JP3377067B2 - Brillouin frequency shift distribution measuring method and apparatus - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a measuring method and a measuring apparatus for a Brillouin frequency shift distribution of an optical fiber used when measuring a temperature distribution and the like by using the optical fiber as a sensor, and particularly to improving the performance thereof. Regarding

[0002]

2. Description of the Related Art When light in the visible portion is incident on an optical fiber,
Backscattered light that scatters at an angle of 90 ° or more with respect to the incident angle is generated. When the spectrum of this backscattered light is measured, it can be seen that the scattered light mainly contains three components. They are Rayleigh scattered light, Raman scattered light, and Brillouin scattered light. Rayleigh scattered light is generated by a slight fluctuation of the refractive index of the optical fiber glass, and its wavelength is the same as that of the incident light. On the other hand, Raman and Brillouin scatterings are inelastic scatterings due to nonlinear interaction with optical phonons and acoustic phonons, respectively, and their wavelengths are different from the incident light. In Raman scattering, the frequency shift is about 13 THz (about 100 at wavelength).
However, in the case of Brillouin scattering, the frequency shift is about 10 GHz (about 0.1 n in terms of wavelength).
m) small.

Of these scattered lights, Brillouin scattering has recently attracted particular attention. The reason is that the Brillouin frequency shift has strain and temperature dependence, and it is possible to sense strain and temperature by utilizing this. By measuring the Brillouin frequency shift at each position z in the length direction of the optical fiber, the strain and temperature distribution can be sensed. As a method that enables this, BOTDA (Brillouin Optical Fiber Time-Dom)
ain Analysis; Brillouin optical time domain analysis) is known.

In BOTDA, the first light, which is pulsed light, and the second light, which is different from the first light, are caused to propagate in an optical fiber so as to face each other. Now, it is assumed that the difference Δν = ν1-ν2 between the frequency ν1 of the first light and the frequency ν2 of the second light is matched with a value near the Brillouin frequency shift ν _B of the optical fiber. In this state, when the first light and the second light meet in the optical fiber, the power of the second light increases due to the Brillouin effect. In BOTDA, this increase amount is regarded as a signal to be measured (this method will be referred to as a Brillouin gain method for convenience of description).

In the Brillouin gain method, the power (intensity) of the signal (increased amount of second light) is met by the first light and the second light after the first light enters the optical fiber. , First
Of the second light amplified by the first light is measured as a function of the delay time t until the first light reaches the point of incidence on the optical fiber, and the measured value is S _B (t, Δν) . Further, S _B (t, Δν) is measured for various Δν, and a data group {S _B (t, Δν); Δν} is obtained. Here, the delay time t has the following relationship with the position coordinate z along the length direction of the optical fiber.

[0006]

## EQU1 ## t = (1 / V ₁ + 1 / V ₂ ) z (1) where V ₁ and V ₂ are the velocities of the first and second lights in the optical fiber, respectively. Then, in the above data group {S _B (t, Δν); Δν}, when t is fixed and Δν that maximizes S _B (t, Δν) is obtained, it is expressed by the formula (1). Position z in the length direction of the fiber
Coincides with the Brillouin frequency shift at. That is, the Brillouin frequency shift distribution ν _B (z) is obtained.

[0007]

However, the above-mentioned measurement method by the Brillouin gain method has the following problems. That is, when the power of the first or second light is increased in an attempt to obtain a large signal, the light of the first pulse interacts with the second light by the Brillouin effect,
As it propagates through an optical fiber, it loses its energy. As a result, the light of the first pulse is attenuated near the far end of the optical fiber, even if the loss in the optical fiber is negligible. Further, this attenuation amount differs depending on the optical frequency difference Δν.

This can be easily understood by considering that the Brillouin effect occurs only when the optical frequency difference Δν is equal to or close to the Brillouin frequency shift ν _B. Therefore, the optical fiber section near the far end of the optical fiber (the coordinates of this section are [z _m , z _m + d
z]), that is, the first optical power propagating in the section [z _m -dz, z _m ] has an optical frequency difference Δν dependency. Therefore, this section [z _m −
Without considering the Δν dependence of the power of the first light propagating in dz, z _m ], simply the signal S _B (t _m , Δν) from the interval [z _m , z _m + dz] (where t _m and z _m are connected by the relation of the equation (1)), and Δν that maximizes the relationship is regarded as the Brillouin frequency shift ν _B in the interval [z _m , z _m + dz], the measured value is This results in a very large error.

The problems of the Brillouin gain method have been described above. BOTDA also has a pair of Brillouin loss methods. In the case of the Brillouin loss method, the first
Difference between the frequency ν1 of the second light and the frequency ν2 of the second light Δν = ν
Match 1-ν2 with a value near -ν _B (Δν ~-
ν _B ). In this state, when the first light and the second light meet in the optical fiber, the power of the second light is attenuated by the Brillouin effect. The Brillouin loss method regards this attenuation as the signal to be measured. The subsequent measurement procedure is completely the same as that of the Brillouin gain method. That is, the power of this signal is changed to the first power after the first light enters the optical fiber.
Light and the second light meet, the second light attenuated by the first light
Of light is measured as a function of the delay time t for the first light to reach the point of incidence on the optical fiber, which is S
Let _B (t, Δν). Further, S _B (t, Δν) is measured for various Δν, and the data group {S _B (t, Δν
ν); Δν} is obtained. Then, the data group {S _B (t, Δ
ν); Δν}, with t fixed, S _B (t, Δ
When Δν that maximizes ν) is obtained, it agrees with the Brillouin frequency shift at the position z in the length direction of the optical fiber represented by the equation (1). That is, the Brillouin frequency shift distribution ν _B (z) is obtained.

The difference between the Brillouin loss method and the Brillouin gain method is that in the Brillouin gain method, when the power of the first or second light is increased in order to obtain a large signal, as described above, The light loses its energy as it propagates through the optical fiber due to the interaction with the second light due to the Brillouin effect. In contrast, in the Brillouin loss method, the light of the first pulse has the second effect due to the Brillouin effect. It is to get energy from the light of. That is, it can be said that the Brillouin loss method is superior to the Brillouin gain method in terms of signal power. However, the Brillouin loss method is similar to the Brillouin gain method, and the optical fiber section [z _m , z _m near the far end of the optical fiber is used.
The power of the first light incident on + dz], that is, the power of the first light propagating in the section [z _m −dz, z _m ] is
There is an optical frequency difference Δν dependency. Therefore, unless this is corrected, the Brillouin frequency shift distribution ν _B (z) cannot be measured with high accuracy as in the case of the Brillouin gain method.

In view of the situation of the prior art as described above, an object of the present invention is to improve the measurement accuracy of the Brillouin frequency shift distribution in the BOTDA method and a measurement for implementing the Brillouin frequency shift distribution measuring method. To provide a device.

[0012]

In order to achieve the above object, the Brillouin frequency shift distribution measuring method according to the present invention uses the above-mentioned signal (hereinafter referred to as BOTDA signal) which is an increase amount of the second light due to the Brillouin effect. Not only is measured, but also backward Rayleigh scattered light or backward Raman scattered light is measured, and the BOTDA signal is corrected using this measurement data, thereby improving the measurement accuracy of the Brillouin frequency shift distribution in the BOTDA method.

More specifically, as a first form of the measuring method of the present invention, two lights are made to propagate in an optical fiber so as to face each other, and at least one of the two lights is pulsed light, Using the pulsed light as the first light and the other light as the second light, the difference Δν = ν1-ν2 between the frequency ν1 of the first light and the frequency ν2 of the second light is calculated by the Brillouin frequency shift of the optical fiber. It is made to match the neighborhood value of ν _B , and in that state, when the first light and the second light meet, the increase amount of the power of the second light amplified by the first light is signaled. Or the frequency ν1 of the first light
And the difference Δν = ν1-ν2 between the frequencies ν2 of the second light and −
The amount of attenuation of the power of the second light attenuated by the first light when the first light and the second light meet in the vicinity of ν _B in that state. As a signal,
The power of the signal is amplified or attenuated by the first light when the first light and the second light meet after the first light enters the optical fiber. Measuring the second light as a function of the delay time t until the first light reaches the point where the first light is incident on the optical fiber,
Let this measured value be S _B (t, Δν)
_{In the method} of measuring _B (t, Δν) for various Δν and measuring the Brillouin frequency shift distribution ν _B (z) as a function of the position z in the length direction of the optical fiber based on the measured data, The power of the backward Rayleigh scattered light by the first light is measured as a function of the delay time t _Ray , and the measured value is S _Ray (t _Ray , Δν), and the above S _B
It is characterized in that the Brillouin frequency shift distribution ν _B (z) in the length direction of the optical fiber is measured from a signal obtained by correcting (t, Δν) by the above S _Ray (t _Ray , Δν).

As a second form of the measuring method of the present invention, the power of the backward Raman scattered light by the first light is a function of the delay time t _Ram , that is, along the length direction of the optical fiber. It is measured as a function of the position z, and the measured value is S _Ram (t _Ram , Δν), and S _B (t,
It is characterized in that the Brillouin frequency shift distribution ν _B (z) in the length direction of the optical fiber is measured from the signal obtained by correcting Δν) by S _Ram (t _Ram , Δν).

Furthermore, the measuring method of the present invention is, as an embodiment thereof, that the first light of pulsed light is made incident from one end of the optical fiber and at the same time the second light is made incident from the other end of the optical fiber. A step of propagating the light and the second light in opposition, and a difference Δν = ν1-ν2 between the frequency ν1 of the first light and the frequency ν2 of the second light is -ν _B or ν _B (ν _B Is a value close to the Brillouin frequency shift of the optical fiber), a value S _B (t, Δν) corresponding to the power attenuation amount of the second light due to the Brillouin effect, and the first light To detect the value S _Ray (t _Ray , Δν) corresponding to the intensity of the backward Rayleigh scattered light by S _b (t, Δν) and S _Ray (t _Ray , Δν), respectively, as a function P of the position z. _B (z, Δν), P _Ray (z, Δν
ν), and BYR (z, Δν) = P _B (z, Δν)
/ P _Ray (z, Δν) and all the above steps are performed by changing Δν to maximize the value of BYR (z, Δν) at each position z of the optical fiber.
Value of Δν |, that is, Brillouin frequency shift ν
_And a step of obtaining _B (z).

Further, the measuring method of the present invention, as another embodiment, a step of detecting a value S _Ram (t _Ram , Δν) corresponding to the intensity of the backward Raman scattered light by the first light,
The above S _B (t, Δν) and the above S _Ram (t _Ram , Δν) are respectively functions P _B (z, Δν) and P _Ram (z,
Δν), and BMR (z, Δν) = P _B (z, Δ
ν) / P _Ram (z, Δν) and all the above steps are performed by changing Δν to maximize the value of BMR (z, Δν) at each position z of the optical fiber. The value of │Δν│, that is, the Brillouin frequency shift ν _B
(Z) is obtained.

The measuring device according to the present invention has not only means for measuring the BOTDA signal due to the Brillouin effect, but also means for measuring the backward Rayleigh scattered light or the backward Raman scattered light, and using the measurement data thereof. It also has a means for correcting.

More specifically, the measuring apparatus of the present invention has, as a first form thereof, at least one of the two lights as pulsed light, the pulsed light as the first light, and the other light as the first light. And a difference between the frequency ν1 of the first light and the frequency ν2 of the second light and a light propagating means for propagating the two lights in an optical fiber in an opposed manner.
With a frequency control means capable of matching the neighborhood value of the Brillouin frequency shift ν _B of the optical fiber, or matching the frequency difference Δν with the neighborhood value of −ν _B , and the above Δν is the neighborhood value of ν _B. In the state where the first light and the second light meet, the increase amount of the power of the second light amplified by the Brillouin effect is used as a signal, or Δν is in the vicinity of −ν _B When the first light and the second light meet at a value, the attenuation amount of the power of the second light attenuated by the Brillouin effect is used as a signal, and the power of the signal is set to the first power. First light and the second light encounter each other after the first light has entered the optical fiber, and the second light amplified or attenuated by the first light is the second light. Until the light of 1 reaches the point of incidence on the optical fiber S _B (t, Δν) relating to various frequency differences Δν, where S _B (t, Δν) is the measurement data measured by the first measurement means and the measurement data measured by the first measurement means. From the data of, the Brillouin frequency shift distribution ν _{B in} the length direction of the optical fiber
In a Brillouin frequency shift measuring device having a calculating means for calculating (z), second measuring means for measuring the power of the backward Rayleigh scattered light by the first light as a function of delay time t _Ray , and the second measuring means. Let S _Ray (t _Ray , Δν) be the measurement data measured by the second measuring means, and
_B (t, Δν) is corrected by S _Ray (t _Ray , Δν), and the calculating means uses the data corrected by the correcting means to shift the Brillouin frequency in the length direction of the optical fiber. The feature is that the distribution ν _B (z) is calculated.

As a second mode, the measuring method of the present invention further comprises second measuring means for measuring the power of the backward Raman scattered light by the first light as a function of the delay time t _Ram , and the second measuring means. S measurement data measured by the measuring means of
_Ram (t _Ram , Δν), and correction means for correcting S _B (t, Δν) with S _Ram (t _Ram , Δν), and the calculation means uses the data corrected by the correction means. It is characterized in that the Brillouin frequency shift distribution ν _B (z) in the length direction of the optical fiber is calculated. next,
The operation of the present invention having the above configuration will be described.

As described above, the frequency difference Δν dependence of the BOTDA signal is dependent on the focused optical fiber section [Zn, Z
[n + dz] due to the Brillouin effect and the Δν dependence of the power of the first optical pulse incident on the optical fiber section are combined. Originally, what should be measured is the above. Therefore, in order to separate these, the present invention uses BO as described above.
In addition to the measurement of the TDA signal, the backward Rayleigh scattered light or the backward Raman scattered light due to the first light pulse in BOTDA is measured. Since the power of the backward Rayleigh scattered light or the backward Raman scattered light is proportional to the power of the first light pulse at the scattering point, the above is obtained from these measured values. Therefore, using the measured data, BOT
Correcting the Δν-dependent measurement of the DA signal allows an accurate Brillouin frequency shift measurement.

This correction is effective for both the Brillouin gain method and the Brillouin loss method, but when it is applied to the Brillouin loss method, as described above, BOTDA is used.
Since the signal increases due to the Brillouin effect, it is possible to improve the measurement accuracy of the Brillouin frequency shift and increase the measurement distance at the same time.

[0022]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

(First Embodiment) First, a measuring method according to a first embodiment of the present invention will be described.

FIG. 1A shows a model of Brillouin frequency shift distribution of an optical fiber for explaining the present invention. The Brillouin frequency shift of the interval [0, z _m ] and the minute interval [z _m , z _m + dz] of interest for measurement is
Let ν _B1 and ν _B2 , respectively. Further, the incident power (intensity) of the first light (pulse) propagated in the opposite direction is P
₁ (incident power from the left side at z = 0) and second
The incident power of the light (continuous light) is P ₂ (incident power from the right side at z = z _m + dz). At this time, the power P ₁ (z, Δ when the first light propagates to a certain position z
ν) is

[0025]

(2) P ₁ (z, Δν) = P ₁ · exp (−α ₁ z) · D (z, Δν) (2) Where Δν is the frequency of the first light ν1 and the second
Difference Δν = ν1-ν2 of the frequency ν2 of the light. α
₁ is the loss coefficient of the optical fiber for the frequency ν1 wave of the first light. Further, D (z, Δν) is the energy exchange between the first light and the second light due to the Brillouin effect generated when the first light propagates in the section [0, z _m ]. It is a power change coefficient indicating that the power of the first light changes when it occurs.

The characteristics of D (z, Δν) are as follows.

When there is no Brillouin effect, D (z,
Δν) = 1.

When Δν = −ν _B , D (z, Δν) has a maximum value, and in the vicinity thereof, as Δν moves away from −ν _B , it gradually approaches 1.

When Δν = ν _B , D (z, Δν) takes a minimum value, and in the vicinity thereof, as Δν moves away from ν _B , it gradually approaches 1.

Since the Brillouin effect increases as z increases, D (z, Δν) also increases when Δν = −ν _B , and D (z, Δν) decreases when Δν = ν _B. To do.

[0031] Thus, the Δν near the -v _B, -v _B -
2 δ → −ν _B −δ → −ν _B → −ν _B + δ →
When changed to −ν _B + 2δ, the first optical power P ₁ (z, Δν) changes as shown by the curve 1 → 2 → 3 → 2 → 1 as shown in FIG. . Further, in the vicinity of the _{Δν ν B, -ν B -2δ →} -ν B -δ → -ν B
When changed to → −ν _B + δ → −ν _B + 2δ, as shown in the diagram (c) of FIG. 1, as shown in the curve 1 → 4 → 5 → 4 → 1, the first optical power P ₁ (z , Δν) changes.

In this way, the first light whose power changes with respect to Δν enters the minute section [z _m , z _m + dz] and changes the power of the second light by the Brillouin effect. The second light propagates in the section [0, z _m ], reaches the position 0, and is detected by the photodetector (9 in FIGS. 3 and 4) described later. At this time, the absolute value of the change in the power of the second light becomes the BOTDA signal. Minute section [z _m , z _m
+ Dz] BOTDA signal P _B based on Brillouin effect
(Z _m , Δν) is as follows.

[0033]

P _B (z _m , Δν) = P ₁ (z _m , Δν) ・ P ₂・ g (Δν, ν _B2 ) ・ dz ・ exp (-α ₂ z _m ) / A (3) where , G (Δν, ν _B ) is the Brillouin gain,
It is known to exhibit Lorentz type characteristics as shown below.

[0034]

G (Δν, ν _B ) = g ₀ · (Δν _B / 2) ² / {(| Δν | -ν _B ) ² + (Δν _B / 2) ² } (4) where g ₀ Is a Brillouin gain coefficient that represents the Brillouin gain when | Δν | = ν _B , and Δν _B is called the Brillouin line width.

From equations (3) and (4), | Δν | is ν _B
It can be seen that the Brillouin effect occurs efficiently in the frequency region of width Δν _B centered at. When the Brillouin line width Δν _B of the optical fiber was measured at a wavelength of 1.55 μm, the value was about 40 MHz.

Further, α ₂ in the equation (3) is a loss coefficient of the optical fiber with respect to the frequency ν ₂ of the second light. Further, A is the effective area of the core of the optical fiber.

Substituting equation (2) into equation (3),

[0038]

P _B (z _m , Δν) = P ₁ · P ₂ · exp (-α ₁ z _m -α ₂ z _m ) ・ dz ・ D (z _m , Δν) ・ g (Δν, ν _B2 ) / A (5).

In the BOTDA measurement, the change amount of Δν is about 1 GHz at most, so α ₁ and α _{2 at} that time are changed.
The frequency (wavelength) dependence of is negligible. Therefore, BOT
The Δν dependence of the DA signal P _B (z _m , Δν) is expressed by the equation (5).
As can be seen from, D (z _m , Δν) · g (Δν,
ν _B2 ). FIG. 2 shows this state by taking the case of the Brillouin loss method as an example. Figure 2 (a)
The figure shows D (z _m , Δν) and g (Δν, ν _B2 ) respectively.

FIG. 2B shows the BOTDA signal P.
_This shows the dependence of _B (z _m , Δν) on Δν. As can be seen from FIG. 2B, the value of Δν at which the BOTDA signal has the maximum value is ν _m , and this value ν _m is the true Brillouin frequency shift in the minute section [z _m , z _m + dz]. It is different from the value ν _B2 . That is, it can be seen that the systematic measurement error of the Brillouin frequency shift occurs when the BOTDA signal increasing effect in the Brillouin loss method is used.

In the first embodiment of the present invention described later, this systematic measurement error is corrected using the measurement data of the backward Rayleigh scattered light. When the backward Rayleigh scattered light from the section [z, z + dz] by the first light (pulse light) is measured at the incident end of the first light, its reception power P
_Ray (z, Δν) can be expressed by the following equation, as is well known.

[0042]

[6] _{P Ray (z, Δν) =} P 1 (z, Δν) · R Ray · dz · exp (-α 1 z) (6) where R _Ray is backward Rayleigh scattering coefficient. Therefore, the minute section [z _m , z _m + in FIG.
The received power of the backward Rayleigh scattered light from dz] can be calculated from the equations (2) and (6) as follows.

[0043]

P _Ray (z _m , Δν) = P ₁ · exp (−2α ₁ z _m ) · R _Ray · dz · D (z _m , Δν) (7)

Next, the BOTDA signal P _B (z _m , Δν)
And the ratio of the backward Rayleigh scattered light signal R _Ray (z _m , Δν) (= BYR (z _m , Δν)), from Equation (5) and Equation (7),

[0045]

BYR (z _m , Δν) = P _B (z _m , Δν) / P _Ray (z _m , Δν) = P ₂ · exp (α ₁ z _m −α ₂ z _m ) · g (Δν, We obtain ν _B2 ) / (A · R _Ray ) (8). By taking the ratio of the two in this way, D
Since the term of (z _m , Δν) is canceled (erased),
The only term that has a dependency on Δν included in BYR (z _m , Δν) is g (Δν, ν _B2 ). Therefore, BYR (z
By measuring Δν that takes the maximum value of _m , Δν),
It is possible to accurately measure the Brillouin frequency shift value ν _B2 in the section [z _m , z _m + dz].

In the above description, the section to be measured is
Although it is limited to [z _m , z _m + dz], any interval [z, z
It is easily understood that the Brillouin frequency shift can be accurately measured in the same manner with + dz].

Further, in the above description, the BOTDA signal and the backward Rayleigh scattered light signal are expressed as a function of the position z, but the directly measured values are the functions of time S _B (t, Δν) and S, respectively. _Ray (t _Ray , Δν). Here, t and t _Ray are connected to the position z in the following relationship.

[0048]

T = (1 / V ₁ + 1 / V ₂ ) z (9) t _Ray = (2 / V ₁ ) z (10) Therefore, the measured values S _B (t, Δν) and S
_Ray (t _Ray , Δν) is given by equation (9) and equation (1), respectively.
0), and the position function P _B (z, Δν) = S
_B ((1 / V ₁ + 1 / V ₂ ) z, Δν) and P
_Ray (z, Δν) = S _Ray ((2 / V ₁ ) z, Δν) is converted to a ratio BYR (z, Δν) = equal to Equation (8).
P _B (z, Δν) / P _Ray (z, Δν) will be obtained. Then, at each position z, BYR (z, Δν)
It is possible to accurately measure the Brillouin frequency shift distribution ν _B (z) by obtaining | Δν | that maximizes the value of.

However, in reality, since V ₁ and V ₂ are close to each other, that is, t and t _Ray are close to each other, the ratio of the functions of time (= S _B (t, Δν) / S _Ray (t _Ray) , Δν))
There is no problem in deriving the equation (9) or substituting the equation (10) into BYR (z, Δν).

FIG. 3 shows the configuration of the measuring apparatus according to the first embodiment of the present invention, which executes the above-described measuring method of the present invention.

In FIG. 3, 1 is a first narrow linewidth light source with a narrow oscillation linewidth, 2 is an optical pulse modulator for converting continuous light from the narrow linewidth light source 1 into optical pulses (first light), Reference numeral 3 is an optical directional coupler that is optically coupled (optically coupled) with the optical pulse modulator 2, and 4 is an optical fiber that is optically coupled with the optical directional coupler 3 at one end. Numeral 5 is a second oscillating line width that generates the second light
Narrow linewidth light source of the optical fiber 4 facing the first light.
The second light is incident from the other end of the. 6 is a frequency control for controlling the frequency of the first narrow line width light source 1 and the second narrow line width light source 5, or the frequency difference between the first narrow line width light source 1 and the second narrow line width light source 5. It is a device. 7 is an optical branching device,
Light (including backscattered light) incident from the optical fiber 4 is branched into two through the optical directional coupler 3.

Reference numeral 8 is a first optical filter which transmits only the second light in the incident light from the optical branching device 7, and 9 is the second light which has passed through the first optical filter 8 and receives the electric light. A first photodetector for converting into a signal, 10 is a first amplifier for amplifying the converted electric signal to a predetermined level, 11 is a first AD converter for converting the amplified analog signal into a digital signal, 12 Is a first averaging processor for obtaining the average value of the digital signal.

Further, 13 is a second optical filter that passes only the backward Rayleigh scattered light of the first light in the incident light from the optical branching device 7, and 14 is the backward Rayleigh that has passed through the second optical filter 13. The second that receives scattered light and performs photoelectric conversion
Photodetector, 15 is a second amplifier for amplifying the converted electric signal to a predetermined level, 16 is a second AD converter for converting the amplified analog signal into a digital signal, 17
Is a second averaging processor for obtaining the average value of the digital signal. 18 is the first and second averaging processing devices 12,
This is a digital signal processing device that calculates the Brillouin frequency shift distribution by performing the arithmetic processing according to the above equations (9) and (10) based on the measurement data supplied from 17. As the digital signal processing device 18, for example, a personal computer (personal computer) can be used.

In the present invention, at least one of the first light and the second light propagating in opposition to the optical fiber 4 is pulsed light.

The continuous light output from the first narrow line width light source 1 is converted into pulsed light by the optical pulse modulator 2. This pulsed light is the first light as described above. The first light is incident on the optical fiber 4 via the optical directional coupler 3.
At the same time, the output light of the second narrow line width light source 5 (this light is referred to as the second light) is propagated so as to be opposed to the first light.
It is incident on the optical fiber 4. Further, the frequency controller 6 controls the frequency difference Δν = ν1-ν2 between the frequency ν1 of the first light and the frequency ν2 of the second light, and Δν is -ν _B (ν
_B is set to a value near the Brillouin frequency shift of the optical fiber 4. At this time, as described above, the first
When the first light and the second light meet, the BOTDA signal, which uses the amount of power attenuation of the second light attenuated by the first light due to the Brillouin effect as a signal, is incident on the first light. It can be observed at the fiber end.

In order to extract this BOTDA signal, the second light emitted from the optical fiber 4 is separated from the first light by the optical directional coupler 3, and a part of the second light is divided by the optical branching device 7. To the first optical filter 8. The first optical filter 8 transmits the second light but has a characteristic of blocking the light of a different frequency, for example, the light of the same frequency as the first light reflected or scattered in the optical fiber 4. Have. Such optical filter characteristics can be realized by a Fabry-Perot etalon, fiber grating, dielectric multilayer film, or the like. The second light transmitted through the first optical fiber 8 is
The signal is converted into an electric signal by the first photodetector 9, amplified to a desired (predetermined) magnitude by the first amplifier 10, and then converted into a digital signal by the first AD converter. The digital signal is averaged by the first averaging processor 12 a desired (predetermined) number of times. This averaged BOTDA signal is S _B (t, Δν). The digital signal processing device 18 uses the equation (9) to convert the signal S _B (t, Δν) into a function P _B (z, Δν) of the position z.
Convert to.

In the present invention, the backward Rayleigh scattered light by the first light is also measured in parallel with the above measurement of the BOTDA signal. The backward Rayleigh scattered light by the first light, which is scattered backward in the optical fiber 4, is guided to the second optical filter 13 via the optical directional coupler 3 and the optical branching device 7.
The second optical filter 13 has a characteristic of allowing the backward Rayleigh scattered light of the first light to pass therethrough, but blocking the light of a different frequency, for example, the second light. Such characteristics can be realized by a Fabry-Perot etalon, a fiber grating, a dielectric multilayer film, or the like. The backward Rayleigh scattered light that has passed through the second optical filter 13 is converted into an electric signal by the second photodetector 14 and amplified by the second amplifier 15 to a desired (predetermined) magnitude, and then the second AD.
It is converted into a digital signal by the converter 16. The digital signal is averaged by the second averaging processor 17 a desired (predetermined) number of times. This averaged signal is S _Ray (t _Ray , Δν). Digital signal processor 18 uses equation (10) to _calculate the signal S _Ray (t
_Ray , Δν) is transformed into a function P _Ray (z, Δν) of the position z.

The digital signal processor 18 measures P _B (z, Δν) and P _Ray (z, Δ) thus measured.
BYR (z, Δν) = P _B (z, Δ
ν) / P _Ray (z, Δν) is calculated (see the above equation (8)).

The above measurement is performed by the digital signal processing device 1
The first light and the second light are controlled by the frequency controller 6 under the control of 8.
By changing the frequency difference Δν of the light of
BYR (z, Δν) at each position z of the optical fiber 4
The value of | Δν | that maximizes the value of, that is, the Brillouin frequency shift ν _B (z) can be accurately obtained.

Particularly, in the case of the Brillouin loss method (Δν is −
(approx. ν _B ), the first light is amplified by the second light due to the Brillouin effect as it propagates through the optical fiber 4, and the optical power (light intensity) of the first light increases. The BOTDA signal and the backward Rayleigh scattered light by the first light also increase, and as a result, highly accurate measurement is possible.

In addition to the signal processing described above, the digital signal processing device 18 includes the optical pulse modulator 2 and the first A
D converter 11, first averaging processing device 12, second AD
A timing signal is also supplied to the converter 16 and the second averaging processor 17.

In the first embodiment described above, the second optical filter 13 is used to separate the backward Rayleigh scattered light component from other light components. However, it goes without saying that instead of the optical filter 13, the backward Rayleigh scattered light may be detected by coherent detection (optical heterodyne detection or optical homodyne detection) and separated from the signal of other light components by an electrical filter. Yes.

(Second Embodiment) Next, a measuring method according to a second embodiment of the present invention will be described.

In the second embodiment of the present invention, the systematic measurement error described above is corrected by using backward Raman scattered light.
When the backward Raman scattered light from the section [z, z + dz] due to the first light (pulse light) is measured at the incident end, its reception power P _Ram (z, Δν) can be expressed by the following equation.

[0065]

Equation 10] _{P Ram (z, Δν) =} P 1 (z, Δν) · R Ram · dz · exp (-α 3 z) (11) where R _Ram is a backward Raman scattering coefficient. Also, α
₃ is the loss coefficient of the optical fiber 4 at the frequency of the backward Raman light. At this time, a minute section [z _m , z _m + dz]
The received power of the backward Raman scattered light from is calculated from Equation (2) and Equation (11),

[0066]

P _Ram (z _m , Δν) = P ₁ · exp (−α ₁ z _m −α ₃ z _m ) · R _Ram · dz · D (z _m , Δν) (12)

Next, the BOTDA signal P _B (z _m , Δν)
And the ratio of the backward Raman scattered light signal P _Ram (z _m , Δν) (=
Taking BMR (z _m , Δν)), equation (5) and equation (1
From 2)

[0068]

## EQU12 ## BMR (z _m , Δν) = P _B (z _m , Δν) / P _Ram (z _m , Δν) = P ₂・ exp (α ₃ z _m -α ₂ z _m ) ・ g (Δν, ν _B2 ) / (A · R _Ram ) (13) is obtained. In the BOTDA measurement, as described above, the change amount of Δν is at most about 1 GHz, so α _{3 at} that time is
The frequency (wavelength) dependence of α ₂ and α ₂ can be ignored. Therefore, by taking the ratio of the two, the term of D (z _m , Δν) is canceled and Δ contained in BMR (z _m , Δν).
The only term that has a dependence on ν is g (Δν, ν _B2 ).
Therefore, it is possible to accurately measure the Brillouin frequency shift value ν _B2 in the section [z _m , z _m + dz] by measuring Δν that takes the maximum value of BMR (z _m , Δν).

In the above description, the section to be measured is
Although it is limited to [z _m , z _m + dz], any interval [z, z
It is easily understood that the Brillouin frequency shift can be accurately measured in the same manner with + dz].

Further, in the above description, the BOTDA signal and the backward Raman scattering signal are expressed as a function of the position z, but the directly measured values are the functions of time S _B respectively.
(T, Δν) and S _Ram (t _Ray , Δν). Here, t is connected to the position z by the relationship of the above-mentioned expression (9). On the other hand, t _Ram is connected to the position z in the following relationship.

[0071]

T _Ram = (1 / V ₁ + 1 / V ₃ ) z (14) Here, V ₃ is the speed of light in the optical fiber 4 at the wavelength of the backward Raman scattered light. Therefore, the measured value S _B (t, Δ
ν) and S _Ram (t _Ram , Δν) are respectively given by equation (9).
And the equation (14) are substituted, and the position function P _B (z, Δ
ν) = S _B ((1 / V ₁ + 1 / V ₂ ) z, Δν), and P _Ram (z, Δν) = S _Ram ((1 / V ₁ + 1 /
V ₃ ) z, Δν) and the ratio B corresponding to equation (13)
MR (z, Δν) = P _B (z, Δν) / P _Ram (z, Δ
ν). Then, at each position z, B
By obtaining | Δν | that maximizes the value of MR (z, Δν), it is possible to accurately measure the Brillouin frequency shift distribution ν _B (z).

When the length of the optical fiber 4 is short, since t is close to t _Ram , the ratio of the functions of time (= S
_{Even if B} (t, Δν) / S _Ram (t _Ram , Δν)) is found and the obtained value is substituted into equation (9) or equation (14), it is regarded as BMR (z, Δν). There is no. However, unlike the first embodiment, when the length of the optical fiber 4 is long, t cannot be regarded as almost the same as t _Ram . This is because the frequency of the backward Raman scattered light largely shifts from the frequency of the first light that is the incident light, and thus V ₃ cannot be approximated by V ₁ . Incidentally, in the case of the quartz optical fiber, this shift amount is about 13 THz (about 100 nm in terms of wavelength). Therefore, in the second embodiment of the present invention, when the length of the optical fiber 4 is long, the ratio BMR (z, Δν) is obtained after the conversion from the function of time to the function of position described above. There is a need.

The backward Raman scattered light has Stokes light whose wavelength shifts to the long wavelength side (that is, the frequency becomes lower than that of the incident light) and conversely shifts to the short wavelength side (that is, the frequency of that of the incident light). There is anti-Stokes light. In the present invention, a combination of both may be measured, or only one of them may be measured. However, in the case of measuring a combination of both, if the length of the optical fiber 4 is long, the time difference between the Stokes light and the anti-Stokes light propagating in the optical fiber 4 becomes large and the distance resolution deteriorates. The problem arises. In addition, the power of Stokes light is generally larger than that of anti-Stokes light, and the former is about 5 times that of the latter at room temperature. Further, the difference becomes larger as the temperature becomes lower. Therefore, it is most desirable to use only Stokes light.

Further, comparing the first embodiment of the present invention utilizing the backward Rayleigh scattered light with the second embodiment of the present invention utilizing the backward Raman scattered light, the latter has the following features. There is.

The power of the backward Raman scattered light is at a level that is two or three orders of magnitude lower than that of the backward Rayleigh scattered light. However, when light from a narrow line width light source is used as the first light as in the present invention, fading noise occurs in the backward Rayleigh scattered light. The amplitude of this noise reaches a level comparable to the average level of backscattered light and fluctuates with time. Therefore, fading noise causes a large measurement error. On the other hand, such fading noise does not occur in the backward Raman scattered light. This is because (a) backward Raman scattered light is generated by thermal disturbance, and fading noise is averaged naturally, so that (b) and the backward Raman scattered light have a wide spectral line width (in the case of a quartz optical fiber, This is because averaging regarding wavelength is performed. Therefore, rather than using backscattered Rayleigh light with a large level,
Higher precision measurement is possible by using the backward Raman scattered light.

FIG. 4 shows the configuration of a measuring apparatus that executes the measuring method according to the second embodiment of the present invention described above.

In FIG. 4, reference numeral 19 denotes a third optical filter having a characteristic of allowing the backward Raman scattered light of the first light to pass therethrough but blocking the light of a frequency different from this, for example, the second light. 3 except that a third filter 19 is provided instead of the second filter 13.
The configuration is the same as that of the first embodiment, and the same reference numerals have the same functions, and thus detailed description thereof is omitted.

As described above, all the other components except the third optical filter 19 are the same as those of the first embodiment shown in FIG. Therefore, the BOTDA signal measurement is the first
This is exactly the same as the case of the above embodiment. On the other hand, the measurement of backward Raman scattered light is performed as follows. That is, the backward Raman scattered light by the first light, which is scattered backward in the optical fiber 4, is guided to the third optical filter 19 via the optical directional coupler 3 and the optical branching device 7. Third optical filter 1
9 allows the backward Raman scattered light by the first light to pass,
The light having a different frequency, for example, the second light has a characteristic of being blocked. Such characteristics can be realized by a dielectric multilayer film or fiber grading.

The backward Raman scattered light transmitted through the third optical filter 19 is converted into an electric signal by the second photodetector 14 and amplified by the second amplifier 15 to a desired (predetermined) magnitude, and then the It is converted into a digital signal by the A / D converter 16 of 2. The digital signal is averaged by the second averaging processor 17 a desired (predetermined) number of times. This averaged signal is S _Ram (t _Ram , Δ
ν). The digital signal processing device 18 uses the equation (1
4) is used to transform the signal S _Ram (t _Ram , Δν) into the function P _Ram (z, Δν) at position z.

The digital signal processor 18 measures P _B (z, Δν) and P _Ram (z, Δν) thus measured.
BMR (z, Δν) = P _B (z, Δν) /
Calculate P _Ram (z, Δν).

The above measurement is performed by the digital signal processing device 1
Under the control of 8, the frequency control device 6 sequentially changes the frequency difference Δν between the first light and the second light to perform the operation, so that at each position z of the optical fiber 4, BMR (z,
The value of | Δν | that maximizes the value of Δν, that is, the Brullian frequency shift ν _B (z) can be accurately obtained.

In particular, when the Brillouin loss method is adopted (when Δν and −ν _B are almost the same), the first light propagates through the optical fiber 4 and is amplified by the second light by the Brillouin effect. Since the optical power increases, B
The back Raman scattered light by the OTDA signal and the first light is also increased, and as a result, highly accurate measurement is possible.

In particular, when the third optical filter 19 has a characteristic of allowing the Stokes light component of the backward Raman scattered light to pass but blocking the light of other wavelengths including the anti-Stokes light, Because of
It is possible to measure the Brillouin frequency shift distribution over a long distance with higher accuracy.

[0084]

As described above, according to the present invention,
The frequency difference Δν dependence of the backward Rayleigh scattered light power or the backward Raman scattered light power between the two lights (first light and second light) is measured, and the measured data is used to measure the Δν dependence of the BOTDA signal. As a result, the Brillouin frequency distribution of the optical fiber can be accurately measured over a long distance.

[Brief description of drawings]

FIG. 1A is a diagram showing a model of an optical fiber for explaining the present invention, and FIG. 1B is a diagram showing a change in power of first light in the Brillouin loss method.
FIG. 6C is a diagram showing a change in the power of the first light in the Brillouin gain method.

FIG. 2A is a power variation coefficient D (z _m , Δν) and a normalized Brian gain g (Δν, ν _B2 ) / g ₀ | Δ.
[nu | is a diagram showing the dependence, (b) is, BOTDA signal P _B (z _m, Δν) of | .DELTA..nu | is a diagram showing the dependence.

FIG. 3 is a block diagram showing a configuration of a measuring device according to a first embodiment of the present invention.

FIG. 4 is a block diagram showing a configuration of a measuring device according to a second embodiment of the present invention.

[Explanation of symbols]

1 First narrow linewidth light source 2 Optical pulse modulator 3 Optical directional coupler 4 optical fiber 5 Second narrow linewidth light source 6 Frequency control device 7 Optical splitter 8 First optical filter 9 First photodetector 10 First amplifier 11 First AD converter 12 First averaging processor 13 Second optical filter 14 Second photodetector 15 Second amplifier 16 Second AD converter 17 Second averaging processor 18 Digital signal processor 19 Third optical filter

Continuation of the front page (56) Reference JP-A-6-230091 (JP, A) JP-A-6-273270 (JP, A) JP-A-2-6725 (JP, A) JP-A-5-172657 (JP , A) JP-A-8-54257 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) G01K 11/12 G01B 11/16 G01L 1/24

Claims (11)

(57) [Claims] 1. Two lights are made to propagate in an optical fiber so as to oppose each other, at least one of the two lights is pulsed light, the pulsed light is first light, and the other light is second light. And the frequency ν1 of the first light and the frequency ν2 of the second light
The difference Δν = ν1-ν2 of the optical fiber is matched with a value near the Brillouin frequency shift ν _B of the optical fiber, and in that state, when the first light and the second light meet, the first light causes The increased amount of the amplified power of the second light is used as a signal, or the difference Δν = ν1-ν2 between the frequency ν1 of the first light and the frequency ν2 of the second light is set to a value near −ν _B. When the first light and the second light meet in that state, the power attenuation amount of the second light attenuated by the first light is used as a signal, and the signal The power of the first light is incident on the optical fiber, and then the first light and the second light meet and are amplified or attenuated by the first light. 2 is a function of the delay time t for the second light to reach the point where the first light is incident on the optical fiber And measured,
Let this measured value be S _B (t, Δν),
_{A method} of measuring _B (t, Δν) for various Δν and measuring the Brillouin frequency shift distribution ν _B (z) as a function of the position z in the longitudinal direction of the optical fiber based on the measured data, The power of the backward Rayleigh scattered light by the first light is measured as a function of the delay time t _Ray , and the measured value is S
_Ray (t _Ray , Δν), and S _B (t, Δν) is corrected by the S _Ray (t _Ray , Δν) from the signal, and the Brillouin frequency shift distribution ν _B (z) in the length direction of the optical fiber is obtained. A Brillouin frequency shift distribution measuring method, which comprises: 2. Two lights propagating in an optical fiber in opposition to each other, at least one of the two lights being pulsed light, the pulsed light being first light, and the other light being second light. And the frequency ν1 of the first light and the frequency ν2 of the second light
The difference Δν = ν1-ν2 of the optical fiber is matched with a value near the Brillouin frequency shift ν _B of the optical fiber, and in that state, when the first light and the second light meet, the first light causes The increased amount of the amplified power of the second light is used as a signal, or the difference Δν = ν1-ν2 between the frequency ν1 of the first light and the frequency ν2 of the second light is set to a value near −ν _B. When the first light and the second light meet in that state, the power attenuation amount of the second light attenuated by the first light is used as a signal, and the signal The power of the first light that has been amplified by the first light or has been attenuated by the first light after the first light has entered the optical fiber. 2 is a function of the delay time t for the second light to reach the point where the first light is incident on the optical fiber And measured,
Let this measured value be S _B (t, Δν),
_{A method} of measuring _B (t, Δν) for various Δν and measuring the Brillouin frequency shift distribution ν _B (z) as a function of the position z in the length direction of the optical fiber based on the measured data, The power of the backward Raman scattered light by the first light is measured as a function of the delay time t _Ram , that is, the position z along the length of the optical fiber, and the measured value is S.
_Ram (t _Ram , Δν), and the S _B (t, Δν) is corrected by the S _Ram (t _Ram , Δν) to obtain a Brillouin frequency shift distribution ν _B (z) in the length direction of the optical fiber. A Brillouin frequency shift distribution measuring method, which comprises: 3. At least one of the two lights is pulsed light, the pulsed light is first light, the other light is second light, and the two lights are opposed to an optical fiber. A light propagating means for propagating, a frequency ν1 of the first light and a frequency ν2 of the second light
Frequency control means capable of matching the difference Δν = ν1-ν2 of the optical fiber to a value near the Brillouin frequency shift ν _B of the optical fiber, or the frequency difference Δν to a value near the −ν _B of the optical fiber; Is a value near the ν _B , and when the first light and the second light meet, the increase amount of the power of the second light amplified by the Brillouin effect is used as a signal,
Alternatively, the amount of attenuation of the power of the second light that is attenuated by the Brillouin effect when the first light and the second light meet while the Δν is a value near −ν _B is signaled. And the power of the signal is amplified by the first light after the first light is incident on the optical fiber, the first light and the second light encounter each other, or
First measuring means for measuring the attenuated second light as a function of a delay time t until the first light reaches a point where the first light is incident on an optical fiber; and the first measuring means. S to the measured data
_B (t, Δν) and then, S _B for the various frequency difference .DELTA..nu
In a Brillouin frequency shift measuring device having a calculating means for calculating a Brillouin frequency shift distribution ν _B (z) in the length direction of the optical fiber from the data of (t, Δν), the rear Rayleigh by the first light is used. Second measuring means for measuring the power of the scattered light as a function of the delay time t _Ray , and the measurement data measured by the second measuring means S
_Ray (t _Ray , Δν), and S _B (t, Δν) is corrected by the S _Ray (t _Ray , Δν), and the calculation unit calculates from the data corrected by the correction unit. A Brillouin frequency shift distribution measuring device for calculating a Brillouin frequency shift distribution ν _B (z) in the length direction of the optical fiber. 4. At least one of the two lights is pulsed light, the pulsed light is first light, the other light is second light, and the two lights are opposed to an optical fiber. A light propagating means for propagating, a frequency ν1 of the first light and a frequency ν2 of the second light
Frequency control means capable of matching the difference Δν = ν1-ν2 of the optical fiber to a value near the Brillouin frequency shift ν _B of the optical fiber, or the frequency difference Δν to a value near the −ν _B of the optical fiber; Is a value near the ν _B , and when the first light and the second light meet, the increase amount of the power of the second light amplified by the Brillouin effect is used as a signal,
Alternatively, the amount of attenuation of the power of the second light that is attenuated by the Brillouin effect when the first light and the second light meet while the Δν is a value near −ν _B is signaled. And the power of the signal is amplified by the first light after the first light is incident on the optical fiber, the first light and the second light encounter each other, or
First measuring means for measuring the attenuated second light as a function of a delay time t until the first light reaches a point where the first light is incident on an optical fiber; and the first measuring means. S to the measured data
_B (t, Δν) and then, S _B for the various frequency difference .DELTA..nu
A Brillouin frequency shift measuring device having a calculating means for calculating a Brillouin frequency shift distribution ν _B (z) in the length direction of the optical fiber from the data of (t, Δν), wherein the backward Raman by the first light is used. Second measuring means for measuring the power of scattered light as a function of the delay time t _Ram , and S for measuring data measured by the second measuring means.
_Ram (t _Ram , Δν), and correction means for correcting the S _B (t, Δν) by the S _Ram (t _Ram , Δν), and the computing means uses the data corrected by the correction means. A Brillouin frequency shift distribution measuring device for calculating a Brillouin frequency shift distribution ν _B (z) in the length direction of the optical fiber. 5. The Brillouin frequency shift distribution measuring method according to claim 2, wherein the backward Raman scattered light is Stokes light. 6. The Brillouin frequency shift distribution measuring device according to claim 4, wherein the backward Raman scattered light is Stokes light. 7. The first light of pulsed light is made incident from one end of the optical fiber and at the same time the second light is made incident from the other end of the optical fiber to propagate the first light and the second light in opposition. And a frequency ν1 of the first light and a frequency ν2 of the second light.
Difference Δν = ν1-ν2 to a value near −ν _B or ν _B (ν _B is the Brillouin frequency shift of the optical fiber), and a value corresponding to the amount of change in the power of the second light due to the Brillouin effect. Detecting S _B (t, Δν), detecting a value S _Ray (t _Ray , Δν) corresponding to the intensity of the backward Rayleigh scattered light by the first light, and S _B (t, Δν) , S _Ray (t _Ray , Δν) are functions P _B (z, Δν) and P _Ray (z,
ΔR), and BYR (z, Δν) = P _B (z, Δν) / P _Ray (z,
Δν) is calculated, and all of the above steps are performed by changing Δν, and the value of | Δν | that maximizes the value of BYR (z, Δν) at each position z of the optical fiber, that is, Brillouin And a step of obtaining a frequency shift ν _B (z). 8. The first light of pulsed light is made incident from one end of the optical fiber, and at the same time the second light is made incident from the other end of the optical fiber to propagate the first light and the second light in opposition. And a frequency ν1 of the first light and a frequency ν2 of the second light.
Difference Δν = ν1-ν2 to a value near −ν _B or ν _B (ν _B is the Brillouin frequency shift of the optical fiber), and a value corresponding to the amount of change in the power of the second light due to the Brillouin effect. Detecting S _B (t, Δν); detecting a value S _Ram (t _Ram , Δν) corresponding to the intensity of the backward Raman scattered light by the first light; and S _B (t, Δν) , S _Ram (t _Ram , Δν) are functions P _B (z, Δν) and P _Ram (z,
ΔMR), BMR (z, Δν) = P _B (z, Δν) / P _Ram (z,
Δν) is calculated, and all of the above steps are performed by changing Δν, and the value of | Δν | that maximizes the value of BMR (z, Δν) at each position z of the optical fiber, that is, Brillouin And a step of obtaining a frequency shift ν _B (z). 9. The first light of pulsed light is made incident from one end of the optical fiber and at the same time the second light is made incident from the other end of the optical fiber to propagate the first light and the second light in opposition to each other. A light propagating means for causing the frequency ν1 of the first light and the frequency ν2 of the second light
The difference Δν = ν1−ν2 between −ν _{B and} ν _B (ν _B is a Brillouin frequency shift of the optical fiber) in the vicinity of the frequency control means, and the power change amount of the second light due to the Brillouin effect. Detecting means S _B (t, Δν) and second detecting means detecting a value S _Ray (t _Ray , Δν) corresponding to the intensity of the backward Rayleigh scattered light by the first light. , S _B (t, Δν) and S _Ray (t _Ray , Δν) are functions P _B (z, Δν) and P _Ray (z,
ΔR), and BYR (z, Δν) = P _B (z, Δν) / P _Ray (z,
[Delta] [nu]) for calculating all of the above processing by changing [Delta] [nu] via the frequency control means, and performing BYR (z, [Delta] [nu] at each position z of the optical fiber. ) Value that maximizes the value of), that is, the Brillouin frequency shift ν
A Brillouin frequency shift distribution measuring device characterized by obtaining _B (z). 10. The first pulsed light is emitted from one end of the optical fiber.
A light propagating means for injecting light and at the same time for injecting second light from the other end of the optical fiber to propagate the first light and the second light in opposition, and a frequency ν1 of the first light. Frequency of the second light ν2
The difference Δν = ν1−ν2 between −ν _{B and} ν _B (ν _B is a Brillouin frequency shift of the optical fiber) in the vicinity of the frequency control means, and the power change amount of the second light due to the Brillouin effect. Detecting means for detecting a value S _B (t, Δν) and a second detecting means for detecting a value S _Ram (t _Ram , Δν) corresponding to the intensity of the backward Raman scattered light by the first light. , S _B (t, Δν) and S _Ram (t _Ram , Δν) are functions P _B (z, Δν) and P _Ram (z,
ΔMR), BMR (z, Δν) = P _B (z, Δν) / P _Ram (z,
[Delta] [nu]) for calculating the BMR (z, at each position z of the optical fiber by performing [Delta] [nu] via the frequency control means to perform all of the above processing. The value of | Δν | that maximizes the value of Δν, that is, the Brillouin frequency shift ν _B
A Brillouin frequency shift distribution measuring device characterized by obtaining (z). 11. The Brillouin frequency shifter according to claim 10, wherein the second detection unit has an optical filter or a coherent detection unit that passes only the Stokes light component of the backward Raman scattered light. Distribution measuring device.