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Claims  |
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I claim:
1. A method of measuring temperature sensed by a temperature sensing
element comprising the steps of:
applying to said temperature sensing element input pulses of light at two
different wavelengths .lambda..sub.1 and .lambda..sub.2 to obtain
scattered light from said temperature sensing element;
detecting the scattered light;
deriving from the detected scattered light signals indicative of the
intensity of light within the scattered light occurring at a third
wavelength intermediate .lambda..sub.1 and .lambda..sub.2, .lambda..sub.3
being chosen such that 1/.lambda..sub.1 -1/.lambda..sub.3 =.nu.where .nu.
is the Stokes shift in wavenumber units of the scattered light for a light
pulse of wavelength .lambda..sub.1 ; and
processing the derived signals to provide a measurement of the temperature
sensed by said temperature sensing element.
2. A method as claimed in claim 1, in which light at said third wavelength
is Raman scattered light.
3. A method as claimed in claim 2, further comprising the steps of
detecting backscattered light at wavelengths .lambda..sub.1 and
.lambda..sub.2 from said temperature sensing element;
deriving an additional output signal indicative of the intensity of the
backscattered light; and
compensating for effects of attentuation of light in said element according
to the derived additional output signal.
4. A method as claimed in claim 1, in which an elongate optical fibre is
used as the temperature sensing element, said input pulses being applied
to one end thereof.
5. A method as claimed in claim 1, in which light at said third wavelength
is Brillouin scattered light.
6. A method as claimed in claim 1, in which the scattered light is
backscattered.
7. A method as claimed in claim 1, in which the scattered light is
forwardscattered.
8. A method of measuring temperature, comprising the steps of:
providing an elongate optical fiber, having an end, for use as a
temperature sensing element;
consecutively launching input pulses of light at two different wavelengths
.lambda..sub.1 and .lambda..sub.2 into said end of said temperature
sensing element;
maintaining a predetermined position along the optical fibre from said end
at a predetermined temperature to provide a reference for deriving
temperature measurements at other positions along the optical fibre;
passing scattered light from said element and deriving from said input
pulses, at a third wavelength .lambda..sub.3 intermediate said two
different wavelengths, to an intensity detector, .lambda..sub.3 being
chosen such that
1/.lambda..sub.1 -1/.lambda..sub.3 =1/.lambda..sub.3 -1/.lambda..sub.2
=.nu.
where .nu. is the Stokes shift in wavenumber units of the Stokes scattered
light for a pulse of wavelength .lambda..sub.1 ;
obtaining from said detector output signals indicative of the intensity of
the scattered light at said third wavelength deriving from said input
pulses; and
processing said output signals to provide a temperature measurement.
9. Apparatus for measuring temperature comprising:
a temperature sensing element;
means for applying to said temperature sensing element input pulses of
light at two different wavelengths .lambda..sub.1 and .lambda..sub.2 to
obtain scattered light from said temperature sensing element; means for
detecting the scattered light;
means for deriving from the detected scattered light signals indicative of
the intensity of light within the scattered light occurring at a third
wavelength .lambda..sub.3, intermediate .lambda..sub.1 and .lambda..sub.2,
.lambda..sub.3 being chosen such that 1/.lambda..sub.1 -1/.lambda..sub.3
=1/.lambda..sub.3 -1/.lambda..sub.2 =.nu. where .nu. is the Stokes shift
in wavenumber units of the scattered light for a pulse of wavelength
.lambda..sub.1 ; and
means for processing the derived signals to provide a measurement of the
temperature sensed by said temperature sensing element.
10. Apparatus as claimed in claim 9, wherein
said detecting means includes means for detecting backscattered light at
wavelengths .lambda..sub.1 and .lambda..sub.2 ;
said deriving means further comprises means for deriving an additional
output signal indicative of the intensity of the total backscattered
light; and
said processing means further comprises means for processing the derived
additional output signal to compensate for effects of attenuation of light
in said element.
11. Apparatus as claimed in claim 9, in which said applying means comprises
a single tunable source of monochromatic light.
12. Apparatus as claimed in claim 9, in which said applying means comprises
two separate light sources, one of said separate sources providing light
at wavelength and the other of said sources providing light at wavelength.
13. Apparatus as claimed in claim 12, further comprising a dichroic
beamsplitter interposed between said light sources and said temperature
sensing element.
14. Apparatus as claimed in claim 9, further comprising a monochromator
interposed in a path of the scattered light from said temperature sensing
element to said detecting means.
15. Apparatus as claimed in claim 9, in which temperature sensing element
is an elongate optical fibre.
16. A method of measuring temperature sensed by a temperature sensing
element comprising the steps of:
applying to said temperature sensing element input pulses of light of a
single wavelength to obtain scattered light from the temperature sensing
element;
detecting the scattered light;
deriving from the detected scattered light signals indicative of the
intensity of the Stokes and anti-Stokes shifted Brillouin scattered light;
and
processing the derived signals to provide a measurment of the temperature
sensed by said temperature sensing element.
17. A method of measuring temperature sensed by a temperature sensing
element comprising the steps of:
applying to said temperature sensing element input pulses of light to
obtain scattered light from said temperature sensing element;
detecting the scattered light;
deriving from the detected scattered light signals indicative of the
intensity of the scattered light;
determining the ratio between intensity measurements taken between an
anti-Stokes scattered intensity measurement and a Rayleigh scattered
intensity measurement in the scattered light; and
deriving the temperature sensed by said temperature sensing element from
the determined ratio.
18. A method as claimed in claim 17, in which the scattered light is Raman
scattered.
19. A method as claimed in claim 17, in which the scattered light is
Brillouin scattered.
20. A method of measuring the temperature sensed by a temperature sensing
element comprising the steps of:
maintaining a first predetermined part of said temperature sensing element
at a predetermined temperature to provide a reference for use in measuring
the temperature sensed at other parts of said temperature sensing element;
applying to said temperature sensing element input pulses of light to
obtain scattered light from said first predetermined part and from a
second part of said temperature sensing element;
detecting the scattered light;
deriving from the detected scattered light signals indicative of the
intensity of the scattered light from said first predetermined part and
said second part; and
processing the derived signals, with the derived signal from said first
predetermined part providing a reference signal to provide a measurement
of the temperature at said second part.
21. A method as claimed in claim 10, in which the scattered light is
backscattered.
22. A method as claimed in claim 20, in which the scattered light is
forwardscattered.
23. A method as claimed in claim 20, in which the scattered light is Raman
scattered.
24. A method as claimed in claim 20, in which the scattered light is
Brillouin scattered.
25. A method as claimed in claim 20, in which the input pulses have the
same wavelength.
26. A method as claimed in claim 20, in which an elongate optical fibre is
the temperature sensing element. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
This invention relates to a method of measuring temperature, and in
particular to a method of measuring temperature using optical time domain
reflectometry (OTDR).
Such a method of temperature measurement involves the launching of short
pulses of light into one end of an optical fibre temperature sensing
element, and then detecting the intensity of the backscattered light at a
position at or close to the launch end of the optical fibre. The spectrum
of the backscattered light will include a major component at or near the
wavelength of the input pulses due to Rayleigh, Mie and Brillouin
scattering, and will also include weaker components at significantly
longer and shorter wavelengths due to Stokes and anti-Stokes Raman
scattering, respectively. There may also be some longer wavelength
fluorescence component in the backscattered light
The time of receipt of backscattered light at the detection position
relative to the time of input pulse launch is dependent upon the distance
from the pulse input position that scattering occurred, and thus the
temperature at different positions along the optical fibre sensing element
can be measured by taking into account such time delay.
In British Patent Application No. 2,140,554, published on Nov. 28, 1984,
there is disclosed such an optical time domain reflectometry (OTDR)
temperature measuring method in which the Rayleigh and Mie and Brillouin
wavelengths are filtered out of the backscattered light, while the Stokes
and anti-stokes Raman wavelengths are fed to detecting and processing
apparatus which calculates therefrom the temperature at the position from
which the light was backscattered.
This known method uses input pulses of a single wavelength, with
temperature measurement being carried out by calculation of the ratio of
backscattered light intensity at the Stokes and anti-Stokes Raman
wavelengths only.
As disclosed, a laser, for example a semi-conductor laser is used as an
input pulse source, while a dichromator is used to effect the necessary
filtering of the backscattered light, the dichromator passing the Stokes
and anti-Stokes Raman wavelengths to two separate detectors, respectively.
This known method and apparatus have a number of disadvantages.
Firstly, the efficiency of the dichromator, or other device, used to effect
the necessary filtering of the backscattered light, and the response of
the detectors used to determine the intensity may be different at the
Stokes and anti-Stokes wavelengths.
Secondly, the disclosed apparatus takes no account of the likely difference
in the attenuation of the backscattered light by the optical fibre at the
Stokes and anti-Stokes wavelengths, which attenuation will progressively
alter the intensity ratio as the backscattered light returns along the
optical fibre. The alteration in the ratio is equivalent to an error in
temperature measurement and will increase with increase in distance
between the input end of the optical fibre and the position of scattering
and temperature measurement.
Thirdly, there may be fluorescence produced in the fibre at wavelengths
longer than the Rayleigh scattered wavelength, which fluorescence may
interfere with the measurement of the Stokes Raman scattered light
intensity.
Fourthly, the anti-Stokes Raman scattered light intensity at very low
temperatures may be too low to give an adequate signal from the detector
for use in determining the temperature measurement ratio.
SUMMARY OF THE INVENTION
According to the present invention there is provided a method of measuring
temperature, comprising the steps of consecutively launching input pulses
of light at two different wavelengths .lambda..sub.1 and .lambda..sub.2
into a temperature sensing element; passing scattered light from said
element and deriving from said input pulses, at a third wavelength
.lambda..sub.3 intermediate said two different wavelengths, to an
intensity detector, .lambda..sub.3 being chosen such that
1/.lambda..sub.1 -1/.lambda..sub.3 =1/.lambda..sub.3 -1/.lambda..sub.2
=.nu.
where .nu. is the Stokes shift in wavenumber units of the Stokes scattered
light for a pulse of wavelength .lambda..sub.1 ; obtaining from said
detector output signals indicative of the intensity of the scattered light
at said third wavelength deriving from said input pulses; and processing
said output signals to provide a temperature measurement.
BRIEF DESCRIPTION OF THE DRAWING
This invention will now be described by way of example with reference to
the drawing which is a block diagram of one embodiment of apparatus for
use in carrying out the method of the invention.
DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT
The apparatus comprises two sources 1 and 2 of monochromatic light at
wavelengths .lambda..sub.1 and .lambda..sub.2 respectively. Otherwise a
single source tunable to the two wavelengths can be used. Pulses of light
from the sources 1 and 2 are launched into one end of an elongate optical
fibre 3 which serves as a temperature sensing element, by way of a
dichroic beamsplitter 7 which transmits light at wavelength .lambda..sub.1
from source 1 and reflects light at wavelength .lambda..sub.2 from source
2, a partially reflective beamsplitter 8, and a partially reflective
beamsplitter 9.
Backscattered light from the fibre 3 is partially reflected by the
beamsplitter 9 through a monochromator 5, or equivalent filter device,
which passes only light at a wavelength .lambda..sub.3 to an intensity
detector 6. The remaining backscattered light is also partially reflected
by the beamsplitter 8 to an intensity detector 4. The detectors 4 and 6
give output signals indicative of the intensity of the light passed
thereto, which output signals are supplied to a processing means 10
operative to provide a temperature measurement therefrom, as will be
described hereafter.
The fibre 3 is arranged to extend over a path along which temperature
measurements are to be made. A known position 11 along the fibre 3 is
maintained at a known temperature by any conventional means, such as a
thermostatically controlled heating jacket. To provide the possibility of
carrying out a reference calculation for temperature measurements at other
positions along the fibre 3, as will also be described hereafter.
Pulses from the sources 1 and 2 are launched into the fibre 3 consecutively
and the apparatus used to effect optical time domain reflectometry (OTDR)
combined with Raman spectroscopy techniques, in accordance with the
following principles.
The wavelength .lambda..sub.1, .lambda..sub.2 and .lambda..sub.3 are set
such that:
1/.lambda..sub.1 -1/.lambda..sub.3 =1/.lambda..sub.3 -1/.lambda..sub.2
=.nu.(1)
where .nu. is the Stokes shift in wavenumber units of the Stokes Raman
backscattered light derived from an input pulse of wavelength
.lambda..sub.1 launched into the fibre.
Thus, the detector 6 provides consecutively an output signal indicative of
the Stokes Raman back-scattered light intensity at wavelength
.lambda..sub.3 derived from input pulses of wavelength .lambda..sub.1 and
an output signal indicative of the anti-Stokes Raman backscattered light
intensity at wavelength .lambda..sub.3 derived from input pulses of
wavelength .lambda..sub.2. Simultaneously the detector 4 provides output
signals indicative of the total back-scattered light intensity, mainly
from Rayleigh scattering, at the wavelengths .lambda..sub.1 and
.lambda..sub.2 for the input pulses, respectively.
The time dependence of the output signals from the detectors 4 and 6 in
relation to the input pulses is used in accordance with conventional OTDR
techniques to determine the position along the fibre 3 from which the
backscattered light has been received, and thus the position at which the
temperature is being measured.
The intensity of light Raman scattered in the fibre 3, either Stokes or
anti-Stokes shifted, varies with the temperature of the fibre in a well
understood manner (see "Raman Spectroscopy" by D.A. Long, 1977). The ratio
of the scattered light intensities varies exponentially according to the
reciprocal of the absolute temperature at the position of scatter, for
scattering at a given Raman shift .nu.. The output signals from detector
6, corresponding to anti-Stokes or Stokes backscatter from the input
pulses in turn can therefore be used to provide an indication of the
temperature of the scattering position in the fibre. As in conventional
OTDR measurements the time dependence of the Raman signals corresponds to
the spatial dependence of Raman scattering in the fibre, so that the
output signals from the detector 6 can be used to derive the temperature
distribution along the fibre.
To provide accurate quantitative measurements of temperature, rather than
just indications of temperature variations, it is necessary to process the
output signals from the detector in an appropriate manner.
In conventional Raman scattering measurement of temperature an input pulse
at a single wavelength .lambda. is used and the anti-Stokes and Stokes
Raman scattered intensities are measured at different wavelengths
.lambda..sub.a and .lambda..sub.s respectively.
When the wavelengths are related by the equation:
1/.lambda..sub.a -.nu.=1/.lambda.=1/.lambda..sub.s +.nu. (2)
(corresponding to equal anti-Stokes and Stokes shifts, v) the
temperature-dependent ratio R(T) of the intensities is given by:
R(T)=I.sub.a /I.sub.s =(.lambda..sub.s /.lambda..sub.a).sup.4 exp (-hcv/kT)
(3)
where
I.sub.a, I.sub.s are the anti-Stokes and Stokes intensities
h is Planck's constant
k is Boltzmann's constant
c is the velocity of light
v is the Raman shift in wavenumber units
and T is the absolute temperature.
However, the output signals corresponding to I.sub.a and I.sub.s depend on
the spectral response function of the measuring equipment. The measured
ratio M(T) of anti-Stokes signal divided by Stokes signal will generally
differ from the I.sub.a /I.sub.s intensity ratio by some unknown factor, F
say, which must be found before temperature can be deduced according to
the above equation (3).
With the method and apparatus of this invention two input pulse wavelengths
.lambda..sub.1 and .lambda..sub.2 are used and the anti-Stokes and Stokes
Raman shifted intensities therefrom are measured at a common wavelength
.lambda..sub.3. Since both the Raman scattered light intensities are
measured at the same wavelength .lambda..sub.3 by the same detector 6, the
spectral response function of the monochromator and that detector need not
be known.
In comparing the Raman signals to obtain a temperature measurement the
relative intensities I.sub.1 and I.sub.2 of the input pulses at
wavelengths .lambda..sub.1 and .lambda..sub.2 need to be considered.
Signals from detector 4 correspond to these two intensities, but again the
measured ratio of the signals will differ from the actual ratio of
intensities according to the spectral response function of the apparatus,
in particular detector 4.
One solution to these difficulties would be a measurement of the
appropriate spectral response functions or input pulse intensities as part
of an initial calibration of the apparatus. This approach has the
disadvantages of inconvenience, especially if components later have to be
adjusted or replaced, and introduces a risk of calibration errors if the
spectral response function or input pulse intensities alter, through
ageing of components or other causes.
A convenient and practical method which avoids the need to know the
spectral response functicn or input pulse intensities is to maintain the
section 11 of the fibre 3 at a known absolute temperature .theta. and make
backscattered light measurements at this `reference` position in the
fibre, as well as at those positions where temperature is to be measured.
For conventional Raman scattering measurement, the measured ratio
M(.theta.) for the reference position would be given by:
M(.theta.)=F.R(.theta.) (4)
and for another `measurement` position at an unknown temperature T:
M(T)=F.R(T) (5)
From equation (3) it can be shown that:
1/T=1/.theta.-(k/hcv) 1n (M(T)/M(.theta.)) (6)
so that the unknown temperature can be found from .theta., .nu.,
fundamental physical constants and the measured Raman signal ratios at the
`reference` and `measurement` positions in the fibre. The value of F need
not be explicitly considered.
With the method and apparatus of this invention, instead of using signals
from detector 4 corresponding to the input pulse intensities I.sub.1 and
I.sub.2, the measured ratio S of Stokes backscatter signals from the
`measurement` and `reference` positions in the fibre and the measured
ratio A of the anti-Stokes backscatter signals from the same `measurement`
and `reference` positions are used.
The temperature may be calculated from the relationship:
1/T=1/.theta.-(k/hcv) 1n (A/S) (7)
where A=V.sub.a (m)/V.sub.a (r) and S=V.sub.s (m)/V.sub.s (r), where V
denotes the signal from detector 6 corresponding to anti-Stokes (a) or
Stokes (s) scattering from the measurement (m) or reference (r) position
in the fibre.
Only signals from detector 6 are required to derive temperature in this
way.
Thus, for the conventional Raman spectroscopy method the ratios involve
signals corresponding to different wavelengths
(.lambda..sub.a,.lambda..sub.s) and kinds of scattering (Stokes or
anti-Stokes) but for the same position in the fibre, while with the method
of this invention the ratios involve signals corresponding to the same
wavelength .lambda..sub.3 and kind of scattering, but for different
positions in the fibre (the `reference` and the `measurement` positions).
It has so far been implicitly assumed that attenuation of light by the
fibre has no effect on the temperature measurements, except by reducing
the light intensities, which might make measurement of the signals more
difficult. However it will generally be the case that the attenuation of
light by the fibre will depend on the wavelength of the light and that it
will be different for the scattered wavelengths .lambda..sub.a and
.lambda..sub.s, or the input pulse wavelengths .lambda..sub.1 and
.lambda..sub.2, for either the conventional Raman spectroscopy method, or
the method according to this invention. These spectral attenuation
differences will alter the ratios of the scattered intensities by a
changing factor as the distance to the scattering position increases. The
effect is to cause a systematic temperature error, which increases with
distance if the fibre properties are constant throughout its length.
As before, one approach to this difficulty would be to measure the spectral
attenuation characteristic of the fibre before use, as part of an initial
calibration. Alternatively fibre could be specially chosen to have equal
attenuations at the relevant wavelengths. However, these approaches have
the same practical inconveniences as before: lack of interchangeability of
sensors without recalibration or special selection and risk of error
through unrecognised changes in spectral attenuation.
With the apparatus of this invention shown in the drawing spectral
attenuation effects in the fibre may be measured using the total Rayleigh
backscatter signals (corresponding to wavelengths .lambda..sub.1 and
.lambda..sub.2) obtained from detector 4 as usual in OTDR measurements of
attenuation. Appropriate corrections may then be applied to the
anti-Stokes and Stokes backscatter signals from detector 6 before in the
processing means 10 deriving the temperature distribution along the
fibres.
Although in the method described above Raman scattering is utilised, it is
otherwise possible to use Brillouin scattered light in a similar manner.
The relative intensities of anti-Stokes and Stokes-shifted
Brillouin-scattered light in a fibre are also exponentially-dependent on
absolute temperature, so that:
I.sub.a /I.sub.s =exp(-hcv/kT) (8)
where I.sub.a, I.sub.s are the anti-Stokes and Stokes Brillouin intensities
and v is now the Brillouin wavenumber shift, (the (.lambda..sub.a
/.lambda..sub.s).sup.4 factor can be ignored because the Brillouin shift
is small, typically 1 cm.sup.-1).
The relative intensities of Brillouin-scattered light may therefore be used
to measure the temperature distribution along an optical fibre, or the
mean temperature of an optical fibre, by methods analogous to those
described for using Raman-scattered light.
The spectral analysis apparatus must have a correspondingly greater
spectral resolution, which may be achieved by using a Fabry-Perot
interferometer, for example. The light sources 1 and 2 must also be
sufficiently monochromatic, such as a single-mode laser.
The use of Brillouin-scattered light is advantageous for measuring very low
temperatures, where the intensity of anti-Stokes Raman-scattered light may
become too low to provide adequate output signals.
The very small differences in source and scattered wavelengths also
eliminate any effect of spectral attenuation differences in the fibre 3.
Although in the methods and apparatus described above input pulses at two
different wavelengths are used, the use of a `reference` position
temperature measurement in the fibre is also advantageous when
conventional methods using a single input pulse wavelength are used, since
the need to know the spectral response function of the apparatus is again
avoided.
Thus, also according to this invention there is provided a method of
measuring temperature, comprising launching input pulses of light into a
temperature sensing element and deriving the temperature at a position in
the element from the intensity of light scattered at said position, in
which a part of the element is maintained at a known temperature in order
to provide a reference for deriving temperature measurements at other
positions in the element.
Either Raman or Brillouin, forwardscattered or backscattered light can be
used in such method.
Some optical fibres are known to fluoresce. Fluorescence is a common
problem in Raman spectroscopy, since it may interfere with the measurement
of the Stokes-shifted Raman-scattered light, since both are at longer
wavelengths than the input pulse wavelength.
In making temperature measurements using an optical fibre sensor and Raman
scattering it is possible to avoid interference from fluorescence by using
only the anti-Stokes scattered light to make temperature measurements,
since there is only significant fluorescence at wavelengths longer than
that of the input pulse.
The ratio of two anti-Stokes scattered intensity signals measured at
different anti-Stokes wavenumber shifts may be used, since the temperature
dependencies at different wavenumber shifts are well-known. The
calibration now requires knowledge of the Raman cross-section of the
optical fibre material at different Raman shifts, but this can be
eliminated as with the other spectral calibration factors by using
additional measurements at reference positions in fibre at known
temperature (as above described), or by a prior calibration measurement.
Otherwise the ratio of an anti-Stokes scattered intensity signal and a
Rayleigh scattered intensity signal may be used, to provide correction for
attenuation effects in the fibre.
Thus, also according to this invention there is provided a method of
measuring temperature, comprising launching input pulses of light into a
temperature sensing element and deriving a temperature in the element from
the intensity of backscattered light obtained from the element and
deriving from the input pulses, in which the temperature is calculated
from the ratio between two intensity measurements taken at two anti-Stokes
wavenumber shifts, or between an anti-Stokes scattered intensity
measurement and a Rayleigh scattered intensity measurement, in the
backscattered light.
Again input pulses of either a single or two wavelengths can be used, with
either Raman or Brillouin scattered light being used for the measurements.
As discussed above the use of Brillouin scattered light for temperature
measurement purposes is advantageous for measuring very low temperatures
where the intensity of anti-Stokes Raman scattered light may be too low to
provide adequate output signals for processing.
The use of Brillouin scattered light gives the further advantage that the
very small differences in wavelength between the input pulses and the
scattered light substantially reduce the effect of spectral attenuation
differences in the fibre.
The use of Brillouin scattering from input pulses of two different
wavelengths is discussed above.
However, Brillouin scattering from input pulses of a single wavelength can
also be used.
Thus, also according to this invention there is provided a method of
measuring temperature, comprising the steps of launching input pulses of
light of a single wavelength into a temperature sensing element; passing
backscattered light from said element and deriving from said input pulses
to intensity detector means; deriving from said detector means output
signals indicative of the intensity of the Stokes and anti-Stokes shifted
Brillouin backscattered light from said element; and processing said
output signals to provide a temperature measurement.
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