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Optical fiber sensor (OFS) technologies have developed rapidly over the last few decades, and various types of OFS have found practical applications in the field of civil engineering. In this paper, which is resulting from the work of the RILEM technical committee “Optical fiber sensors for civil engineering applications”, different kinds of sensing techniques, including change of light intensity, interferometry, fiber Bragg grating, adsorption measurement and distributed sensing, are briefly reviewed to introduce the basic sensing principles. Then, the applications of OFS in highway structures, building structures, geotechnical structures, pipelines as well as cables monitoring are described, with focus on sensor design, installation technique and sensor performance. It is believed that the State-of-the-Art review is helpful to engineers considering the use of OFS in their projects, and can facilitate the wider application of OFS technologies in construction industry.
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ORIGINAL ARTICLE
Review: optical fiber sensors for civil engineering
applications
Christopher K. Y. Leung Kai Tai Wan Daniele Inaudi Xiaoyi Bao
Wolfgang Habel Zhi Zhou Jinping Ou Masoud Ghandehari Hwai Chung Wu
Michio Imai
Received: 13 May 2013 / Accepted: 11 October 2013
ÓRILEM 2013
Abstract Optical fiber sensor (OFS) technologies
have developed rapidly over the last few decades, and
various types of OFS have found practical applications
in the field of civil engineering. In this paper, which is
resulting from the work of the RILEM technical
committee ‘Optical fiber sensors for civil engineering
applications’’, different kinds of sensing techniques,
including change of light intensity, interferometry,
fiber Bragg grating, adsorption measurement and
distributed sensing, are briefly reviewed to introduce
the basic sensing principles. Then, the applications of
OFS in highway structures, building structures, geo-
technical structures, pipelines as well as cables
monitoring are described, with focus on sensor design,
installation technique and sensor performance. It is
believed that the State-of-the-Art review is helpful to
engineers considering the use of OFS in their projects,
and can facilitate the wider application of OFS
technologies in construction industry.
Keywords Optical fiber sensors Monitoring
Fiber Bragg grating Distributed sensor
Interferometry Time domain reflectometry
Frequency domain reflectometry
1 Introduction
Infrastructure decay is a big problem faced by many
developed countries in the world. After years of
service, many structures, such as bridges, tunnels,
dams and power plants, are showing severe deterio-
ration. To ensure safety of these structures and to
This work is derived from a study by the RILEM Technical
Committee on ‘Optical Fiber Sensors for Civil Engineering
Applications’’. Other members of the committee are: Farhad
Ansari, University of Illinois, Chicago, USA; Evangelos
Astrinidis, CRD Group, Greece; Muhammed Basheer, Queen’s
University, Belfast, UK; Rolf Broennimann, EMPA,
Switzerland; Paulo Cruz, University of Minho, Portugal; Wei-
Liang Jin, Zhejiang University, China; Ki Soo Kim; Stijn
Matthys, Ghent University, Belgium; Aftab Mufti, University
of Manitoba, Canada; John Newhook, Dalhousie University,
Canada; Stephanie Schuler, BAM, Germany; Joe Seinfield,
Purdue University, USA; Gamil Tadros, Speco Engineering,
Ltd, Canada; Leon Wegner, University of Saskatchewan,
Canada; Zhishen Wu, Ibaraki University, Japan.
C. K. Y. Leung
Hong Kong University of Science and Technology, Clear
Water Bay, Hong Kong
e-mail: ckleung@ust.hk
K. T. Wan (&)
Nano and Advanced Materials Institute Limited, Shatin,
Hong Kong
e-mail: ktwan@nami.org.hk
D. Inaudi
Smartec, Manno, Switzerland
X. Bao
University of Ottwa, Ottwa, ON, Canada
W. Habel
BAM, Berlin, Germany
Materials and Structures
DOI 10.1617/s11527-013-0201-7
perform proper maintenance/rehabilitation, there is a
need to monitor the structural condition or ‘health’
over time. Also, for important new structures, sensors
are often installed during the construction phase so
minor degradations can be identified at an early stage.
Low-cost minor repair can then be performed to avoid
major damages that require costly renovations or even
re-construction. The use of new materials in construc-
tion also creates a need for monitoring. For example,
fiber reinforced polymers (FRP) are now being
employed for the fabrication of components for bridge
construction and repair. While the performance of
these materials has been verified in the laboratory,
real-world experience is still limited. The installation
of monitoring system in a FRP structure allows
engineers to assess its in-situ performance and ensure
safe operation. The obtained information can also be
employed to improve the future design of structures
with these new materials.
The use of any structural health monitoring system,
if correctly designed and used, can have a positive
impact on the lifetime cost of a structure. By providing
quantitative information on the state of a structure, it
allows a better management of its maintenance and
inspections, resulting in a positive benefit to cost
comparison. Conventionally, electrical gauges and
transducers have been the technology of choice for
measuring many physical and chemical parameters.
Recently, fiber optic based monitoring systems have
been successfully developed and employed. In optical
sensing, the sensing element is part of an optical fiber
which transforms a change in the monitored parameter
into a corresponding change in the properties of the
guided light, which can be its intensity, phase, spectral
content, polarization state or a combination of these.
The sensor is linked to the data acquisition system
through an optical fiber communication link. In some
cases, the signal from many sensors can be transmitted
through the same fiber link. Field installation can
hence be simplified.
For various kinds of OFS, there are corresponding
data acquisition units that would convert the optical
measurement into the parameter of interest. Being a
new technology, an optical fiber sensing system is
more expensive than its electrical counterpart, with the
exception of distributed sensing where the cost per
measurement point can be much lower than individual
conventional sensors. However, optical sensing tech-
nology possesses a number of advantages that justify
its use in practical applications. OFS are intrinsically
immune to electromagnetic interference (EMI), such
as those generated by lightning strikes, nearby power
lines or wireless communication systems. By design,
OFS are intrinsically safe and naturally explosion
proof, making them particularly suitable for health
monitoring applications of risky civil structures such
as gas pipelines or chemical plants. Another advantage
of OFS is their small size. The diameter of bare OFS,
usually in the range of 125–1,000 lm, makes them
applicable in space-restricted environments such as
thin composite structures. The ability of measuring
over long distances (of several tens of kilometers),
without the need for any electrically active compo-
nent, is an important feature in the monitoring of large
and remote structures such as pipelines or multiple
bridges along a single highway. Depending on the
length of the sensing element, the sensor can be
configured into a ‘point’ sensor performing measure-
ment at a particular point or an ‘‘integrated’ (or long-
gauge) sensor obtaining the averaged information over
a particular region. Along a single fiber, several
‘point’ sensors can be multiplexed to obtain infor-
mation at a number of specific points. Also, sensors on
the same fiber can be configured to measure different
parameters (e.g., strain and temperature). More
importantly, since an optical fiber possesses sensing
capacity at any point along its length, it is possible to
perform truly ‘distributed’ measurement along the
fiber. The capability for multiplexing and distributed
sensing extends the repertoire of existing monitoring
techniques. If designed and packaged properly, OFS
can be very robust, and last for a long time in the most
challenging environments. With the long-term dura-
bility and low maintenance of OFS, it is possible for
Z. Zhou
Harbin Institute of Technology, Harbin, China
J. Ou
Dalian University of Technology, Dalian, China
M. Ghandehari
Polytechnic Institute of New York University, Brooklyn,
NY, USA
H. C. Wu
Wayne State University, Detroit, MI, USA
M. Imai
Kajima Technical Research Institute, Tokyo, Japan
Materials and Structures
the life-cycle cost of an optical sensing system to be
lower than an electrical one. With the above advan-
tages, OFS have been employed (though in limited
extent) to replace conventional sensors in structural
monitoring applications. They have also been used in
experimental research as tools to provide accurate and
stable measurements in the laboratory. Actually, by
exploiting the special properties of optical fibers,
novel sensors can be designed to provide sensing
capabilities not achievable with existing instruments,
and hence make possible the acquisition of new
information useful to engineers.
As discussed above, optical fiber sensing systems
can replace existing electrical systems if (i) conven-
tional sensor fails to satisfy performance requirements
(e.g., stability, accuracy, durability, etc) under specific
conditions, or (ii) the optical sensor can provide useful
information not obtainable with conventional sensors.
In many cases it is also possible to combine traditional
sensors and fiber optic sensors (e.g. vibrating-wire
piezometers and fiber optic distributed leakage detec-
tion systems in the same dam), to get the best of both
worlds. Data from the two systems can be combined at
the processing stage. To identify suitable applications
of the OFS, a good understanding of the principles and
advantages of such sensors is required. Such under-
standing, however, is often lacking for civil engineers.
The major objective of this paper is to review the
current State-of-the-Art for the application of optical
fiber sensors in civil engineering. Such information
can hopefully facilitate the further application of this
new technology in civil engineering practice. In the
next section, common optical sensing principles are
first briefly described. Then, practical applications of
OFS in monitoring highway structures, building
structures, geotechnical structures, pipelines and
cables will be discussed in Sect. 3.
2 Optical fiber sensing principles
In this section, common optical fiber sensing princi-
ples are reviewed to provide the required background
for readers to appreciate the various practical appli-
cations to be described in Sect. 3. To serve this
purpose, the description for each kind of sensor will be
kept very brief, in order not to duplicate the effort of
other works in the literature. In general every fiber
optic sensor is designed to somehow change the
properties of the light that is transmitted through or
reflected from the sensors. Changes can include
variations of intensity, polarization and spectral con-
tent of phase. Readers interested in more information,
should refer to the cited references.
2.1 Change of light intensity
The intensity of light signal passing through an optical
fiber or reflected from its end is easy to measure. The
breakage of a fiber can result in a sudden drop in the
forward signal (or a sudden increase in the reflected
signal). If a fiber is bonded strongly to a structure, a
crack formed in the structure can induce fiber breakage
[45,83]. If several parallel fibers are placed perpen-
dicular to the anticipated direction of crack growth, the
propagation of a crack can then be monitored [36]. The
major disadvantage of these sensors lies in the
difficulty in controlling the failure consistency. To
achieve consistency, all fibers need to be coupled to
the structure in exactly the same way—a task not
easily accomplished on site. Also, since glass is a
brittle material with high material variability, even
fibers bond in the same way may fail under very
different strains. Signal intensity change due to fiber
breakage is hence not very useful if accurate quanti-
tative information is required. Bending of an optical
fiber is another way to induce change in the light
intensity. In a straight optical fiber, the light wave is
guided within the core of the optical fiber. As the fiber
is bent, part of the light will escape through the
cladding into the surrounding. The light intensity
passing through the fiber is hence reduced. Sensors
based on a fiber loop have been developed by Wolff
and Messelier [101] and Ansari et al [1]. For these
sensors, the fiber loops are coupled to a concrete
structure in such a way that cracking will induce
change in the loop geometry and hence the amount of
bending loss. The formation and opening of cracks can
hence be monitored.
Monitoring of signal intensity can also be employed
to study the chemical condition of a certain environ-
ment. For example, a thin reflective film can be coated
on the smooth cleaved end of an optical fiber. If the
presence of a certain chemical will lead to depletion of
the film, the fiber can be employed as a sensor for that
particular chemical. By leaving the fiber in a certain
environment, a sudden drop in reflected signal
Materials and Structures
indicates significant loss of the coated film, which
reveals the presence of the chemical.
Intensity monitoring exhibits an inherent problem.
The light source itself may fluctuate in power over
time. Also, local microbending along the connecting
fiber induces losses that vary with time and the
insertion loss may vary if the connection is removed
after each measurement. Therefore, the measured
change in signal intensity is not necessarily due to
change in the measured parameter alone. If the
magnitude of a reflected signal is to be measured,
the above-mentioned problem can be alleviated with
the use of a time domain reflectometer (which will be
discussed further in Sect. 2.5), where the reflected
signal is compared directly to the signal right before
the reflection point to obtain a relative reading that is
not affected by light intensity of the source or losses at
other points.
2.2 Interferometry
Interferometry involves the combination of two sep-
arate light signals from the same source. To explain
the technique, it is best to consider the Mach-Zehnder
interferometer in which a light beam is split and
coupled into two separate fibers. One fiber is attached
to a structure while the other is left free. At the other
end, signal from the two fibers are re-combined and
monitored. When the structure is loaded, the length of
the attached fiber will change, leading to an increase in
optical path for the light. The corresponding phase
shift will lead to a periodic variation of light intensity
when light from the two fibers are re-combined. Since
each fringe (or complete periodic variation of light
intensity) corresponds to a change in length equal to
the wavelength of light, which is around one micron,
counting the number of fringes can provide enough
resolution for the measurement of relative large
strains. For small strain measurements, feedback loops
can be employed to convert the periodic intensity into
a linearly varying in voltage output [12].
The Mach-Zehnder interferometer has several dis-
advantages. Two fibers need to be used at each sensing
point. Very tight control of bonded fiber length is
required to ensure a consistent gauge length, so the
measured length change can be correctly translated
into a strain value. Also, when low-cost light sources
such as LED are employed, the low coherence length
requires close matching of the length of the attached
and free fibers. In the instrumentation of large
structures, long fiber lengths are required and close
length matching can be very difficult.
To overcome the above shortcomings, the extrinsic
Fabry-Perot Interferometer (EFPI) can be employed
[31,32,71]. The EFPI is constituted by a capillary
tube containing two cleaved optical fibers facing each
other (Fig. 1), but leaving an air gap of a few microns
or tens of microns between them. When light is
launched into one of the fibers, a back-reflected
interference signal is obtained from the reflections of
the incoming light on the glass-to-air and air-to-glass
interfaces, respectively. This interference can be
demodulated using coherent or low-coherence tech-
niques to reconstruct the changes in the fiber spacing.
Since the two fibers are attached to the capillary tube
near its two extremities (with a typical spacing of
10 mm), the gap change will correspond to the average
strain variation between the two attachment points.
Using the principle of white light interferometry,
researchers at the Swiss Federal Institute of Technol-
ogy in Lausanne (EPFL) have developed the SOFO
system, which is a long-gauge fiber optic deformation
Structure
Air cavity
Glue
Gauge length
Alignment tube
core
cladding
light
single mode optical fiber
Fig. 1 Functional principle
of EFPI
Materials and Structures
sensor with a resolution in the micrometer range [48,
5456]. The sensor is now commercialized by SMAR-
TEC and Roctest Group. The functional principle of
the SOFO system is shown schematically in Fig. 2.
The sensor consists of a pair of single-mode fibers
placed inside a tube which can be attached to the
structure to be monitored. One of the fibers, called
measurement fiber, is in mechanical contact with the
host structure, being attached to it at its two extrem-
ities and pre-stressed in-between (see Fig. 2), while
the other, the reference fiber, is placed loose in the
same tube. Deformation of the structure will then
result in a change of the length difference between
these two fibers. To make an absolute measurement of
this path unbalance, a low-coherence double Michel-
son interferometer is used. The first interferometer is
made of the measurement and reference fibers, while
the second is contained in a portable reading unit. This
second interferometer can introduce, by means of a
scanning mirror, a known path unbalance between its
two arms. Because of the reduced coherence of the
source used (the 1.3 micron radiation of a LED),
interference fringes are detectable only when the
reading interferometer compensates exactly the length
difference between the fibers in the structure. With the
unbalance of the reading interferometer determined by
the position of the scanning mirror, the strain on the
SOFO sensor can be easily obtained. Note that this
sensor provides absolute strain reading, not affected
by light source intensity or losses along the optical link
as well as change of temperature that affects both
fibers equally so the effects cancel each other.
2.3 Fiber Bragg gratings
A Bragg grating is a periodic variation of refractive
index along the length of the fiber, normally about
10 mm in total length. Gratings with periods Kare
commonly fabricated by holographic [73] or phase-
mask technique [41,79]. The working principle of the
Bragg grating sensor is shown in Fig. 3. When a
broadband or tunable signal passes through the optical
fiber, the wavelength corresponding to the period of
index variation (kB) will be preferentially reflected.
Internal
External
LED
Bandpass
Fixed mirror
Movable mirror
A/D
Amplifier
Photodioide
Structure
Sensor
Bonded fiber Loose fiber Coupler
Gauge length
SOFO Readout System
Computer computer
Filter
1330nm
Fig. 2 Functional principle of SOFO system
Materials and Structures
The relationship between Bragg wavelength and the
periodic spacing of the grating is given by Eq. 1[40,
80].
kB¼2neKð1Þ
where neis the effective refractive index of the core of
the grating. When the fiber is under mechanical strain
(emech) or temperature variation (DT), the index
variation period will change, leading to a peak shift
in the reflected wavelength. To perform measurement,
a tunable laser, spectrometer or wavelength filter is
normally employed. The relationship between the shift
of Bragg wavelength and the total induced axial strain
is given by Eq. 2.
DkB
kB
¼1pe
ðÞemech þaþfðÞDT;ð2Þ
where p
e
,aand fare strain-optic coefficient, thermal
expansion coefficient and thermal-optic coefficient,
respectively. To compensate the thermal induced
strain, additional thermal compensation FBG sensor
should be installed in the same sensing region. The
wavelength of the thermal compensation FBG sensor
(k
T
) is different from the mechanical strain sensitive
FBG sensor and it should be isolated from any
mechanical strain. The mechanical induced strain
can be estimated from the change in Bragg wavelength
of the total strain and thermal induced strain by Eq. 3.
emech ¼1
1pe
DkB
kB
DkT
kT
 ð3Þ
When strain values are required at more than one point
along the fiber, gratings of different periods can be
placed at the corresponding points. The reflected
signal will then exhibit a number of peaks corre-
sponding to individual gratings. By monitoring the
shifts of all the peaks, strain at each point can be
deduced. Typically, 4–16 gratings can be measured on
a single fiber line. It should be noticed that since the
gratings have to share the spectrum of the source used
to illuminate them, there is a trade-off between the
number of gratings and the dynamic range of their
measurements.
2.4 Absorption measurement
Absorption measurement is normally employed for the
sensing of chemicals. For example, when light is sent
through an optical fiber into a chemical environment
with preferential absorption of a particular wave-
length, the spectrum of the reflected signal will show a
drop in the absorbed wavelength. Similarly, one can
design a sensor with two flat-end fibers separated by a
small gap. Light passing through the gap will exhibit a
change in its spectrum if chemicals that absorb certain
wavelengths are present in the surrounding environ-
ment and enter the inter-fiber gap. Absorption spec-
troscopy is to measure the electromagnetic radiation
absorbed by atoms, molecules or other chemical
entities. In microwave spectroscopy, the absorption
is accompanied by a transition from one rotational
energy level of a molecule to another. In infrared
spectroscopy, the transition is from one vibrational
energy level of a molecule to another. In ultraviolet-
visible electronic absorption spectroscopy, transition
levels relate to valence electrons in the molecule.
For a step-index multimode optical fiber, the
number of possible modes guided through the fiber
increases with increasing core diameter and wave-
length. The energy guided through the core by total
internal reflection also generates a surface-specific,
electromagnetic disturbance at the interface between
the two dielectric media (the core and the cladding).
There is a standing wave at every point of interface
incidence. This harmonic wave, which penetrates the
cladding over a small distance, is called the evanescent
field. For chemical sensing, the cladding is replaced by
chromoionophores which are indicator molecules
that, in the presence of specific ions (H
?
,Ca
2?
,
Cl
-
,K
?
, etc.), exhibit a change in color, i.e. a change
in the absorption spectrum. As chromoionophores
exhibiting unique absorption spectra with different
1
1
Core
Cladding
2
2
incident light
Broad band
Fig. 3 Working principle
of fiber Bragg grating
Materials and Structures
wavelengths of maximum absorption (k
max
) in the
absence/presence of the specific ions, chemical sens-
ing can be performed by sending a broad band light
signal into the fiber and measuring the spectrum at the
other side.
2.5 Time domain reflectometry
Developed for telecommunication applications, opti-
cal time domain reflectometers (OTDRs) have been
the starting point of distributed sensing techniques.
Conventionally, the Rayleigh scattered light has been
used to measure the attenuation profiles of long-haul
fiber optics links. In OTDR technique, a short optical
pulse is launched into the fiber and a photo detector
measures the amount of light that is backscattered as
the pulse propagates down the fiber. The detected
signal, the so-called Rayleigh signature, presents an
exponential decay with time that is directly related to
the linear attenuation of the fiber. The time informa-
tion is converted to distance information if the speed of
light is known, similar to radar detection techniques.
In addition to the information on fiber losses, the
OTDR profiles are very useful to localize breaks, to
evaluate splices and connectors, and in general to
assess the overall quality of a fiber link.
Raman and Brillouin scattering phenomena have
been used for distributed sensing applications over the
past few years. Raman was first proposed for sensing
applications in the 80s, whereas Brillouin was intro-
duced later as a way to enhanced the range of OTDR
and then for strain and/or temperature monitoring
applications. Figure 4shows schematically the spec-
trum of the scattered light from a single wavelength k
o
in an optical fiber. Note that the Rayleigh scattering has
frequency components close to the forward-propagat-
ing light. However, both Raman and Brillouin scatter-
ing effects are associated with different dynamic non-
homogeneities in the silica and therefore have com-
pletely different spectral characteristics.
The Raman scattered light is caused by thermally
influenced molecular vibrations. Consequently, the
backscattered light carries the information on the local
temperature where the scattering occurred [9,37]. The
amplitude of the anti-stokes component is strongly
temperature dependent whereas the amplitude of the
stokes component is not. Measuring the intensity ratio
between these bands, called the stokes and anti-stokes
emissions, it is possible to calculate the temperature at
any given point along the fiber line [89]. Typical
spatial resolutions for distributed temperature mea-
surements are of the order of one meter. Also, the
temperature resolution is 0.2 °C.
Since the magnitude of the spontaneous Raman
backscattered light is quite low, high numerical
aperture multimode fibers are used in order to
maximize the guided intensity of the backscattered
light. However, the relatively high attenuation char-
acteristics of multimode fibers limit the distance range
of Raman-based systems to approximately 30 km.
Brillouin scattering [8,42,43,92] occurs due to the
interaction between the propagating optical signal and
thermally excited acoustic waves in the GHz range
present in the silica fiber, giving rise to frequency
Raman Raman
Brillouin
Rayleigh
Brillouin
Anti-stokes components Stokes components
Wavelen
g
th
λ
0
Fig. 4 Optical scattering
components in optical fibers
Materials and Structures
shifted components. It can be seen as the diffraction of
light on a dynamic grating generated by an acoustic
wave (an acoustic wave is actually a pressure wave
which introduces a modulation of the index of
refraction through the elasto-optic effect). The dif-
fracted light experiences a Doppler shift since the
grating propagates at the acoustic velocity in the fiber.
The acoustic velocity is directly related to the density
of the medium that is temperature and strain depen-
dent. As a result, the so-called Brillouin frequency
shift carries the information about the local temper-
ature and strain of the fiber.
The active stimulation of Brillouin scattering can
be achieved by using 2 optical light waves. In addition
to the optical pulse usually called the pump, a
continuous wave (CW) optical signal, the so-called
probe signal is used to probe the Brillouin frequency
profile of the fiber [2,3]. A stimulation of the Brillouin
scattering process occurs when the frequency differ-
ence (or wavelength separation) of the pulse and the
CW signal corresponds to the Brillouin shift (reso-
nance condition) and provided that both optical signals
are counter-propagating in the fiber. The interaction
leads to a larger scattering efficiency resulting in an
energy transfer from the pulse to the probe signal, and
an amplification of the probe signal. The frequency
difference between pulse and probe can be scanned for
precise and global mapping of the Brillouin shift along
the sensing fiber. At every location, the maximum of
the Brillouin gain is computed and the information
transformed to temperature or strain using the appro-
priate calibration coefficients. The probe signal inten-
sity can be adjusted to acceptable levels for low-noise
fast acquisition whatever the measurement conditions
and fiber layout, thus solving the main problem that is
generally associated with distributed sensing based on
spontaneous light scattering.
For applications where the sensing area is located
more than 25 km away from the instrument, it is
possible to boost the optical signal using light
amplifiers: the so-called range extender modules.
The module performs active signal regeneration by
using optical amplification techniques similar to those
extensively used in optical telecommunications. The
modules can be cascaded leading to remote distances
in excess of hundreds of kilometers.
For distributed temperature measurements, both the
Brillouin and Raman OTDR can be employed. For
distributed strain sensing, the Brillouin OTDR is the
most powerful. Since the Brillouin frequency shift
depends on both the local strain and temperature of the
fiber, the sensor configuration will determine the
actual sensitivity of the system. For measuring tem-
perature, it is sufficient to use a standard telecommu-
nication cable that shields the optical fibers from
mechanical strain. The fiber will therefore remain in
its unstrained state and the frequency shifts can be
unambiguously assigned to temperature variations.
For strain measurement, the sensor configuration
should be designed to ensure proper mechanical
coupling between the sensor and the host structure
along the whole length of the fiber. To resolve the
cross-sensitivity to temperature variations, it is also
necessary to install a reference fiber along the strain
sensor. Knowing the frequency shift of the unstrained
fiber allows an absolute strain measurement.
2.6 Frequency domain reflectometry
When the spatial resolution of OTDR systems is
reduced to millimeters scale, it requires a data acqui-
sition device with a bandwidth of 10 GHz and a
sampling rate of tens of G Sample/s. At the same time,
the pulse generator should output sufficiently high
energy in a very short duration and the light detection
device should be sensitive enough to measure the
scattered signal with sufficient signal-to-noise ratio. All
these factors make the high spatial resolution OTDR-
based distributed sensor very expensive. A cost effec-
tive distributed sensor with millimeter scale spatial
resolution has been developed based on the optical
frequency domain reflectometry (OFDR) of Rayleigh
scattering [13,14,60,90]. Instead of measuring the
intensity of Rayleigh backscattered signal, OFDR
measures the interference fringes of the Rayleigh
scattered light from a tunable laser source and a static
reference fiber in frequency domain. The amplitude and
phase in frequency domain is converted into time/
spatial domain by inverse Fourier transform. Although
Rayleigh scattering itself is independent of temperature
and strain, a change of path difference between the
sensing fiber and the reference fiber with fixed length of
local oscillator in the interferometer provides temper-
ature and strain variation induced phase differences
through index variation, which can be measured at each
fiber location (Fig. 5). The spatial resolution of OFDR
(Dz) is determined by the optical frequency sweep
range of the tunable laser source (DF) as in Eq. 4.
Materials and Structures
Dz¼c
2ngDFð4Þ
where cand n
g
are the speed of light in vacuum and
the group refractive index, respectively. In general,
OFDR is suitable for short sensing length (\100 m)
with no sharp change in strain and temperature
between two measurements. By using polarization
maintaining fiber, both temperature and strain can be
obtained simultaneously.
The classical approach for measuring stimulated
Brillouin scattering (SBS) in time domain is limited by
similar constraints in light source, light detection
components and data acquisition units as OTDR. To
overcome the drawbacks, Brillouin optical frequency
domain analysis (BOFDA) has been developed [27,
76]. The spatial resolution of BOFDA system is
determined by the modulation bandwidth of the pump
beam DFas in Eq. 4. The amplitude of the pump beam
is sinusoidally modulated. Figure 6shows the sche-
matic diagram of a typical BOFDA system. The stokes
beam amplified by SBS and the excited modulated
beam are compared in amplitude and phase as a
complex transfer function by a vector network
analyzer (VNA). The pulse response in time domain
can be obtained by inverse Fourier transform of the
complex transfer function. The frequency difference
of the two Nd:YAG lasers is tuned by a control loop. A
photodioide (PD1) detects the beat of the lasers. An
electrical spectrum analyzer measures the beat fre-
quency. The results are sent to a frequency controller
to calculate the offset from the desired frequency. An
external digital-to-analog converter generates volt-
ages to tune the resonator of the pump laser by means
of the temperature element and piezoelectric actuator.
Each spectral component of the pulse response is
recorded separately and hence a narrow-banded filter
can be used in the VNA. This filter enhances the
dynamic range of the system but it takes much longer
time for data acquisition because the bandwidth of the
filter determines the settlement time of the system.
The spatial resolution, measurement range, strain
tunable
laser
trigger interferometer
triggering signal
10%
90%
Measurement interferometer
A/D
Computer
PS
Optical path difference 600m
PC1
PS = Polarization splitter
PC = Polarization controller
FUT = Fiber under test
PC2
FUT
A/D = Analog-to-digital converter
Fig. 5 Schematic diagram of optical frequency domain reflectometry
Pump
Laser
Strokes
Laser
EOM
PC
VNA
PD1
PD3
PD2
D/A
ESA
FC
FUT
FUT=Fiber under test
ESA=Electrical spectrum analyze
r
PD=photo dioide
FC=Frequency controller
D/A=Digital to analog
PC=Polarization controller
VNA=Vectornetwork analyzer
Fig. 6 Schematic diagram of Brillouin optical frequency
domain analysis
Materials and Structures
resolution and temperature resolution of a commercial
BOFDA monitoring system are 1 m, 12 km, 2
microstrains and 0.1 °C, respectively. The duration
of data acquisition depends on the measurement
distance. It ranges from 30 s for 200 m fiber to
5 min for 12 km fiber.
3 Civil engineering applications of the OFS
3.1 Highway structures
Bridges and highways are important infrastructures.
Any closure may lead to heavy traffic congestion and
enormous economic and social costs. Many OFS have
been installed on bridges and highways around the
world. They monitor the global and local mechanical
behaviors of bridges as well as environmental param-
eters such as temperature, pH level, humidity and
chloride content. Point sensors are applied at critical
components of the bridge such as bridge cables,
anchorages, bridge decks, piers and pavements. Inte-
gral sensors are installed to measure the curvature and
deflection of the bridge, as well as the onset of
cracking. Distributed sensors are applied on the
pavement to monitor the impact stress wave generated
by high speed vehicles.
3.1.1 Bridges
When a bridge designed many years ago cannot satisfy
the current traffic capacity, an economic solution is to
retrofit the existing structure instead of building a new
one. The North and South Versoix bridges in Swit-
zerland were typical examples of bridge upgrade.
They were two parallel twin bridges, each one
supporting two lanes of the Swiss National Highway
A9 between Geneva and Lausanne. The bridges were
classical parallel prestressed concrete beams struc-
tures supporting a concrete deck and two overhangs. In
order to support a third traffic lane and a new
emergency lane, the exterior beams were widened
and the overhangs extended. The construction pro-
gressed in two phases: the interior and the exterior
overhang extension. The first phase began by demol-
ishing the existing interior overhang followed by the
reconstruction of a larger one. The second phase
consisted of demolishing the old exterior overhang,
widening the exterior web and rebuilding a larger
overhang supported by metallic beams (Fig. 7). More
than a hundred long-gauge SOFO interferometers
were installed on the Versoix bridges in order to
monitor the deformation due to differential shrinkage
between the old and new concrete. Also, the monitor-
ing demonstrated how the deformation along the
longitudinal direction of the bridge can be used to
estimate the vertical deflection of the beam [28,49,
56]. With a pair of SOFO interferometers installed on
the compression side and tension side at the same
location (Fig. 8), the local averaged curvature can be
computed. The vertical deflection of the beam can be
estimated by integration based on appropriate bound-
ary conditions.
In 1997, the Waterbury bridge in Vermont, USA
was rehabilitated and fiber Bragg grating (FBG) strain
sensors, speckle pattern based vibration sensors [58]
and chloride sensors [15,16] were embedded in the
bridge deck [17]. There were three different
approaches for the installation of FBG strain sensors.
The first approach was to cast the bare FBG sensors in
a relatively malleable plastic compound (Castolite)
and metal pin was placed to locate the central position
Old bridge
New concrete
Steel truss
Fig. 7 The Versoix bridge
SOFO sensors
Beam
Fig. 8 The schematic diagram of the position SOFO interfer-
ometers on Versoix bridge
Materials and Structures
of the FBG sensor. The completed Castolite FBG
sensor was mounted on the steel reinforcement before
concrete casting. The second approach was to glue the
FBG strain sensor to a 1 m long epoxy-coated steel
reinforcement by the same glue used for electrical
strain gauges. The epoxy coating of the steel rein-
forcement is to protect the steel from corrosion. The
instrumented 1 m long rebar was physically attached
to the steel reinforcing system of the bridge deck. The
third approach was to attach the FBG strain sensors
directly on the bridge deck reinforcements by epoxy.
The advantage of the second approach over the third
approach is that the second approach can be performed
in well controlled environment while the quality of the
third approach depends on weather conditions. The
sensing principle of the 36 installed chloride sensors
relies on the color change (from milky white to pink)
when chemical reaction occurs between the water
transported chloride ion and the sol-gel film of the
sensor. By varying the chemistry of the sol-gel, the
range of the chloride threshold can vary from 20 mg/L
to over 2300 mg/L. The vibration sensor consists of a
coherent laser light source, a multimode optical fiber
and a photo detector. While the total intensity
traveling through the optical fiber remains the same,
the intensity of individual mode varies with the
variation of phase change and it shows different
speckle patterns at the cleaved fiber end due to
interference among different modes (Fig. 9). By
inserting an opaque annulus in front of the photo
detector, the light intensity detected by the photo
detector changes with the variation of the phase
difference induced by the mechanical strain in the
sensing region. When the intensity of the laser source
varies sinusoidally, it is possible to shift the frequency
of the vibrating signal into a less noisy region at low
frequency range as in civil engineering infrastructures.
In this project, all the lead cables and the access boxes
were embedded in concrete. The access boxes were
filled with paper to absorb moisture and keep the
cables out of concrete. They were excavated after
removing the wooden formwork. All sensors survived
and showed reasonable values after concrete pouring
and excavation of the access boxes.
FBG sensors have also been employed to monitor
the internal strain of (i) the box girder of a prestressed
concrete bridge across the Ring Canal in Ghent,
Belgium and (ii) the trough girder of a railway bridge
along the rail track Gent-Moeskroen, Belgium during
post-tensioning, proof load tests and in service load.
However, as bare FBG sensor is too fragile to be
embedded directly into the structure, different kinds of
packaging techniques were developed. One approach
was to attach FBG sensors on a steel reinforcing bars
to be embedded inside the structure [72]. The sensing
bar consisted of a FBG strain sensor and a thermo-
couple for temperature compensation. A narrow
groove was notched on the bar and the FBG sensor
was attached into the groove with adhesive at the
middle of the bar while the thermocouple was bonded
on the opposite side (Fig. 10). The test results showed
that the strain measured by the sensing bars agreed
with the results from the mechanical deformeter
(demec).
Another approach to package FBG strain and
temperature sensors is to embed the sensors into fiber
reinforced polymer (FRP) (Fig. 11). The strain sensors
can measure both tensile and compressive strain with
high signal-to-noise ratio. Strain up to 5,000 micro-
strains with 1–2 microstrains resolution can be mea-
sured [77]. This packaging method has been validated
extensively in Shangdong Binzhou Yellow River
Highway Bridge in Mainland China, which was open
for traffic in July 2004. The bridge girder is made of
prestressed concrete supported by 200 stay cables. The
entire length of the bridge is 1698.4 m [66]. The
maximum allowable truck load is 120 tons, which
Annulus
Speckle before strain applied
Speckle after strain applied
Fig. 9 Different speckle patterns at the cleaved end of a
multimode optical fiber
Materials and Structures
exceeds the maximum design load specified in the code
of practice in Mainland China. The bridge was heavily
instrumented with 1688 FBG strain sensors on the
girders and the towers near the joint positions, as well as
180 FBG temperature sensors. The survival rate of
those FBG sensors was about 75 %. The FBG strain
sensors measured the longitudinal strain and transverse
strain of the girder to estimate the effective prestress
level and the strain near the cable anchorages.
Apart from monitoring the state of the bridge compo-
nents during operation, the FBG sensors can also be used
in monitoring the strain development of different com-
ponents during construction stage. In October 2004, FBG
strain and temperature sensors were installed in the
foundation of the piers of the Third Nanjing Yangtze
Bridge [100]. They monitored the internal temperature
and internal strain of the mass concrete of the foundation
during construction and operation.
When degradation occurs in cable stayed or
suspension bridges, the load distribution among the
cables will be changed. By continuously monitoring
the tensile stresses at the cables induced by traffic load
and temperature variation, any abnormal variation
may indicate damage and fatigue of the bridge
structure. The point sensor in Fig. 11 is not appropri-
ate for installation on the cable. A smart cable was
therefore developed to measure the load carried by the
cable (Fig. 12). The optical fiber and the glass fibers
were dragged by tension in parallel (Fig. 13)[44].
Resin was applied and then the composite solidified
through heating in a furnace. The resulting FRP-FBGs
consisted of an optical fiber at the center of the cross
section and the FBG sensors were located at the pre-
specified positions. The strain of the FBG sensors
would be the same as the surrounding glass fibers. To
find the actual mechanical strain, additional temper-
ature sensors should be employed (either by using
FBG temperature sensors in Fig. 11b or thermocou-
ple). In the smart cable, the FRP-FBG cable replaces
the central wire of a typical 7-wire steel cable
FBG sensor
Thermocouple
14 mm
Thermocouple
FBG sensor
1.2 m
Steel bar
diameter
Fig. 10 A sensing steel reinforcing bar with a FBG strain sensor and a thermocouple
FRP solid plate/tube
Optical cable
FBG
FRP hollow tube
(a)
(b)
Fig. 11 Schematic diagram
of pointwise FRP packaged
FBG sensors. aStrain sensor
and btemperature sensor
Materials and Structures
(Fig. 12). Since the stiffness of FRP is much lower
than steel, the load capacity of the smart cable is
assumed to be six in seven of the original steel cable.
The smart cables have been tested extensively in
Sichuan Erbian Arch bridge [64,65] and Hunan
Maocaojie Bridge at the arch suspenders and tie cables
[77].
Due to excellent mechanical strength and corrosion
resistance, carbon fiber reinforced polymer (CFRP)
wires may replace steel cables in bridge construction.
Two bridges in Switzerland with different types of
CFRP cables were instrumented by FBG sensors [5].
For the Storchenbru
¨cke cable stayed bridge in Win-
terthur, Switzerland, one of the twelve usual steel
cable pairs were replaced by CFRP cables. Each cable
is 35 m long and consists of 241 5 mm diameter CFRP
wires in a hexagonal structure and seven FBG sensors
were installed. Three FBG sensors were attached at the
circumference and spaced by 120°relative to the
center of the cable to measure the average strain as
well as the strain gradient inside the cable. The strain
level was between 1,000 and 1,500 microstrains. In
addition, three FBG sensors were attached to three
30 cm long CFRP wire and another FBG sensor was
bonded on an aluminum rod, which was bonded to the
loaded wires in a way that it was insensitive to
mechanical strain. The 4 mechanical strain insensitive
FBG sensors served for temperature compensation and
monitoring of long-term drift. By improving the data
acquisition and wavelength evaluation techniques, the
standard deviation of single strain measurement can be
reduced from 7 to 2.5 microstrains.
A new steel-concrete-composite footbridge near
Luzern, Switzerland was constructed in 1998. Under
the bridge deck, there are two 47 m long, 5 mm
diameter CFRP prestressing cables consisting of 91
wires in hexagonal structure. About 1–1.5 % prestress
strain is expected. FBG sensors were embedded in the
CFRP cables during fabrication to monitor the strains
at the different cross sections of the four anchorage
heads as well as the prestressed cables. Each CFRP
wire consists of 30 rovings with each containing
12,000 7 lm diameter carbon filaments. The optical
fiber was placed at the center of the filaments. Then,
the CFRP wires with the sensing fiber were pulled
through a pultrusion machine and two ovens at
temperatures between 170 and 190 °C. To fabricate
a mechanical strain insensitive FBG sensor for tem-
perature compensation, the uncoated optical fiber was
embedded in a Teflon tube with inner and outer
diameters of 0.3 and 0.5 mm, respectively. The reason
of removing the fiber coating inside the Teflon tube is
to improve the reproducibility, since the coating may
have different thermal expansion coefficient with the
silica fiber, degrades under high humidity and exhibits
stick-slip effect. To connect the embedded optical
Glass fiber filament
Mould
FRP-FBG cable
Resin
Optical fiber with FBG sensors at predefined positions
Splitting plate
Pull direction
Fig. 13 Schematic diagram
of the fabrication of FRP-
FBG
5 mm diameter steel wire in spiral
5 mm diameter FRP-FBG cable
Fig. 12 Schematic diagram of the smart cable, which consists
of a FRP-FBG cable at the middle and six steel wires in spiral
Materials and Structures
fiber to an external measurement system, it was
located by elevating the temperature up to 650 °C, at
which the CFRP wire oxidizes while the optical fiber
survive. The optical fiber was then spliced with a lead
cable. The splice point was protected by a protective
tube filled with epoxy and reinforced by Kevlar at the
fiber exit point for better anchorage. All strained
sensors showed reliable values and only one strained
sensor debonded during the half year on-site
measurement.
The major drawback of FBG sensor is the sensitiv-
ity to both mechanical and temperature induced strain.
In conventional design, temperature sensors were
placed alongside the mechanical strain sensor. A
special packaging technique for FBG strain sensor
with self temperature compensation by using two FBG
sensors has also been developed [74]. Two FBG
sensors were connected in series (about 30 mm
separation) and sandwiched between two plastic
(polypropylene) slabs (Fig. 14). The mechanical strain
sensitive FBG sensor was fixed by cyanoacrylate
adhesive. The other sensor was isolated from mechan-
ical strain by a special packaging scheme. The grating
was slightly bent and enclosed in a thin metal tube in
order to protect the grating and prevent the transfer of
mechanical strain to the grating. The packaged sensor,
which was 80 mm in length and 6 mm in width, were
installed successfully in Monkstown Bridge in UK,
which is a flexi-arch bridge, to monitor the strain
development during construction and operation.
Loss of prestressing force of bridge structures has
significant consequence on safety and serviceability.
The immediate loss due to elastic deformation can be
estimated precisely. However, it is difficult to predict
the time dependent loss from several intertwined
factors such as concrete creep, steel relaxation,
concrete shrinkage and thermal effects. A smart steel
strand similar to the 7-wire smart cable in Fig. 12 was
developed with a single mode optical fiber to monitor
the prestressing force during operation [38,62,104].
The central steel wire is replaced by a FRP cable with
single mode silica optical fiber at the center of the rod
(Fig. 13). The strain distribution along the smart steel
strand was monitored by using Brillouin optical time
domain analysis (BOTDA). Unlike Brillouin optical
time domain reflectometry, the sensor has to form a
closed loop for measurement. Since the strain is
averaged within the spatial resolution and the duration
of data acquisition is several minutes, it is only suitable
for quasi-static measurement for long sensing distance.
By the laboratory calibration tests, the coefficients of
strain-to-Brillouin frequency shift (BFS) related to
either mechanical or thermal effects depends on both
the gauge length and the spatial resolution [103]. When
the gauge length is shorter than the spatial resolution,
the measured averaged strain includes the strain in the
region beyond the gauge length.
The spatial resolution of commercial BOTDR/A
model is about 1 m. The high strain gradient near stress
concentration region is averaged and may not be
identified from the BFS in time domain. An innovative
and simple method to identify any local damage is
shown in Fig. 15. Two optical fibers with different
lengths L
1
and L
2
are connected to an optical switch.
When L1L2
jj
is less than the spatial resolution, it
can improve the density of measurement points with
fixed spatial resolution. If there is local stress concen-
tration, a significant deviation is shown near the stress
concentration region in the plot of the difference
between the two strain measurements.
Strain induced by temperature change can be
compensated by two optical fibers embedded in the
same matrix. With one of them sensitive to both
mechanical and thermal strain (B1) while the other
Polypropylene sandwiches
in metal casing
Optical fiber
FBG strain sensor
Slightly curved FBG temperature sensor
Fig. 14 Schematic diagram of a FBG strain sensor with self temperature compensation
Materials and Structures
sensitive only to thermal strain (B2), the mechanical
induced strain can be deduced from Eq. 5with a single
calibration coefficient (Ke)[103].
De¼DmB1DmB2
Ke
ð5Þ
where De;DmB1;DmB2and Keare the mechanical
induced strain, BFS of sensor B1, BFS of sensor B2
and the coefficient of strain-to-BFS, respectively.
The sensing capability can be enhanced by incor-
porating FBG strain sensors to provide precise strain
measurement at critical positions such as the anchor-
age points and perform dynamic strain measurement
with sampling rate in range of kilo-hertz. In practical
measurement, the FBG interrogator and BOTDA can
be coupled as shown in Fig. 16. From the tests in
[104], when the Bragg wavelength does not overlap
with the wavelength of the laser of the distributed
sensor, there is no noticeable interaction between FBG
sensors and BOTDA. By incorporating FBG sensors
with BOTDA measurement, the mechanical and
temperature induced strain can be decoupled [38].
Assume there is no coupling effect between the
mechanical and thermal induced strain of both sensors,
the change in the Bragg wavelength (DkB) and the
Brillouin frequency shift (DmB) are related to the
change in mechanical strain (De) and temperature
(DT) through the sensitivity coefficients Cek ;CTk;Cem
and C
Tm
. The mechanical induced strain and change in
temperature can be obtained uniquely by solving
Eq. 6.
De
DT

¼Cek CTk
Cem CTm

1DkB
DmB
 ð6Þ
Go
¨taa
¨lvbron, the bridge over Go
¨ta river, was built
in the 30s and is now more than 60 years old. The
bridge is more than 900 meters long and consists of a
concrete slab supported on nine steel continuous
BOTDR
Switch
Coupler
Fiber 1 Fiber 2
Length L1Length L2
Measuring points of Fiber 2
Measuring points of Fiber 1
Fig. 15 Schematic diagram
of a equidistance difference
measuring method
FBG
Interrogator
BOTDA
Coupler
FBGs
Smart cable with FBGs
Out
In
Fig. 16 Schematic diagram of a coupled FBG strain sensors and BOTDR
Materials and Structures
girders, and nearly 40 columns. During maintenance, a
number of cracks were found in the steel girders,
notably in zones near columns where there are
hogging bending moment. Two reasons can be
proposed for the cause of steel cracking: fatigue and
mediocre quality of the steel. The bridge authorities
decided to keep the bridge in service for another
15 years, but in order to increase the safety and reduce
uncertainties related to the bridge performance, an
integrity monitoring system is mandatory. The aim of
the monitoring system is to detect and locate new
cracks that may occur due to fatigue and to automat-
ically send warning messages to responsible engi-
neers. The main issue related to the selection of the
monitoring system is that the total length of all nine
girders is over 8 km. It was therefore decided to
monitor the five girders that are most heavily loaded
(with total length of 4.5 km approximately) and
logically applied a fiber optic distributed sensing
system based on Brillouin scattering and tape-shaped
sensors. It is the first time a truly distributed fiber optic
sensing system was employed in such a large scale to
monitor bridge integrity [24].
By using OTDR, several intensity based sensors
can be multiplexed in time domain. A multi-gauge
crack sensor based on the intensity of Fresnel reflec-
tion was developed [29,30]. An optical fiber was
sliced into several segments by precision cleaver, each
representing a gauge length (Fig. 17). The cleaved
segments were spliced along one line to form the
quasi-distributed sensor. By using OTDR, the inten-
sity of the Fresnel reflection at each splicing point was
measured. The sensor showed linear relation between
the integral crack width and return loss of the
corresponding segment. The sensor can be embedded
into reinforced concrete structure and the loss was
repeatable under fatigue loading.
Due to high inhomogeneity of concrete, it is
difficult to have priori-knowledge of exact crack
location. However, the direction of crack opening can
be predicted. A distributed fiber optic crack sensor
based on OTDR was developed [7,63,96] to monitor
multiple cracks by a single optical fiber. With known
crack opening direction, the optical fiber is aligned at
an angle to the crack. To facilitate the installation, the
optical fiber with predefined orientation is first
embedded into a 2 mm thick polyester plate filled
with sand to make the plate more brittle (Fig. 18). The
sensor plate is attached onto concrete surface by
epoxy. To embed the plate into concrete, coarse
aggregates, which provide interlocking with concrete,
are inserted before hardening of polyester plate. When
crack in concrete opens, the sensor plate is cracked and
the optical fiber has to bend in order to maintain
continuity. Bend loss (and hence a drop in the intensity
of the Rayleigh backscattered signal) is hence induced
near the crack location (the lower graph of Fig. 18).
The OTDR is used to measure the intensity of
Rayleigh backscattered signal with respect to time.
The slight decrease in backscattered signal is due to
attenuation, while sudden signal loss corresponds to
the opening of a crack. The amplitude of the signal loss
is related to the crack opening size, optical fiber type
and the angle between the optical fiber and the crack
opening direction [63]. The location of the crack can
be estimated from the arrival time of backscattered
OTDR
Splice
Splice Splice
Gauge 1 Gauge 2
Reflection at
Fresnel reflection
Time
Intensity
of the OTDR
the buckhead
Fig. 17 Schematic diagram of an OTDR based multi-gauge crack sensor
Materials and Structures
signal, as the speed of light in optical fiber is known.
With this technique, several cracks can be monitored
by a single optical fiber. The limitation of the sensor is
the spatial resolution, accuracy and dynamic range of
the OTDR. If the distance between two adjacent
cracks are smaller than the spatial resolution of the
OTDR, the losses from individual crack cannot be
distinguished from the OTDR reading. The accuracy
of the OTDR determines the uncertainty of crack size
estimation. The dynamic range determines the max-
imum number of cracks that can be monitored because
the signal intensity drops after traveling through each
crack. The sensor prototype has been verified by
experiments and field trials. The sensor was used in the
loading test of Ovid Bridge in Sweden before its
demolition, and the average crack opening obtained
from the sensor was in reasonable agreement with
direct measurements. For a field trial in Mongkok,
Hong Kong, the crack sensor plate was successfully
installed on a surface of a highway bridge pier. To
improve the spatial resolution of low-end OTDR
(about 3 m), fiber loop (more than 10 m) was inserted
between two adjacent optical fiber segments. The
sensors showed stable reading after 2 years in outdoor
environment. In the laboratory, the sensor was further
extended to monitor in-plane mixed mode crack
opening [97].
The spatial resolution of Rayleigh scattering can be
enhanced in a cost effective manner by using optical
frequency domain reflectometry (OFDR) instead of
optical time domain reflectometry (OTDR). Optical
fibers were bonded on the lateral surface of a
reinforced concrete beam as shown in Fig. 19. The
spatial resolution is 6 mm. From Fig. 19, the local
stress concentration at tension side as well as
compressive strain can be measured.
A pH sensor for cable corrosion was developed based
on the absorption spectrum of evanescent field for
tracking the drop of pH level [18]. The 15 lmcladding
is removed from a 600 lmcorediametermultimode
optical fiber. The indicators used for the sensors are pH
sensitive, non-fluorescent chromoionophores, such as
methyl red, thymol blue, and thymolphtalein that are
embedded into a polymethylmethacrylate (PMMA)
matrix to reform the cladding of the optical fiber
(Fig. 20). The PMMA cladding possesses several
characteristics: (i) good bonding with the silica fiber
core, (ii) permeable to water-born analysts, (iii) good
bond with the dye molecules and (iv) lower refractive
index than the fiber core to guide the light wave by total
internal reflection. When there is a pH sensitive
chromoionophore in the cladding, certain wavelength
of the spectrum within the evanescent field is absorbed.
The absorption spectrum depends on the pH value. The
response time of this pH sensor is about 10 h and it is
determined by the permeability coefficient of cladding.
By changing the material used for the cladding from
PMMA with indicators to cellulose [19], which is a
highly porous polymer, the ingress of the liquid phase
moisture content for the bridge cables can be monitored.
A corrosion sensor for reinforced concrete struc-
tures was developed based on the variation of Fresnel
concrete surface
crack surfaces
sensor plate
optical fiber
Time
optical fiber
Intensity of the
crack openings
backscattered
signal
Bottom view
Fig. 18 Sensing principle of the OTDR based distributed crack sensor
Materials and Structures
reflection in corrosive environment [99]. The sensor is
made by sputtering a very thin pure iron coating (about
200 nm) on the cleaved end of a single mode
telecommunication optical fiber (Fig. 21). The iron
coating reflects the light as a mirror. When the
surrounding environment becomes corrosive (either
by chloride ion or carbonation), the coating is depleted
and the reflectivity is significantly reduced. The sensor
reflectivity can be measured by OTDR. To monitor the
reflectivity of multiple sensors, an optical splitter can
be placed between the OTDR and the sensors [98]. The
sensor can be installed in existing or new structures. In
a field trial test in Deep Bay, Hong Kong, 10 sensors
were installed in two footbridge piers under aggressive
marine environment. Two of them were controls
installed at the non-corrosive locations, and they were
still working over 3 years after installation. The
projected durability of the sensors by accelerated life
test and freezing-thawing cyclic test is about 70 years
and 350 cycles, respectively.
3.1.2 Pavements
Highway pavement consists of several layers from
compacted soil to concrete/bitumen surface. The strain
distribution along vertical layers and circumferential
directions may change dramatically. The three-
Recoated PMMA cladding
Buffer (205 microns thick)
Silica core
PMMA cladding (15 microns thick)
(10 microns thick, 65 mm len
g
th)
with chromoionphore
Fig. 20 Schematic diagram of a pH sensor based on the absorption spectrum of evanescent field
Iron thin film Cladding Most of the
(a)
(b)
Cladding Small fraction o
f
Light escapes
the core of
the o
p
tical fiber
is reflected
light in the core
light in the core
is reflected
Fig. 21 Sensing principle of the corrosion sensor based on
Fresnel reflection. aOriginal and bat corrosive environment
Fig. 19 Experimental results of distributed strain with 6 mm spatial resolution by optical frequency domain reflectometry
Materials and Structures
dimensional stress state governs the yielding and
failure of the material at a particular point. As
conventional FBG sensor can only measure the
longitudinal strain, a three-dimensional embeddable
strain sensor was developed [106]. Three FBG strain
sensors were embedded in FRP with appropriate steel
annular anchorage in three orthogonal directions.
Figure 22 shows the projection of the three-dimen-
sional strain sensor on x-z plane. The configuration
along y direction is the same as that in the x direction.
The gauge length in the vertical direction (z) was only
14 mm to prevent instability under the vertical
compressive stress and limit the total height of the
sensor to be less than one-third of the typical thickness
of a pavement layer. However, the short gauge length
might lead to inefficient strain transfer, and correction
factor should be applied to the measured vertical
strain. The size and shape of the anchorage were
designed to minimize the stress concentration and
maximize the strain transfer efficiency. The FBG
three-dimensional strain sensors have been embedded
into different layers of highway pavement of Tailai
highway in Shandong Province, Mainland China to
monitor the induced strain by a static heavy vehicle on
pavement surface.
FRP reinforced concrete has been used in bridges
and pavements to eliminate the corrosion problem of
steel but the compressive strength of FRP can be
significantly reduced by impact damage, which cannot
be identified by visual inspection. Strain monitoring is
a way to assess damage. In a field trial at Highway 40
East, Montreal, Quebec, Canada, Brillouin optical
time domain analysis was used to measure the impact
wave on concrete pavement induced by high speed
vehicles ([100 km/h) [4]. Standard telecommunica-
tion silica single mode optical fiber was attached on
the FRP bars, which were embedded in continuous
reinforced concrete pavement slabs of the highway.
The sensor can monitor both the static and dynamic
impact strain. The distributed impact wave is moni-
tored based on the change in polarization state induced
by the local change in birefringence from the pressure
wave. The response time is in the range of millisec-
onds and the maximum detectable frequency compo-
nent is about 10 kHz when the number of waveform
averaging is kept at minimum. With this technique,
there is a trade-off among the accuracy in strain
measurement, spatial resolution and maximum fre-
quency response. The field trial showed that the
system could measure static strain to an accuracy of 50
microstrains with spatial resolution of 2 m.
3.2 Building structures
Building structures are mostly related to human
activities. Ultimate or serviceability failure will lead
to safety problems and inconvenience. When new
innovations in materials, structural forms and con-
struction technologies are employed in modern build-
ings, engineers may not be able to understand and
anticipate the exact behavior of the structures during
construction and operation. It is then desirable to have
a continuous monitoring system to evaluate the
symptoms of operational incidents, anomalies, deteri-
oration that may affect operation, serviceability, safety
and reliability of the structure. For historical buildings,
the technical details of the structures are usually not
available and the degree of deterioration is often not
Lead cable
FBG sensors
Stainless steel anchor
z
x
y
FRP anchor
Stainless steel anchor
Fig. 22 Schematic diagram
of FBG based 3D strain
sensor
Materials and Structures
known. Structural monitoring can then be employed to
facilitate the planning of appropriate management and
maintenance scheme.
3.2.1 Modern buildings
Singapore is a cosmopolitan city-state with many tall
buildings. The Housing and Development Board
(HDB), which is the public housing authority of
Singapore, has been providing public housing for
Singaporeans through a comprehensive building pro-
gram. As part of the quality assurance of new HDB tall
buildings, long-term structural monitoring of a new
building project at Punggol East Contract 26 was
started in 2001. This monitoring project was consid-
ered as a pilot project with two objectives: (i) to
develop a monitoring strategy for column-supported
building structures, and (ii) to collect data and provide
information related to the behaviors and health
conditions of this particular building type from
construction to in-service operation. The project
consisted of six nineteen-storey building blocks
founded on piles and each block consisted of 6 units
supported by more than 50 columns at ground level.
The specific aims of monitoring are to (i) increase
the knowledge of the real structural behaviors, (ii)
have better control of construction process, (iii)
increase the safety during the service life, (iv) enhance
the efficiency of maintenance activities and (v) eval-
uate the structural conditions after extreme events
such as earthquake, typhoon or terrorist attack. The
monitoring is performed at (i) local, column level and
(ii) global, structural level. The ground columns,
which are the most critical elements in the building,
were selected for monitoring. Ten SOFO long gauge
sensors with 2 m gauge length were embedded in each
block to measure the vertical deformation of the
columns and the readings were taken manually during
construction [22].
After the pilot project, about 600 other similar
buildings were instrumented in the same way in
Sinpagopre with approximated 10 sensors for each
building block. They probably constituted the world’s
largest deployment of fiber optic sensors to a fleet of
similar structures.
It was the first time in Singapore to deploy OFS on
such a large scale structural monitoring on residential
high-rise buildings and the results are beneficial to
building designers by providing better understanding
to the behaviors of building structures from construc-
tion to in-service operation. From the analysis of the
collected data, it showed unexpected behaviors of
columns during construction and these facilitate future
research on the modeling of complex structures. In
addition, with appropriate modeling and analysis
software, it is possible to separate the measured total
strain to time-independent component (elastic strain)
and time dependent components (creep and shrinkage
strain).
To understand the complex behaviors of modern
buildings and structures, computational methods such
as finite element modeling is often employed in the
design stage. However, even sophisticated computer
model involves many assumptions and uncertainties.
As an example, Guangzhou New TV Tower (GNTVT)
is a tube-in-tube structure with height of 610 m. The
structure consists of a reinforced concrete inner tube
and a structural steel outer tube with concrete filled
tube columns. The hyperbolic shape makes the struc-
ture aesthetically attractive but extremely complex in
structural behaviors, especially the wind-structure
interaction. Even the wind characteristic at the top
level of the building cannot be reliably obtained. 120
FBG strain and temperature sensors were installed in
GNTVT at 5 different levels for in-service monitoring
as shown in Fig. 23 [75]. Specially packaged FBG
strain sensors were welded on the surface of the
structural steel of the outer tube columns in factory to
measure both cumulative and dynamic strain. The
sensors were packaged in a specially designed steel
cage to prevent damage during welding. At each level,
24 FBG sensors were attached in 4 separated sensor
chains. In each sensor chain, there were 4 FBG strain
sensors and 2 FBG temperature sensors for temperature
compensation. The strain and temperature resolutions
are 1 microstrain and 0.1 °C, respectively. The max-
imum allowable strain is 2,500 microstrains and the
allowable working temperature range of the FBG
temperature sensors is between -40 and 120 °C. Since
the FBG interrogator can only handle four channels at
200 Hz sampling rate, all FBG sensor chains were
connected to a 4-to-16 multiplexer. The major draw-
back of this approach is the reduction of sampling
frequency on each sensor chain from 200 Hz to 50 Hz.
Other examples of FBG based structural health
monitoring systems for modern buildings can be found
in Shenzhen Civic Center, Vanke Center and Nation
Aquatic Center in China [93]. The Shenzhen Civic
Materials and Structures
Center consists of a space truss structure supporting a
giant roof that is 486 m long, 154 m wide and 9 m in
maximum thickness. 12 FBG strain sensors were
installed in the brackets and other key members to
monitor the stress of the space truss and roof during
service and under extreme loading condition such as
typhoon. In Vanke Center, the floor area is more than
130,000 m
2
supported by 8 giant tubes and thick walls
to provide maximum open space for a garden under-
neath. The main structure consists of a mixed frame-
cable system. The steel cables transfer the vertical load
from the steel truss girders to the concrete-in-steel
columns. In order to monitor the stress of the key
components during the construction and operation
phases, 70 FBG strain sensors were installed on the
steel truss girders, steel beams, concrete-in-steel
columns and the giant columns. 16 FRP-FBG smart
cables as shown in Fig. 12 were installed to monitor
the tensile stress carried by the steel cables. In
addition, 35 FBG temperature sensors were installed
for temperature compensation of the strain sensors.
The National Aquatic Center is a complex structural
steel-membrane structures. Due to high redundancy of
the steel structure, thermal induced stress may be
significant. 240 FBG strain sensors were installed on
the membrane roof and steel structures to monitor the
fluid-solid interaction of the membrane, thermal
induced stress on the steel members, as well as
vibration under wind and other human activities. 40
FBG temperature sensors were installed for temper-
ature compensation.
Comprehensive structural health monitoring was
performed in the Berlin Central Railway Station,
Germany [39]. The station is a complex structure
made of concrete, steel and glass. At the station, the
railway platform is supported by curved girders that
need to be partially prestressed. Long guage SOFO
interferometers were installed to measure the strain of
the structure. The readout unit contains only single
channel. For multichannel operation, the sensors are
connected to a multiplexer and all data are transmitted
to a central computer through Internet. The monitoring
system is expected to work reliably over a long period
of time and withstand all operational and environ-
mental influences.
The distributed internal strain can provide valuable
information for structural health evaluation. A typical
building consists of beams, columns, slabs and walls.
It is extremely difficult and costly to provide outlet for
data logging from embedded sensors in each structural
component. In addition, bare optical fiber is too fragile
to survive concrete pouring and compaction. An
innovative sensor installation method, called long-
distance embedded optical fiber sensor (LEOFS), for
measuring distributed internal strain sensing from the
Brillouin scattering, was developed [70]. Aluminum/
plastic tubes were fixed in the formwork before
concrete casting to form a connected network. Single
mode optical fiber with enlarged polymeric jacket
(3 mm outer diameter) was laid through the tubes by
air flow technique with air velocity between 20 m per
minute and 50 m per minute. The one-time maximum
length laid by air flow technique is about 500 m. Then,
the tubes were sealed by vacuum grouting technique
using cementitious grout with properties of high
fluidity, reasonable expansion rate and long setting
time, made possible by using appropriate water
content, water reducing agent, expansive agent, air
entraining agent and retarding agent.
3.2.2 Historic buildings
Historic structures may have an important role in the
cultural heritage of society because of the age,
4-to-16 multiplexer
4-channel FBG interrogator computer
inner reinforce concrete tube
outer concrete in steel tube
17m 4×6 FBG sensors
250m 4×6 FBG sensors
315m 4×6 FBG sensors
110m 4×6 FBG sensors
417m 4×6 FBG sensors
antenna
Fig. 23 Schematic diagram of the sensor allocations in
Guangzhou New TV Tower
Materials and Structures
architectural beauty, historical events, construction
challenges at their era and many other reasons.
However, with the old construction techniques and
long time exposure to environmental conditions, there
may be unknown degrees of deterioration that affects
the structural functions. Also, records of the design
and construction details are usually missing. For
conservation of historic structures, it is desirable to
have periodic/continuous monitoring systems to pro-
vide valuable information and accurate knowledge of
the structural behavior for the development of proper
management and maintenance scheme.
San Vigilio church is situated at Lugano lake in
Switzerland. It was first constructed in the sixteenth
and seventeenth century, while the frontal fac¸ade and
portal was built in the nineteenth century. There were
many significant cracks running along the center of the
cylindrical vault of the church while some smaller
cracks existed on the upper convex side of the vault.
To assess the stability of the cracks, 10 long-gauge
SOFO interferometers (50–60 cm long) were mounted
on both the top and bottom surfaces of the vault to
monitor the cracks and the curvature (Fig. 24)[23].
The installed sensors are hardly noticed by unin-
formed observers.
Royal Villa in Monza, Italy, was built from 1777 to
1779. It was abandoned since 1900 and severe
cracking was found along the barrel vaults of the
central corridor at various levels. There was also
significant degradation of the 18 m long truss wooden
structures. Repair and conservation work was carried
out to renovate the villa and transform it to a museum.
Long-gauge SOFO interferometers were installed
between the walls orthogonal to the corridor axes to
measure the global structural displacements (Fig. 25),
while short-gauge length SOFO interferometers were
installed to measure the propagation of the existing
main cracks [23].
Bolshoi Moskvoretskiy Bridge in Moscow, Russia,
was built in 1936 to 1937. As one of the main traffic
routes to the Red Square, it is made up of three 100 m
long reinforced concrete arches. The settlement of the
center of the arches caused cracking in the stone walls
near the abutments on both sides of the bridge. Also,
chloride induced corrosion has led to cracking of the
reinforced concrete arches. 16 long-gauge SOFO
interferometers were installed on both upper and
lower sides along the bridge to monitor the curvature
continuously in both horizontal and vertical directions
as well as deformation shape [23]. The data was sent to
a central control station through telephone line.
Seok-Ga Pagoda in Kyung Ju, Korea, was built in
the eighth century in the court of the Bulkook
(Bulguksa) temple. After centuries of service, the
three-storey pagoda was subjected to differential
settlements that caused the movement of pagoda
top view
SOFO sensors
vault side view
Fig. 24 Long-gauge SOFO
interferometers on the vault
of San Vigilio church
SOFO interferometer
Walls
Fig. 25 SOFO interferometers in Royal Villa
Materials and Structures
stones that might lead to serious damage. Long-gauge
SOFO interferometers were installed along the base of
the pagoda to monitor the deformation during main-
tenance and conservation works [23].
For displacement monitoring, polymer optical fiber
(POF) was embedded in textile for retrofitting the
masonry structures of historic buildings (Fig. 26)[33,
68]. With the high ultimate strain of POF (about
40 %), large local displacement (a few millimeters)
caused by crack propagation can be monitored by
OTDR. Depending on the capability of the OTDR, the
spatial resolution can be as small as 10 cm. The POF
crack sensor can measure crack from 1 mm up to
20 mm. In the testing of a single storey brick building
on a shaking table to simulate damage under earth-
quake, two cracks were identified from the backscat-
tered signal of an OTDR. The size of one of the cracks
was 2 mm while the other was nearly invisible [34,
61].
3.3 Geotechnical structures
Due to high uncertainties in the design parameters of
geotechnical structures, it is desirable to collect in-situ
data to verify the design assumptions, construction
quality and actual behavior in service. As visual
inspection and surface mounted sensors are inappli-
cable for this task, embedded fiber optic sensors have
been developed for foundations, piles, anchorages,
tunnels, dams, embankments as well as natural slopes.
3.3.1 Foundations, piles and anchorages
The defects of piles after construction are difficult to
identify, as pile load test can only provide overall load
capacity of pile. It is desirable to have embedded
sensors to measure the internal response. EFPI strain
wave sensors with specially packaged sensor body that
matched the aggregate size of the concrete mix were
developed [33,35,84]. Eight sensors were embedded
in a precasted driven pile at five different levels to
monitor the arrival time of wave at different locations.
The sensors are loosely mounted (rather than rigidly
fixed) on the longitudinal steel reinforcing bars
(Fig. 27) so the measurement is not affected by the
steel reinforcement. All sensors survived after pile
installation, dynamic pile test with high impact drop
weight and static pile test. The bearing capacity of the
pile was estimated by the results of the dynamic and
static pile tests. The integrity of the pile and the subsoil
conditions can be estimated by wave theory and the
arrival time of the stress wave generated from an
impact pulse at the pile head to the embedded EFPI at
different locations of the pile.
The EFPI strain wave sensor is further optimized in
performance and economy (Fig. 28)[34,85]. In the
original EFPI sensor illustrated in Fig. 27, a sensor of
standard length is packaged inside a steel cage. The
measured strain is hence much lower than the
concrete. To improve the sensitivity, a new design is
developed (Fig. 28). For this design, a gap is intro-
duced in the steel cage. By filling the gap with soft
material, the sensor exhibits very low stiffness under
axial deformation. Small deformations in the concrete
can therefore be easily captured. To prevent damage
by bending and shear, the sensor is reinforced by small
steel rods at several locations around the internal
circumference. To measure the strain wave transmit-
ting through the concrete, instead of welding the
sensor on the steel reinforcement, the sensor is
supported by a rod attached to the reinforcement (see
Fig. 28). The sensitivity of EFPI increases with
decreasing separation between the two mirrors, but
the mirrors should not touch each other at any time.
The optimal mirror separation of the EFPI strain wave
sensor is therefore determined by two important
deformations, which are the shrinkage deformation
during concrete curing and the deformation during
testing and operation. Optimized EFPI strain wave
sensors were tested in a large-scale cast-in-place bored
model pile of 10 m length and 0.75 m diameter at the
BAM Test Site in Horstwalde, Germany. The sensors
were installed at three different depths at 1.5 m, 5 m
and 8.5 m from the ground surface. At each level, the
EFPI sensors were mounted on the reinforcement cage
at 0°, 120°and 240°in angular direction. In addition, a
textile with embedded polymer optical fiber
crack
masonry beam
Fig. 26 Smart textile with embedded with plastic optical fiber
to measure crack propagation
Materials and Structures
FBG strain sensor, a temperature sensor and a resistive
strain gauge (RSG) were installed at each measure-
ment level for comparison. The EFPI strain wave
sensors detected the wave propagation from a low
strain impact clearly and correlated well to the RSG
signals.
Lead cable Steel cage
EFPI sensor
concrete pile
Steel reinforcement
EFPI sensor
Fig. 27 Concrete pile with
embedded special packaged
EFPI sensors
coherent
light
gap with soft protection
fixed point
fiber without coating
and can slide freely in the glass capillary
glass capillary
fixed point
Steel cage
Steel Reinforcement
Steel rod air cavity
Fig. 28 Specially packaged
EFPI sensors for improved
performance
Materials and Structures
The load bearing capacity of socket steel H-pile,
mini-pile, soil nail and ground anchor depends mainly
on the skin friction at adjacent material interface (soil
or rock). Conventionally, pull-out tests are conducted
on anchors with different lengths to obtain the total
load capacity, but this cannot provide information on
the skin friction distribution, which is useful for the
optimization of anchorage length. The efficiency of
ground anchor depends on the interfacial shear stress
transfer which varies along the length of the ground
anchor in a highly nonlinear manner (Fig. 29). The
effective length of ground anchor, which depends on
the loading and the properties of the surrounding
materials, can be estimated by the distributed tensile
stress along the ground anchor. To evaluate load
transfer behavior, a FBG sensor array was attached on
the reinforcing bar of the anchor, which was used to
restrain the uplift force of the foundation plates of a
sluice [33,35]. All sensors survived after the trans-
portation from factory, where was several hundred
kilometers from the site, and installation. The sensor
array was then used for long-term monitoring of the
anchor bonding. To make a similar smart ground
anchor, several FBG strain sensors were embedded
along a 7-wire steel strand [59]. FBG sensors were
embedded in the central wire, while the other six wires
were wrapped helically around the central one. The
concept is similar to the smart cable in Fig. 12. The
only difference was that the central wire consisted of a
steel tube instead of FRP. The outer and inner
diameters of the tube were 5.24 and 2 mm, respec-
tively. The FBG sensors were embedded inside the
steel tube and grouted by liquid epoxy glue.
A new semi-conductor production facility in Ta-
inan Scientific Park, Taiwan, is to be founded on a soil
with poor mechanical properties. The facility requires
a highly stable foundation and approximately 3000
piles are necessary. All the piles have identical
mechanical properties as well as geometrical dimen-
sions of 1.20 m in diameter and 35 m in length. SOFO
sensors were mounted on the steel reinforcement of
the piles before pouring of concrete to monitor the
performance and behaviors of piles under push-down,
pull-out and flexural full-scale on-site pile tests [21].
Two sets of piles, located at the East and West sides of
the foundation respectively, were tested. Each set
consisted of three piles, and each pile was tested with
different loading types, compression, tension or lateral
force, to collect information on the pile including the
elastic modulus, deformation shape, skin friction
distribution, lateral earth pressure along the pile,
ultimate load capacity and failure mechanism. Each
pile was loaded and unloaded by a hydraulic jack
according to a predefined load schedule. At each pre-
defined load level, the load was held unchanged for
prescribed duration.
A fiber optic pH sensor was developed for rein-
forced concrete structures based on ratiometric
absorption method that measured the ratio of intensi-
ties at two different wavelengths [10,33]. Since
relative intensity is measured, this method can over-
come the instability problems caused by decrease of
the indicator concentration due to photodegradation or
leaching out, drifts of the light source intensity as well
as bending of optical fibers. The sensor consists of a
fiber bundle, a glass window, a pH sensitive mem-
brane and a reflective layer (Fig. 30). The fiber bundle
maximizes the intensity of light transmission. When
pH level changes, the absorbed wavelength of the pH
sensitive membrane also changes. The absorption
spectrum is measured by a spectrometer. The sensor
was used to monitor steel anchor corrosion to avoid
bond failure with the fixed anchorage length [33]. The
sensitive range of pH level of the sensor is between 9.5
and 13.5. The measurement resolution is between 0.1
Applied load
Reinforcement
Bed rock or soil
Low applied
High applied load
Grouting
FBG sensors
Tensile stress
in the reinforcement
load
Fig. 29 Embedded FBG sensors to measure the nonlinear
distribution of tensile stress along a ground anchor
Materials and Structures
and 0.6 pH at different pH levels. The most sensitive
range is between pH 9.7 and pH 11. The homoge-
neous sensitive membrane, prepared by colored
adsorbent resin beads, exhibits long-term stability
under strong basic conditions without any leaching.
The response time for measuring the decrease in pH
level is about 60 min, which is not a problem because
the pH change in concrete structures is much slower
than the response time. The main issue with the sensor
durability is to maintain the hydrophilicity of the
membrane to assure the ion diffusion and the proton-
ation or deprotonation of the adsorbed pH sensitive
indicator, so the membrane must stay wet during
storage, application and in-service. A field trial at a
harbor of Rostock in North Germany from summer
2010 demonstrated that the sensor could evaluate the
alkalinity of the concrete matrix around the steel.
3.3.2 Tunnels
Generally, concrete lining is installed in a tunnel for
traffic safety purposes. An accurate and efficient
approach to monitor the structural health of the
concrete lining is highly desirable. To serve this
purpose, a single mode telecommunication optical
fiber was attached by epoxy adhesive on the surface of
a concrete tunnel lining with inner diameter of 9.1 m.
The strain along the optical fiber was measured by
Brillouin optical correlation domain analysis (BO-
CDA) [46,47,91]. The spatial resolution of the strain
distribution is less than 100 mm. However, the
measurement accuracy might deteriorate with distance
of measurement. Hence, the temperature and optical
polarization issues should be considered. Theoreti-
cally, there is a trade-off between the measurable
range and spatial resolution by using BOCDA. As the
strain can be sampled at fast rate, the approach is also
suitable for dynamic strain monitoring at any arbitrary
location.
Fire hazard is a particular safety concern of tunnels.
It is necessary to detect and determine the exact
location of fire in a short time and take action
accordingly. It is expensive and impractical to employ
point sensors for fire detection. A distributed temper-
ature sensing system based on Raman optical time
domain reflectometry was installed in Xuanwu Lake
tunnel in China. The length of the tunnel is 1.6 km. A
single optical fiber link was attached using fixtures
with design life of 30 years along the crown of the
tunnel, which is expected to be the hottest location as
fire causes hot air to rise up. The installation took 4
days between 1 a.m. and 4 a.m. in the morning by a
4-man team with a hydraulic elevation truck. The
installed system was subjected to a fire test with
ignition of a 50 cm diameter basin of diesel (Fig. 31).
The point of fire could be clearly located in 80 s [88].
3.3.3 Dams, embankments and slopes
Internal pressure of dams and embankments is an
important parameter for health evaluation. With
extremely high sensitivity, the interferometer is a
light
computer spectrometer
coupler
fiber bundle
glass window
pH sensitive
reflective laye
r
sensor head
of hydrogen ion
for infiltration
membrane
source
Fig. 30 Schematic diagram of the ratiometric adsorption spectrum based pH sensor
Tunnel
Burned diesel
Optical Fiber
Fig. 31 Fire test of a tunnel by using Raman OTDR
Materials and Structures
candidate for measuring the displacement of a dia-
phragm under pressure. There were many pressure
sensors developed based on EFPI [102] as the
displacement precision of EFPI can be less than
1lm relative to the reference point. However, when
the measurement device is switched off, the reference
point is lost. So, the conventional configuration of
EFPI may not be suitable candidate of long term static
measurement. A dual-EFPI pressure sensor that could
specify a stable zero-point for every intermittent
measurement was therefore developed [25,26]. One
EFPI is for measurement and the other is for triggering
(Fig. 32). The self-calibration procedure is started by
applying compressed air to the head so that the elastic
element is slightly deformed to reach a well defined
reference position, which is detected by the triggering
EFPI. Then, the head is bounced back to the measuring
EFPI by the elastic element. The diaphragm displace-
ment is obtained from the measuring EFPI as the
displacement between the well defined reference point
and the position before applying the compressed air.
Several of these dual-EFPI sensors have been installed
at the coal mine Belchatow in Poland for long-term
monitoring of the water and soil pressure.
One of the early warnings of failure of retaining
structures such as dams and embankment is excessive
displacement. It requires a large number of point
sensors to acquire adequate monitoring results, which
is impractical and uneconomical. Distributed sensor
provides an alternative. Geotextile is commonly used
in retaining structures for reinforcement and drainage.
An instrumented geotextile integrated with telecom-
munication silica single mode optical fiber was
embedded into embankments or dikes (Fig. 33).
Displacement was calculated from the distributed
strain along the optical fiber obtained from stimulated
Brillouin scattering measured by Brillouin optical
time domain reflectometry/analysis [33,67,76]or
Brillouin optical frequency domain analysis (BOFDA)
[34]. The cost of BOFDA is potentially lower than
BOTDA. However, the ultimate strain of common
silica optical fiber is only about 5 %, which is not
sufficient for monitoring slope stability and long-term
soil creep. In [34,67