Open AccessFault Diagnosis of Rolling Bearing Based on Improved VMD and KNN
Author(s) -
Quanbo Lu,
Xinqi Shen,
Xiujun Wang,
Mei Li,
Jia Li,
Mengzhou Zhang
Publication year - 2021
Publication title -
mathematical problems in engineering
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.262
H-Index - 62
eISSN - 1026-7077
pISSN - 1024-123X
DOI - 10.1155/2021/2530315
Subject(s) - fault (geology) , eigenvalues and eigenvectors , extension (predicate logic) , modal , singular value decomposition , bearing (navigation) , hilbert–huang transform , algorithm , pattern recognition (psychology) , decomposition , artificial intelligence , computer science , mathematics , computer vision , physics , materials science , ecology , filter (signal processing) , quantum mechanics , seismology , polymer chemistry , biology , programming language , geology
Variational modal decomposition (VMD) has the end effect, which makes it difficult to efficiently obtain fault eigenvalues from rolling bearing fault signals. Inspired by the mirror extension, an improved VMD is proposed. This method combines VMD and mirror extension. The mirror extension is a basic algorithm to inhibit the end effect. A comparison is made with empirical mode decomposition (EMD) for fault diagnosis. Experiments show that the improved VMD outperforms EMD in extracting the fault eigenvalues. The performance of the new algorithm is proven to be effective in real-life mechanical fault diagnosis. Furthermore, in this article, combining with singular value decomposition (SVD), fault eigenvalues are extracted. In this way, fault classification is realized by K-nearest neighbor (KNN). Compared with EMD, the proposed approach has advantages in the recognition rate, which can accurately identify fault types.
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