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Description  |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to an optical sensing system for industrial
measurement.
2. Description of the Prior Art
From a need for a complete safeguard against explosion in a chemical plant
as well as a measure against an antiground potential difference in a heavy
electrical apparatus and a measure against noises etc., an optical sensing
system covering the entire route from signal transmission to signal
translation as an optical means has come into the limelight in place of a
conventional electrical sensing system.
In a measurement by an optical means in particular, the technique of a
light interferometer utilizing the shortness of an optical wavelength is
currently used so that sensing can be effected at high accuracy and high
sensitivity. A wavelength interferometer is known which is adapted to
measure a physical quantity at a place by measuring a shift of an
interference fringe which is produced by varying an optical path length of
a path at that place by the physical quantity such as temperature,
pressure, length etc. In the optical sensing system of this type it is
easy to know a variation of a to-be-measured quantity at high accuracy by
making longer an optical path at the place where measurement is effected.
In order to find the absolute value of the to-be-measured quantity it is
necessary to know how many light or dark bands are moved in an
interference fringe. This involves a time-consuming operation.
SUMMARY OF THE INVENTION
It is accordingly the object of this invention to provide an optical
sensing system which can measure the absolute value of a to-be-measured
physical quantity at high accuracy.
According to this invention there is provided an optical sensing system
comprising; means for generating a coherent light beam whose wavelength is
monotonically varied with time; means for transferring the coherent light
beam; means for dividing the light beam transferred into two beams; means
for sensing a physical quantity based on a phase difference which is
produced between the two beams dependent upon the physical quantity to be
measured; means for synthesizing the two beams through intereference to
produce an amplitude-modulated optical signal; means for transfering the
beam; and means for detecting an amplitude variation of the beam
transferred as a function of the physical quantity.
BRIEF DESCRIPTION OF THE DRAWINGS
This invention can be more fully understood from the following detailed
description when taken in conjunction with the accompanying drawings, in
which:
FIG. 1 is a block diagram showing an optical sensing system according to
one embodiment of this invention;
FIG. 2 is a graph showing the characteristic of a Fabry-Perot resonator as
shown in FIG. 1; and
FIGS. 3 and 4 are block diagrams each showing an optical sensing system
according to another embodiment of this invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
Referring to FIG. 1 an optical sensing system according to one embodiment
of this invention is shown. The system includes a wavelength variable
laser unit 2 for monotonically increasing or decreasing the wavelength of
emergent laser beams from .lambda. to .lambda.+.DELTA..lambda. or
.lambda.-.DELTA..lambda. with time. The laser unit 2 has a laser diode of
which the oscillation wavelength monotonically varies by varying the
ambient temperature around the laser diode. As well known, the wavelength
.lambda. of the laser beam generated from the laser diode can be varied.
For example, the wavelength can be varied by the extent of 3 to 4 A,
usually 2 A, per 1.degree. C. The laser diode of the unit 2 has its
oscillation wavelength .lambda. varied by varying an injection current.
For example, the oscillation wavelength .lambda. can be monotonically
increased by the extent of 0.4 A by varying the injection current of about
1 mA. As set out in M. Okuda et al.; "Tunability of Distributed
Bragg-reflector Laser by using the Electro-Optic effect" papers on
Technical Group Meeting of Inst. Electron, Commun, Eng. Jpn. OQE 76-61
(1976) (in Japan), the refractive index of a distributed Brugg reflector
area of a laser diode is varied by applying an electric field to the laser
diode, to permit the oscillation wavelength .lambda. to be monotonically
increased.
A laser beam generated by the wavelength variable laser unit 2 is split
into first and second beams for distribution. The first beam is supplied
by way of an optical fiber 4 to a 3 dB optical directional coupler 6 which
is located in a measuring area. The beam so supplied is split by the
coupler 6 into two beams equal in intensity to each other which are
launched into first and second optical fibers optically connected to the
coupler 6. At least one of the optical fibers 8 and 10 is located on a
point where a physical quantity is measured. The characteristic of the
optical fiber, i.e. the refractive index of the core and cladding of the
optical fiber is varied by the physical quantity from the above-mentioned
point. As a result, the optical path length of the optical fibers 8 and 10
is varied to permit a phase difference to occur between the two beams. The
two dephased beams are supplied to a second 3 dB optical directional
coupler 12, located in the measuring area, where the light intensity or
light amplitude is modulated through additive interference. The
amplitude-modulated optical signal is supplied through an optical fiber 14
to a photodetector 16 where it is converted to an electric signal. As
explained in more detail, the optical signal from the coupler 12 is an
alternate light-and dark-band optical signal i.e. an optically digitized
signal. In consequence, the electric signal is supplied to a counter 18
where it is counted.
The above-mentioned second laser beam from the wavelength variable laser
unit 2 is supplied by way of an optical fiber 26 to a Fabry-Perot
resonator 22 through an optical isolator 20 which prevents a return of the
laser beam. As already known in the art, the Fabry-perot resonator 22 has,
for the incident beam, a resonance wavelength .lambda. corresponding to a
free spectrum range .DELTA..lambda.s(=.lambda..sup.2 /2L) defined by a
length L between a pair of half mirrors not shown and has the
characteristic of emitting a light beam of a resonance wavelength as shown
in FIG. 2. Where the wavelength .lambda. of the laser beam emitted from
the wavelength variable laser unit 2 is monotonically increased to
.lambda.+.DELTA..lambda., laser beam impulses are supplied from the
Fabry-Perot resonator to a photodetector 24, the number of the laser beam
impulses corresponding in number to the number of resonance wavelengths
included in a monotonically increasing wavelength range of from .lambda.
to .lambda.+.DELTA..lambda.. By counting the number of electric pulses
from the photodetector 24 by means of the counter 25 it is possible to
detect a change in wavelength of laser beams from .lambda. to
.lambda.+.DELTA..lambda. or .lambda.-.DELTA..lambda..
When the counter 25 starts to count the electric pulse, it supplies a start
signal to the counter 18, starting the counter 18 to count the electric
signals supplied from the photodetector 16. When the counter 25 have
counted a predetermined number of electric pulses, it supplies a stop
signal 18, stopping the counter 18 to count the electric signals from the
photodetector 16. The physical quantity to be sensed is quantized by
counting the number of electric pulses by the counter 18 during the time
period from the generation of the start signal to the generation of a stop
signal.
Suppose that a phase difference .phi. between both the laser beams is
2m.pi.(m=1, 2 . . . n) which is given by a physical quantity involved when
both laser beams of a specified wavelength .lambda. pass through the
single mode optical fibers 8 and 10. In this case, an optical signal
produced through the addition of both the laser beams at the second 3 dB
optical directional coupler has an amplitude of "light" as opposed to
"dark". If, likewise, a phase difference .phi. between both the laser
beams is (2m+1).pi.(m=1, 2 . . . n), the optical signal has an amplitude
of "dark". The phase difference .phi. varied dependent not only upon the
physical quantity to be measured, but also the wavelength of the laser
beam. In consequence, if the wavelength .lambda. of the laser beams
minutely varies while the physical quantity to be measured does not vary,
the phase difference .phi. varies. If, for example, the wavelength of the
laser beams is monotonically increased from .lambda. to
.lambda.+.DELTA..lambda..sub.1, the corresponding difference .phi. varies
from 2m.pi. to (2m+1).pi. or from (2m+1).pi. to 2m.pi.. As a result, the
optical signal is intensity modulated from the amplitude of "light" to the
amplitude of "dark" and vice versa. The same event also occurs when the
wavelength of the laser beam is increased from
.lambda.+.DELTA..lambda..sub.1 to
(.lambda.+.DELTA..lambda..sub.1)+.DELTA..lambda..sub.2. With the monotonic
increase of the laser beam width from .lambda. to
.lambda.+.DELTA..lambda.(.DELTA..lambda.=.DELTA..lambda..sub.1
+.DELTA..lambda..sub.2 + . . . +.DELTA..lambda..sub.n) the amplitude of
the optical signal varies and the photodetector 16 detects an alternate
light and dark variation. The number of "light" or "dark" bands i.e. the
number of optical pulses, N, as detected by the photodetector 16 bears a
predetermined relation to the physical quantity as evident from the
relation of the physical quantity (to be measured) to the sensitivity as
will be later explained. When the counter 18 counts the number of optical
pulses, N, as detected by the photodetector 16 until the number of the
optical signals supplied from the Fabry-Perot resonator 22 to the
photodetector 24 reaches a predetermined number, the physical quantity is
determined. In other words, the counter 18 starts the count of the optical
pulses by the optical signals from the Fabry-Perot resonator 22 and when
the number of the optical signals from the resonator 22 reaches a
predetermined number, the counter 18 ends the count of the optical pulses
and the number of optical pulses, N, is supplied as an output signal to,
for example, the processor (not shown). The processor gives an instruction
to a controller for controlling the point (where the physical quantity is
measured) by the output corresponding to the number of optical pulses, N,
counted. Or the processor permits a physical quantity corresponding to the
number of counted optical pulses, N, to be displayed on a display unit.
Explanation will be given below of the relation of an actual physical
quantity to the phase difference .phi. as well as the theoretical
sensitivity of the optical sensing system to the actual physical quantity.
Suppose that the physical quantity is a temperature. With the lengths of
the single mode optical fibers 8 and 10 represented by L1 and L2,
respectively, and the temperatures of the fibers 8 and 10 by T.sub.1 and
T.sub.2, respectively, the phase difference .phi. will be given below:
##EQU1##
where T.sub.1, T.sub.2 denotes the relative temperatures with a
temperature T.sub.0 as a reference and n denotes the refractive index of
the cores of the optical fibers 8 and 10. Assume that the optical fibers
are made of the same material and that the linear expansion coefficients
.alpha.
##EQU2##
of the fibers are equal to each other. Equation (1) is reduced to
##EQU3##
The variation of the phase difference when the wavelength .lambda. suffers
a minute variation is
##EQU4##
The variation .psi. of the phase difference .phi. when the wavelength of
the laser beam is monotonically increased from .lambda. to
.lambda.+.DELTA..lambda. is
##EQU5##
Where the wavelength of the laser beam from the laser unit 2 is
monotonically increased, the optical pulse from the second 3 dB optical
directional coupler 12 has an amplitude of "light" or "dark" corresponding
to each 2.pi. variation of the phase difference .phi.. In consequence, the
number of optical pulses, N, counted by the counter 18 corresponds to the
integral part of a number obtained by dividing the variation .psi. of the
phase difference .phi. by 2.pi..
N=[.vertline..psi..vertline./2.pi.] . . . (5)
As evident from Equations (4) and (5) the number of optical pulses, N,
counted is a function of a temperature T. If the integral number, N,
counted is determined, it is possible to find out the temperature T. That
is, the variation .psi. of the phase difference .phi. can be found from
the integral number, N, of Equation (5) and the phase difference .phi.
from Equation (4), since the quantity in the curly brackets of Equation
(4) is constant and since .DELTA..lambda./.lambda. is beforehand
determined by the laser unit 2. The temperature T.sub.1 or T.sub.2 can be
found from Equation (2) if the phase difference .phi. is obtained. Where
the temperatures T.sub.1 and T.sub.2 given to the fibers 8 and 10 are
equal to each other (T.sub.1 =T.sub.2) the lengths of the fibers 8 and 10
can be made different from each other (L.noteq.L.sub.2). By maintaining
one of the fibers 8 and 10 at a known reference temperature it is possible
to know the temperature given to the other fiber.
Explanation will be given below of the snsitivity of the present system
based on the above-mentioned Equations which uses single mode fibers 8 and
10 made of quartz.
Table I shows the value of each term of Equations (2) and (4). The value
already appears in I. H. Malitson, "Interspecimen Comparison of the
Relative Index of Fused Silica" Journal of the Optical Society of America
Vol. 55, No. 10, Oct. 1965, page 1205.
TABLE I
______________________________________
.lambda. 0.63.mu. band
1.mu. band
______________________________________
n 1.457 1.451
##STR1## 10.4 .times. 10.sup.-6 /.degree.C.
10.5 .times. 10.sup.-6 /.degree.C.
.alpha. 5 .times. 10.sup.-7 /.degree.C.
5 .times. 10.sup.-7 /.degree.C.
##STR2## -3.11 .times. 10.sup.4 /m
-1.33 .times. 10.sup.4 /m
##STR3## 10.sup.-1 /.degree.C.m
-1.2/.degree.C.m
______________________________________
The temperature sensitivity of the system of this invention as found from
the numerical values of Table I is shown in Table II, where it is assumed
that a variation .DELTA..lambda. of the wavelength .lambda. of the laser
beam is enough small i.e. .DELTA..lambda./.lambda.<<1.
TABLE II
______________________________________
.lambda. 0.63.mu. band 1.mu. band
______________________________________
.phi..sub.0
111 radians/.degree.cm
70.5 radians/.degree.cm
.phi..sub.0 /2.pi.
17.7 fringes/.degree.cm
11.2 fringes/.degree.cm
.psi..sub.0
110 .DELTA..lambda./.lambda. radians/.degree.cm
78.1 .DELTA..lambda./.lambda. radians/.degree.cm
.psi..sub.0 /2.pi.
17.6 .DELTA..lambda./.lambda. fringes/.degree.cm
12.4 .DELTA..lambda./.lambda. fringes/.degree.cm
______________________________________
.phi..sub.0 means that a phase difference per meter between both the laser
beams occurs for a 1.degree. C. temperature rise when laser beams of a
specified wavelength .lambda. pass through the fibers 8 and 10. At this
time, the optical pulses of light or dark band occur, the number of the
optical pulses corresponding to the number of an integral part of a value
.phi..sub.0 /2.pi.. .psi..sub.0 denotes a variation of a phase difference
per unit temperature given to the unit length (optical fibers) between
both the laser beams when the laser beams vary from .lambda. (specified
wavelength) to .lambda.+.DELTA..lambda., the number of optical pulses
corresponding to a value of an integral part of .psi..sub.0 /2.pi..
From Table II it will be understood that the sensitivity of the optical
sensing system when the wavelength of the laser beams is monotonically
increased from .lambda. to .lambda.+.DELTA..lambda. is proportional to the
increment .DELTA..lambda..
Where a laser diode having a maximum wavelength variable range of about 50
A is used as a laser unit 2, the length of one of the optical fibers 8 and
10 which can obtain a 0.1% accuracy over a temperature measuring range of
about 500.degree. C. with a 0.5.degree. C. minimum detection temperature
scale is given by Table III.
TABLE III
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.lambda. 0.63.mu. band 1.mu. band
______________________________________
.DELTA..lambda./.lambda.
0.5% 0.1% 0.5% 0.1%
L 5.7m 28.4m 8m 40m
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As apparent from Table III, if the temperature variable range
.DELTA..lambda. is about 10 A a longer optical fiber will be required.
Since the optical fiber has a smaller diameter of 0.1 mm, if it is wound,
its volume does not become greater and can be restricted to substantially
2.times.2.times.0.2 cm. The coherent length of laser beams emitted from
the laser diode is enough greater, permitting the optical fiber to be used
as a sensor.
Suppose that the physical quantity is a pressure. With L.sub.1 and L.sub.2
representing the lengths of the single mode optical fibers 8 and 10,
respectively, and P.sub.1 and P.sub.2 representing pressures being applied
to the fibers 8 and 10, respectively, if the optical fiber isotropically
suffers pressure .phi., then the three-direction vector components of the
stress of the optical fibers resulting from the pressure .phi. will be
##EQU6##
The resulting deformations will be:
##EQU7##
where .mu.: Poisson ratio
E: Young's modulus
Here the linear approximation of the phase transition of each optical fiber
resulting from the deformation will be
##EQU8##
where D: the diameter of the fiber
.beta.: n.sub.eff k.
Since a difference between the diffraction indices of the core and cladding
of the optical fiber is below about 1%,
d.beta./dn=k . . . (11)
the optical indicatrix will be
##EQU9##
Since there is no slip stress when the optical fibers isotropically undergo
pressure such that they are isotropical with respect to stress,
.epsilon..sub.4 =.epsilon..sub.5 =.epsilon..sub.6 =0 . . . (13)
Therefore, Pij can be expressed as a 3.times.3 matrix
##EQU10##
Thus,
.DELTA.(1/n.sup.2).sub.xyz =-(P/E)(1-2.mu.)(P.sub.11 +2P.sub.12) . . . (15)
Therefore,
.DELTA.n=-1/2n.sup.3 .DELTA.(1/n.sup.2).sub.xy =1/2n.sup.3
(P/E)(1-2.mu.).times.(2P.sub.12 +P.sub.11) . . . (16)
A variation .DELTA.D in the diameter of the optical fiber is
.DELTA.D=.epsilon..sub.x D=-PD(1-2.mu.)/E . . . (17)
Using a standardized frequency etc., d.beta./dD can be expressed as
follows:
##EQU11##
If the single mode fibers are used as the optical fibers,
V1/32.4 db/dV=0.5 . . . (22)
The third term of Equation (21) is about 10.sup.-3 in comparison with the
other terms. Disregarding the third term, the phase difference .phi. is
given below:
##EQU12##
In Equation (23) the variation of the phase difference when the wavelength
varies minutely will be
##EQU13##
A variation .psi. of the phase difference when the wavelength of the laser
beam is monotonically varied from .lambda. to .lambda.+.DELTA..lambda. is
given below.
##EQU14##
The number of optical pulses, N, is shown in Equation (5). The pressure
P.sub.1 or P.sub.2 can be obtained from Equations (5), (25) and (23).
Tables IV and V show the characteristic and sensitivity respectively of the
quartz glass with respect to pressure.
TABLE IV
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.lambda. 0.63.mu. band
1.mu. band
______________________________________
n 1.457 1.451
##STR4## -3.11 .times. 10.sup.4 /M
-1.33 .times. 10.sup.4 /m
.beta. 1.453 .times. 10.sup.7 /m
0.912 .times. 10.sup.7 /m
.mu. 0.17 0.17
E 7.0 .times. 10.sup.10 N/m.sup.2
7.0 .times. 10.sup.10 N/m.sup.2
P.sub.12 +0.270 +0.270
P.sub.11 +0.121 +0.121
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TABLE V
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.lambda.
0.63.mu. band 1.mu. band
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.phi..sub.0
4.09 radians/kg/cm.sup.2 . m
2.61 radians/kg/cm.sup.2 . m
.phi..sub.0 /2.pi.
0.65 fringes/kg/cm.sup.2 . m
0.42 fringes/kg/cm.sup.2 . m
.psi..sub.0
4.21 .DELTA..lambda./.lambda.
2.66 .DELTA..lambda./.lambda.
radians/kg/cm.sup.2 . m
radians/kg/cm.sup.2 . m
.psi..sub.0 /2.pi.
0.67 .DELTA..lambda./.lambda.
0.42 .DELTA..lambda./.lambda.
fringes/kg/cm.sup.2 . m
fringes/kg/cm.sup.2 . m
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.phi..sub.0 shows a phase difference per meter between the laser beams when
the fibers 8 and 10 undergo a pressure of 1 kg per cm.sup.2 upon passage
of laser beams of a predetermined wavelength through the fibers. At this
time, optical pulses occur, the number of the optical pulses corresponding
to the integer given by .phi..sub.0 /2.pi..psi..sub.0 shows a variation of
a phase difference per unit pressure applied for the unit length of the
laser beams when the laser beams are monotonically varied from .lambda. to
.lambda.+.DELTA..lambda.. The counter 18 counts optical pulses, the number
of optical pulses so counted corresponding to the value, N, of an integer
of .psi..sub.0 /2.pi..
From Table V it will be understood that the pressure sensitivity of the
system when the laser beams suffer a wavelength sweeping is proportional
to the wavelength variable amount .DELTA..lambda.. Table VI shows a senser
fiber length necessary to obtain a 0.5% accuracy when
.DELTA..lambda./.lambda. is 0.5% and 0.1% for the wavelength variable
amount .DELTA..lambda./.lambda. of 50 A max.
TABLE IV
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.lambda. 0.63.mu. band 1.mu. band
______________________________________
.DELTA..lambda./.lambda.
0.5% 0.1% 0.5% 0.1%
L 11.9m 59.7m 19.1m 95.2m
______________________________________
In the actual available range, the sensitivity of the system is lower upon
being measured in terms of pressure than upon being measured in terms of
temperature. However, the pressure sensitivity of the system can be made
more than 100 times as accurate by encapsulating the fiber with elastic
material.
The optical sensing system as shown in FIG. 1 is of a so-called
Mach-Zenhder interferometer type. The system of this invention is not
restricted only to such type. This invention can be achieved if it is a
transmissive type Michelson interferometer or a reflective type Michelson
interferometer.
FIG. 3 shows a transmissive type optical sensing system. In this system, a
laser beam supplied from an optical fiber 4 is changed by an optical
element, such as a rod lens 30, into a parallel beam which in turn is
projected onto a half mirror 32. One of both laser beams split by the half
mirror 32 penetrates a crystal, such as a LiNbO.sub.3 crystal, for sensing
a physical quantity and is directed onto a reflective mirror 34 where it
is reflected toward the half mirror 32. The other laser beam is directed
toward a reflective mirror 36 where it is reflected toward the half mirror
32. At the half mirror 32 the laser beams suffer an additive interference
and the resultant beam is conducted to a rod lens 40 which is optically
coupled to the optical fiber 14. At the rod lens 40 the added laser beam
is converged and launched into the optical fiber 14. The laser beam is
detected at a photodetector 16 as an optical signal.
As well known in the art, the LiNbO.sub.3 crystal 38 has its refractive
index changed by applied voltage. In consequence, the optical path length
in the crystal varies dependent upon voltage. The laser beam, when it
passes through the crystal 38, suffers retardation. The retarded beam
meets the laser beam reflected by the reflective mirror 36, producing a
phase difference therebetween. As already set out in detail above, if the
wavelength of the laser beam emitted from the laser unit 2 is
monotonically varied from .lambda. to .lambda.+.DELTA..lambda., the laser
beam is modulated by voltage into an alternate dark- and light-band
optical signal and it is therefore possible to know a voltage applied,
from the number of optical pulses, N.
An optical sensing system of FIG. 4 is similar to the system of FIG. 3
except that it is a reflective type system. In FIG. 4 a circulator 40 is
optically coupled to optical fibers 4 and 14. In this case, a laser beam
transmitted through the optical fiber 4 is sent into an optical fiber 42
and an optical signal returned through the optical fiber 42 to the
circulator 40 is sent into the optical fiber 14. A nonmodulated laser beam
and a modulated laser beam (i.e. the optical signal) pass through the
optical fiber 42. A rod lens 44 is optically coupled to the optical fiber
42 to permit the laser beam to be projected onto a half mirror 32. The
optical signal which suffers interference at the half mirror 32 is
launched into optical fiber 42. In the reflective type optical sensing
system the optical fiber 42 is shared, as an optical path, by the
nonmodulated and modulated laser beams and it is therefore possible to
provide an economy of the optical fiber.
Although in the above-mentioned embodiment the temperature, pressure and
voltage are listed as the physical quantity a proper sensor can be used,
in place of the sensors 8, 10 and 38, for the sensing of a length and
magnetic field etc.
Since according to the optical sensing system of this invention an optical
signal modulated by the physical quantity is a light-and-dark band
alternating, amplitude-modulated signal, the physical quantity can be
accurately sensed without a substantial detection error, even if a longer
optical path is used for transmission of optical signals.
* * * * *
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