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基于Savitzky-Golay-长短期记忆网络的交流断路器剩余电气寿命预测

The Prediction of Residual Electrical Life in Alternating Current Circuit Breakers Based on Savitzky-Golay-Long Short-Term.

作者信息

Ouyang Junfeng, Chi Changchun

机构信息

School of Electrical Engineering, Shanghai Dianji University, Shanghai 200240, China.

出版信息

Sensors (Basel). 2023 Aug 1;23(15):6860. doi: 10.3390/s23156860.

DOI:10.3390/s23156860
PMID:37571643
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10422557/
Abstract

In order to improve the accuracy of predicting the remaining electrical life of AC circuit breakers, ensure the safe operation of electrical equipment, and reduce economic losses caused by equipment failures, this paper studies a method based on the Savitzky-Golay convolution smoothing long short-term memory neural network for predicting the electrical life of AC circuit breakers. First, a full lifespan test is conducted to obtain degradation data throughout the entire life cycle of the AC circuit breaker, from which feature parameters that effectively reflect its operational state are extracted. Next, principal component analysis and the maximum information coefficient are used to remove redundancy in the feature parameters and choose the best subset of features. Subsequently, the Savitzky-Golay convolutional smoothing algorithm is employed to smooth the feature sequence, reducing the impact of noise and outliers on the feature sequence while preserving its main trends. Then, a secondary feature extraction is performed on the smoothed feature subset to obtain the optimal secondary feature subset. Finally, the remaining electrical lifespan of the AC circuit breaker is treated as a long-term sequence problem and the long short-term memory neural network method is used for precise time-series forecasting. The proposed model outperforms backpropagation neural networks and the gate recurrent unit in terms of prediction precision, achieving an impressive 97.4% accuracy. This demonstrates the feasibility of using time-series forecasting for predicting the residual electrical lifespan of electrical equipment and provides a reference for optimizing the method of predicting remaining electrical life.

摘要

为提高交流断路器剩余电气寿命预测的准确性,确保电气设备安全运行,减少设备故障造成的经济损失,本文研究了一种基于Savitzky-Golay卷积平滑长短期记忆神经网络的交流断路器电气寿命预测方法。首先,进行全寿命试验以获取交流断路器整个生命周期的退化数据,并从中提取有效反映其运行状态的特征参数。接着,利用主成分分析和最大信息系数去除特征参数中的冗余信息,选择最佳特征子集。随后,采用Savitzky-Golay卷积平滑算法对特征序列进行平滑处理,减少噪声和异常值对特征序列的影响,同时保留其主要趋势。然后,对平滑后的特征子集进行二次特征提取,得到最优二次特征子集。最后,将交流断路器的剩余电气寿命视为长期序列问题,采用长短期记忆神经网络方法进行精确的时间序列预测。所提模型在预测精度方面优于反向传播神经网络和门控循环单元,准确率达到了令人瞩目的97.4%。这证明了使用时间序列预测来预测电气设备剩余电气寿命的可行性,并为优化剩余电气寿命预测方法提供了参考。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/5a70/10422557/9a75fcbd9ea2/sensors-23-06860-g012.jpg
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