CV）是机器学习领域在不同负载条件下检测电机异常方面的一大进步，在所有负载条件下的准确率均达到 99%，被证明是 DTC 控制感应电机预防性维护和防止故障的有效机制。

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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来源期刊

ACS Applied Bio Materials Chemistry-Chemistry (all)

CiteScore

9.40

自引率

2.10%

发文量

464