JP2013072800A - Vibration detection system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To detect vibrations at a part provided with an optical fiber.SOLUTION: In an optical fiber earthquake detection system 1, an optical pulse tester 2 is connected to an existing optical cable 4, makes an optical pulse (optical signal) be incident on an unused one-core optical fiber in the optical cable 4, monitors a level (intensity) of the optical pulse, and transmits optical level data which is a result of the monitoring to an earthquake detector 3. The earthquake detector 3 receives the optical level data in the optical cable 4 from the optical pulse tester 2, determines the intensity of an earthquake occurring at a pertinent part on the basis of an attenuation part in the optical level data, and displays the intensity of the earthquake for each part. In an optical cable 4a attached to an electric pole 5a, a slack part 4a1 wound in order to avoid congestion is present. In an optical cable 4b attached to an electric pole 5b, a bent part 4b1 bent due to arrangement of the electric pole 5b is present. Attenuation of the optical pulses at such parts is detected, and the intensity of the earthquake is detected.

Description

  The present invention relates to a system for detecting vibrations such as earthquakes by utilizing the extra length of an optical fiber.

  Conventionally, various methods for detecting earthquakes and their signs using optical fibers have been proposed. For example, Patent Documents 1 and 2 disclose a method of measuring a weak ground current with high accuracy by utilizing the fact that the polarization fluctuation of an optical signal transmitted through an optical fiber changes due to the ground current flowing through an overhead ground wire. And a system thereof is disclosed.

JP 2006-046938 A JP 2010-249848 A

  Since the techniques of Patent Documents 1 and 2 use the fact that the optical signal of the optical fiber is affected by the ground current of the overhead ground wire, it is assumed that the overhead ground wire and the optical fiber are integrated. Become. On the other hand, in the distribution pole erected in the urban area, the overhead ground wire and the optical fiber are separated, so that it is difficult to apply the above technique. Therefore, it is desirable to detect vibrations such as earthquakes using only optical fibers.

  The present invention has been made in view of the above-described problems, and its main purpose is to detect vibration at a location where an optical fiber is provided.

  In order to solve the above-described problems, the present invention provides a vibration detection system that detects vibration using an existing optical fiber having a swingable curved portion, and is a light that is the intensity of an optical signal in the optical fiber. Means for acquiring a position distribution of attenuation of intensity, means for specifying a location where the attenuation amount of light intensity is greater than or equal to a predetermined value based on the acquired position distribution of attenuation of light intensity, and the specified location And a means for outputting that the object supporting the optical fiber vibrates.

  According to this configuration, in the optical fiber, when the curvature of a certain portion exceeds the threshold value and the optical signal passing through the inside does not totally reflect (that is, reflection leakage occurs), the intensity of the optical signal (light intensity) Is attenuated. Then, when the support of the optical fiber vibrates in the portion bent in advance, the curvature of the portion tends to exceed the threshold value, that is, the light intensity tends to attenuate. Therefore, the position distribution of the attenuation of the light intensity in the optical fiber having the curved portion is acquired, and if the light intensity is attenuated by a predetermined value or more, the support of the optical fiber (for example, a power pole or the like) is more than a predetermined value at that location. You can see that it vibrates. According to this, the vibration of the location where the optical fiber was provided can be detected.

  Further, in the vibration detection system of the present invention, means for storing optical fiber characteristic data in which the attenuation amount and the seismic intensity of the earthquake that is the cause of the vibration are associated with each other at the position of each curved portion of the optical fiber; A means for identifying the seismic intensity from the attenuation amount at the identified location based on the optical fiber characteristic data; and an earthquake output means for outputting that an earthquake having the identified seismic intensity has occurred at the identified location; , May be further provided.

  According to this configuration, in preparation for the case where the vibration of the support of the optical fiber is caused by an earthquake, the relationship between the attenuation of light intensity and the seismic intensity in each curved portion of the optical fiber is specified in advance. . That is, the curve portion differs in the initial curvature, the position of the support, the height of the support point, and the like, and the amount of attenuation with respect to vibration changes accordingly. Therefore, characteristic data is stored for each curve portion. Then, based on the characteristic data, the seismic intensity is specified from the position of the curved portion and the amount of attenuation, and output. According to this, when an earthquake occurs, the seismic intensity can be detected with high accuracy.

The vibration detection system according to the present invention further includes means for storing map data of a region where the optical fiber is installed, and the earthquake output means is specified at the specified location on the map data. It is good also as displaying a seismic intensity.
According to this configuration, when the seismic intensity of the earthquake is output, the seismic intensity is displayed at a corresponding position on the map data, so that the seismic intensity in the area included in the map data can be grasped. And in the said area | region, it can grasp | ascertain finely the two-dimensional distribution of seismic intensity by extending | stretching the optical fiber which has a curve part.

In the vibration detection system of the present invention, the curved portion may be a surplus length around which the optical fiber is wound.
According to this configuration, the extra length is a thing wound outward from the extending direction of the optical fiber, and is freely swingable. Therefore, a curve for measuring the light intensity and detecting the attenuation of the light intensity. Very useful as part.

In the vibration detection system of the present invention, two extra lengths perpendicular to each other may be provided as the curved portion within a predetermined distance on the optical fiber.
When the normal extra length swings in the extending direction of the optical fiber, distortion occurs and the light intensity is attenuated, so that vibration can be detected. However, when shaking in the direction perpendicular to the extending direction (lateral direction), distortion does not occur and vibration cannot be detected. According to this configuration, since the extra length is provided not only in the extending direction of the optical fiber but also in the vertical direction, vibration from the extending direction to the vertical direction can be detected.

  In addition, the problems disclosed by the present application and the solutions thereof will be clarified by the description of the mode for carrying out the invention and the drawings.

  According to the present invention, it is possible to detect vibration at a location where an optical fiber is provided.

1 is a diagram illustrating a configuration of an optical fiber earthquake detection system 1. FIG. It is a figure which shows the principle of an earthquake detection, (a) shows the principle which detects an earthquake with the extra length of an optical cable, (b) shows the principle which detects the omnidirectional earthquake with the extra length of an optical cable, (c) Indicates the relationship between the distance of the optical cable and the reflected light level. It is a figure for demonstrating the relationship between the attenuation of an optical level, and the seismic intensity of an earthquake, (a) shows the relationship between the curvature radius of an optical fiber, and transmission loss (attenuation), (b) is Examples of bending characteristics of the optical fiber are shown, (c) shows the relationship between the period and the acceleration for each seismic intensity of the earthquake, and (d) shows how the radius of curvature of the optical fiber decreases when the earthquake occurs. It is a figure which shows the structure of the data memorize | stored in the memory | storage part 35 of the earthquake detection apparatus 3, (a) shows the structure of the optical cable characteristic data 35A, (b) shows the content of the seismic intensity display data 35B. It is a flowchart which shows the process of the earthquake detection apparatus 3. FIG.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. In an optical fiber earthquake detection system (vibration detection system) according to an embodiment of the present invention, an extra length portion or a bent portion in the middle of an optical cable (optical fiber) attached to a utility pole is a vibration such as an earthquake. The position of the optical cable is monitored by monitoring the change in transmitted light and reflected light using the optical pulse tester by utilizing the fact that the light is refracted and reflected inside the optical cable when it is swung and deformed. In addition, it is possible to grasp how much vibration is generated. And in the area where the optical cable is stretched, the seismic motion at each place is grasped in detail. In addition, it is desirable that the extra length portion or the bent shape portion can be freely swung without being constrained. The optical pulse tester is also called OTDR (Optical Time-Domain Reflectometer).

≪System configuration and overview≫
FIG. 1 is a diagram showing a configuration of an optical fiber earthquake detection system 1. The optical fiber earthquake detection system 1 includes an optical pulse tester 2 and an earthquake detection device 3, which are connected so as to communicate with each other. The optical pulse tester 2 is connected to an existing optical cable 4, and an optical pulse (optical signal) is incident on an unused single-core optical fiber of the optical cable 4, and the level (intensity) of the optical pulse is determined. Monitoring is performed, and light level data (for example, data shown in FIG. 2C) that is a result of the monitoring and is a distance distribution of the reflected light level is transmitted to the earthquake detection device 3. The earthquake detection device 3 receives the optical level data in the optical cable 4 from the optical pulse tester 2, determines whether or not an earthquake has occurred at the corresponding location based on the attenuation portion in the optical level data, and the determination Based on the result, the occurrence status of the earthquake is displayed.

  The optical cable 4 attached to the overhead ground wire or the utility pole has a wound extra length or a bent shape, and detects the occurrence of an earthquake by detecting the attenuation of the light pulse in such a portion. 1 is a side view showing a state in which the optical cable 4a is installed on the utility pole 5a. In the optical cable 4a, a surplus length portion 4a1 exists at the place of the utility pole 5a. The extra length portion 4a1 is a portion wound to avoid congestion of the cable while maintaining the communication quality by maintaining the bending radius of the optical cable 4a so as not to be smaller than the minimum bending radius. .Has a diameter of 5 to 1 m. 1b of FIG. 1 is a top view which shows a mode that the optical cable 4b was constructed by the utility pole 5b. The optical cable 4b has a bent portion 4b1 at the center of the three utility poles 5b at the center of the utility pole 5b. The bent portion 4b1 is a portion where the optical cable 4b is bent by the arrangement of the installed utility pole 5b.

  The earthquake detection device 3 includes a communication unit 31, a display unit 32, an input unit 33, a processing unit 34, and a storage unit 35, and is configured so that each unit can transmit and receive data via a bus 36. The communication unit 31 is a part that performs data communication with the optical pulse tester 2 via a communication line, and is realized by, for example, a communication protocol control module. The display unit 32 is a part that displays data according to an instruction from the processing unit 34, and is realized by, for example, a liquid crystal display (LCD). The input unit 33 is a part where an operator inputs data (for example, seismic intensity data for each optical cable 4) and instructions, and is realized by, for example, a keyboard, a mouse, a touch panel, or the like. The processing unit 34 exchanges data between the respective units via a predetermined memory and controls the entire earthquake detection device 3. A program in which a CPU (Central Processing Unit) is stored in the predetermined memory It is realized by executing. The storage unit 35 stores data from the processing unit 34 and reads the stored data, and is realized by, for example, a nonvolatile storage device such as an HDD (Hard Disk Drive) or an SSD (Solid State Drive). The

≪Principle of earthquake detection≫
FIG. 2 is a diagram showing the principle of earthquake detection. FIG. 2A shows the principle of detecting an earthquake using the extra length of the optical cable. The optical cable is bent downward from the fulcrum with a predetermined curvature and wound several times as a surplus portion, and then returns to the horizontal direction from the same fulcrum and extends as it is. When an earthquake occurs, if the extra length portion swings in the optical cable installation direction around the fulcrum, the optical fiber near the fulcrum is deformed and distortion occurs. As a result, the amount of reflection of the light pulse is increased, and the level of the light pulse is attenuated. Therefore, it is determined whether or not an earthquake has occurred according to the amount of attenuation, and the seismic intensity of the occurred earthquake is estimated.

  With respect to the bent portion, in the plan view of 10b in FIG. 1, for example, when the central electric pole 5b is shaken upward in the drawing due to an earthquake without the electric poles 5b at both ends moving, the position of the bent portion 4b1 is higher in the drawing. Strain occurs in the optical fiber in the vicinity. As a result, the amount of reflection of the light pulse is increased, and the level of the light pulse is attenuated. Therefore, it is determined whether or not an earthquake has occurred according to the amount of attenuation, and the seismic intensity of the occurred earthquake is estimated.

  FIG. 2B shows the principle of detecting omnidirectional earthquakes using the extra length of the optical cable. When the extra length portion of FIG. 2 (a) is swayed in a direction perpendicular to the extending direction of the optical cable as compared with the case of swaying in the extending direction of the optical cable (light traveling direction), the deformation of the optical fiber is Get smaller. Therefore, in order to detect vibration in all directions with high sensitivity, an extra length portion is also provided in a direction (perpendicular direction) perpendicular to the installation direction of the optical cable. Note that the fulcrum of the surplus part in the extending direction (the point where the start point and end point of the loop overlap) and the fulcrum of the surplus part in the vertical direction may be at the same position or a distance that can be regarded as the same location. May be within.

  FIG. 2C shows the relationship between the distance of the optical cable and the reflected light level. Based on the principle shown in FIGS. 2 (a) and 2 (b), the transmitted light and reflected light inside the optical cable 4 are monitored using the optical pulse tester 2, so that the light level is attenuated. , To detect where the earthquake is occurring. In addition, the magnitude of the seismic motion is grasped two-dimensionally by monitoring a plurality of optical cables 4 passing through different routes or one optical cable 4 stretched around so as to cover a predetermined area range.

  Specifically, if the attenuation level of the light level is constantly monitored, the attenuation will be larger than usual when an earthquake occurs. Therefore, the data indicating the change in the optical level in the entire optical cable 4 (optical level data) is taken in, and a portion where a change (abrupt attenuation or the like) exceeding a predetermined value is detected.

  FIG. 3 is a diagram for explaining the relationship between the attenuation of the light level and the seismic intensity of the earthquake. FIG. 3A shows the relationship between the radius of curvature of the optical fiber and the transmission loss (attenuation). According to FIG. 3A, the amount of attenuation decreases as the radius of curvature of the optical fiber increases (that is, distortion decreases). In other words, the amount of attenuation increases as the distortion of the optical fiber increases.

  FIG. 3B is an example of the bending characteristics of the optical fiber, and shows the relationship between the radius of curvature of the optical fiber and the light quantity retention rate. The light quantity retention rate indicates the ratio of the light quantity after passing through the light quantity before the optical signal passes through the bent portion of the optical fiber. According to FIG. 3 (b), the larger the radius of curvature of the optical fiber, the higher the light quantity retention rate, approaching 100%.

  FIG.3 (c) shows the relationship between a period and an acceleration for every seismic intensity of an earthquake. The standard extra length of the optical fiber is 10 m wound four times, and the radius of the extra length is 10/4 / π / 2≈0.4 [m] = 40 [cm]. It is assumed that the extra length is stationary and the optical fiber moves when an earthquake occurs. Further, the period of the earthquake is set to several seconds, and the time for the optical fiber to move is set to 1 second.

(1) In the case of seismic intensity 3 The acceleration α when the period is several seconds is typically about 10 cm / sec ^2, so it moves 1 / 2αt ² = 5 [cm] per ^second . As shown in FIG. 3 (d), for example, if one end of the optical fiber corresponding to a quarter arc of the extra length portion having a circumference of 40 cm is moved by 40 cm, the radius is 20 cm. .

(2) In the case of seismic intensity 5 The acceleration α when the period is several seconds is typically 100 cm / sec ² = 1 m / sec ² , so it moves 1 / 2αt ² = 0.5 [m] per ^second. . Since the moving distance exceeds 40 cm, which is the radius of the extra length, it is pulled by tension, the angle at the fulcrum is close to a right angle, and the radius of curvature is further reduced.

According to the above, since the relationship between the radius of curvature and the amount of attenuation is known, and the relationship between the seismic intensity and the radius of curvature is known, the relationship between the amount of attenuation and the seismic intensity can be specified.
For example, the earthquake detection device 3 manages the route and distance of the optical cable, the position of the support and the height of the support point, and the position and diameter of the extra length on the map system. Based on the above characteristics, the relationship between the strain and attenuation of the optical fiber and the seismic intensity of the optical fiber due to the vibration of each extra length part against the earthquake motion of each support is calculated in advance from these specifications. And associate them. Then, by monitoring the attenuation measured by the optical pulse tester 2, the seismic intensity can be grasped in real time and in time series every several hundred meters on the map (depending on the distance of the extra length portion). Examples relating to this will be described later.

<< Data structure >>
FIG. 4 is a diagram illustrating a configuration of data stored in the storage unit 35 of the earthquake detection device 3. FIG. 4A shows the configuration of the optical cable characteristic data 35A. The optical cable characteristic data 35A is data indicating the relationship between the attenuation at each position of the extra length portion 4a1 and the bent portion 4b1 and the seismic intensity for each optical cable 4. From the record including the distance 35A1, the attenuation 35A2 and the seismic intensity 35A3. Become. The distance 35A1 is a distance between the optical pulse tester 2 connected to the end of the optical cable 4 and the positions of the extra length part 4a1 and the bent part 4b1 on the optical cable 4, and more specifically, the optical pulse This corresponds to the distance at which the tester 2 has detected an attenuation greater than or equal to a predetermined value. The attenuation amount 35A2 indicates the attenuation amount of the light level at the distance 35A1, and corresponds to the degree of distortion due to the shaking of the extra length portion 4a1 and the bent portion 4b1. The seismic intensity 35A3 indicates a seismic intensity corresponding to the attenuation 35A2 at the distance 35A1, and depends on the shaking characteristics of the extra length portion 4a1 and the bent portion 4b1. The correspondence between the attenuation and the seismic intensity can be adjusted by the initial setting of the curvature of the optical cable 4.

  FIG. 4B shows the contents of the seismic intensity display data 35B. The seismic intensity display data 35B is data indicating the seismic intensity at each position of the extra length portions 4a1, 4c1 and the bent portion 4b1 on the optical cable 4. In FIG. 4B, the route of the optical cable 4 is indicated by a solid line, the positions of the extra length portions 4a1 and 4c1 on the route are indicated by circles, and the position of the bent portion 4b1 is indicated by a triangle. Then, the seismic intensity at each position is displayed in a circle or a triangle. The seismic intensity display data 35 </ b> B and map data 35 </ b> C (not shown) are displayed together on the display unit 32, thereby making it possible to grasp the seismic intensity at each position on the map. In the initial seismic intensity display data 35B, it is assumed that no number indicating seismic intensity is displayed, and that circles and triangles are blank.

  In addition, the memory | storage part 35 shall further memorize | store map data 35C (not shown) which covers the area which has jurisdiction.

≪Device processing≫
FIG. 5 is a flowchart showing processing of the earthquake detection device 3. In this process, in the earthquake detection apparatus 3, the processing unit 34 mainly receives the data from the optical pulse tester 2 through the communication unit 31, and refers to the update of the data in the storage unit 35 while updating the optical cable characteristic data 35A. The seismic intensity display data 35B and the map data 35C are displayed.

First, the earthquake detection device 3 creates the optical cable characteristic data 35A and stores it in the storage unit 15 (S501). In detail, the electric pole 5a is vibrated by experiment, the attenuation amount of the optical signal in the extra length portion 4a1 of the optical cable 4a is measured, and the attenuation amount is associated with the seismic intensity corresponding to the vibration. Moreover, the electric pole 5b is vibrated, the attenuation amount of the optical signal in the bending part 4b1 of the optical cable 4b is measured, and the attenuation amount is associated with the seismic intensity corresponding to the vibration. Then, the data of the attenuation 35A2 and the seismic intensity 35A3 are further associated with the distance 35A1 where the surplus part 4a1 and the bent part 4b1 are located.
Subsequently, the earthquake detection device 3 performs the processing of S502 to S504 for each optical cable 4.

  The optical pulse tester 2 transmits an optical pulse to the optical fiber at a time interval of about once per second, monitors the level of the optical pulse, and transmits optical level data as the monitoring result to the earthquake detection device 3. . On the other hand, the earthquake detection device 3 acquires optical level data from the optical pulse tester 2 through the communication unit 31 (S502). The acquired light level data is stored in a predetermined memory, and for example, as shown in FIG. 2C, the relationship between the distance and the light level (position distribution of attenuation of light intensity) can be referred to. Become.

  Next, the earthquake detection device 3 extracts the attenuation amount and distance in the extra length portion and the bent portion of the optical cable 4 from the optical level data (S503). For example, referring to the light level data in FIG. 2C, the attenuation amount of the light level per unit distance is greater in the portion surrounded by the broken circle than in the other portions. If the attenuation amount is equal to or greater than a predetermined value, the attenuation amount and the distance corresponding to the location are extracted. For example, the minimum attenuation 35A2 (the attenuation 35A2 corresponding to the seismic intensity 35A3 equal to 1) in the distance 35A1 is used as the reference value at this time, for example, in the optical cable characteristic data 35A.

  Subsequently, the earthquake detection device 3 specifies the seismic intensity from the extracted attenuation amount and distance based on the optical cable characteristic data 35A, creates seismic intensity display data 35B, and stores it in the storage unit 35 (S504). Specifically, in the optical cable characteristic data 35A corresponding to the optical cable 4, the seismic intensity 35A3 corresponding to the extracted distance 35A1 and attenuation 35A2 is specified. Then, the seismic intensity display data 35 </ b> B is read from the storage unit 35, and a number indicating the seismic intensity is written in the extra-long circle or the bent triangle of the optical cable 4 according to the distance. In the blank that remains at that time, zero indicating that there was no shaking of the earthquake is entered because it means that the amount of attenuation greater than the predetermined value was not detected at that location.

  Further, the earthquake detection device 3 reads the seismic intensity display data 35B and the map data 35C from the storage unit 35, and displays both the data on the display unit 32 (S505). Thereby, if the display part 32 is seen, the location where the earthquake of each seismic intensity occurred on the map can be confirmed.

  In the above embodiment, in order to make each part in the earthquake detection apparatus 3 shown in FIG. 1 function, a program executed by the processing unit 34 is recorded on a computer-readable recording medium, and the recorded program is recorded. It is assumed that the earthquake detection device 3 according to the embodiment of the present invention is realized by being read and executed by a computer. In this case, the program may be provided to the computer via a network such as the Internet, or a semiconductor chip or the like in which the program is written may be incorporated in the computer.

  According to the embodiment of the present invention described above, it is possible to detect an earthquake at a place where the optical cable 4 is provided, that is, the surplus length portion 4a1 or the bent portion 4b1.

  In detail, as shown in FIG. 3, the optical fiber included in the optical cable 4 (particularly, the extra length portion or the bent portion) changes the attenuation amount of the optical signal in accordance with the radius of curvature, and the curvature due to vibration due to an earthquake or the like. The radius changes. Therefore, the earthquake detection device 3 specifies the relationship between the attenuation and the seismic intensity for each distance on the optical cable 4 as shown in S501 of FIG. 5, and the optical cable characteristic data 35A as shown in FIG. Remember as. Then, as shown in S502 to S504, optical level data is acquired from the optical pulse tester 2, and seismic intensity display data 35B is created from the optical level data and the optical cable characteristic data 35A. According to this, it is possible to detect the vibration of the optical cable 4, particularly the place where the surplus length part 4 a 1 and the bent part 4 b 1 are provided, and it is possible to grasp the seismic intensity of the earthquake.

  Subsequently, as shown in S505, the seismic intensity display data 35B and the map data 35C are displayed together. According to this, the planar distribution of seismic intensity can be grasped by extending the optical cable 4 over the area.

  According to the above, since the seismic motion in the region and place where the optical cable 4 is stretched can be grasped in detail, a recovery plan corresponding to the magnitude of the seismic motion is established for each region and location, and efficient and quick Recovery is possible.

<< Other embodiments >>
As mentioned above, although the form for implementing this invention was demonstrated, the said embodiment is for making an understanding of this invention easy, and is not for limiting and interpreting this invention. The present invention can be changed and improved without departing from the gist thereof, and equivalents thereof are also included in the present invention. For example, the following embodiments can be considered.

(1) In the above-described embodiment, it has been described that an earthquake is detected and the seismic intensity thereof is estimated. However, when an automobile collides with the utility pole 5, vibration generated in the utility pole 5 may be detected. In any case, it is possible to detect vibrations that occur in a place where the extra length portion or the bent portion of the optical cable 4 is supported in the structure or the ground where the optical cable 4 is installed. In addition, since the change is slow in the case of shaking by the wind, it can be distinguished from the case of an earthquake or a collision by the speed of change.

(2) Even in a portion other than the extra length portion of the optical cable, it is possible to create optical cable characteristic data 35A indicating the correspondence between the attenuation 35A2 and the seismic intensity 35A3 by performing an experiment of vibration.

(3) In the above embodiment, it has been described that the occurrence of an earthquake is detected in consideration of the position of the extra length part or the bent part. However, the attenuation amount of the optical signal is not necessarily related to the position, and the predetermined value is used. You may extract the location which was the above, and display that there was an earthquake and vibration in the location.

1 Optical fiber earthquake detection system (vibration detection system)
2 Optical Pulse Tester 3 Earthquake Detection Device 34 Processing Unit 35 Storage Unit 35A Optical Cable Characteristic Data 35A1 Distance (Position)
35A2 Attenuation 35A3 Seismic intensity 35B Seismic intensity display data 4, 4a, 4b Optical cable (optical fiber)
4a1 Extra length (curved part)
4b1 Bent part (curved part)
5, 5a, 5b Utility pole

Claims (5)

A vibration detection system for detecting vibration using an existing optical fiber having a swingable curved portion,
Means for obtaining a position distribution of attenuation of light intensity which is an intensity of an optical signal in the optical fiber;
Based on the acquired position distribution of attenuation of the light intensity, means for specifying a location where the attenuation amount of the light intensity is a predetermined value or more;
Means for outputting that the object supporting the optical fiber vibrates at the specified location;
A vibration detection system comprising: The vibration detection system according to claim 1,
Means for storing optical fiber characteristic data in which the attenuation amount and the seismic intensity of the earthquake that is the cause of the vibration are associated with each other at the position of each curved portion of the optical fiber;
Based on the optical fiber characteristic data, means for specifying the seismic intensity from the attenuation at the specified location;
In the specified location, an earthquake output means for outputting that the earthquake of the specified seismic intensity has occurred,
The vibration detection system further comprising: The vibration detection system according to claim 2,
Means for storing map data of a region where the optical fiber is installed;
The earthquake output means includes
The vibration detection system, wherein the specified seismic intensity is displayed at the specified location on the map data. The vibration detection system according to any one of claims 1 to 3,
The vibration detection system, wherein the curved portion is a surplus length around which the optical fiber is wound. The vibration detection system according to claim 4,
Two extra lengths perpendicular to each other are provided as the curved portion within a predetermined distance on the optical fiber.