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Claims  |
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I claim:
1. A correlation method for measuring the optical path difference .DELTA.
of an imbalanced interferometer in a system including a wavelength
modulated laser, comprising:
A. preforming a characteristic matrix S(j,i), of size r x n, of the system
such that each row j (j=1,2,3 . . . r) is preformed at a predetermined
constant optical path difference .DELTA..sub.j ;
wherein
r=number of rows of the matrix
n=number of columns of the matrix
B. transmitting light from said laser through the system at n different
laser wavelengths .lambda..sub.i such that;
##EQU40##
where .DELTA..sub.min =minimum optical path difference of the sensor
i=1,2,3, . . . n
.lambda..sub.i is indexed so that .lambda..sub.i increases in magnitude as
i increases in magnitude
each element of the characteristic matrix is expressed as
##EQU41##
where A and C are constants related to the throughput and the contrast of
the sensor at the wavelength of the corresponding laser;
C. obtaining a different datum at each wavelength .lambda..sub.i whereby to
obtain a set of n different data;
D. forming a vector D(i) from said n different data;
where
##EQU42##
E. multiplying said characteristic matrix by said vector to obtain a
correlation vector V(j);
F. determining which element of the vector V(j) has the largest magnitude,
V(j=j');
whereby it is determined that the phase .phi. of the sensor
##EQU43##
and
.DELTA.=.DELTA..sub.j' +k.lambda.
where
k=a positive or negative integer
##EQU44##
2. A method as defined in claim 1 wherein said system comprises means for
detecting output light intensity I.sub.out (.lambda..sub.i) of said
interferometer at each of said wavelengths; and
means for detecting the gain G(.lambda..sub.i) of said laser at each of
said wavelengths;
and including the step of determining the ratio
##EQU45##
wherein
##EQU46##
3. A method as defined in claim 2 wherein said characteristic matrix S(j,i)
preformed by:
selecting r different optical path differences .DELTA..sub.j ;
setting said interferometer to said optical path differences .DELTA..sub.j
one at a time;
at each jth optical path difference, transmitting light from said laser
through the system at n different laser wavelengths .lambda..sub.i ;
whereby, the magnitude of each element S(j,i) is given by the ratio:
##EQU47##
4. A method as defined in claim 3 wherein r.ltoreq.m;
wherein
m is an integer; and
m is selected such that .lambda./m is the fraction of a fringe the system
can resolve.
5. A least absolute deviation method for measuring the optical path
difference .DELTA. of an imbalanced interferometer in a system including a
wavelength modulated laser, comprising:
A. preforming a characteristic matrix S(j,i), of size r x n, of the system
such that each row j (j=1,2,3 . . . r) is preformed at a predetermined
constant optical path difference .DELTA..sub.j ;
wherein
r=number of rows of the matrix
n=number of columns of the matrix
B. transmitting light from said laser through the system at n different
laser wavelengths .lambda..sub.i such that;
##EQU48##
where .DELTA..sub.min =minimum optical path difference of the sensor
i=1,2,3 . . . n
.lambda..sub.i is indexed so that .lambda..sub.i increases in magnitude as
i increases in magnitude
each element of the characteristic matrix is expressed as
##EQU49##
where A and C are constants related to the throughput and the contrast of
the sensor at the wavelength of the corresponding laser;
C. obtaining a different datum at each wavelength whereby to obtain a set
of n different data;
D. forming a vector D(i) from said n different data;
where
##EQU50##
E. dividing said vector by each row of said characteristic matrix to
obtain a second matrix A(j,i);
F. forming an absolute deviation vector E(j) using the relationship:
##EQU51##
wherein n=number of readings in the data set which satisfy the condition:
##EQU52##
wherein a.sub.th is a threshold value such that 0<a.sub.th <1;
G. determining which element of the vector E(j) has the smallest magnitude,
E(j=j');
whereby, it is determined that
.DELTA.=.DELTA..sub.j' +k.lambda.
where k=a positive or negative integer
##EQU53##
6. A method as defined in claim 5 wherein said system comprises means for
detecting output light intensity I.sub.out (.lambda..sub.i) of said
interferometer at each of said wavelengths; and
means for detecting the gain G(.lambda..sub.i) of said laser at each of
said wavelengths;
and including the step of determining the ratio
##EQU54##
wherein
##EQU55##
7. A method as defined in claim 6 wherein said characteristic matrix is
S(j,i), and said characteristic matrix is preformed by:
selecting r different optical path differences .DELTA..sub.j ;
setting said interferometer to said optical path differences .DELTA..sub.j
one at a time;
at each jth optical path difference, transmitting light from said laser
through the system at n different laser wavelengths .lambda..sub.1 ;
whereby, the magnitude of each element S(j,i) given by the ratio:
##EQU56##
8. A method as defined in claim 7 wherein r.gtoreq.m;
wherein
m is an integer; and
m is selected such that .lambda./m is the fraction of a fringe the system
can resolve.
9. A method for measuring the optical path difference .DELTA. of an
imbalanced interferometer whose range is defined by .DELTA..sub.o
-K.lambda..sub.1 .ltoreq..DELTA..ltoreq..DELTA..sub.o +K.lambda..sub.1
using a system including a wavelength modulated laser which emits light at
two center wavelengths .lambda..sub.1 and .lambda..sub.2, comprising:
A. preforming a first characteristic matrix S.sub.1 (j,i), of size r x
n.sub.1, for the system such that each row j (j=1,2,3 . . . r) is
preformed at a predetermined constant optical path difference
.DELTA..sub.j ;
wherein
r=number of rows of the matrix
n.sub.1 =number of columns of the matrix
B. transmitting light from said laser through the system at n.sub.1
different laser wavelengths .lambda..sub.li such that;
##EQU57##
where .DELTA..sub.min =minimum optical path difference of the sensor
i=1,2,3 . . . n.sub.1
.lambda..sub.li is indexed so that .lambda..sub.li increases in magnitude
as i increases in magnitude
each element of the characteristic matrix is expressed as
##EQU58##
where A and C are constants related to the throughput and the contrast of
the sensor at the wavelength of the corresponding laser;
C. obtaining a different datum at each wavelength .lambda..sub.li whereby
to obtain a set of n.sub.1 different data;
D. forming a vector D.sub.1 (i) from said n.sub.1 different data;
where
##EQU59##
and then either E1. multiplying said characteristic matrix by said vector
to obtain a correlation vector V.sub.1 (j);
F1. determining which element of the vector V.sub.1 (j) has the largest
magnitude, V.sub.1 (j=j'); or
E2. dividing said vector by each row of said characteristic matrix to
obtain a second matrix A.sub.1 (j,i);
F2. forming an absolute deviation vector E.sub.1 (j) using the
relationship:
##EQU60##
wherein n.sub.1 =number of readings in the data set which satisfy the
condition:
##EQU61##
wherein a.sub.th is a threshold value such that 0<a.sub.th <1;
F2.1 determining which element of the vector E.sub.1 (j) has the smallest
magnitude, E.sub.1 (j=j'); or
E1. multiplying said characteristic matrix by said vector to obtain a
correlation vector V.sub.1 (j);
F1. determining which element of the vector V.sub.1 (j) has the largest
magnitude, V.sub.1 (j=J');
to determine approximate values for .DELTA.'=.DELTA..sub.J' and then:
E2. dividing each vector by each row, within the neighbourhood of J' such
that J'-r'.ltoreq.j.ltoreq.J'+r', where r'<r, of said characteristic
matrix to obtain a second matrix A.sub.1 (j,i);
F2. forming an absolute deviation vector E.sub.1 (j) using the
relationship:
##EQU62##
wherein n.sub.1 =number of readings in the data set which satisfy the
condition:
##EQU63##
wherein a.sub.th is a threshold value such that 0<a.sub.th <1;
F2.1 determining which element of the vector E.sub.1 (j) has the smallest
magnitude, E(j=j');
whereby to determine more accurate values for .DELTA.'=.DELTA..sub.j' ;
whereby it is determined that the phase of the sensor
##EQU64##
and
.DELTA.'=.DELTA..sub.j' +k.sub.l .lambda..sub.1
where
k.sub.1 is an integer such that .vertline.k.sub.1 .vertline..ltoreq.K
##EQU65##
j'=the index such that (a) V.sub.1 (j=j') is the maximum element in the
correlation vector, or, (b) E.sub.1 (j=j') is the minimum element in the
absolute deviation vector E(j)
G. preforming a second characteristic matrix S.sub.2 (j,i), of size r x
n.sub.2, for the system such that each row j (j=1,2,3 . . . r) is
preformed at the same predetermined constant optical path difference
.DELTA..sub.j as in A. above
H. transmitting light from said laser through the system at n.sub.2
different laser wavelengths .lambda..sub.2i such that;
##EQU66##
where .DELTA..sub.min =minimum optical path difference of the sensor
i=1,2,3 . . . n.sub.2
.lambda..sub.2i is indexed so that .lambda..sub.2i increases in magnitude
as i increases in magnitude
each element of the characteristic matrix is expressed as
##EQU67##
where A and C are constants related to the throughput and the contrast of
the sensor at the wavelength of the corresponding laser;
I. obtaining a different datum at each wavelength .lambda..sub.2i whereby
to obtain a set of n.sub.2 different data;
J. forming a vector D.sub.2 (i) from said n.sub.2 different data;
where
##EQU68##
and then either K1. multiplying said characteristic matrix by said vector
to obtain a correlation vector V.sub.2 (j);
L1. determining which element of the vector V.sub.2 (j) has the largest
magnitude, V.sub.2 (j=j"); or
K2. dividing said vector by each row of said characteristic matrix to
obtain a second matrix A.sub.2 (j,i);
L2. forming an absolute deviation vector E.sub.2 (j) using the
relationship:
##EQU69##
wherein n.sub.2 =number of readings in the data set which satisfy the
condition:
##EQU70##
wherein a.sub.th is a threshold value such that 0<a.sub.th <1;
L2.1 determining which element of the vector E.sub.2 (j) has the smallest
magnitude, E.sub.2 (j=j"); or
k1. multiplying said characteristic matrix by said vector to obtain a
correlation vector V.sub.2 (j);
L1. determining which element of the vector V.sub.2 (j) has the largest
magnitude, V.sub.2 (j=J");
to determine approximate values for .DELTA." and .DELTA..sub.J" and then:
K2. dividing each vector by each row, within the neighbourhood of J" such
that J"-r".ltoreq.j.ltoreq.J"+r", where r".ltoreq.r, of said
characteristic matrix to obtain a second matrix A.sub.2 (j,i);
L2. forming an absolute deviation vector E.sub.2 (j) using the
relationship:
##EQU71##
wherein n.sub.2 =number of readings in the data set which satisfy the
condition:
##EQU72##
wherein a.sub.th is a threshold value such that 0<a.sub.th <1;
L2.1 determining which element of the vector E.sub.2 (j) has the smallest
magnitude, E.sub.2 (j=j");
whereby to determine more accurate value for .DELTA."=.DELTA..sub.j" ;
whereby it is determined that the phase of the sensor
##EQU73##
and
.DELTA."=.DELTA..sub.j" +k.sub.2 .lambda..sub.2
where
k.sub.2 is an integer such that .vertline.k.sub.2 .vertline..ltoreq.K
##EQU74##
j"=the index such that (a) V.sub.2 (j=j") is the maximum element in the
correlation vector, or, (b) E.sub.2 (j=j") is the minimum element in the
absolute deviation vector E.sub.2 (j)
determining k.sub.1 or k.sub.2 by determining the minimum
.vertline..DELTA.'-.DELTA.".vertline. among all possible values of k.sub.1
and k.sub.2 ;
whereby to obtain the optical path difference
.DELTA.=.DELTA..sub.j' +k.sub.l .lambda..sub.1 =.DELTA..sub.j" +k.sub.2
.lambda..sub.2.
10. A method as defined in claim 9 wherein said system comprises means for
detecting output light intensity I.sub.1 (.lambda..sub.li) and I.sub.2
(.lambda..sub.2i) of said interferometer at each of said wavelengths; and
means for detecting the gain (G.sub.1 (.lambda..sub.li) and G.sub.2
(.lambda..sub.2i) of said lasers at each of said wavelengths;
determining the ratio
##EQU75##
wherein
##EQU76##
and the further step of determining the ratio
##EQU77##
wherein
##EQU78##
11. A method as defined in claim 10 wherein said characteristic matrices
S.sub.1 (j,i) and S.sub.2 (j,i) are preformed by:
selected r different optical path differences .DELTA..sub.j ;
setting said interferometer to said optical path differences .DELTA..sub.j
one at a time;
at each jth optical path difference transmitting light from said lasers
through the system at n.sub.1 different laser wavelengths .lambda..sub.li,
and at n.sub.2 different laser wavelengths .lambda..sub.2i ;
whereby, the magnitude of each element S.sub.1 (j,i) and S.sub.2 (j,i) are
determined by calculating the ratios:
##EQU79##
12. A method as defined in claim 11 wherein r.gtoreq.m;
wherein
m is an integer; and
m is selected such that .lambda..sub.1 /m is the fraction of a fringe the
system can resolve. |
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Claims |
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Description |
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BACKGROUND OF INVENTION
1. Field of the Invention
The invention relates to methods for measuring the optical path difference
of an imbalanced interferometer using a wavelength modulated laser. The
invention also relates to a system for carrying out the method.
2. Description of Prior Art
In my co-pending U.S. application Ser. No. 499,798, filed Mar. 27, 1990, I
describe a method and system for measuring the optical path difference of
an imbalanced interferometer using a wavelength modulated laser wherein
the frequency of the optical fringes generated by modulating the
wavelength of the laser is measured to determine the optical path
difference. To carry out the method in the application, it is necessary to
have a laser which can be tuned through a wide range of wavelengths
without mode hopping. Such lasers are expensive which presents some
restrictions in the commercial implementation of the invention of the
application.
Other interferometric measurement systems are also known in the art as
illustrated in, for example. U.S. Pat. No. 4,874,244, Kersey, Oct. 17,
1989, U.S. Pat. No. 4,552,457, Giallorenzi et al, Nov. 12, 1985, and U.S.
Pat. No. 4,594,003, Sommargren, June 10, 1986.
The '244 patent uses two lasers 4 and 5 (see FIG. 1) operating at different
wavelengths .lambda..sub.1 and .lambda..sub.2. The signals from the two
lasers are combined in couplers 6 and 7, and the combined signal is
introduced to an interferometric optical fiber system. An output of the
interferometric optical fiber system is detected and divided into portions
attributable to .lambda..sub.1 and .lambda..sub.2, and the phase lag
between the output signals is measured. Lasers 4 and 5 may be modulated
with signals f.sub.1 and f.sub.2.
As seen in the system diagram illustrated in FIG. 4 of the '457 patent,
this system also uses two lasers with different wavelengths. The
interferometer, as seen in FIG. 1, comprises fiber optic reference arm and
difference length fiber optic sensing arm 14 and 12 respectively. The
output of the interferometer is split into third and fourth beams to
determine which lasers should be energized.
U.S. Pat. No. 4,594,003 teaches only a single laser 11. However, in
accordance with the teachings in this patent, this laser can have its
wavelength varied by current source 58.
SUMMARY OF INVENTION
It is therefore an object of the invention to provide a method for
measuring the optical path difference of an imbalanced interferometer
which overcomes the shortcomings of the prior art.
It is also an object of the invention to provide a system for carrying out
the method.
In accordance with the broad principles of the invention, a characteristic
matrix of the system is preformed. The characteristic matrix includes n
columns. Each row of the matrix is formed by taking readings at n
different wavelengths at a predetermined optical path difference. A set of
n data readings are then taken at the same wavelengths, and a vector is
formed from the set of the n data.
The matrix and vector are then mathematically manipulated to determine
which row of the matrix has a greater corelationship with the set of n
data than any other row. Accordingly, it is determined that the optical
path difference tested is proportional to the predetermined optical path
difference of the row having the greatest corelationship.
In accordance with the invention there is provided a correlation method for
measuring the optical path difference .DELTA. of an imbalanced
interferometer in a system including a wavelength modulated laser,
comprising:
A. preforming a characteristic matrix S(j,i), of size r x n, of the system
such that each row j (j=1,2,3 . . . r) is preformed at a predetermined
constant optical path difference .DELTA..sub.j ;
wherein
r=number of rows of the matrix
n=number of columns of the matrix
B. transmitting light from said laser through the system at n different
laser wavelengths .lambda..sub.i such that;
##EQU1##
where .DELTA..sub.min =minimum optical path difference of the sensor
i=1,2,3 . . . n
.lambda..sub.i is indexed so that .lambda..sub.i increases in magnitude as
i increases in magnitude
each element of the characteristic matrix is expressed as
##EQU2##
where A and C are constants related to the throughput and the contrast of
the sensor at the wavelength of the corresponding laser;
C. obtaining a different datum at each wavelength .lambda..sub.i whereby to
obtain a set of n different data;
D. forming a vector D(i) from said n different data;
where
##EQU3##
E. multiplying said characteristic matrix by said vector to obtain a
correlation vector V(j);
F. determining which element of the vector V(j) has the largest magnitude,
V(j=j');
whereby it is determined that the phase .phi. of the sensor
##EQU4##
and
.DELTA.=.DELTA..sub.j' +k.lambda.
where
k=a positive or negative integer
##EQU5##
In accordance with the invention there is further provided a least absolute
deviation method for measuring the optical path difference .DELTA. of an
imbalanced interferometer in a system including a wavelength modulated
laser, comprising:
A. preforming a characteristic matrix S(j,i), of size r x n, of the system
such that each row j (j=1,2,3 . . . r) is preformed at a predetermined
constant optical path difference .DELTA..sub.j ;
wherein
r=number of rows of the matrix
n=number of columns of the matrix
B. transmitting light from said laser through the system at n different
laser wavelengths .lambda..sub.i such that;
##EQU6##
where .DELTA..sub.min =minimum optical path difference of the sensor
i=1,2,3 . . . n
.lambda..sub.i is indexed so that .lambda..sub.i increases in magnitude as
i increases in magnitude
each element of the characteristic matrix is expressed as
##EQU7##
where A and C are constants related to the throughput and the contrast of
the sensor at the wavelength of the corresponding laser;
C. obtaining a different datum at each wavelength .lambda..sub.i whereby to
obtain a set of n different data;
D. forming a vector D(i) from said n different data;
where
##EQU8##
E. dividing said vector by each row of said characteristic matrix to obtain
a second matrix A(j,i);
F. forming an absolute deviation vector E(j) using the relationship:
##EQU9##
wherein n.sub.1 =number of readings in the data set which satisfy the
condition:
##EQU10##
wherein a.sub.th is a threshold value such that 0<a.sub.th <1;
G. determining which element of the vector E(j) has the smallest magnitude
E(j=j');
whereby, it is determined that
.DELTA.=.DELTA..sub.j' +k.lambda.
In accordance with the invention there is still further provided a method
for measuring the optical path difference .DELTA. of an imbalanced
interferometer whose range is defined by .DELTA..sub.o -K.lambda..sub.1
.ltoreq..DELTA..ltoreq..DELTA..sub.o +K.lambda..sub.1, using a system
including a wavelength modulated laser which emits light at two center
wavelengths .lambda..sub.1 and .lambda..sub.2, comprising:
A. preforming a first characteristic matrix S.sub.1 (j,i), of size r x
n.sub.1, for the system such that each row j (j=1,2,3 . . . r) is
preformed at a predetermined constant optical path difference
.DELTA..sub.j ;
wherein
r=number of rows of the matrix
n.sub.1 =number of columns of the matrix
B. transmitting light from said laser through the system at n.sub.1
different laser wavelengths .lambda..sub.li such that;
##EQU11##
where .DELTA..sub.min =minimum optical path difference of the sensor
i=1,2,3 . . . n.sub.1
.lambda..sub.li is indexed so that .lambda..sub.li increases in magnitude
as i increases in magnitude
each element of the characteristic matrix is expressed as
##EQU12##
where A and C are constants related to the throughput and the contrast of
the sensor at the wavelength of the corresponding laser;
C. obtaining a different datum at each wavelength .lambda..sub.li whereby
to obtain a set of n.sub.1 different data;
D. forming a vector D.sub.1 (i) from said n.sub.1 different data;
where
##EQU13##
and then either E1. multiplying said characteristic matrix by said vector
to obtain a correlation vector V.sub.1 (j);
F1. determining which element of the vector V.sub.1 (j) has the largest
magnitude, V.sub.1 (j=j'); or
E2. dividing said vector by each row of characteristic matrix to obtain a
second matrix A.sub.1 (j,i);
F2. forming an absolute deviation vector E(j) using the relationship:
##EQU14##
wherein n.sub.1 =number of readings in the data set which satisfy the
condition:
##EQU15##
wherein a.sub.th is a threshold value such that 0<a.sub.th <1;
F2.1 determining which element of the vector E.sub.1 (j) has the smallest
magnitude, E.sub.1 (j=j'); or
E1. multiplying said characteristic matrix by said vector to obtain a
correlation vector V.sub.1 (j);
F1. determining which element of the vector V.sub.1 (j) has the largest
magnitude, V.sub.1 (j=J');
to determine approximate values for .DELTA.'=.DELTA..sub.J' and then:
E2. dividing said vector by each row, within the neighbourhood of J' such
that J'-r'.ltoreq.j.ltoreq.J'+r' where r'<r, of said characteristic matrix
to obtain a second matrix A.sub.1 (j,i);
F2. forming an absolute deviation vector E.sub.1 (j) using the
relationship:
##EQU16##
wherein n.sub.1 =number of readings in the data set which satisfy the
condition:
##EQU17##
wherein a.sub.th is a threshold value such that 0<a.sub.th <1;
F2.1 determining which element of the vector E.sub.1 (j) has the smallest
magnitude, E(j=j');
whereby to determine more accurate value for .DELTA.'=.DELTA..sub.j' ;
whereby it is determined that the phase of the sensor
##EQU18##
and
.DELTA.'=.DELTA..sub.j' +k.sub.1 .lambda..sub.1 (i)
where
k.sub.1 is an integer such that .vertline.k.sub.1 .vertline..ltoreq.K
##EQU19##
j'=the index such that (a) V.sub.1 (j=j') is the maximum element in the
correlation vector, or, (b) E.sub.1 (j=j') is the minimum element in the
absolute deviation vector E.sub.1 (j)
G. preforming a second characteristic matrix S.sub.2 (j,i), of size r x
n.sub.2, for the system such that each row j (j=1,2,3 . . . r) is
preformed at the same predetermined constant optical path difference
.DELTA..sub.j as in A. above;
H. transmitting light from said laser through the system at n.sub.2
different laser wavelengths .lambda..sub.2i such that;
##EQU20##
where .DELTA..sub.min =minimum optical path difference of the sensor
i=1,2,3 . . . n.sub.2
.lambda..sub.2i is indexed so that .lambda..sub.2i increases in magnitude
as i increases in magnitude
each element of the characteristic matrix is expressed as
##EQU21##
where A and C are constants related to the throughput and the contrast of
the sensor at the wavelength of the corresponding laser;
I. obtaining a different datum at each wavelength .lambda..sub.2i whereby
to obtain a set of n.sub.2 different data;
J. forming a vector D.sub.2 (i) from said n.sub.2 different data;
where
##EQU22##
and then either K1. multiplying said characteristic matrix by said vector
to obtain a correlation vector V.sub.2 (j);
L1. determining which element of the vector V.sub.2 (j) has the largest
magnitude, V.sub.2 (j=J"); or
K2. dividing each vector by each row of said characteristic matrix to
obtain a second matrix A.sub.2 (j,i);
L2. forming an absolute deviation vector E.sub.2 (j) using the
relationship:
##EQU23##
wherein n.sub.2 =number of readings in the data set which satisfy the
condition:
##EQU24##
wherein a.sub.th is a threshold value such that 0<a.sub.th <1;
L2.1 determining which element of the vector E.sub.2 has the smallest
magnitude, E.sub.2 (j=j"); or
K1. multiplying said characteristic matrix by said vector to obtain a
correlation vector V.sub.2 (j);
L1. determining which element of the vector V.sub.2 (j) has the largest
magnitude, V.sub.2 (j=J");
to determine approximate values for .DELTA."=.DELTA..sub.J" and then:
K2. dividing said vector by each row, within the neighbourhood of J" such
that J"-r"<j<J"+r", where r"<r, of said characteristic matrix to obtain a
second matrix A.sub.2 (j,i);
L2. forming an absolute deviation vector E.sub.2 (j) using the
relationship:
##EQU25##
wherein n.sub.2 =number of readings in the data set which satisfy the
condition:
##EQU26##
wherein a.sub.th is a threshold value such that 0<a.sub.th <1;
L2.1 determining which element of the vector E.sub.2 (j) has the smallest
magnitude, E.sub.2 (j=j");
whereby to determine more accurate value for .DELTA."=.DELTA..sub.j" ;
whereby it is determined that the phase of the sensor
##EQU27##
and
.DELTA."=.DELTA..sub.j" +k.sub.2 .lambda..sub.2 (ii)
where
k.sub.2 is an integer such that .vertline.k.sub.2 .vertline..ltoreq.K
##EQU28##
j"=the index such that (a) V.sub.2 (j=j") is the maximum element in the
correlation vector, or, (b) E.sub.2 (j=j") is the minimum element in the
absolute deviation vector E.sub.2 (j)
determining k.sub.1 or k.sub.2 in equations (i) or (ii) by determining the
minimum .vertline..DELTA.'-.DELTA.".vertline. among all possible values of
k.sub.1 and k.sub.2 ;
whereby to obtain the optical path difference
.DELTA.=.DELTA..sub.j' +k.sub.l .lambda..sub.1 =.DELTA..sub.j" +k.sub.2
.lambda..sub.2.
In accordance with the invention there is still further provided a system
for measuring the optical path difference .DELTA. of an imbalanced
interferometer, comprising:
at least one diode laser means having a control terminal and a laser diode
and a photodiode, said laser diode having a laser diode output terminal
and said photodiode having a photodiode output terminal;
laser driver means having a control terminal and an output terminal;
said imbalanced interferometer having an input terminal and an output
terminal;
a detector having an input terminal and an output terminal;
processor means having input means and output means;
said output means of said processor means being electrically connected to
said control terminal of said laser drive means;
said output means of said laser driver means being connected to said
control terminal of said diode laser;
said output terminal of said laser diode being optically connected to said
input terminal of said interferometer;
said output terminal of said interferometer being optically connected to
said input terminal of said detector;
divider means having a first input terminal, a second input terminal and an
output terminal;
said output terminal of said detector being electrically connected to said
first input terminal of said divider means;
said output terminal of said photodiode being electrically amplified by the
laser driver and connected to said second input terminal of said divider
means; and
said output terminal of said divider means being connected to said input
means of said processor means.
BRIEF DESCRIPTION OF DRAWINGS
The invention will be better understood by an examination of the following
description, together with the accompanying drawings, in which:
FIG. 1 illustrates one embodiment of an inventive system for implementing
the inventive method;
FIGS. 2A, 2B, 2C and 2D are graphs useful in understanding the invention;
and
FIG. 3 illustrates an alternative embodiment of the inventive system.
DESCRIPTION OF PREFERRED EMBODIMENTS
Referring to FIG. 1, the system includes two wavelength modulated diode
laser means 1 and 2, each driven by a temperature stabilized laser driver
5 and 8 respectively. Each diode laser comprises a laser diode (1L and 2L)
which emits light, and a photodiode (1P and 2P) which monitors the
intensity variation of its associated laser diode. Preferably, the
photodiode outputs are amplified by amplifier means in their associated
laser drivers. Laser diode 1L has a center wavelength of 780 mn, and laser
diode 2L has a center wavelength of 810 nm. It is, of course, not
necessary that these particular wavelengths be used. In addition, the
invention can be carried out with only a single laser as long as the laser
has a width enough wavelength band. However, when a single laser cannot
provide the breadth of wavelengths needed, then two separate lasers must
be used.
The outputs of laser diodes 1L and 2L are optically coupled to the inputs
of directional coupler 6, The output of the directional coupler 6 is
optically coupled to the input of sensor 7.
The output of sensor 7 is optically connected to the input of detector 9
where the optical signal is transformed to an electrical signal. The
amplified outputs of photodiodes 1P and 2P are connected to respective
input terminals of divider 13.
The output of detector 9 is electrically connected to a third input
terminal of divider 13, and the output of the divider 13 is electrically
coupled to an input of processor 15.
Processor 15 provides control signals S.sub.1 and S.sub.2 to control laser
drivers 5 and 8 respectively. Laser drivers 5 and 8, in turn, provide
signals to control the operation of laser diodes 1L and 2L, i.e., turn
them ON or OFF, adjust their frequency, etc. When both laser diodes 1L and
2L are used, only one laser will operate at a time.
Likewise, there is an optical connection between the output of sensor 7 and
the input of detector 9.
The output of detector 9 constitutes electrical signals, so that the
connection between the output of 9 and the third input of divider 13 and
the connection between output of 13 and the input of processor 15 are
electrical connections.
Turning now to FIG. 2, it can be seen that, as the laser current is
increased, the wavelength at the output of the laser will also increase.
However, in view of the mode hopping characteristics of the lasers, the
increase will not be smooth but rather will be accomplished in steps.
Although each step is shown as horizontal, there is actually a slight rise
from left to right.
As is known in the art, the relationship between the input intensity and
output intensity of an interferometric sensor, e.g., a MACH-ZEHNDER
interferometer, which could be used as the sensor 7 in FIG. 1, can be
expressed as:
##EQU29##
where I.sub.out =output intensity of the interferometer
I.sub.in input intensity of the interferometer
.phi.=phase of the interferometer
.lambda.=wavelength of the laser
.DELTA.=optical path difference.
It is also well known that, unless a very complex and expensive laser is
used, it is possible to achieve only very small deviations, typically of
the order of a few angstroms, of the laser wavelength before mode hopping
occurs. In prior art methods and systems, very large imbalance
interferometers, .DELTA.>2000.lambda., are required. As will be seen, in
the present system, only slightly imbalanced interferometers are required,
.DELTA.>300.lambda..
Using the system as illustrated in FIG. 1, it is possible to obtain data
sets D(i):
##EQU30##
by varying the wavelength of the laser, despite mode hopping which occurs
during the modulation process. Because this is a discrete method, it will
work either with continuous wavelength change or discrete wavelength
changes.
In the above equation, D is a data set and G is a factor determined by the
gain of the laser with respect to current changes.
In view of equation (1) above, D can also be expressed as:
##EQU31##
where A and C are constants relating to the throughput and contrast of the
interferometer at the wavelength of the laser.
In accordance with the inventive method, a characteristic matrix, S(j,i) is
preformed as follows:
For each jth row of the matrix, the interferometer is preset at a
predetermined optical path differences .DELTA..sub.j. For example, if the
interferometer is to be measuring temperature, then the temperature of the
interferometer will be preset to known values corresponding to known
optical path differences. At each predetermined optical path difference,
the wavelength of the laser is varied through n different wavelengths.
Thus, the optical path difference for the jth row will be set in the
interferometer, and the wavelength of the laser will be varied through the
n wavelengths. Readings are taken at each of the wavelengths, in
accordance with equation (2) above. The n values thus obtained will
constitute the n values in the jth row.
The optical path difference is then set to a different predetermined value
to calculate the data for the (j+1)th row, and the wavelength of the laser
is then varied through the same n wavelengths as above. This is continued
until all of the rows have been completed.
The matrix S(j,i) can be formed using the arrangement in FIG. 1 by placing
the interferometer 7 in a reference mode in which the optical path
difference of the interferometer 7 can be actively changed. In order to be
able to recalibrate the system without disturbing the interferometer from
its measurement mode, a system as illustrated in FIG. 3 can be used. As
can be seen, FIG. 3 is identical to FIG. 1 except that it includes the
reference interferometer 17, whose optical path difference can be actively
changed, a second detector 19 and a fourth input terminal and second
output terminal at divider 13. Directional coupler 6 directs the output of
laser diodes 1L or 2L to sensor 7 and reference sensor 17. In the FIG. 3
embodiment, the divider has two output channels, an the two output
channels of the divider 13 are connected to two input terminals of
computer 15. With this arrangement, it is possible to both read data and
perform a calibration either independently or simultaneously under the
control of the computer 15. Thus, a new characteristic matrix can be
formed whenever the system needs calibration. The interferometer 7 can be
passive. No active means is required to vary the optical path difference
of the sensor by the system as in the system shown in FIG. 1, and
measurements from sensor 7 can be taken any time when the system is ready.
A vector is formed from these measurements. Typically, the formation of the
vector will be accomplished by the processor 15.
The remainder of the steps in the correlation and least absolute deviation
methods, described below, are performed by the processor.
STEP I--CALCULATING THE PHASE OF THE INTERFEROMETER
The objective is to obtain the phases of the interferometer, as described
in equation (1), at the two center wavelengths, .lambda..sub.1 and
.lambda..sub.2, respectively.
The two methods can be used to calculate the phases. For each center
wavelength, either Method I (correlation) or Method II (least absolute
deviation) or the combination of both, described below may be used.
METHOD I--CORRELATION METHOD
Using the characteristics matrix and the vector D, a correlation vector is
calculated as follows:
##EQU32##
where S is the m x n characteristic matrix
m is an integers such as that .lambda./m is the fraction of a fringe the
system can resolve.
The S matrix above consists of the m sets of D(i) premeasured at the center
fringe of the full range of the sensor. For example, if the imbalance of
the interferometer is at .DELTA..sub.0 and the full range of the sensor is
two K fringes, i.e.,
.DELTA..sub.0 -K.lambda..ltoreq..DELTA..ltoreq..DELTA..sub.0 +K.lambda.(5)
then
S(j,i)=D(i) measured at .DELTA..sub.j =.DELTA..sub.0 j.lambda./m (6)
where .lambda.=the average wavelength around one of the center wavelengths
of the modulated laser. If 780 nm and 810 nm are the center wavelengths of
the laser being used, then .lambda. is either approximately equal to 780
nm or 810 nm.
Since V(j) is the cross correlation with zero lag between the jth row of
the S matrix and the measured data D, the maximum of V, V(j=j') indicates
there is a strong direct correlation between the two sets of data. This
may be interpreted as indicating that the phase of the interferometer is
##EQU33##
or that the path difference of the sensor is
.DELTA.=.DELTA..sub.j' +k.lambda. (8)
METHOD II--LEAST ABSOLUTE DEVIATION METHOD
Once again, the matrix S(j,i) is formed, and a data set is taken to provide
a vector D(i). However, in this case, the vector is divided by the matrix
to form a new matrix A(j,i). That is:
##EQU34##
Using the above matrix, an absolute deviation vector E(j) is formed such
that:
##EQU35##
In equation (10), n.ltoreq.n, and n is the number of datum in the data set
which satisfy the condition:
##EQU36##
where a.sub.th is a threshold value.
In accordance with the present method, the minimum of E(j) is determined.
The minimum of E(j), E(j=j') indicates that the j'th row of the matrix S
has the least absolute deviation from the data of the vector D compared to
the absolute deviation of all other rows. Accordingly, it can once again
be said that
##EQU37##
and
.DELTA.=.DELTA..sub.j' +k.lambda.. (13)
STEP 2--COMPARING THE OPTICAL PATH DIFFERENCES
To remove the ambiguity having regards to the constant k in equation (8) or
equation (13), this step compares the optical path differences obtained at
the two different center wavelengths.
The procedure of the first step above-described is carried out using a
center wavelength, .lambda..sub.1 for example, 780 nm. This will yield the
equation:
.DELTA.'=.DELTA..sub.j' +k.sub.1 .lambda..sub.1 (14)
The procedure would then once again be used using a center wavelength 810
nm, i.e., .lambda..sub.2. This would yield the equation
.DELTA."=.DELTA..sub.j" +k.sub.2 .lambda..sub.2 (15)
It is noted that for carrying out the second part of the procedure, a
characteristic matrix must be formed using the second center wavelength
810 n | | |
