An Adaptive Noise-Resistant Learning Method for DSSE Considering Inaccurate Label Data

IF 7.2 1区工程技术 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE Transactions on Power Systems Pub Date : 2024-12-16 DOI:10.1109/TPWRS.2024.3518098

Jiaxiang Hu;Weihao Hu;Di Cao;Qianwen Xu;Qi Huang;Zhe Chen;Frede Blaabjerg

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Abstract

The training process of learning-based distribution system state estimation (DSSE) methods relies on accurate state variables, which typically contain unknown noise and outliers in practice. To this end, this paper proposes an adaptive noise-resistant graphical learning-based DSSE method considering the impact of inaccurate state variables. Specifically, two global-scanning graph jumping connection networks are first developed to capture the regression rules between measurements and state variables considering the structure constraints. To mitigate the negative impact caused by inaccurate labels, a collaborative learning framework is further developed, within which Gaussian mixture model-based discriminators are employed to adaptively select clean samples in each mini-batch. These allow the method to obtain robustness against noisy state labels in historical data, as well as anomalous measurements during online operations. Comparative tests show the superiority of the proposed method in tackling abnormal data in both the training and test phases.

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考虑到不准确标签数据的 DSSE 自适应抗噪学习方法

基于学习的配电系统状态估计（DSSE）方法的训练过程依赖于精确的状态变量，而在实际应用中，这些状态变量通常包含未知噪声和异常值。为此，本文提出了一种考虑不准确状态变量影响的基于自适应抗噪声图形学习的DSSE方法。具体而言，首先建立了两个全局扫描图跳跃连接网络，以捕获考虑结构约束的测量值与状态变量之间的回归规律。为了减轻标签不准确造成的负面影响，进一步开发了一个协作学习框架，在该框架中，基于高斯混合模型的判别器自适应地选择每个小批量的干净样本。这使得该方法对历史数据中的噪声状态标签以及在线操作期间的异常测量具有鲁棒性。对比实验表明，该方法在训练和测试阶段处理异常数据方面都具有优越性。

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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来源期刊

IEEE Transactions on Power Systems 工程技术-工程：电子与电气

CiteScore

15.80

自引率

7.60%

发文量

696

审稿时长

3 months

期刊介绍： The scope of IEEE Transactions on Power Systems covers the education, analysis, operation, planning, and economics of electric generation, transmission, and distribution systems for general industrial, commercial, public, and domestic consumption, including the interaction with multi-energy carriers. The focus of this transactions is the power system from a systems viewpoint instead of components of the system. It has five (5) key areas within its scope with several technical topics within each area. These areas are: (1) Power Engineering Education, (2) Power System Analysis, Computing, and Economics, (3) Power System Dynamic Performance, (4) Power System Operations, and (5) Power System Planning and Implementation.