A novel random spectral similar component decomposition method and its application to gear fault diagnosis

• Published in: Mechanical systems and signal processing Vol. 208; p. 111032
• Main Authors: Liu, Feng, Cheng, Junsheng, Hu, Niaoqing, Cheng, Zhe, Yang, Yu
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 15.02.2024
• Subjects: Fault significance measure; Gear fault diagnosis; Random spectral similar component decomposition; Spectral similarity criterion; Random spectral similar component decomposition; Gear fault diagnosis; Fault significance measure; Spectral similarity criterion
• ISSN: 0888-3270; 1096-1216
• DOI: 10.1016/j.ymssp.2023.111032

•A new signal processing method called RSSCD is proposed, and it is applied to gear fault diagnosis.•The ideas of randomization and sparsification of time–frequency features are utilized to represent the input signal.•The spectral similarity criterion is defined to adaptively recombine the initial signal components.•A fault significance measure index is designed to guide the selection of parameter in sparse random feature representation.•Simulation and two experimental cases are applied to fully validate the proposed method. Sparse random mode decomposition (SRMD) is a decomposition approach established by combining sparse random feature model with clustering algorithm. It is not subject to the sampling process of signal and can mitigate mode mixing. However, the performance of SRMD is limited by its own hyperparameters, and it is prone to derive inaccurate clustering decomposition results when processing strong noise interference signal. To overcome these defects, a novel method called random spectral similar component decomposition (RSSCD) is proposed. In RSSCD, the time–frequency localized features produced by randomization and sparsification are adopted to represent the input signal. Subsequently, the initial signal components formed by sparse random features are taken as a whole, and the spectral similarity criterion is defined to adaptively form independent random components (RCs), thus improving the accuracy of decomposition. Furthermore, RSSCD is applied to gear fault diagnosis, and a fault significance measure (FSM) index is designed to guide the selection of parameter in sparse random feature representation, which ensures the fault information richness of the required RCs. Finally, the feasibility and effectiveness of RSSCD are fully validated by simulation signals and two experimental cases. The results indicate that RSSCD has excellent decomposition performance and fault feature extraction ability.