JP2019117060A - Monitoring device, monitoring method, and program - Google Patents

Abstract

To reduce an effort of recording the correspondence with the distance from a reference point of an optical fiber covering the position of a monitoring target.SOLUTION: Measurement data including the relationship between state intensity and a distance point is acquired from a measuring instrument that measures the state intensity at the distance point referring the reference point of an optical fiber, on the basis of the observation of the scattered light of the light entering the optical fiber. The distance point relating to a monitoring target position is identified based on the occurrence timing of the state change generated by a generator at the monitoring target position in the optical fiber.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a monitoring device, a monitoring method, and a program.

  When detecting an abnormality of the monitoring target based on changes in the state of the monitoring target such as vibration, heat, sound, etc., sensors for detecting state conversion of vibration, heat, sound, etc. are installed at the position of the monitoring target. The Patent Document 1 discloses an optical fiber sensing technology as a technology for detecting a state change in a monitored object.

JP, 2010-8409, A

  By the way, in the technology of optical fiber sensing as described above, it is labor to record in advance the correspondence between predetermined monitoring target information and the distance from the reference point of the optical fiber covering the position of the monitoring target. It was over.

  Then, this invention aims at providing the monitoring apparatus, the monitoring method, and program which solve the above-mentioned subject.

According to the first aspect of the present invention, the monitoring device measures the state intensity at the distance point based on the reference point of the optical fiber based on the observation of the scattered light of the light incident on the optical fiber. A measurement data acquisition unit acquiring measurement data including the relationship between the state intensity and the distance point; and the monitor target position based on a generation timing of a state change generated by a generator at the monitor target position in the optical fiber. And a specifying unit for specifying the distance point.

  According to the second aspect of the present invention, the monitoring method is performed by the measuring instrument which measures the state intensity at the distance point based on the reference point of the optical fiber based on the observation of the scattered light of the light incident on the optical fiber. Acquiring measurement data including the relationship between the state intensity and the distance point, and identifying the distance point relating to the monitoring target position based on the occurrence timing of the state change generated by the generator at the monitoring target position in the optical fiber It is characterized by

  According to the third aspect of the present invention, the program causes the computer of the monitoring device to calculate the state intensity at the distance point based on the reference point of the optical fiber based on the observation of the scattered light of the light incident on the optical fiber. Measurement data acquisition means for acquiring measurement data including the relationship between the state intensity and the distance point from a measuring instrument, the generation timing of the state change generated by the generator at the monitoring target position in the optical fiber, It is characterized in that it functions as specifying means for specifying the distance point with respect to the monitoring target position.

  According to the present invention, it is possible to reduce the labor of the work of recording in advance the correspondence between the information of the predetermined monitoring target and the distance from the reference point of the optical fiber covering the position of the monitoring target.

It is a 1st figure which shows the structure of the monitoring system by this embodiment. It is a hardware block diagram of the monitoring apparatus by this embodiment. It is a functional block diagram of a surveillance device by this embodiment. It is a 1st figure which shows the processing flow of the monitoring apparatus by this embodiment. It is a 2nd figure which shows the structure of the monitoring system provided with the monitoring apparatus by this embodiment. It is a 2nd figure which shows the processing flow of the monitoring apparatus by this embodiment. It is a 3rd figure which shows the structure of the monitoring system provided with the monitoring apparatus by this embodiment. It is a figure which shows the minimum structure of the monitoring apparatus by this embodiment.

Hereinafter, a monitoring device according to an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a first diagram showing the configuration of a monitoring system provided with a monitoring device.
As shown in this figure, the monitoring system 100 includes a monitoring device 1, a measuring instrument 2, a display device 3, a communication device 5, and a portable terminal 7 which is an aspect of a transmission device connected to the communication device 5.
The monitoring device 1 is connected to the optical fiber 20 via the measuring device 2. The optical fiber 20 has a length of, for example, 10000 m, and is installed so as to cover a plurality of predetermined monitoring targets AA, AB,. The monitoring device 1 communicates with the portable terminal 7 via the communication device 5.
The measuring instrument 2 makes light enter the optical fiber 20 and observes the scattered light scattered at each point of the optical fiber 20. The measuring device 2 measures the state intensity at each distance point with respect to the reference point of the optical fiber based on the scattered light.

  The monitoring device 1 is connected to the measuring instrument 2, acquires the state intensity at each distance point from the measuring instrument 2, and specifies the state intensity detected at the distance point corresponding to the predetermined monitoring target position. The state intensity is an intensity when the physical state of the optical fiber 20 is changed by vibration, sound, heat or the like. The display device 3 is an example of an output destination of output information by the monitoring device 1. The monitoring device 1 outputs the state intensity at least at the position of the monitoring target to the display device 3.

  The display device 3 displays the display image received from the monitoring device 1. The display image is, for example, information in which the distances from the reference points of the optical fibers 20 to the observation target positions AA, AB,..., And the state intensities at the observation target positions are associated. As a method of detecting the state intensity at each distance point of the optical fiber 20, for example, there is OTDR (Optical Time Domain Reflectometry), etc., but in the monitoring system according to the present embodiment, scattered light Any technique of optical fiber sensing may be used as long as it is a technique for measuring the state intensity at a distance point based on the reference point of the optical fiber 20 based on observation.

  The portable terminal 7 generates a state change at the position where the optical fiber 20 covers the monitoring target. In the present embodiment, the portable terminal 7 emits a vibration. Alternatively, the portable terminal 7 may emit sound or heat. The portable terminal 7 transmits the timing at which the state change has occurred to the communication device 5 of the monitoring system 100. Information that the portable terminal 7 transmits to the communication device 5 of the monitoring system 100 is referred to as state change occurrence notification data. The portable terminal 7 may be communicably connected to the communication device 5 wirelessly or by wire. The frequency of the vibration emitted by the portable terminal 7 in the present embodiment is a predetermined frequency. The monitoring device 1 stores the frequency of the vibration generated by the mobile terminal 7.

FIG. 2 is a hardware configuration diagram of the monitoring device.
As shown in the figure, the monitoring device 1 includes a central processing unit (CPU) 10-1, a read only memory (ROM) 10-2, a random access memory (RAM) 10-3, and a hard disk drive (HDD) 10-4. It is a computer provided with each hardware of communication module 10-5 grade | etc.,. The measuring instrument 2, the display device 3, the communication device 5, and the portable terminal 7 may have the same configuration.

FIG. 3 is a functional block diagram of the monitoring device.
The monitoring device 1 is activated when the power is turned on, and executes a monitoring program stored in advance. As a result, the monitoring device 1 is provided with functions such as the control unit 101, the measurement data acquisition unit 102, the identification unit 103, the recording unit 104, the output unit 105, and the like.
The control unit 101 controls other functional units.
The measurement data acquisition unit 102 acquires, from the measuring instrument 2, measurement data including information indicating the correspondence between the state intensity and the distance point.
The identifying unit 103 identifies the occurrence timing of the state change generated by the portable terminal 7 at the position of the monitoring target in the optical fiber 20, and based on the occurrence timing, the reference point of the distance point of the optical fiber 20 where the monitoring target is located. Identify the distance based on The distance point is the distance from the reference point of the optical fiber.
The recording unit 104 records the distance of the monitoring target specified by the specifying unit 103.
The output unit 105 outputs the state intensity at least at a predetermined monitoring target position to the display device 3.

FIG. 4 is a diagram showing a processing flow of the portable terminal.
The user carries the portable terminal 7 and goes to the monitoring target. There may be a plurality of targets to be monitored, and the optical fiber 20 is installed on the targets to be monitored. The user operates the portable terminal 7 to be monitored and generates vibration. The generating unit 72 of the portable terminal 7 generates a vibration (step S401). The generator 72 may be, for example, a vibrator. The frequency of the vibration is predetermined, and may be 5 times per second, 10 times per second, or the like. The frequency of the vibration may be a higher frequency vibration. When the generation unit 72 generates vibration, the communication unit 71 transmits state change occurrence notification data to the communication device 5 (step S402). The communication device 5 outputs state change occurrence notification data to the monitoring device 1. The monitoring device 1 detects the timing at which vibration is generated by the portable terminal 7 based on the state change occurrence notification data, and specifies the distance point at which the portable terminal 7 is vibrating based on the vibration frequency at that time.

FIG. 5 is a first diagram showing a process flow of the monitoring device.
Next, the processing flow of the monitoring device will be described in order.
Based on the vibration of the portable terminal 7, the specifying unit 103 of the monitoring device 1 acquires state change occurrence notification data via the communication module 10-5 (step S501). The status change occurrence notification data may include the ID of the monitoring target. The monitoring target ID is information for identifying the monitoring target input by the user on the portable terminal 7. The specifying unit 103 detects that it is the timing at which the portable terminal 7 is generating vibration by acquiring state change occurrence notification data (step S502). When receiving the status change occurrence notification data, the identifying unit 103 reads the ID of the monitoring target from the data (step S503). The identifying unit 103 instructs the measurement data acquisition unit 102 to acquire measurement data.

  The measurement data acquisition unit 102 instructs the measuring instrument 2 to start measurement. Then, the measuring instrument 2 makes light enter the optical fiber 20. The measuring device 2 observes the scattered light of light. The measuring instrument 2 detects the state intensity at each distance point of the optical fiber 20 using an optical fiber sensing technique. The state intensity is represented by a numerical value, and the larger the state of the vibration, temperature, volume, etc. emitted by the portable terminal 7, the higher the numerical value of the state intensity. Each distance point at which the measuring instrument 2 detects the state intensity is, for example, a reference interval such as 1 m (meter) or 2 m. When the optical fiber 20 has a length of, for example, 10000 m, the distance point at which the measuring instrument 2 can detect the state intensity is a large amount of data, such as 10000 points.

  The acquisition unit 102 of the monitoring device 1 acquires, from the measuring device 2, measurement data in which the distance based on the reference point of each distance point of the optical fiber is associated with the state intensity (step S504). The measurement data acquisition unit 102 sequentially acquires the measurement data from the measuring instrument 2 at predetermined intervals such as 1 ms. In the measurement data, the distance based on the reference point of the optical fiber 20 at each distance point and the state intensity at the distance point are associated and held. The measurement data acquisition unit 102 sequentially outputs the acquired measurement data to the identification unit 103.

  The identifying unit 103 reads the information of the combination of the state intensity and the distance included in each measurement data. The identifying unit 103 generates a measurement result indicating the state intensity at each predetermined time interval for each distance based on the reference point of the optical fiber 20 (step S505). In the measurement result, the identifying unit 103 identifies a distance that indicates that the state intensity is equal to or greater than the threshold at the same frequency as the frequency of vibration generation of the portable terminal 7 (step S506). The recording unit 104 acquires the distance identified by the identifying unit 103, the ID of the observation target, and the identifying unit 13. The recording unit 104 associates the ID of the observation target with the distance and records the ID in the storage unit such as the HDD 10-5 (step S507). For example, as shown in FIG. 1, the distance based on the reference point of the distance point of the optical fiber 20 corresponding to the ID of the monitoring target AA at the position where the mobile terminal 7 generates vibration and the position of the monitoring target AA , 034 m) are recorded in association with each other. When the recording process is completed, the recording unit 104 notifies the control unit 101 that the recording has been completed. The control unit 101 transmits the recording completion information to the portable terminal 7 via the communication device 5 (step S508). The communication unit 71 of the portable terminal 7 receives the recording completion information (step S403). The portable terminal 7 controls the stop of the vibration based on the reception of the recording completion information, and the generation unit 72 stops the vibration (step S404).

  By the above processing, the monitoring apparatus 1 can easily record identification information (ID) of the monitoring target and the distance from the reference point of the optical fiber 20 installed so as to cover the position of the monitoring target. The user performs an operation to generate vibration using the portable terminal 7 at a plurality of monitoring target positions. This makes it possible to easily record identification information on a plurality of monitoring targets and the distance from the reference point of the optical fiber 20 installed so as to cover the positions of the monitoring targets.

  After the ID of each monitoring device and the distance from the reference point of the distance point of the optical fiber 20 at the position of the monitoring device are recorded, the monitoring system 100 monitors an abnormality to be monitored.

  For example, the measuring instrument 2 injects light into the optical fiber 20 in the same manner as the process described above. The measuring device 2 observes the scattered light of light. The measuring instrument 2 detects the state intensity at each distance point of the optical fiber 20 using an optical fiber sensing technique. The measurement data acquisition unit 102 of the monitoring device 1 acquires measurement data from the measuring device 2. The measurement data acquisition unit 102 outputs the acquired measurement data to the identification unit 103. The identifying unit 103 acquires the distance based on the reference point of the predetermined monitoring target optical fiber 20 from the storage unit based on the ID of the monitoring target AA. This distance is the distance recorded by the process of steps S501 to S507 described above. The identifying unit 103 outputs, to the output unit 105, a combination of the distance based on the reference point of the optical fiber 20 of the monitoring target AA and the state intensity held in the measurement data in association with the distance. The output unit 105 generates a display image in which the distance based on the reference point of each of the monitoring target optical fibers 20 is associated with the state intensity at that distance. The output unit 105 outputs the display image to the display device 3. The display device 3 outputs a display image to a monitor.

FIG. 6 is a second diagram showing the configuration of a monitoring system provided with a monitoring device and a portable terminal.
The monitoring system 100 shown in FIG. 6 is different from the monitoring system 100 shown in FIG. 1 in that the mobile terminal 7 includes a positioning unit 73.
The portable terminal 7 may detect coordinates of the own terminal such as latitude and longitude in the positioning unit 73. Then, the communication unit 71 transmits state change occurrence notification data further including coordinates in the above-described step S402 to the communication device 5. Thus, the recording unit 104 of the monitoring device 1 associates the ID of the observation target, the distance based on the reference point of the distance point of the optical fiber 20 corresponding to the position of the observation target, and the coordinates of the observation target point Can be recorded in the storage unit such as the HDD 10-5.

FIG. 7 is a third diagram showing the configuration of a monitoring system provided with a monitoring device and a portable terminal.
In the monitoring system 100 shown in FIG. 7, the monitoring device 1 is connected to the database 4. The plan view data is recorded in the database 4. The plan view data may be, for example, a layout of devices to be monitored that are installed on a floor in a factory. The equipment to be monitored may be various, such as a motor and a pump. The plan view data holds the ID of the monitoring target in the plan view and the information of the coordinates in the plan view of the monitoring target. The monitoring device 1 may output a display image including a plan view to the display device 3. An example of processing in this case will be described below.

  The measurement data acquisition unit 102 of the monitoring device 1 acquires, from the measuring device 2, measurement data in which each distance point of the optical fiber is associated with the state intensity. The measurement data acquisition unit 102 outputs the acquired measurement data to the identification unit 103. The identifying unit 103 acquires, from the storage unit, a distance based on the reference point of the optical fiber 20 of the predetermined monitoring target AA. The identifying unit 103 repeats the process of sequentially acquiring the state intensities held in association with the distance based on the reference point of the optical fiber 20 of the monitoring target AA among the state intensities included in the measurement data. The identifying unit 103 outputs a combination of the ID of the monitoring target AA and the state intensity held in the measurement data in association with the distance based on the reference point of the optical fiber 20 corresponding to the position of the monitoring target AA. Output to 105. The output unit 105 acquires plan view data from the database 4. The output unit 105 acquires the coordinates of the monitoring target AA from the plan view data based on the ID of the monitoring target AA. The output unit 105 generates a display image 32 including state intensity information in which the plan view data and the state intensity corresponding to the coordinates of the monitoring target AA are associated. The output unit 105 outputs the display image 32 to the display device 3. The display device 3 outputs a plan view based on the display image 32 to a monitor. The display image 32 displays the layout of each monitoring target included in the plan view and the numerical value of the state intensity of the monitoring target at the position of the monitoring target.

  In the above-described process, the portable terminal 7 transmits state change occurrence notification data to the monitoring device 1 wirelessly or by wire. However, the status change occurrence notification data may be read by the monitoring device 1 via the recording medium without being transmitted to the monitoring device 1 using the communication means. In this case, the monitoring device 1 includes occurrence date / time information when the mobile terminal 7 has generated vibration in the state change occurrence notification data. The measurement data acquisition unit 102 records the past measurement data in a storage unit such as the HDD 10-4. The identifying unit 103 of the monitoring device 1 reads occurrence date and time information included in state change occurrence notification data. The identifying unit 103 acquires measurement data of a predetermined time interval from the storage unit such as the HDD 10-4 with the occurrence date and time information as a starting point. The identifying unit 103 performs the same processing as the above-described steps S503 to S507 based on the acquired measurement data and the vibration frequency emitted by the portable terminal 7 that has generated the state change occurrence notification data.

FIG. 8 is a diagram showing the minimum configuration of the monitoring device.
The monitoring device 1 may include at least the measurement data acquisition unit 102 and the identification unit 103.
The measurement data acquisition unit 102 acquires measurement data.
The identifying unit 103 detects the occurrence timing of the state change generated by the generator such as the portable terminal 7 at the position of the monitoring target in the optical fiber 20, and the distance point of the optical fiber corresponding to the position of the monitoring target Identify the distance based on the reference point of

  Each of the above-described devices internally includes a computer system. The process of the process described above is stored in the form of a program in a computer readable recording medium, and the process is performed by the computer reading and executing the program. Here, the computer readable recording medium refers to a magnetic disk, a magneto-optical disk, a CD-ROM, a DVD-ROM, a semiconductor memory or the like. Alternatively, the computer program may be distributed to a computer through a communication line, and the computer that has received the distribution may execute the program.

  Further, the program may be for realizing a part of the functions described above. Furthermore, it may be a so-called difference file (difference program) that can realize the above-described functions in combination with a program already recorded in the computer system.

1 ... monitoring device 2 ... measuring instrument 3 ... display device 4 ... database 5 ... communication device 7 ... portable terminal (generation device)
71 ... communication unit 72 ... generation unit 73 ... positioning unit 101 ... control unit 102 ... acquisition unit 103 ... identification unit 104 ... recording unit 105 ... output unit 100 ... ··Monitoring system

Claims (7)

Measurement data including the relationship between the state intensity and the distance point from a measuring instrument that measures the state intensity at the distance point based on the reference point of the optical fiber based on observation of scattered light of light incident on the optical fiber Measurement data acquisition unit to acquire,
An identification unit that identifies the distance point with respect to the monitoring target position based on the occurrence timing of the state change generated by the generator at the monitoring target position in the optical fiber;
A monitoring device comprising The specifying unit is a timing of occurrence of a state change generated by a generator at a monitoring target position in the optical fiber, position information of the monitoring target position at which the generator is present at the generation timing, and the information acquired from the measuring instrument. The monitoring device according to claim 1, wherein a relationship between the position information and the distance point is specified based on a state intensity and the relationship between the distance points. The specifying unit relates the relationship between the position information and the distance point based on the degree of coincidence between the change in state generated by the generator and the change in state measured by the measuring device based on the state intensity included in the measurement data. The monitoring apparatus according to claim 2, wherein: A measurement data storage unit for storing the measurement data;
The specification unit reads measurement data after acquiring state change occurrence notification data including the position information detected by the coordinate detection device provided in the generation device and time information indicating the generation timing, and the state change occurrence notification The monitoring device according to claim 2 or 3, wherein a relationship between the position information and the distance point is specified using data and the measurement data. An output unit that outputs the state intensity of the monitoring target position;
The monitoring apparatus according to any one of claims 1 to 4, comprising: Measurement data including the relationship between the state intensity and the distance point from a measuring instrument that measures the state intensity at the distance point based on the reference point of the optical fiber based on observation of scattered light of light incident on the optical fiber Acquired,
A monitoring method for identifying the distance point related to the monitoring target position based on the occurrence timing of the state change generated by the generator at the monitoring target position in the optical fiber. Monitor computer,
Measurement data including the relationship between the state intensity and the distance point from a measuring instrument that measures the state intensity at the distance point based on the reference point of the optical fiber based on observation of scattered light of light incident on the optical fiber Measurement data acquisition means to acquire,
Specifying means for specifying the distance point with respect to the monitoring target position based on the generation timing of the state change generated by the generator at the monitoring target position in the optical fiber;
A program to function as

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