«Previous Article|Table of Contents|Next Article»

《南京师大学报（自然科学版）》[ISSN:1001-4616/CN:32-1239/N]

Issue:

2018年04期

Page:

39-

Research Field:

·数学与计算机科学·

Publishing date:

Info

Title:

A Machinery Fault Feature Extraction Approach IntegratingReweighted SVD with Periodic Overlapping Group Sparsity

Author(s):

Ren Shijin¹; Li Xinyu²; Xu Guiyun²; Pan Jianhan¹; Yang Maoyun¹

(1.School of Computer Science & Technology,Jiangsu Normal University,Xuzhou 221116,China)(2.School of Mechatronic Engineering,China University of Mining and Technology,Xuzhou 221116,China)

Keywords:

reweighted singular value decomposition(RSVD); periodic overlapping group sparsity(POGS); machinery fault diagnosis; sparse feature extraction; periodic modulation intensity(PMI)

PACS:

TP181

DOI:

10.3969/j.issn.1001-4616.2018.04.008

Abstract:

The machinery fault features are generally periodic,sparse and corrupted by heavy background noise. Most feature extraction methods like locally linear embedding(LLE),local tangent space alignment(LTSA)and etc.,are susceptible to noise. Therefore,signal denoising and faulty feature enhancement are critical for machinery fault detection. To address the issue,a reweighted singular value decomposition integrating with periodic overlapping group sparsity(RSVD-POGS)-based feature extraction approach is developed for machinery fault detection in this study. Firstly,RSVD is introduced to decompose multiple-component vibration signal into a set of singular components and periodic modulation intensity(PMI)criterion is utilized to select salient singular components. POGS is then conducted to enhance sparse and periodic impulse features hidden in the remained singular components,and the original signal can be constructed by the denoised singular components. The comparison between RSVD-POGS and POGS is carried out on low SNR simulated sparse periodic signal and RSVD-POGS is utilized to extract features rom normal and fault vibration signals collected from experimental platform. The experimental results demonstrate that the proposed method can effectively enhance the periodic and sparse fault features for machinery fault diagnosis.

References:

[1] ZHAO M,JIA X D. A novel strategy for signal denoising using reweighted SVD and its application to weak fault enhancement of rotating machinery[J]. Mechanical systems and signal processing,2017,94:129-147.
[2]JIANG H M,CHEN J,DONG G M,et al. Study on Hankel matrix-based SVD and its application in rolling element bearing fault diagnosis[J]. Mechanical systems and signal processing,2015,52/53:338-359.
[3]王聪. 基于稀疏表达的机械信号处理方法及其在滚动轴承故障诊新中的应用研究[D]. 合肥:中国科学技术大学,2017.
[4]YU F J,ZHOU F. Classification of machinery vibration signals based on group sparse representation[J]. Journal of vibration engineering,2016,18(3):1540-1554.
[5]YANG H G,LIN H B,DING K. Sliding window denoising ngular value decomposition and its application on rolling bearing impact fault diagnosis[J]. Journal of sound and vibration,2018,421:205-219.
[6]YUAN J,JI F,GAO Y,et al. Integrated ensemble noise-reconstructed empirical mode decomposition for mechanical fault detection[J]. Mechanical systems and signal processing,2018,104:323-346.
[7]ZHANG G,YI T,ZHANG T Q,et al. A multiscale noise tuning stochastic resonance for fault diagnosis in rolling element bearings[J]. Chinese journal of physics,2018,56(1):145-157.
[8]CHEN J L,ZI Y Y,HE Z,et al. Adaptive redundant multiwavelet denoising with improved neighboring coefficients for gearbox fault detection[J]. Mechanical systems and signal processing,2013,38:549-568.
[9]Lü Y,YUAN R,SONG G B. Multivariate empirical mode decomposition and its application to fault diagnosis of rolling bearing[J]. Mechanical systems and signal processing,2016,81:219-234.
[10]HU A,YAN X A,XIANG L. A new wind turbine fault diagnosis method based on ensemble intrinsic time-scale decomposition and WPT-fractal dimension[J]. Renewable energy,2015,83:767-778.
[11]GOLAFSHAN R,SANLITURK K Y. SVD and Hankel matrix based denoising approach for bearing fault detection and its assessment using artificial faults[J]. Mechanical systems and signal processing,2016,70/71:36-50.
[12]LIU T,CHEN J,DONG G. Singular spectrum analysis and continuous hidden Markov model for rolling element bearing fault diagnosis[J]. Journal of vibration and control,2015,21(8):1506-1521.
[13]CONG F,CHEN J,GONG M G,et al. Short-time matrix series based singular value decomposition for rolling bearing fault diagnosis[J]. Mechanical systems and signal processing,2013,34:218-230.
[14]JIANG Y H,TANG B P,QIN Y,et al. Feature extraction method of wind turbine based on adaptive Morlet wavelet and SVD[J]. Renewable energy,2011,36:2146-2153.
[15]SANLITURK K Y,CAKAR O. Noise elimination from measured frequency response functions[J]. Mechanical systems and signal processing,2005,19:615-631.
[16]MURUGANATHAM B,SANJITH M,KUMAR B K,et al. Roller element bearing fault diagnosis using singular spectrum analysis[J]. Mechanical systems and signal processing,2013,35:150-166.
[17]ZHU K P,LIN X,LI K X,et al. Compressive sensing and sparse decomposition in precision machining process monitoring:from theory to applications[J]. Mechatronics,2015,31:3-15.
[18]TAN Y,HOU X S,CHEN Z,et al. Image compressive sensing reconstruction based on collaboration reduced rank preprocessing[J]. Electronics letters,2017,53(11):717-718.
[19]WEN F Q,ZHANG G,BEN D. Estimation of multipath parameters in wireless communications using multi-way compressive sensing[J]. Journal of systems engineering and electronics,2015,26(5):908-915.
[20]SHAO H D,JIANG H K,ZHANG H Z,et al. Rolling bearing fault feature learning using improved convolutional deep belief network with compressed sensing[J]. Mechanical systems and signal processing,2018,100:743-765.
[21]SUN R B,YANG Z B,CHEN X F. Gear fault diagnosis based on the structured sparsity time-frequency analysis[J]. Mechanical systems and signal processing,2018,102:346-363.
[22]FAN W,CAI G G,ZHU Z K. Sparse representation of transients in wavelet basis and its application in gearbox fault feature extraction[J]. Mechanical systems and signal processing,2015,56/57:230-245.
[23]TANG G,YANG Q,WANG H Q,et al. Sparse classification of rotating machinery faults based on compressive sensing strategy[J]. Mechatronics,2015,31:60-67.
[24]张新鹏. 压缩感知及其在旋转机械健康监测中的应用[D]. 长沙:国防科技大学,2015.
[25]刘畅. 基于压缩感知的滚动轴承特征提取与特征约简方法研究[D]. 昆明:昆明理工大学,2017.
[26]HAN T,JIANG D X,SUN Y K,et al. Intelligent fault diagnosis method for rotating machinery via dictionary learning and sparse representation-based classification[J]. Measurement,2018,118:181-193.
[27]GANESAN V,DAS T,RAHNAVARD N,et al. Vibration-based monitoring and diagnosis using compressive sensing[J]. Journal of sound and vibration,2017,394:612-630.
[28]CHEN X F,DU Z H,LI J M,et al. Compressed sensing based on dictionary earning for extracting impulse components[J]. Signal processing,2014,96:94-109.
[29]CHEN G,LIN F,HUANG W. Sparse discriminant manifold projections for bearing fault diagnosis[J]. Journal of sound and vibration,2017,399:330-334.
[30]贺王鹏. 周期簇稀疏特征提取方法及其在机械故障诊断中的应用研究[D]. 西安:西安交通大学,2017.

Memo

Memo:

-

Common functions

Last Update: 2018-12-30