《电力自动化设备》

引用本文:	杨毅,范栋琛,殷浩然,韩佶,苗世洪.基于深度-迁移学习的输电线路故障选相模型及其可迁移性研究[J].电力自动化设备,2020,40(10):
	YANG Yi,FAN Dongchen,YIN Haoran,HAN Ji,MIAO Shihong.Transmission line fault phase selection model based on deep-transfer learning and its transferability[J].Electric Power Automation Equipment,2020,40(10):

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基于深度-迁移学习的输电线路故障选相模型及其可迁移性研究
杨毅¹, 范栋琛¹, 殷浩然^2,3, 韩佶^2,3, 苗世洪^2,3
1.国网江苏省电力有限公司电力科学院研究院，江苏南京 211103;2.华中科技大学电气与电子工程学院强电磁工程与新技术国家重点实验室，湖北武汉 430074;3.电力安全与高效湖北省重点实验室，湖北武汉 430074

摘要:

为提高输电线路故障诊断模型的可迁移性，根据迁移学习理论将输电线路分为源线路和目标线路，提出一种基于深度-迁移学习的输电线路故障类型识别方法。通过组合不同故障条件，生成输电线路故障期间的时序数据，并通过对数据的预处理，得到面向卷积神经网络的输入数据样本；利用源域数据对初始卷积神经网络进行预训练，获取适用于源线路故障类型识别的预训练模型；采用最大均值差异法对源线路和目标线路进行相似性检验，筛选出待迁移的源域预训练模型；利用目标域数据对预训练模型进行微调迁移训练，获取最终的目标域故障诊断模型。仿真结果表明，利用源域数据量5 %的目标域数据对预训练模型进行微调迁移训练，得到的目标域模型对目标线路故障诊断的准确率达99 %以上。

关键词: 输电线路迁移学习深度学习故障类型识别卷积神经网络

DOI：10.16081/j.epae.202008008

分类号:TM77

基金项目:国家自然科学基金资助项目(61602251)；国家电网公司科技项目(5210EF190010)

Transmission line fault phase selection model based on deep-transfer learning and its transferability

YANG Yi¹, FAN Dongchen¹, YIN Haoran^2,3, HAN Ji^2,3, MIAO Shihong^2,3

1.State Grid Jiangsu Electric Power Research Institute, Nanjing 211103, China;2.State Key Laboratory of Advanced Electromagnetic Engineering and Technology, School of Electrical and Electronic Engineering, Huazhong University of Science and Technology, Wuhan 430074, China;3.Hubei Electric Power Security and High Efficiency Key Laboratory, Wuhan 430074, China

Abstract:

In order to improve the transferability of transmission line fault diagnosis models, the transmission lines are divided into source lines and target lines based on transfer learning theory, then a method based on deep-transfer learning for identifying transmission line fault types is proposed. The time series data during transmission line faults is generated by combining different fault conditions, and the input data samples of CNN(Convolutional Neural Network) are obtained by data preprocessing. Then the initial CNN is pre-trained by using the source domain data to obtain a pre-trained model of the source line fault type identification. Next, the maximum mean difference method is used to test the similarity of source and target lines, and the source domain pre-trained model to be migrated is screened out. The target domain data is used to fine-tune the migration training to obtain the final target domain fault diagnosis model. The simulative results show that by using the target domain data of 5 % of the source domain data to fine-tune the migration training of the pre-trained model, the target line fault diagnosis accuracy of the target domain model can reach more than 99 %.

Key words: power transmission line transfer learning deep learning fault type identification convolutional neural network

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