A New Criterion for Transformer Excitation Inrush Current Identification Based on the Wasserstein Distance Algorithm

A New Criterion for Transformer Excitation Inrush Current Identification Based on the Wasserstein Distance Algorithm

To circumvent the computational bottlenecks associated with the intermediate steps (e.g., least squares fitting) in conventional sine wave similarity principles and directly acquire the energy metrics required for stabilized sinusoidal waveform characterization, this study leverages time domain prob...

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Bibliographic Details
Main Authors: Shanshan Zhou, Jingguang Huang, Yuanning Zhang, Yulong Li
Format: Article
Language:English
Published: MDPI AG 2025-07-01
Series:Energies
Subjects:
Wasserstein distance
fault current
inrush current
energy distribution
Online Access:https://www.mdpi.com/1996-1073/18/14/3872
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Summary:To circumvent the computational bottlenecks associated with the intermediate steps (e.g., least squares fitting) in conventional sine wave similarity principles and directly acquire the energy metrics required for stabilized sinusoidal waveform characterization, this study leverages time domain probability distribution theory. From a complementary advantage perspective, a novel transformer inrush current identification criterion is developed using the Wasserstein distance metric. The methodology employs feature discretization to extract target/template signals, transforming them into state vectors for sample labelling. By quantifying inter-signal energy distribution disparities through this framework, it achieves a precise waveform similarity assessment in sinusoidal regimes. The theoretical analysis and simulations demonstrate that the approach eliminates frequency domain computations while maintaining implementation simplicity. Compared with conventional sine wave similarity methods, the solution streamlines protection logic and significantly enhances practical applicability with accelerated response times. Furthermore, tests conducted on field-recorded circuit breaker closing waveforms using MATLAB R2022a confirm the effectiveness of the proposed method in improving transformer protection performance.
ISSN:1996-1073

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