Random wavelet kernels for interpretable fault diagnosis in industrial systems
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2025-07-15
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0007-8506
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Deng H, Khan S, Erkoyuncu JA. (2025) Random wavelet kernels for interpretable fault diagnosis in industrial systems. CIRP Annals, Volume 74, Issue 1, 2025, pp. 49-53
Abstract
Deep learning is a powerful method for fault diagnosis, but its "black-box" nature raises concerns in critical applications. This paper presents an interpretable, lightweight method combining random convolution kernel transformation (ROCKET) with wavelet kernels, which offer systematic time-frequency analysis and intuitive insights. Principal component analysis (PCA) is used to extract relevant patterns, forming a health indicator that guides maintenance decisions. A case study on linear actuator fault diagnosis demonstrates the method's balance of interpretability and computational efficiency, making it a valuable tool for reliable asset health monitoring in resource-limited settings.
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Github
Keywords
40 Engineering, 4010 Engineering Practice and Education, Industrial Engineering & Automation, 4014 Manufacturing engineering, 4017 Mechanical engineering, Failure, Machine learning, Maintenance
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Attribution 4.0 International
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Engineering and Physical Sciences Research Council (EPSRC)
The research was partially supported with EPSRC funding (EP/P027121/1).
The research was partially supported with EPSRC funding (EP/P027121/1).