A novel fault diagnosis method for PV arrays using convolutional extension neural network with symmetrized dot pattern analysis

IF 1.4 4区工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

Iet Science Measurement & Technology Pub Date : 2023-10-11 DOI:10.1049/smt2.12166

Shiue-Der Lu, Chia-Chun Wu, Hong-Wei Sian

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Abstract

PV fault diagnosis remains difficult due to the non-linear characteristic of PV output, which makes PV output to be likely disturbed by the ambient environment. This study proposes a novel convolutional extension neural network (CENN) algorithm, which is a jointed architecture based on convolutional neural network (CNN) and extension neural network (ENN), takes advantage of CNN and ENN. The CENN is combined with the symmetrized dot pattern (SDP) analysis method to diagnose the common eight PV array faults. The SDP is used to transform the measured PV signals into the point coordinate feature image; then, the CENN is trained to identify the different PV faults. Experimental results show an obvious improvement in short detection times and high accuracy compared with traditional CNN and the histogram of oriented gradient (HOG) extraction method with support vector machine (SVM), K-nearest neighbours (KNN), and back propagation neural network (BPNN) classifiers, with 95.3%, 94%, 93.5%, and 93.3% accuracy, respectively. Using the proposed CENN, the accuracy can be raised to 97.3%. Additionally, the signals measured by various sensors are collected using programmable logic controller (PLC). The human–machine interface (HMI) and the proposed algorithm are developed using LabVIEW for graphical design. Finally, the information is transmitted to a tablet PC for performing real-time remote monitoring.

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利用卷积扩展神经网络和对称点模式分析的新型光伏阵列故障诊断方法

由于光伏输出的非线性特性，光伏输出很可能受到周围环境的干扰，因此光伏故障诊断仍然存在困难。本研究提出了一种新颖的卷积扩展神经网络（CENN）算法，它是一种基于卷积神经网络（CNN）和扩展神经网络（ENN）的联合架构，利用了 CNN 和 ENN 的优势。CENN 与对称点模式（SDP）分析方法相结合，可诊断常见的八种光伏阵列故障。SDP 用于将测量的光伏信号转换为点坐标特征图像，然后训练 CENN 来识别不同的光伏故障。实验结果表明，与传统的 CNN 和带有支持向量机 (SVM)、K-近邻 (KNN) 和反向传播神经网络 (BPNN) 分类器的定向梯度直方图 (HOG) 提取方法相比，CENN 在检测时间短和准确率高方面有明显改善，准确率分别为 95.3%、94%、93.5% 和 93.3%。使用建议的 CENN，准确率可提高到 97.3%。此外，使用可编程逻辑控制器（PLC）收集各种传感器测得的信号。人机界面（HMI）和建议的算法使用 LabVIEW 进行图形设计。最后，将信息传输到平板电脑上，进行实时远程监控。

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来源期刊

Iet Science Measurement & Technology 工程技术-工程：电子与电气

CiteScore

4.30

自引率

7.10%

发文量

审稿时长

7.5 months

期刊介绍： IET Science, Measurement & Technology publishes papers in science, engineering and technology underpinning electronic and electrical engineering, nanotechnology and medical instrumentation.The emphasis of the journal is on theory, simulation methodologies and measurement techniques. The major themes of the journal are: - electromagnetism including electromagnetic theory, computational electromagnetics and EMC - properties and applications of dielectric, magnetic, magneto-optic, piezoelectric materials down to the nanometre scale - measurement and instrumentation including sensors, actuators, medical instrumentation, fundamentals of measurement including measurement standards, uncertainty, dissemination and calibration Applications are welcome for illustrative purposes but the novelty and originality should focus on the proposed new methods.