Abstract Angular sampling is a useful tool to study cyclic rotating machine vibrations. It can be implemented by using computer order tracking, directly, or by extracting position information from an acceleration signal. Instantaneous speed can also be angularly sampled using a counter technique. Angular sampling is sensitive to hardware imperfections (optical encoder precision, electrical perturbation, etc.). Angular sampled signal quantification step or sampling frequency determination is not identical to time domain. Angular sampling is also not adapted to study time domain signals like impulse response. Some of these imperfections can be viewed as non-uniform sampling. Non-uniform sampling consists in introducing a jitter in an angular sampling position. This jitter is random and different for every position. This jitter can be caused physically by some inaccuracies in position sensor measurements. Sampling a time domain relative signal against the angle can also be viewed as a non-uniform sampling. In this case the jitter is caused by speed fluctuation (constant speed case). Non-uniform sampling introduces an additional noise (that can be cyclostationary at order 2 if the original signal is cyclostationary at order 1). Non-uniform sampling also acts as a low pass filter. Its cut-off frequency depends on jitter standard deviation. An experimental bench was built. This bench uses a synchronous data acquisition board, an arbitrary generator, and a non-uniform clock generator. Experimentations are performed using various jitter values (from 0.1% to 20%) and are corroborated by previous theoretical studies.
[1]
L. Renaudin,et al.
Natural roller bearing fault detection by angular measurement of true instantaneous angular speed
,
2010
.
[2]
K. R. Fyfe,et al.
ANALYSIS OF COMPUTED ORDER TRACKING
,
1997
.
[3]
Robert B. Randall,et al.
Enhanced Unsupervised Noise Cancellation using Angular Resampling for Planetary Bearing Fault Diagnosis
,
2004
.
[4]
Robert B. Randall,et al.
Use of the acceleration signal of a gearbox in order to perform angular resampling (with limited speed fluctuation)
,
2005
.
[5]
M. B. Romdhane.
Echantillonnage non uniforme appliqué à la numérisation des signaux radio multistandard
,
2009
.
[6]
J. Antoni.
Cyclostationarity by examples
,
2009
.
[7]
Robert B. Randall,et al.
Model-based diagnosis of large diesel engines based on angular speed variations of the crankshaft
,
2010
.
[8]
Andrew Ball,et al.
The measurement of instantaneous angular speed
,
2005
.
[9]
Frédéric Bonnardot,et al.
Comparaison entre les analyses angulaire et temporelle des signaux vibratoires de machines tournantes : étude du concept de cyclostationnarité floue
,
2004
.
[10]
Robert B. Randall,et al.
EFFECTIVE VIBRATION ANALYSIS OF IC ENGINES USING CYCLOSTATIONARITY. PART II—NEW RESULTS ON THE RECONSTRUCTION OF THE CYLINDER PRESSURES
,
2002
.
[11]
F. Guillet,et al.
New applications of the real cepstrum to gear signals, including definition of a robust fault indicator
,
2004
.