Fault Feature Extraction Method of Rotor Vibration Signals Based
on Blind Source Separation and Wavelet Transform
Feng Miao
1
and Ruzhi Feng
2
1
School of Physical and Electrical Information, Luoyang Normal University, Luoyang 471022, China
2
Henan Mechanical and Electrical Vocational College, Zhengzhou 451191, China
miaofeng3699@163.com,229042106@qq.com
Keywords: Fault feature extraction, Wavelet De-noising, Blind source separation, Rotor.
Abstract: In this paper, a new fault feature extraction method is presented based on wavelet transform and blind
source separation. At first, wavelet transform is employed to de-noise measured signals to remove the
process noise. Then blind source separation based on second order statistics is used to extract blind source
signals of the process. The simulation and experiment testing results show the proposed method that
compare with other method based on blind source analysis directly with process information can effectively
extract the quantitative feature extraction. Finally,the signals of rotor vibration with noise interference
were separated successfully using the proposed method.
1 INTRODUCTION
Blind source separation (BSS) means that the
observation signal can be used to recover the
independent component process of the source signal
according to the statistical characteristics of the
input source signal without knowing the source
signal and the transmission channel parameters. In
recent years, BBS has become a very popular signal
processing technology. Since Zeng and Li(2002,
2003) proposed a class method of neural blind
source separation, the blind source signal separation
method has made a number of fruitful research, in
the field of communications, voice and biomedical
rapid development and promotion.
The vibration signal of the mechanical
equipment is an important information source for
fault identification and diagnosis, and the vibration
signal is often mixed with several signals, which
brings difficulties to the feature recognition and
diagnosis. The study of blind source signal
separation method provides the conditions for the
separation of vibration signals and fault feature
recognition. In the mechanical fault diagnosis
system, the signal obtained by the sensor is
inevitably disturbed by different types of unknown
noise. In the unknown general noise environment,
the separation effect of BSS-based mechanical
source signal is often poor if the influence of noise is
neglected (Miao, 2014; Lei, 2011; Hu, 2003; Yu,
2005). Therefore, the influence of noise must be
taken into account in BSS-based mechanical fault
diagnosis. In this paper, combined with wavelet
filtering and BSS, the wavelet filter is used to de-
noise the test signal, and then the second order
statistic of the signal is used to separate the blind
source signal, and the simulation and experimental
study are carried out.
2 THE LIKELIHOOD OF THE
BSS MODEL WITH NOISE
MIXING
In the model of linear instantaneous mixing with
noise, the relationship between the unknown source
signal and the observed signal can be described as
the form (Huang, 2008; Ye, 2010) of the equation
(1)
() () ()yt Ast nt=+
(1)
Where
12
( ) [ ( ), ( ),..., ( )]
T
M
y
t
y
t
y
t
y
t=
is the
M-dimensional random observation vector in the
case of noise,
12
( ) [ ( ), ( ),..., ( )]
T
N
st s t s t s t=
is
the N-dimensional source signal, the components
114
Miao, F. and Feng, R.
Fault Feature Extraction Method of Rotor Vibration Signals Based on Blind Source Separation and Wavelet Transform.
In 3rd International Conference on Electromechanical Control Technology and Transportation (ICECTT 2018), pages 114-118
ISBN: 978-989-758-312-4
Copyright © 2018 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
()
i
st in the source signal are assumed to be
statistically independent,
12
( ) [ ( ), ( ),..., ( )]
T
M
nt n t n t n t= is the M-
dimensional additive observation noise, and
M
N≥ , A is a mixed matrix of an unknown
M
N× ,In this case, the purpose of blind source
separation is to find an
M
N× full rank separation
matrix B, so that the estimated source signal vector
between the various components as independent as
possible, such as Figure 1 shows. In the figure, the
output signal
'( )st is the estimation result of the
source signal
()
s
t
. It is defined as
'( ) ( ) ( ) ( )s t By t BAs t Bn t== +
(2)
Obviously, if the noise item
()nt in equation (2)
is not Gaussian noise, then its appearance makes the
estimation of separation matrix B become a biased
estimate.
However, even if B obtains an exact estimate of
S, the
()
B
nt in Eq. (2) also increases the variance
of the source estimate S. Therefore, in the strong
noise environment, if you want to improve the
separation performance, the first need for effective
de-noising method for signal de-noising.
Fig.1 Model of blind source separation with noise
3 THE METHOD OF BLIND
SOURCE SEPARATION BASED
ON WAVELET
3.1 The principle of wavelet de-noising
Wavelet transform can simultaneously analyze the
local characteristics of the signal in the time domain
and frequency domain. The continuous wavelet
transform of the square integrable function
2
() ( )
f
tLR∈ is defined as (Li, 2005)
,
1
(,) () ( )
(), ()
f
ab
tb
WT a b
f
tdt
a
a
ft t
ψ
ψ
∞
−∞
−
=
=< >
∫
The kernel function
,
1
() ( )
ab
tb
t
a
a
ψψ
−
= of
the wavelet transform is the result of the time shift
()t
ψ
and scale scaling
b
of the parent wavelet
a
,
and
,<>
is the inner product operation. The basic
idea of wavelet transform is to use a family of
functions to represent or approximate a signal. The
family function is called the wavelet function
system. It is through a wavelet function of the
expansion and translation, to produce its "wavelet"
to form.
3.2 The method of blind source
separation based on wavelet
In BSS-based mechanical fault diagnosis, people
often on the test signal directly blind source signal
separation, while ignoring the impact of noise, the
separation effect is often poor (Miao, 2014). In order
to eliminate the pollution of the noise signal and
improve the effect of the blind source separation
method, before the separation of the mixed signal
vector
12
( ) [ ( ), ( ),..., ( )]
T
M
y
t
y
t
y
t
y
t=
observed in
the noisy case, it is necessary to de-noise with the
wavelet method and then blind source signal
separation. For wavelet de-noising - BSS method.
This process can be expressed as Figure 2.
In this method, there are two important
processes: wavelet de-noising pretreatment, blind
source separation process. In (Li, 2005), these
wavelet de-noising methods are compared. The
corresponding wavelet de-noising method can be
selected according to need. Here the wavelet soft
threshold de-noising method for pre-processing.
For the blind source separation process, at
present, there are many effective linear or nonlinear
BSS algorithms, such as JADE, Informax, MISEP,
FastICA algorithm. Since the JADE algorithm
(Huang, 2008) is robust and usually obtains a more
stable source estimation result, the JADE algorithm
is chosen.
Fig.2 Wavelet de-noising-BSS method
Fault Feature Extraction Method of Rotor Vibration Signals Based on Blind Source Separation and Wavelet Transform
115
4 SIMULATIONS AND
EXPERIMENTAL RESULTS
4.1 Simulation
Using matlab to generate two simulation signals, as
shown in Figure 3; the mixed matrix is randomly
selected to obtain its mixed signal, and two separate
signals are obtained by BBS separation without
adding noise, as shown in Fig4. The separation
results may also vary in amplitude and order due to
the possibility of proportional distortion and order
reversal in the matrix of weights used in the
separation. It can be seen in Figure 4, the separation
signal sequence and the source signal is consistent,
the separation signal to retain the dynamic
characteristics of the source signal, but in varying
degrees of varying degrees of amplification.
However, this is the result of the ideal without
noise or noise pollution is very small case. But in
reality the impact of noise is inevitable, then the
effect of the classic BBS method will be affected. In
the observation signal to add a certain degree of
white noise, and then BBS separation, separation of
signals and shown in Figure 5, the separation signal
and the original signal is very different, the
separation effect is poor.
Fig.3 Original signals
Fig.4 Separated signals in non-noisy mixtures
Therefore, characteristic signal separation in case
of noisy interference, we must consider the impact
of noise. Here the wavelet de-noising-BSS method is
used, in which the de-noising step uses soft
threshold wavelet de-noising, and the separation
result is shown in Fig6. It can be seen that although
there are some errors in the separation effect, the
overall separation effect is still ideal.
Fig.5 Separated signals in noisy mixtures
(no de-noising process)
Fig.6 Separated signals in noisy mixtures
(P.S.-soft shrinkage)
4.2 Experimental analysis
The test rotor system is shown in Fig7. For the set
test system, two sensors are provided: an eddy
current sensor 9 is mounted in the vertical direction
of the mass disk I; a non-contact eddy current
displacement sensor 10 is mounted in the vertical
direction of the right side of the coupling. Rotor
speed of 3800r / min, sampling frequency of 5kHZ,
sampling points of 1024. Signal acquisition and
recording using a computer-based dynamic signal
acquisition and analysis system.
Figure 8 is the noise source signal without noise
separation, and Figure 9 is the vibration source
signal separated by noise reduction. Corresponding
to Fig. 8 and Fig. 9, it can be seen that the
combination of wavelet de-noising and blind source
separation can separate the vibrating source well.
0 100 200 300 400 500 600 700 800 900 1000
-1
-0.5
0
0.5
1
s'1
0 100 200 300 400 500 600 700 800 900 1000
-1
-0.5
0
0.5
1
s'2
0 100 200 300 400 500 600 700 800 900 1000
-2
0
2
s'1
0 100 200 300 400 500 600 700 800 900 1000
-2
0
2
s'2
0 100 200 300 400 500 600 700 800 900 1000
-1
-0.5
0
0.5
1
s'1
0 100 200 300 400 500 600 700 800 900 1000
-1
-0.5
0
0.5
1
s'2
0 100 200 300 400 500 600 700 800 900 1000
-1
-0.5
0
0.5
1
s1
0 100 200 300 400 500 600 700 800 900 1000
-1
-0.5
0
0.5
1
s2
ICECTT 2018 - 3rd International Conference on Electromechanical Control Technology and Transportation
116
Specific analysis of the results of the following
aspects:
Fig.7 Rotor system and sensor position
Fig.8 Power spectrums of mixed signals from two sensors
Fig.9 Power spectrums of vibration signals after separation
(1) From the spectrum of the two sensor
acquisition signals in Fig. 8, it can be clearly seen
that the non-stationary intrinsic vibration signal of
the rotor is submerged in a number of impulsive
noise generated by the modulator in response to the
frequency distribution of the rotor Band, the
frequency distribution of the two stacked together.
From the perspective of the strength of the signal
component, the strong impulse noise occupies the
main signal component status in the signal. Thus, the
vibration signal is a mixed signal subjected to strong
impulse noise and other random interference.
(2) It can also be seen in Fig. 8 that several fault
characteristic frequencies of the acquisition signal
are aliased on each power spectrum due to the
propagation of the structural vibration, and it is
difficult to determine which faults exist. It is
difficult to accurately diagnose the fault in the event
of an unknown failure.
(3) After the wavelet de-noising and blind source
separation, the power spectrum shown in Fig. 9 is
better separated from the fault characteristic. The
power spectrum of each sensor signal after
separation is basically only showing a fault feature.
Figure 9 (a) shows only the rubbing characteristics,
and Figure 9 (b) shows only the misalignment
feature. Figure 9 (a) and Figure 9 (b), although both
are multiplier, but Figure 9 (b) 2 times the frequency
is significantly greater than 1 octave. This
distinguishes between rupture and misalignment.
(4) The results of wavelet de-noising and blind
source separation clearly eliminate the influence of
strong impulse noise and other random interference
signals in Fig.
5 CONCLUSIONS
In BSS-based mechanical source separation, the
resulting measurement signal is often contaminated
by process noise, the useful signal is buried in the
noise. In this paper, we first use the wavelet function
to de-noise the measurement signal, and then use the
second-order statistics of the signal to separate the
blind source signal. By simulation As a result, it can
be seen that in the case of strong background noise
mixing, the separation of the mechanical source
signal without direct noise removal is often not well
separated because the noise can also be regarded as a
source signal. Finally, the proposed method is
applied to the actual rotor vibration source
separation, although there are some errors in the
separation effect, but the overall separation effect is
still ideal. Simulation and experimental results show
that the blind source signal separation based on
wavelet de-noising is more effective to extract the
essential signal characteristics of rotor vibration
fault than the direct blind source separation.
0 50 100 150 200 250 300 350 400
500
1000
1500
2000
(a)The eddy current sensor 9 samples the power spectrum of the signal(f/Hz)
FFT Am plitude/m m
0 50 100 150 200 250 300 350 400
500
1000
1500
2000
(b)The eddy current sensor 10 samples the power spectrum of the signal(f/Hz)
FFT Am plitude/mm
0 50 100 150 200 250 300 350 400 450 500
50
100
150
200
(a)The eddy current sensor 9 samples the power spectrum of the signal(f/Hz)
FFT Am plitude/m m
0 50 100 150 200 250 300 350 400 450 500
50
100
150
(b)The eddy current sensor 10 samples the power spectrum of the signal(f/Hz)
FFT Am plitude/m m
Fault Feature Extraction Method of Rotor Vibration Signals Based on Blind Source Separation and Wavelet Transform
117
ACKNOWLEDGEMENTS
The research described in this paper was supported
by Foundation of He’nan Educational Committee
(16A470021) and key scientific and technological
project of Henan Province (172102210097).
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