Highly Sensitive Pressure Measurement based on Multimode Fiber
Tip Fabry-Perot Cavity
Wei Ping Chen* and Dongning Wang
College of Optical and Electronic Technology, China Jiliang University, Hangzhou, China
Keywords: Fabry-Perot Interferometer, Multimode Fiber, Pressure Sensors.
Abstract: In this work, a highly sensitive pressure measurement device based on multimode fiber filled with
ultraviolet adhesive is presented. The experimental results show that the device has a high gas pressure
sensitivity of -40.94nm/MPa, a large temperature sensitivity of 213 pm/°C within the range from 55 to
85°C, and a relatively temperature cross-sensitivity is 5.2kPa/°C. The fiber device is miniature, robust and
low cost, in a reflection mode of operation, and has high potential in monitoring environment of high
pressure.
1 INTRODUCTION
A variety of Fabry–Perot interferometric sensors
based on optical fiber have recently been studied and
applied in various industrial areas to measure
temperature, refractive index, strain, pressure, and
fluid dynamics (Roriz P., et al., 2013. Optical fiber
FP interferometer (FPI) pressure sensors can be
divided into two types: operated on cavity length
change (Pevec S. and Donlagic D., 2012; Guo F et
al., 2012; Xu F., et al., 2012; Ma J., et al., 2012; Jin
L., et al., 2013; Eom J., et al., 2015; Ran Z., et al.,
2015; Hou M., et al., 2014.) or mainly rely on cavity
refractive index (RI) variation (Yuan W., et al.,
2011; Coelho L., et al., 2012; Hu G., Chen D., 2012;
Liu Z., et al., 2012; Wu C., et al., 2010). Many FPI
sensors worked on cavity length variation possess
relatively low pressure sensitivity compared with
those based on thin diaphragm. However, the
diaphragm based FPI sensors have a small
measurement range, typically a few tens of kPa (Xu
F., et al., 2012; Ma J., et al., 2012) and relatively
poor mechanical strength. Although the FPI sensors
worked on cavity RI change usually have a large
measurement range and good robustness, their
pressure sensitivity is relatively low, typically on the
order of tens of pm/MPa (Coelho L., et al., 2012; Hu
G., Chen D., 2012; Liu Z., et al., 2012, Wu C., et al.,
2010), except sensor head with a carefully designed
(Xu B., et al., 2015), which increases system
complexity and manufacturing difficulty.
In this work, a novel fiber tip FPI pressure sensor
based on etched end of multimode fiber (MMF)
filled with ultra-violet (UV) adhesive is
experimentally demonstrated. The fiber tip FP cavity
is compact in size, robust in structure, simple in
manufacturing, and convenient in operation.
Because of the special design of the sensing head,
the proposed sensor is effectively exhibits high gas
pressure sensitivity of -40.94nm/MPa within the
measurement range between 0 and 1 MPa (limited
by the pressure meter we used). On the other hand,
the device can measure temperature and the
refractive index, and their sensitivities are 213
pm/°C within the range from 55 to 85°C, ~-73.54
nm/RIU (RI unit) within the range from 1.332 to
1.372, respectively, which shows its versatile
measurement capability. Moreover the fiber tip FP
cavity possesses a relatively low temperature
cross-sensitivity of 5.2 kPa/°C.
2 DEVICE FABRICATION AND
OPERATION PRINCIPLE
The optical fiber FP cavity sensor head is fabricated
by an etched MMF filled with UV adhesive. During
the fabrication process, the end face of MMF with a
core diameter of 62.5 μm and a nominal effective RI
of 1.4682 (at 1550 nm) is etched by use of
hydrofluoric (HF) acid to form a tapered hole cavity.
The UV adhesive (Norland, NOA68) employed can
Chen W. and Wang D.
Highly Sensitive Pressure Measurement based on Multimode Fiber Tip Fabry-Perot Cavity.
DOI: 10.5220/0006103501470151
In Proceedings of the 5th International Conference on Photonics, Optics and Laser Technology (PHOTOPTICS 2017), pages 147-151
ISBN: 978-989-758-223-3
Copyright
c
2017 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
147
sustain the temperature change from -80°C to 90°C,
and has the RI of 1.54. The steps of fabrication are
illustrated in Fig. 1.
a) Firstly, a section of MMF is etched for ~10
minutes by use of HF acid with the
concentration of 40% before a taper-shaped
hole of several tens micrometers in depth is
formed at the end face of the MMF.
b) Secondly, the taper-shaped hole created is
filled with UV adhesive. As shown in the
figure, an inner air-cavity is formed inside the
UV adhesive due to the remaining air in the
taper-shaped hole region during the process
of UV adhesive filling. Then, employing the
UV light to solidify the UV adhesive.
The two reflection surfaces of R
1
and R
2
create an
FP cavity (C
1
). The light lunched into the inner
air-cavity is split into three beams: one traveling
along the MMF arrives at R1, part of the light is
reflected back which is denoted by I1, and the rest
continues to propagate until reaching R
2
and
experiencing partial reflection, denoted by I
2
. The
light beam transmitted through R
2
finally arrives at
R
3
and is partially reflected again which is denoted
by I
3
. The two reflection surfaces of R
2
and R
3
thus
forming another FP cavity (C
2
). Meanwhile, the two
reflection surfaces R
1
and R
3
can also form an FP
cavity (C
3
) with a cavity length that is equal to the
sum of cavity lengths of C
1
and C
2
. The cavity
lengths for C
1
and C
2
are ~37.7 and ~18.7 μm,
respectively.
Fig. 3(a) displays the reflection spectrum of the
device sample fabricated. And the fiber tip FPI
sensor corresponding spatial frequency spectrum
obtained by use of fast Fourier transform as shown
in Fig. 3(b), there are two dominant side peaks in the
spatial frequency spectrum, located at ~0.0239 and
~0.0563 nm
-1
, respectively, which indicates an
interference pattern of two FP cavities.
The well-known expression of free spectral range
(FSR) is written as
FSR=λ
2
/2nL (1)
where λ is the wavelength, n is the RI of the
cavity, and L is the cavity length. As the RI of UV
adhesive is 1.54 and the cavity lengths of C
1
and C
2
are ~37.7 μm, ~18.7 μm, respectively, by taking the
wavelength of 1550 nm, the spatial frequency peak
positions for three FP cavities C
1
, C
2
and C
3
can be
determined as ~0.0314, ~0.0239 and ~0.0554 nm-1,
respectively. This reveals that C
2
and C
3
are the
dominant FP cavities as the experimentally obtained
results agree well with those obtained from the
calculations. Thus, the output spectrum of the device
consists of two superimposed FP spectra of C
2
and
C
3
.
The reflection intensity (I) of the MZI can be
expressed by three beam interference theory as
I=I
1
+I
2
+2I
3
+2
√
I
2
I
3
cos Φ
2
3
+2
√
I
1
I
3
cos Φ
13
(2)
where I
1
, I
2
, and I
3
are the light intensity reflected
from adhesive-air surface R
1
, air-adhesive surface
R
2
, and adhesive-air surface R
3
, respectively, and
Φ
23
and Φ
13
are the introduced phase shifts of the
cavity C
2
and C
3
, respectively, given by
Φ
23
=
4πn
2
L
2
λ
(3)
Φ
13
=
4π(n
1
L
1
+n
2
L
2
)
λ
(4)
where n
1
and n
2
are the RI of air, UV adhesive, L
1
and L
2
are cavity length of C
1
and C
2
, respectively.
From Eqns. (2) - (4), by taking n
1
=1, n
2
=1.54, the
cavity lengths L
1
=37.7 μm, L
2
=18.7 μm, and the
reflection coefficient of the surface of R
1
, R
2
and R
3
as (n
1
-n
2
)
2
/(n
1
+n
2
)
2
=0.0452, the reflection spectrum
of the FP cavity device can be simulated and the
result obtained is displayed in Fig. 4, together with
that obtained from the experiment as shown
previously in Fig, 3(a), to facilitate the comparison.
It can be seen from Fig. 4 that the two reflection
spectra have nearly the same waveform, and their
intensity difference comes from the insertion loss of
the device while the wavelength shift existed in the
experimental fringe pattern is likely due to the initial
phase of the fringe pattern and the dispersion effect
of the optical fiber.
3 EXPERIMENTAL RESULTS
AND DISCUSSION
Fig. 5 shows the schematic of the experimental setup
used to test the response of FP sensor head to gas
pressure. A broadband source (BBS) centered at
1550 nm is used to illuminate the FPI through a
circulator. The reflection spectrum of the FPI is
observed by an optical spectrum analyzer (OSA)
with the resolution of 0.05 nm to monitor the
spectrum. The sensor head is placed in a gas
chamber, where the gas pressure can be adjusted by
use of an air pump (Wisdom Billiton, Y039),
measured by a pressure meter (ZHITUO, YB-150).
The sensor output is directed to an optical spectrum
PHOTOPTICS 2017 - 5th International Conference on Photonics, Optics and Laser Technology
148
analyzer (OSA) with the resolution of 0.05 nm to
monitor the spectrum.
We investigated the responses of the fiber tip FPI
pressure sensor samples with different pressure. In
the measurement, the fiber in the chamber was kept
in a straight line to avoid any bending-induced
effects, gradually increasing the pressure from 0.02
to 0.04 and then to 0.92 MPa with a step of 0.04
MPa, and the reflection spectrum was monitored in
real-time by use of an OSA. Fig. 6 and its inset
demonstrate the shift of dip wavelength in the
reflection spectrum with the pressure variation. It
can be seen from the figure that the dip wavelength
is decreased with the increase of pressure, and a
linear response with a sensitivity of -40.94nm/MPa
is obtained in the range of 0.02 to 0.92 MPa.
The high temperature sensing capability of the
device are tested by placing the sensor head in an
electrical oven and gradually increasing the
temperature from room temperature to 85°C with a
step of 5°C. During the experiment, to make sure the
temperature was stabilized in the chamber, the
temperature was stayed for 10 minute at each step.
Fig. 7 presents the dip wavelength variation with the
temperature change and its inset demonstrates the
reflection spectra at different temperatures. A fringe
dip near ~1540 nm at the temperature of 30°C is
found to experience a red shift with the increase of
temperature. The highest sensitivity obtained is ~213
pm/°C within the temperature range from 55°C to
85°C. However, considering of the pressure
sensitivity of -40.94nm/MPa obtained in the
experiment, the temperature cross-sensitivity is
calculated to be only 5.2 kPa/°C, which is much
smaller than that of the sensors based on side-hole
dual-core PCF (Hu G. and Chen D., 2012) (1
MPa/°C) and on FBG in the SMF (2.3 MPa/°C) (Wu
C et al., 2010).
To test the system response to the RI change, the
fiber device was fixed on a translation stage, and
immersed by concentrations of salt water and the
reflection spectra recorded had a resolution of 0.05
nm. Each time after the liquid sample was measured,
the fiber sensor head was rinsed with methanol
carefully until the original spectrum (i.e., the
reference spectrum) could be restored and no residue
liquid was left on the sensor head surface. Fig. 8
shows the interference fringe dip wavelength shift
with the RI change and the sensitivity of ~73.54
nm/RIU was achieved. In the inset of Fig. 8, the
wavelength variation as a function of RI is plotted.
Currently, the pressure measurement range
achieved in the experiment is limited by the air
pump used, which only provides a pressure value up
to 1 MPa. However, our device has the potential of
achieving much higher pressure measurement range
due to its robust structure. As a number of
wavelength dips exist in the reflection spectrum as
shown in Fig. 3(a), and the device is sensitive to a
range of physical parameters, a simultaneous
multiple parameter measurement can be expected.
4 CONCLUSIONS
In summary, we demonstrated and fabricated an
optical fiber FP interferometer which is composed of
etched MMF filled with UV adhesive. The gas
pressure change induces the air-cavity length
change, which causes the change in optical path
difference of the MZI, and in turn leads to the
reflection spectrum shift. The sensor device exhibits
a high pressure sensitivity of -40.94nm/MPa and a
good temperature sensitivity of 213 pm/°C within
the range from 55°C to 85°C, and a RI sensitivity
of~-73.54 nm/RIU within the range from 1.332 to
1.372. The temperature cross-sensitivity of the
device is 5.2kPa/°C. Such a device is based on low
cost MMF, compact in size, robust in structure,
simple in fabrication, convenient in operation, which
makes it highly attractive for pressure sensing.
ACKNOWLEDGMENTS
This work is supported by the National Natural
Science Foundation of China (Grant No. 61377094).
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APPENDIX
Figure 1: Schematic diagram of the fabrication process of
the optical fiber sensor head. (a) A taper-shaped hole at
the end of MMF is formed by HF etching. (b) The
taper-shaped hole at the end of MMF is filled by UV
adhesive.
Figure 2: (a) Schematic diagram and (b) the microscope
image of the sensor head.
Figure 3: (a) Reflection spectra of the device sample. (b)
Spatial frequency spectra of the device sample.
Figure 4: Reflection spectra of the FP cavity device
obtained from theoretical simulations and experiment.
PHOTOPTICS 2017 - 5th International Conference on Photonics, Optics and Laser Technology
150
Figure 5: Schematic diagram of experimental setup.
Figure 6: Dip wavelength shift with the increase of
pressure, and the inset shows the reflection spectra of the
device at different pressures.
Figure 7: Fringe dip wavelength shift with the temperature
variation. Inset shows the reflection spectra of the device
at different temperatures.
Figure 8: Dip wavelength shift with RI, and the inset
shows the reflection spectra of the device at different RI
values.
Highly Sensitive Pressure Measurement based on Multimode Fiber Tip Fabry-Perot Cavity
151
