Enhanced Neural Network Method-Based Multiscale PCA for Fault Diagnosis: Application to Grid-Connected PV Systems

Signals Pub Date : 2023-05-30 DOI:10.3390/signals4020020
Khadija Attouri, Majdi Mansouri, Mansour Hajji, Abdelmalek Kouadri, Kais Bouzrara, Hazem Nounou
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引用次数: 0

Abstract

In this work, an effective Fault Detection and Diagnosis (FDD) strategy designed to increase the performance and accuracy of fault diagnosis in grid-connected photovoltaic (GCPV) systems is developed. The evolved approach is threefold: first, a pre-processing of the training dataset is applied using a multiscale scheme that decomposes the data at multiple scales using high-pass/low-pass filters to separate the noise from the informative attributes and prevent the stochastic samples. Second, a principal component analysis (PCA) technique is applied to the newly obtained data to select, extract, and preserve only the more relevant, informative, and uncorrelated attributes; and finally, to distinguish between the diverse conditions, the extracted attributes are utilized to train the NNs classifiers. In this study, an effort is made to take into consideration all potential and frequent faults that might occur in PV systems. Thus, twenty-one faulty scenarios (line-to-line, line-to-ground, connectivity faults, and faults that can affect the normal operation of the bay-pass diodes) have been introduced and treated at different levels and locations; each scenario comprises various and diverse conditions, including the occurrence of simple faults in the PV1 array, simple faults in the PV2 array, multiple faults in PV1, multiple faults in PV2, and mixed faults in both PV arrays, in order to ensure a complete and global analysis, thereby reducing the loss of generated energy and maintaining the reliability and efficiency of such systems. The obtained outcomes demonstrate that the proposed approach not only achieves good accuracies but also reduces runtimes during the diagnosis process by avoiding noisy and stochastic data, thereby removing irrelevant and correlated samples from the original dataset.
基于增强神经网络方法的多尺度主成分分析在并网光伏系统故障诊断中的应用
本文提出了一种有效的故障检测与诊断(FDD)策略,旨在提高并网光伏系统的故障诊断性能和准确性。进化的方法有三个方面:首先,使用多尺度方案对训练数据集进行预处理,该方案使用高通/低通滤波器在多个尺度上分解数据,以从信息属性中分离噪声并防止随机样本。其次,将主成分分析(PCA)技术应用于新获得的数据,以选择、提取和保留更相关、信息量更大和不相关的属性;最后,为了区分不同的条件,利用提取的属性来训练神经网络分类器。在这项研究中,努力考虑到所有潜在的和频繁的故障,可能会发生在光伏系统。因此,介绍了21种故障场景(线对线、线对地、连接故障和可能影响隔离通二极管正常工作的故障),并在不同级别和位置进行了处理;每个场景都包含多种多样的情况,包括PV1阵列发生简单故障、PV2阵列发生简单故障、PV1多发故障、PV2多发故障、两个光伏阵列混合故障,以保证完整全局的分析,从而减少发电损失,保持系统的可靠性和效率。结果表明,该方法不仅具有良好的准确率,而且通过避免噪声和随机数据,从而从原始数据集中去除不相关和相关的样本,减少了诊断过程中的运行时间。
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
CiteScore
3.20
自引率
0.00%
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0
审稿时长
11 weeks
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