International Journal of Advanced Network, Monitoring and Controls       Volume 03, No.04, 2018 

87 

Research on Noise Removal in Fiber Grating Sensing Signal 

Xiaobo Zhou * 

Xijing university,  

Xi’an, china 

e-mail: 369146317@qq.com  

 

 

 
Abstract—Signal processing is one of the key technology of 

fiber grating sensor, noise interference on signal transmission, 

influence of fiber grating sensor practical application effect, in 

order to solve the noise problem of fiber grating sensing signal, 

design a denoising method of fiber grating sensing signal based 

on improved contourlet transform. The acquisition of fiber 

grating sensing signal firstly, and remove the unwanted signal, 

select the useful signal, then using contourlet transform, by 

filtering the noise filter, finally through the concrete 

experiment to test the effect of denoising. The results show that 

the improved contourlet transform can completely remove the 

fiber Bragg grating sensing signals, and improve the quality of 

FBG sensor communication, and verify the effectiveness of the 

proposed method. 

Keywords-Fiber Grating; Sensing Signal; Noise Interference; 

Contourlet Transform; Filter 

I. INTRODUCTION 

With the continuous development of optical 
communication technology, fiber grating sensing technology 
obtained the unprecedented development of fiber Bragg 
grating sensor with strong ability of resisting electromagnetic 
interference resistance to corrosion, high sensitivity, small 
body Low cost advantages, has the incomparable advantages 
of traditional sensors, in the national defense military 
aerospace and other fields has been widely used in [1-3] in 
the practical application of fiber Bragg grating sensor and 
sensing signal is very susceptible to noise interference, the 
measurement precision of the fiber Bragg grating sensor is 
affected, so to remove the noise of the fiber Bragg grating 
sensor research has the vital significance. 

At home and abroad in recent years, some studies 
mechanism of fiber Bragg grating sensor signal denoising 

studies [7, 8], but the study also not enough in-depth the 
earliest using Fourier transform to deal with the noise of the 
fiber Bragg grating sensor signal, in order to improve the 
quality of the fiber Bragg grating sensor signals, but as a 
result of the Fourier transform of signal decomposition scale 
is coarser, cannot effectively eliminate the noise of the fiber 
Bragg grating sensor signal [9-11] In order to solve the 
limitations of Fourier transform, some scholars wavelet 
transform denoising method was adopted to realize FBG 
sensing signal quality of ascension, the decomposition scale 
is more detailed, more thoroughly remove noise, but the 
algorithm of wavelet threshold denoising process, the 
threshold selection is critical, whether hard or soft threshold 
threshold was adopted to realize, the current disagreed on 
threshold selection criteria, and the implementation process 
is very complicated, not easy to operation. 

Outline of the wavelet transform is a method of 
multi-scale decomposition can effective denoising signal in 
noise, in order to solve the problem of the current fiber 
Bragg grating sensor signal noise, design a fiber Bragg 
grating sensor based on contour wavelet transform signal 
denoising method, the experimental results, improve the 
outline of the wavelet transform can eliminate noise in the 
fiber Bragg grating sensor signals, won the high quality of 
the grating sensor signal. 

II. WORKING PRINCIPLE OF FIBER GRATING SENSING 

Fiber Bragg grating sensor is a kind of wavelength 
modulated sensor. As the wavelength is a constant, it is not 
affected by the optical fiber loss and energy of the light 
source, so its performance is better than other types of fiber 
sensor. Its working principle is shown in figure 1. 

DOI: 10.21307/ijanmc-2019-026



International Journal of Advanced Network, Monitoring and Controls       Volume 03, No.04, 2018 

88 

 
Figure 1. WorkingPrinciple of Fiber Grating Sensing 

 
Appens, reflection wavelength will have corresponding 

change, so that we can according to the detection wavelength 
to be the measured value of the fiber grating, such as 

temperature and pressure center wavelength drift (  ) and 

the relationship between the longitudinal strain (  ) can be 
described as  

(1 )B
e

B

P






  



1
/

e
P dn d

n
  denotes the elastic modulus. 

The relationship between the center wavelength drift 

(  ) and temperature change ( T ) of the FBG can be 
described as 

( )B
t

B

T


 



  



t


And


respectively represent the coefficient of 
thermal expansion and the coefficient of thermal light. 

 
The relationship between the center wavelength drift 

(  ) and pressure change ( P ) of the fiber Bragg grating 
is 

( ) 1 1n n
P

n P n P



 

     
      

    

Let E be the elastic modulus of the fiber Bragg grating, 
and the formula for calculating the refractive index change of 
the fiber Bragg grating is 

 

(1 2 )L v P

L E

 




2

12 11
(1 2 )(2 )

2

n n P
v

n E
 


  



In the process of fiber Bragg grating sensing, the 
refractive index is related to many factors, especially the 
interference of noise is the biggest, which brings adverse 
effects to the measurement results such as temperature and 
pressure. For this reason, contour transformation is 
introduced in this paper to carry out denoising processing on 
the fiber Bragg grating sensing signal, so as to improve the 
measurement accuracy such as temperature and pressure. 

III. THE METHOD OF RASTER SENSING SIGNAL 
DENOISING BY CONTOURLETTRANSFORM 

A. Contourlet Transform 

Aiming at the limitation of the wavelet transform, some 
scholars raised the outline of the wavelet transform, this 
method can from two aspects of measure frequency, by the 
signal processing has a certain direction, make the effective 
signal to concentrate for a signal containing noise, outline of 
the wavelet transform of the original signal by base structure 
approaching, outline of the wavelet transform at the same 
time also has a certain anisotropic characteristics through the 
Laplacian pyramid to multi-scale decomposition of noise 
signal, find some of the specific signal and noise, through the 
direction of the filter to filter noise operation, after denoising 



International Journal of Advanced Network, Monitoring and Controls       Volume 03, No.04, 2018 

89 

signal Firstly, the fiber Bragg grating sensor signal is 
sampled and the low frequency information of the fiber 
Bragg grating sensor signal is obtained. Then, the fiber 
Bragg grating sensor signal is sampled, and the high 

frequency information of the fiber Bragg grating sensor 
signal is obtained. In figure 2, X represents the fiber Bragg 
grating sensor signal, and H G is a low-pass filter. 

H ¯M M G -
x

a

b
+ H ¯M M G+-

x

a

b
+

 

(a) Decomposition of fiber Bragg grating signals           (b) Reconstruction of fiber Bragg grating signals 

Figure 2. Diagram of decomposition and reconstruction of fiber Bragg grating signals 

The process of three-level directional subband division of 
direction filter is shown in figure 3. The sub-bands of the 
upper level are sampled by resampling operator and the 
sampling results are output. 

 

 
Figure 3. Subband division of direction filter 

B. The De-noising Principle of Fiber Bragg grating (FBG) 
Sensor in Contour Wave Transform 

As the useful FBG sensor signal and noise show different 
characteristics in contour wave transformation, the FBG 
sensor signal is transformed in different levels, and the noise 
in the FBG sensor signal is removed according to the 
appropriate threshold value. 

Set the original fiber Bragg grating sensor signal

 ( ); 1, 2, ,g x x N 
,Signal with noise fiber grating 

sensor
 ( ) ( ) ( ); 1, 2, ,f x g x N x x N   

,Where, 

the mean value of noise is 0, the variance is
2

 , and the 
formula for calculating the standard deviation of each layer 
is 

1,2, ,
( ( ) )

ˆ ( )
0.5

f
j J

Median w j
j








( )
f

w j
means the decomposition coefficient of the

( )f x
JTH layer. 

C. Selection of Threshold Value of Signal Denoising by 
Fiber Bragg Grating Sensor 

There are many threshold selection methods for contour 
wave transformation. Due to the universal and easy 
implementation of the Universe threshold method, this paper 
selects the Universe threshold method to determine the 
threshold of the optical fiber grating sensor signal denoising, 
and the high-frequency sub-band threshold of the Universe 
threshold method is determined as follows 

( ) ( ) 2 lg( ( ) * ( ))TH j j M j N j


Where, 
( ) * ( )M j N j

represents the number of contour 
wave decomposition coefficients of j layer. 

( ) * ( )M j N j
,the larger the size, the denoising 

threshold will set the high frequency coefficient of the 
decomposition result of the fiber Bragg grating sensor to 0. 
In this way, a large number of useful fiber Bragg grating 
sensor signals will be removed. Therefore, equation (7) will 
be corrected as follows 

( )
( )

( ) * ( )

TH j
TH j

M j N j




D. The Process of Signal Denoising by Fiber Bragg 
Grating Sensor 

Step1: contour wave transform is performed on signal f(x) 
of fiber Bragg grating sensor with noise. The coefficients of 
contour transform domain are as follows: 

( ( )) _ _w CT f x CT f CT n  


Step2: according to the denoising rules, the contour 

transformation coefficient ( ŵ ) of the original image g(x) is 



International Journal of Advanced Network, Monitoring and Controls       Volume 03, No.04, 2018 

90 

obtained by applying the denoising rules to the original 
optical fiber grating sensor signal w. The denoising rules are 
as follows: 

, ( )
ˆ

0, ( )

w if w TH j
w

if w TH j

 
 

 

Step3: perform contour wave reconstruction and 

transformation on the estimated value ŵ of contour wave 
transform coefficient, and obtain the signal of fiber Bragg 

grating sensing
'( )g x

after de-noising. 

1 ˆ( )g x CT w
 



IV. TEST AND ANALYSIS OF THEDENOISING EFFECT OF 
FIBER BRAGG GRATING SENSOR 

A. The Signal of Fiber Grating Sensor WithNoise 

In order to analyze the denoising effect of the fiber Bragg 
grating sensing signal of contour wave transform, Matlab 
2014 was used as the test platform to conduct the 
denoisingexperiment. The signal of fiber grating sensor with 
noise is shown in figure 4. 

 

 
Figure 4. The signal of fiber grating sensor with noise 

B. Results and Analysis 

1) The denoising effect of this paper. Contour wave 
transform is used to de-noising the signal-sensing signal of 

the fiber Bragg grating containing noise in figure 4. The 

signal-sensing signal of the fiber Bragg grating after 

de-noising is shown in figure 5. As can be seen from figure 5, 

contour wave transform can remove the noise in the fiber 

Bragg grating sensing signal very well and improve the 

quality of the fiber Bragg grating sensing signal. It is an 

effective method to remove noise from the fiber Bragg 

grating sensing signal. 

 

 
Figure 5. The denoising results of fiber Bragg grating sensor in contour 

wave transform 

2) Performance Comparison with Current Classical 
Methods. In order to test the advantage of contour wave 

transform in denoising, wavelet transform [16] and literature 

[17] were used for comparison experiments, and peak signal 

to noise ratio (PSNR) and root mean square error (MSE)[18] 

were used to evaluate the result of signal de-noising of fiber 

Bragg grating sensor. PSNR and MSE of fiber Bragg grating 

sensor after de-noising were shown in table 1. Can be seen 

from table 1, the outline of the fiber Bragg grating sensor 

signals after wavelet transform denoising PSNR, said fiber 

Bragg grating sensor signal quality is better, noise removal 

more thoroughly, and contrast methods cannot completely 

eliminate the noise in the fiber Bragg grating sensor signals 

effectively, the interferences with fiber Bragg grating sensor 

measurement accuracy, MSE is far less than contrast method 

at the same time, said contour wavelet transform denoising 

results more stable, and the method of denoising time is 

shorter, can satisfy the mass of fiber Bragg grating sensor 

signal denoising practical application requirements. 

TABLE.I. COMPARES THE PERFORMANCE OF THE CLASSICAL RASTER 
SENSING SIGNAL DE-NOISING METHOD 

Denoising method PSNR MSE 

The wavelet 

transform 
20.33 8.00 

The literature[17] 22.19 7.72 

Contour wave 

transform 
24.73 7.24 

V. SUMMARY 

Serious impact on the quality of the fiber Bragg grating 
signal noise, its application scope and bring certain actual 
application value of interference, in order to eliminate the 
adverse effect, was proposed based on wavelet transform 
outline of fiber grating sensing signal denoising method, 
according to outline the multi-scale wavelet transform and 
directional advantages, the fiber Bragg grating sensor signal 
decomposition, found in the decomposition of the signal 
noise data, and through the corresponding filter to remove 
noise, and through the inverse operation outline of the 
wavelet transform denoising signal after refactoring, 
improves the signal-to-noise ratio of the fiber Bragg grating 
sensor signals, and compared with other denoising method 
has carried on the experiment. The contrast method can 



International Journal of Advanced Network, Monitoring and Controls       Volume 03, No.04, 2018 

91 

remove some useful signals while removing noise, while the 
method in this paper may keep the useful signal as much as 
possible, and at the same time improve the real-time 
performance of the fiber Bragg grating sensing signal. 

ACKNOWLEDGEMENT 

Xijing University Scientific Research Foundation 
Project(XJ140236). 

 

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