Series AC Arc Fault Detection Model Based on Hybrid Time and Frequency Analysis

2022 International Conference on Sensing, Measurement & Data Analytics in the era of Artificial Intelligence (ICSMD) Pub Date : 2022-11-30 DOI:10.1109/ICSMD57530.2022.10058442

Xue Zhou, Wenhao Geng, Jianing He, G. Zhai

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Abstract

Series arc fault cannot be protected by a common purpose circuit breaker for its lower fault current amplitude compared with its normal one, hence arc fault circuit interrupters are required for avoiding potential fire hazards. This paper presents an ac series arc fault detection method based on hybrid time and frequency analysis and softmax classification neural network (HTFSCNN). An experimental platform capable of automatically recording normal and arc fault current waveforms is designed in order to collect data set. In this paper, four indicators in time-domain and six indicators in frequency-domain are selected as inputs of the HTFSCNN classifier, according to the characteristics of the current waveforms and frequency spectra. The conjugate gradient method was applied to train the backwards-propagation algorithm. The loss function was cross entropy and the output function was softmax. Experimental results show that this method can effectively separate the fault currents from the normal ones with accuracy of 98.74% under seven loads specified in IEC standards. Finally, the trained HTFSCNN model was implanted into a microcontroller and its feasibility is verified.

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基于时频混合分析的串联交流电弧故障检测模型

串联电弧故障由于其故障电流幅值较普通断路器低，不能采用通用断路器进行保护，因此需要电弧故障断路器来避免火灾隐患。提出了一种基于时频混合分析和softmax分类神经网络(HTFSCNN)的交流串联电弧故障检测方法。为了采集数据集，设计了一个能自动记录正常和电弧故障电流波形的实验平台。本文根据当前波形和频谱的特点，选择4个时域指标和6个频域指标作为HTFSCNN分类器的输入。采用共轭梯度法对反向传播算法进行训练。损失函数为交叉熵，输出函数为softmax。实验结果表明，在IEC标准规定的7种负载下，该方法能有效地分离故障电流和正常电流，准确率达到98.74%。最后，将训练好的HTFSCNN模型植入到单片机中，验证了其可行性。

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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2022 International Conference on Sensing, Measurement & Data Analytics in the era of Artificial Intelligence (ICSMD)

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