Zero-Shot Fault Diagnosis Technique of Transformer Based on Weighted Attribute Matrix
Lei Leixiao1, He Yigang1, Yao Qixin2, Xing Zhikai1
1. School of Electrical Engineering and Automation Wuhan University Wuhan 430072 China; 2. State Grid Hubei Direct Current Company Yichang 443000 China
Abstract:In actual engineering applications, transformer failure is a small probability event, so there is little fault data and low data quality, and the actual data distribution often exhibits a long tail effect. However, traditional data-driven fault diagnosis methods require a large amount of fault data for sample training, which leads to problems such as low model accuracy and model failure in the actual application of traditional supervised models. To address this type of problem, this article proposes a zero-shot fault diagnosis technology for transformers based on variable weight attribute matrix. The spatial mapping function between known fault attribute matrices and dissolved gas data is learned to achieve accurate identification of unknown faults. Firstly, an improved efficient channel attention network-stack autoencoder (IECANet-SAE) network is used to construct a data feature extraction network. Among them, convolutional neural networks extract local important information from input data through convolutional operations, while efficient channel attention networks focus on important information by learning attention weights between channels. The use of feature extraction networks solves the problem of quality and quantity of fault sample data, while adaptively extracting key feature information from dissolved gas data. Secondly, based on the description information of transformer faults, a variable weight attribute matrix is constructed using a topic modeling method based on potential Dirichlet distribution. This includes fault type classification, topic word extraction, similarity calculation, and matrix construction. By enhancing the connection between fault labels and fault information through the fault attribute matrix, data sharing between known and unknown class faults can be achieved. Then, the neural network-based Naive Bayes (NNB) method is used to learn the mapping function between each attribute vector in the fault attribute matrix and the important feature information of known class faults in the feature space. Based on the mapping function, the unknown class feature information is mapped to the same feature space to obtain the corresponding attribute vector. Finally, based on Bayesian principle, the maximum likelihood estimation formula is used to obtain the most likely fault type for unknown class faults. The proposed method was validated using the IEC TC 10 fault database and relevant authoritative literature that has been publicly published. From the accuracy of fault diagnosis results, it can be seen that data-driven fault diagnosis models are difficult to achieve fault diagnosis without sample training, so the diagnostic accuracy of this type of algorithm is 0. On the basis of the transformer fault attribute matrix proposed in this article, zero-shot fault diagnosis is achieved, which has a higher accuracy of up to 0.83 compared to direct attribute prediction (DAP) and indirect attribute prediction (IAP) methods. From the fault diagnosis time, it can be seen that the DAP and IAP methods analyze the original data, so the calculation time is slightly longer due to the large amount of data. The method in this article retains some important features in the data, reducing computational time to a certain extent. The diagnostic time is about 0.18 seconds, which is slightly faster than other methods. The following conclusions can be drawn through experimental analysis: (1) The use of LDA based topic modeling method effectively enhances the correlation between fault information and fault sample labels, solving the problem of difficult fault diagnosis under the condition of no training samples. (2) Extracting the main features of dissolved gas data through the IECANet-SAE network has better fault feature separation performance compared to other methods, which helps to improve transformer fault diagnosis performance. (3) The NNB algorithm is used to construct the mapping relationship between important feature data and fault attribute matrix, efficiently and accurately identifying unknown fault types. The average accuracy and diagnostic time of the diagnostic results are superior to other methods.
雷蕾潇, 何怡刚, 姚其新, 邢致恺. 基于变权属性矩阵的变压器零样本故障诊断技术[J]. 电工技术学报, 2024, 39(20): 6577-6590.
Lei Leixiao, He Yigang, Yao Qixin, Xing Zhikai. Zero-Shot Fault Diagnosis Technique of Transformer Based on Weighted Attribute Matrix. Transactions of China Electrotechnical Society, 2024, 39(20): 6577-6590.
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