Wigner–Ville distribution based on cyclic spectral density and the application in rolling element bearings diagnosis

The vibration signals of rolling element bearings are random cyclostationary when they have faults. Also, statistical properties of the signals change periodically with time. The accurate analysis of time-varying signals is an essential pre-requisite for the fault diagnosis and hence safe operation of rolling element bearings. The Wigner distribution is probably most widely used among the Cohen’s class in order to describe how the spectral content of a signal changes over time. However, the basic nature of such signals causes significant interfering cross-terms, which do not permit a straightforward interpretation of the energy distribution. To overcome this difficulty, the Wigner–Ville distribution (WVD) based on the cyclic spectral density (CSD) is discussed in this article. It is shown that the improved WVD, based on CSD of a long time series, can render the time–frequency distribution less susceptible to noise, and restrain the cross-terms in the time–frequency domain. Simulation and experiment of the rolling element-bearing fault diagnosis are performed, and the results indicate the validity of WVD based on CSD in time–frequency analysis for bearing fault detection.

[1]  Keith Worden,et al.  TIME–FREQUENCY ANALYSIS IN GEARBOX FAULT DETECTION USING THE WIGNER–VILLE DISTRIBUTION AND PATTERN RECOGNITION , 1997 .

[2]  L. Cohen,et al.  Time-frequency distributions-a review , 1989, Proc. IEEE.

[3]  Robert B. Randall,et al.  Differential Diagnosis of Gear and Bearing Faults , 2002 .

[4]  William A. Gardner,et al.  The cumulant theory of cyclostationary time-series. I. Foundation , 1994, IEEE Trans. Signal Process..

[5]  Biao Huang,et al.  On spectral theory of cyclostationary signals in multirate systems , 2005, IEEE Trans. Signal Process..

[6]  A. Izenman Introduction to Random Processes, With Applications to Signals and Systems , 1987 .

[7]  J. Antoni Cyclic spectral analysis of rolling-element bearing signals : Facts and fictions , 2007 .

[8]  Ioannis Antoniadis,et al.  CYCLOSTATIONARY ANALYSIS OF ROLLING-ELEMENT BEARING VIBRATION SIGNALS , 2001 .

[9]  P. D. McFadden,et al.  Model for the vibration produced by a single point defect in a rolling element bearing , 1984 .

[10]  J. Antoni Cyclostationarity by examples , 2009 .

[11]  Georgios B. Giannakis,et al.  Cyclostationary Signal Analysis , 2009 .

[12]  R. Randall,et al.  OPTIMISATION OF BEARING DIAGNOSTIC TECHNIQUES USING SIMULATED AND ACTUAL BEARING FAULT SIGNALS , 2000 .

[13]  Jun He,et al.  Application of Degree of Cyclostationarity in Rolling Element Bearing Diagnosis , 2005 .

[14]  Brejesh Lall,et al.  Second-order statistical characterization of the filter bank and its elements , 1999, IEEE Trans. Signal Process..

[15]  J. Antoni Cyclic spectral analysis in practice , 2007 .

[16]  Robert B. Randall,et al.  THE RELATIONSHIP BETWEEN SPECTRAL CORRELATION AND ENVELOPE ANALYSIS IN THE DIAGNOSTICS OF BEARING FAULTS AND OTHER CYCLOSTATIONARY MACHINE SIGNALS , 2001 .

[17]  William A. Gardner,et al.  The cumulant theory of cyclostationary time-series. II. Development and applications , 1994, IEEE Trans. Signal Process..

[18]  J. Bono,et al.  Wigner/cycle spectrum analysis of spread spectrum and diversity transmissions , 1991 .

[19]  Asoke K. Nandi,et al.  CYCLOSTATIONARITY IN ROTATING MACHINE VIBRATIONS , 1998 .

[20]  Jin Chen,et al.  Frequency-Demodulated Analysis Based on Cyclostationarity for Local Fault Detection in Gears , 2005 .

[21]  Robert B. Randall,et al.  A Stochastic Model for Simulation and Diagnostics of Rolling Element Bearings With Localized Faults , 2003 .