A Robust Serial FBG Sensor Network with CDM Interrogation Allowing
Overlapping Spectra
Marek G¨otten
1,2
, Steffen Lochmann
1
a
, Andreas Ahrens
1 b
and C´esar Benavente-Peces
2 c
1
Bereich Elektrotechnik und Informatik, Hochschule Wismar, Phillip-M¨uller-Straße 14, Wismar, Germany
2
Escuela T´ecnica Superior de Ingenier´ıa y Sistemas de Telecomunicaci´on, Universidad Polit´ecnica de Madrid,
Crtra de Valenica, km 7, Madrid, Spain
Keywords:
Code-Division Multiplex, Fiber-Bragg-Gratings, Smart Structures, Serial Optical Sensor Networks, Optical
Autocorrelation.
Abstract:
Massive optical sensor networks gained a lot of attention in recent years. They offer new advances in the fields
of smart structures and health monitoring. All serial optical sensor networks rely on multiplexing techniques
that provide huge amounts of sensors in a single optical fiber. Wavelength-division multiplex (WDM) which
has been established in many applications, is restricted to the spectral width of the used light source that
needs to be shared by several non-overlapping fiber-Bragg-grating (FBG) spectra. Time-division multiplex
(TDM) uses short impulses and relies on different sensor round trip delays to distinguish each single FBG.
These short impulses and long round trip times lead to a low signal-to-noise ratio (SNR). Optical frequency-
domain reflectometry (OFDR) offers a high spatial resolution of FBGs but only within a short fiber length.
This contribution deals with a code-division multiplex (CDM) interrogation technique that provides numerous
sensors in a single optical fiber, a better SNR, and a long range of distributed sensing points. It requires
codes with good autocorrelation behavior which is characterized by certain criteria. The detectable criteria
are limited which narrows significantly a search for best possible codes for the interrogation system. In this
contribution, practical implementation limits such as the trigger timing and the achievable SNR are studied.
Based on the introduced SNR definitions for CDM and WDM systems, a direct comparison is possible and
it shows the superiority of the proposed CDM scheme. A network with 25 sensors operating at the same
wavelength can provide a 2.67dB improvement compared to WDM
1 INTRODUCTION
In the field of sensor technology, optical sensors,
such as FBGs, gain a lot a attention. Their prop-
erties of being light, small, immune to electromag-
netic interferences and capable of multiplexing, make
them the preferred choice for many sensing appli-
cations (Rajan, 2015). Especially the multiplexing
capability is in the focus of interest for applications
like health monitoring (Gliˇsi´c, 2016; Nawrot et al.,
2017) and smart-structures, where optical fiber sen-
sor networks can be integrated into materials (Braghin
et al., 2013; Kim, 2004). Popular multiplexing tech-
niques are WDM (Kersey et al., 1997), TDM (Wang
et al., 2012) or optical frequency-domain reflectom-
etry (OFDR) (Yamaguchi et al., 2015). This contri-
a
https://orcid.org/0000-0002-0938-2186
b
https://orcid.org/0000-0002-7664-9450
c
https://orcid.org/0000-0002-2734-890X
bution makes use of CDM that overcomes the restric-
tions of other multiplexing techniques. Unlike WDM,
the optical sensors can spectrally overlap within the
spectrum of the light source. Compared to TDM that
makes use of a single short light impulse, a CDM
interrogator collects several light impulses forming
a code which significantly improves the SNR of the
system. While OFDR works within short link net-
works (Yamaguchi et al., 2015), CDM has the po-
tential of covering increased fiber lengths. The CDM
technique requires codes with a good autocorrelation
behavior (Abbenseth et al., 2016). The proposed in-
terrogator for serial fiber optical sensor networks con-
sisting of sensors operating at the same wavelength
relies on the principle of CDM. In this contribution,
the network can consist of several FBG sensors that
partly reflect incident light according to their grat-
ing parameters, applied strain or temperature changes.
In the following, the explanation of the interrogation
Götten, M., Lochmann, S., Ahrens, A. and Benavente-Peces, C.
A Robust Serial FBG Sensor Network with CDM Interrogation Allowing Overlapping Spectra.
DOI: 10.5220/0008942900230028
In Proceedings of the 9th International Conference on Sensor Networks (SENSORNETS 2020), pages 23-28
ISBN: 978-989-758-403-9; ISSN: 2184-4380
Copyright
c
2022 by SCITEPRESS Science and Technology Publications, Lda. All rights reserved
23
principle is shown with the mentioned FBGs. Nev-
ertheless, the principle is not limited to FBGs but
rather works with every reflecting fiber optical sen-
sor. CDM or code-division multiple access (CDMA)
is already well known in the field of telecommuni-
cation, as the works by (Lee and Miller, 1998) or
(Kitayama, 1998) indicate. Transferring this tech-
nique to sensor networks opens a new dimension of
size considering spectral overlapping of sensors. In
WDM systems, the spectral distribution of FBGs is
limited to the spectral width of the light source and
the operating range of each FBG that must not over-
lap with neighbouring FBGs during a measurement.
(Abbenseth et al., 2016) shows that CDM in opti-
cal sensor networks allows spectral overlapping with-
out losing track of the measured sensor. Against this
background the novelty of this contribution focuses
on practical implementation limits such as the trigger
timing and the achievable SNR. Based on the intro-
duced SNR definitions for CDM and WDM systems a
direct comparison is possible and it shows the supe-
riority of the proposed CDM scheme. The remaining
part of the paper is structured as follows: Section 2 ex-
plains the CDM interrogation scheme. Section 3 dis-
cusses the different parameters influencing the over-
all performance. At the end, Section 4 concludes the
work.
2 INTERROGATION PRINCIPLE
2.1 Interrogator Setup
Fig. 1 depicts the scheme of a CDM interrogator for
serial fiber optical sensor networks. A light source
provides the light that is launched into the sensor net-
work and reflected by the FBGs. The spectral band-
width should cover at least the operating region of
each sensor in the network. The light source emits
Light Source
Modulator
λ
0
λ
0
Modulator Modulator
Spectrometer Spectrometer
Differential Spectrum
Code
∆t
INV
Figure 1: Scheme of CDM interrogation system.
continouswave (CW) light that needs to be modulated
for a CDM interrogation. The modulator is driven
with code that is suitable for CDM; further details
can be found in section 2.2. The modulated light is
launched into the network with FBGs operating at the
same wavelength λ
0
. The reflected light travels back
and reaches the detector paths. It is split into two
equal parts that are each modulated with a code again.
This code is a time delayed version of the previous
used code for the left path, the direct path, and for the
right path, the inverted path, the code is time shifted
and inverted. After the second modulation the light
in each path is collected by a spectrometer, which
performs the integration part of the correlation pro-
cess. The inverted spectrum is subtracted from the
direct spectrum which equals a differential spectrum
that is used for peak detection. Further details about
the setup are described by (Abbenseth et al., 2016)
and (G¨otten et al., 2018).
2.2 CDM-interrogation Scheme
Having a deeper look into the maths of the interroga-
tor, the scheme can be reduced to Figure 2. Light
source (LS) and Modulator provide unipolar modu-
lated light. The two detection paths contain each a
modulator that works as a multiplication of the codes.
Only, if a logical ’1’ reaches the modulator and it let’s
light pass (also a logical ’1’), light reaches the sum,
that represents the spectrometer collecting incoming
light. Multiplication and summation equals mathe-
matically a correlation; a unipolar - unipolar auto-
correlation of the used code. Unipolar signal cod-
ing is the consequence of amplitude modulators ap-
plying simple on-off-keying of light. Introducing the
inverted path, where the autocorrelation is performed
with the inverted code, and calculating the difference,
the result is a unipolar-bipolar autocorrelation which
is explained in the work of (G¨otten et al., 2019) on the
example of this interrogation setup.
Unipolar-bipolar correlations result in a scaled ver-
sion of bipolar-bipolar correlations, as shown by
(O'Farrell and Lochmann, 1994). The advantage is
the ability of the autocorrelation function (ACF) to
have low sidelobes. The products of the unipolar-
+
-
LS
Mod S
Mod R
+
Mod R
τ
Figure 2: Principle of SIK.
SENSORNETS 2020 - 9th International Conference on Sensor Networks
24
unipolar correlation that are summed up can only be
0 or 1. The summed up products of bipolar-bipolar
correlations can be -1 or 1. Therefore, the sum rep-
resented by each sidelobe can be close to zero if the
mixture of -1 and 1 products is more or less equally
distributed. In the unipolar-unipolar sum, the prod-
ucts can only add up, as no -1 product appears.
The ACF has the highest value in the autocorrelation
peak for a time shift τ = 0. Considering the value of
the ACF as amount of light in the differential spec-
trum, the code reflected by an FBG that reaches the
modulator exactlysynchronousis the majority of light
after calculating the difference. Assuming an ideal
synchronization, in the direct path the whole light can
pass the modulator and in the inverted path no light
passes the modulator. Therefore, the difference be-
tween the sum of all light impulses of the code and
no light results in a high value, mathematically the
amount of chips of the code. Other reflected codes
reach the detection path asynchronous to the modula-
tors and therefore, not all light can pass or is blocked.
Ideally, the amount of light passing each modulator is
equal, so the difference results in zero. Depending on
the code, the asynchronous reflected codes by other
FBGs do not appear in the differential spectrum. This
is achieved by a code that provides an ACF with very
low sidelobes, ideally equal to zero, hence orthogonal
or quasi-orthogonal codes.
2.3 Improvements of Interrogator Setup
The two detecting paths have to be identical to obtain
a correct unipolar-bipolar correlation. Setting up the
interrogator in a testbed requires identical equipment
for both paths. To overcome this difficulty, the de-
tection path is realized in a serial manner with only
ASE Source
SMF Modulator S FBGs
Pol. Controller
Modulator R
SMF
Spectrometer
∆t
Pattern Generator
Trigger
CH0
CH1
Figure 3: Scheme of a serial CDM interrogation system.
one modulator and one spectrometer. Direct and in-
verted path are now performed sequentially, where
each measurement is repeated two times with direct
and inverted code (Figure 3).
An amplified spontaneous emission (ASE) broadband
light source provides the light that covers the full op-
erating range of the FBGs in the network. The mod-
ulator S is driven with a code from a pattern gen-
erator. A circulator is responsible to guide direct
light into the network and out of it into the detec-
tion path. The code is reflected by each FBG and
has a different time delay introduced by different lo-
cations in the serial network. After the circulator, the
light passes a polarization controller, the modulator R
and reaches the spectrometer, which is a charge cou-
pled device (CCD).The state of polarization (SOP) of
the reflected light is unknown while the modulator is
polarization dependent. Therefore, the polarization
controller helps to improve the modulation result of
the modulator. Modulator R is driven with the time
shifted code. The time delay t matches the time light
takes to travel from the modulator S via a distinct sen-
sor to modulator R. Then the code is synchronized
to that particular sensor. The pattern generator stores
the direct and inverted code and is triggered by the
spectrometer. The spectrometer emits a trigger sig-
nal when the integration time starts. Then the pat-
tern generator emits through channel 0 the code and
through channel 1 the time shifted code. The code
is repeated so that the whole integration time is filled
with the code. The time delay is introduced either
by a channel time delay which is limited to 20ns by
the pattern generator settings or by rotating the code
in the memory registers. Combining both methods, a
coarse time shift is introduced by rotation of the code.
Hence the shifting step equals the chip length. A fine
time shift is added with the channel time delay of the
pattern generator. The result is gapless adjustment
of required time delays. The spectrum is stored on a
computer and a second measurement with the inverted
code is performed. Both spectra are subtracted from
each other and the differential spectrum is used for
peak detection. (G¨otten et al., 2019) provides more
details about the correlation process with this inter-
rogator.
3 INFLUENCES ON
INTERROGATION SCHEME
AND SETUP
The influences of a real testbed setup on the interro-
gation scheme have to be investigated. This section
A Robust Serial FBG Sensor Network with CDM Interrogation Allowing Overlapping Spectra
25
presents two influences that affect the CDM results of
the interrogator. As the interrogator needs to deal with
different time delays, chip lengths and other tempo-
ral adjustments, the time delay of triggers and pattern
generators has to be analyzed. Also the spectrometer,
as one of the main parts of the correlation process is
analyzed in more detail in comparison with a standard
WDM system. A closer look at the modulators can be
found in (G¨otten et al., 2019).
3.1 Trigger Scheme and Delays
Figure 4 shows the time behavior between integration
time of the spectrometer and the code output of the
second modulator. When the spectrometer starts to
measure the spectrum, it emits a trigger that is con-
nected to the data generator to start outputting the
code. This delay time between trigger and the elec-
trical code signal arriving at the first modulator is in-
dicated by the blue part in the time diagram. This de-
lay occurs for every single measurement of the spec-
trometer. After the delay, the first modulator starts
with the code. This light travels through the network
and is reflected at different locations by each FBG.
Therefore, this code reaches the second modulator at
different times, indicated by the light gray boxes in
the diagram. The second modulation is synchronized
to a specific reflected code and is time shifted to all
other reflected codes. The time shift is depicted by
the green part of the time diagram. The codes are re-
peated several times within one integration time. At
the end, a part of the code is not covered by the inte-
gration time t
I
, indicated by the hatched gray part of
the time diagram.
During the trigger delay and the time shift, the second
modulator is set to a logical ’0’. The first modulator
is set to logical ’0’ during the trigger delay as well.
Then it starts modulating the light, according to the
code. In the autocorrelation region, where both codes
are multiplied by means of the second modulator, the
error,introduced by an aperiodic autocorrelation is in-
vestigated in (G¨otten et al., 2018). Since a logical ’0’
does not prevent all light to pass the modulators, the
spectrometer collects light at the beginning of the in-
tegration time. This light is attenuated by the offset
of the first modulator, the reflectance of the FBGs and
t
Code
Code
Code Code
t
I
t
I
Direct Spectrum Inverted Spectrum
Figure 4: Temporal trigger scheme analysis.
the offset of the second modulator. Nevertheless, the
collected light appears in the direct and in the inverted
spectrum. The subtraction of both spectra cancels out
this effect which shows the advantage of a sequence
inverse keying (SIK) approach. The error introduced
in the green region is depending on the code and the
time shift or rather the synchronization point. Re-
flected codes can arrive before the second modulator
starts to switch as well as after the second modulator
starts to switch. For larger time shifts, the expected
error increases, as well as the standard deviation of
that error (G¨otten et al., 2018). For network lengths
in the kilometer range, time shifts of more than 5µs
can occur.
3.2 Spectral Influences of CDM
Compared to WDM
In comparison with a WDM system, in the CDM pro-
cessing all FBGs need to share the same wavelength.
In the testbed, a CCD spectrometer is implemented
that can collect only a certain amount of light that
is represented in counts per wavelength range in the
spectrum. In this testbed the spectrum is limited to
2
16
counts that need to be shared by FBGs, as well
as noise. The distribution inside a spectral peak for
CDM is depicted in Figure 5. The two columns rep-
resent the amount of counts per spectrum, if all FBG
are not strained, or heated so they all overlap. To
achieve a cancellation of all interferences, the amount
of light in both spectra (direct and inverted) needs to
be equal, since the result is the difference out of these
two. The light of the synchronized FBG (here FBG
I-1) appears only in the direct spectrum, so nothing is
subtracted from the desired signal. Therefore, the two
parts of each FBG signal that distribute equally over
FBG 0 FBG 0
FBG 1 FBG 1
FBG 2 FBG 2
FBG i FBG i
FBG I-2 FBG I-2
FBG I-1
FBG I-1
FBG I-1
FBG I-1
65535 Counts
X Counts
=
N N
σ
Dir. Spectrum Inv. Spectrum Diff. Spectrum
X = 2·
65535
N σ ε
I +1
Figure 5: Spectral influences of a CDM approach with SIK.
SENSORNETS 2020 - 9th International Conference on Sensor Networks
26
Table 1: Parameters of testbed components.
Parameter Value Description
C 2
16
= 65535 Maximum capacity of CCD spectrometer (BaySpec, FBGA)
I 25 Amount of serial sensors
N 3000 Mean of noise of spectrometer (measured)
σ 30 Standard deviation of noise (measured)
ε 0 Summary of other influences (modulators, shape of light spectrum, .. .)
both spectra for interference, is located only in the
direct spectrum for the synchronized signal. Addi-
tionally, the noise of each measurement, divided into
mean and standard deviation, is part of each spectrum
and consumes a certain amount of light. The differ-
ence spectrum contains now only the two parts of the
synchronized signal located in the direct spectrum and
two times the standard deviation, since subtracting a
random number from each other, the mean values can-
cel out and the standard deviation sum up. The theo-
retical available counts are calculated by the equation
in the Figure using the example of 2
16
counts.
Since a WDM does not require a second measurement
and a difference spectrum, the noise of the measure-
ment cannot cancel out. Having a look at the SNR of
the two different interrogation techniques, the advan-
tage of a CDM approach can be shown.
The SNR in the CDM system can be calculated by
SNR
CDM
=
C
N σ ε
(I + 1) · 2 · σ
. (1)
C denotes the amount of counts provided in the spec-
trum, or rather the maximal possible height of a peak
in the spectrum minus the noise values (
N + σ) and
minus other influences ε. It is divided by the amount
of sensors I plus 1, as depicted in Figure 5. It is also
divided by two times the standard deviation σ that oc-
curs as the only part of the noise in the differential
spectrum. In comparison the SNR of a WDM system
is derived by
SNR
WDM
=
C
N + σ
, (2)
where the possible peak hight C is divided by the
complete noise consisting of mean value
N and stan-
dard deviation σ. The denominator of both SNRs in-
fluences its value. The larger the denominator, the
worse the SNR. Using values from the testbed com-
ponents in this contribution (see. Table 1), it shows
the difference. For now, the other influences ε are set
to zero.
SNR
CDM
> SNR
WDM
(3)
2
16
3000 30
(25+ 1) · 2 · 30
>
2
16
3000+ 30
(4)
40.07 b= 16.02dB > 21.63 b= 13.35dB (5)
Due to the cancelling of the mean noise value
N in the
differential spectrum, the SNR increases in compari-
son to a WDM system. To obtain the same SNR, as
the WDM approach, other influences can increase up
to
ε C N σ SNR
WDM
· (I + 1) · 2σ (6)
2
16
3000 30 21.63· (25+ 1) · 2· 30
28762 Counts. (7)
Hence, these other influences on the spectrum of a
CDM approach can be up to 43.88% of the maxi-
mum amount of counts, so the maximal possible peak
height measurable by the implemented spectrometer.
The SNR remains larger than in a WDM interrogator
although the wavelengths are shared by all sensors in
the network.
4 CONCLUSIONS
In this work, a CDM interrogation scheme for serial
fiber optical sensor networks is introduced focusing
on CDM-related issues and advantages. The trigger
mechanism is temporally investigated. A delay intro-
duced by the trigger has no influence on the resulting
spectrum for peak detection. The spectral influences,
due to wavelength overlapping, are analyzed and the
advantage in terms of SNR are presented. The inter-
rogation scheme is very robust against other possible
imperfections. These imperfections such as the influ-
ence of the modulators as well as the spectrum of the
source may accumulate up to 43.88% of the maxi-
mum measurable spectral power given by the spec-
trometer. Below this limit the CDM system performs
superior to WDM in terms of the achievable SNR. In-
cluding previous works focusing on other aspects of a
CDM approach, this CDM interrogation scheme is a
promising step in a new dimension of massive sensor
multiplexing in serial fiber optical sensor networks.
A Robust Serial FBG Sensor Network with CDM Interrogation Allowing Overlapping Spectra
27
ACKNOWLEDGEMENTS
This work has been funded by the German Ministry
of Education and Research (No. 13FH030PX8).
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