JP2021025870A - Information processing system and program - Google Patents

Abstract

To enhance worthiness of displaying seismic motion information.SOLUTION: An informational processing system comprises: acquisition means configured to acquire output information of seismic sensors for detecting vibration at installed points; and display control means configured to provide control to allow seismic motion information to be displayed at positions along piping displayed on a map but not at positions other than the piping, when displaying the output information or information generated by processing the output information as the seismic motion information at positions corresponding to the seismic sensors on the map.SELECTED DRAWING: Figure 1

Description

The present invention relates to information processing systems and programs.

In Patent Document 1, a plurality of acceleration sensors installed on a plurality of floors of a building for detecting acceleration at the time of an earthquake and detection data from a plurality of acceleration sensors in the building are received and analyzed, and the analysis result is obtained. It has a recording unit that transmits and records data, and a display that displays the analysis results transmitted from the recording unit. The recording unit is a building based on the seismic intensity of each floor and the diagnostic algorithm in the CPU. A building diagnostic monitoring system that calculates the damage assessment of the building and sends the result to the display is described.

Japanese Unexamined Patent Publication No. 2013-254239

Currently, the development of a seismic sensor that is compact, inexpensive, has a communication function, and can operate for about 10 years with a battery is underway. This type of seismic sensor not only has a low main unit cost, but also requires low installation and maintenance costs.
For this reason, the number of locations where seismic sensors are installed is expected to increase dramatically in the future. In other words, seismic sensors that output information on ground motion (hereinafter referred to as "ground motion information") can be installed at a higher density than ever before. That is, it becomes possible to acquire seismic motion information as a surface instead of a point.

By obtaining the measured values with high density, it is possible to estimate the location where the ground structure and gas pipes are damaged with high probability. On the other hand, increasing the density of measurement points may reduce visibility when displaying the seismic intensity on the screen.
For example, when the user is paying attention to the gas pipe, a large amount of seismic motion information at a point different from the installation location of the gas pipe is displayed. In this case, the visibility of the seismic motion information corresponding to the installation location of the gas pipe of interest may be reduced by the seismic motion information displayed in the surrounding area.
As one of the countermeasures, it is conceivable to thin out the number of displayed seismic motion information, but if the number of displayed seismic motion information is simply thinned out, the seismic motion information corresponding to the installation location of the gas pipe may also be thinned out. Not preferred.

An object of the present invention is to increase the display value of seismic motion information.

The invention according to claim 1 uses the acquisition means for acquiring the output information of the seismic sensor that detects the vibration of the installation position and the output information or the information generated by processing the output information as the seismic motion information. When displaying at the position on the map corresponding to the seismic sensor, the seismic motion information is displayed at the position of the pipeline displayed on the map, while the seismic motion information is displayed at the position other than the pipeline. It is an information processing system having a display control means for controlling so as not to cause the motion.
The invention according to claim 2 is the information processing system according to claim 1, further comprising a receiving means for receiving the designation of the pipeline displayed on the map.
In the invention according to claim 3, when the installation position of the seismic sensor is within a predetermined distance from the pipeline, the display control means displays the seismic motion information corresponding to the seismic sensor. The information processing system according to claim 1 or 2.
The invention according to claim 4 is the information processing system according to claim 3, further comprising a second receiving means for receiving the designation of the predetermined distance.
The invention according to claim 5 further includes a third receiving means for receiving designation of a region for displaying the seismic motion information corresponding to the seismic sensor located within the predetermined distance from the pipeline. Item 3. The information processing system according to item 3.
The invention according to claim 6 uses the function of acquiring the output information of the seismic sensor for detecting the vibration of the installation position and the output information or the information generated by processing the output information as seismic motion information. When displaying at a position on the map corresponding to the seismic sensor, the seismic motion information is displayed at the position of the pipeline displayed on the map, while the seismic motion information is displayed at a position other than the pipeline. It is a program that executes a function to control so that the information is not displayed.

According to the invention of claim 1, the display value of seismic motion information can be increased.
According to the invention of claim 2, the seismic motion information displayed by designating the pipeline can be changed.
According to the invention of claim 3, when the number of seismic sensors installed on the designated pipeline is small, the display amount can be increased.
According to the invention of claim 4, the display amount can be adjusted by increasing or decreasing the designation of the distance.
According to the invention of claim 5, the display amount can be adjusted by designating the area.
According to the invention of claim 6, the display value of the seismic motion information can be increased.

It is a figure explaining the configuration example of the seismic motion information providing system used in Embodiment 1. FIG. It is a figure explaining the processing operation example of the seismic motion information providing system used in Embodiment 1. FIG. It is a figure which shows the example of the screen which displays the seismic intensity with the seismic sensor installed in the designated area as a measurement point. It is a figure which shows the example of the display screen of the seismic intensity which uses the seismic sensor installed at the position which overlaps with the designated pipeline as a measurement point. It is a figure which shows another example of the display screen of the seismic intensity which uses the seismic sensor installed at the position which overlaps with the designated pipeline as a measurement point. It is a figure which shows the example of the display screen of the seismic intensity which uses the seismic sensor installed at the position considered to overlap with a designated pipeline as a measurement point. It is a figure which shows another example of the display screen of the seismic intensity which uses the seismic sensor installed at the position considered to overlap with the designated pipeline as a measurement point. It is a figure explaining the configuration example of the seismic motion information providing system used in Embodiment 2. It is a figure explaining the processing operation example of the seismic motion information providing system used in Embodiment 2.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
<Embodiment 1>
<Overall system configuration>
FIG. 1 is a diagram illustrating a configuration example of the seismic motion information providing system 1 used in the first embodiment.
The seismic motion information providing system 1 is composed of a plurality of seismic sensor 10, a server 20, a terminal 30, and an Internet 40 connecting these.

<Seismic sensor 10>
The seismic sensor 10 used in the present embodiment includes a MEMS (= Micro Electro Mechanical System) type accelerometer, a battery, a memory, and a communication module, and provides seismic motion information such as SI (= Spectral Intensity) values. Output. Seismic motion information is an example of output information.
Hereinafter, the seismic sensor 10 used in the embodiment is also referred to as a MEMS type sensor.

The SI value is calculated as a value obtained by averaging the velocity response spectrum with respect to a structure having a natural period of 0.1 to 2.5 seconds and an attenuation constant of 20%. It is known that the SI value corresponds to the magnitude of the fracture energy for the structure and has a high correlation with the measured seismic intensity. Therefore, the SI value is also called a seismic intensity equivalent value.
The MEMS type accelerometer used in the present embodiment has a function of calculating an SI value from the maximum value of the measured shaking speed (that is, a speed response spectrum), and a memory for storing the calculated SI value and the like several times. have. The output of the acceleration sensor includes, for example, the maximum value of the combined acceleration of the two horizontal axes, the maximum acceleration in each axis direction, the response speed, the earthquake occurrence time, the raw data of the acceleration value, and the like. These outputs are also examples of seismic motion information.

The MEMS type sensor is in the standby state during the period when the shaking caused by the earthquake is not measured, and the standby power is suppressed by this operating condition, and the long-term operation is possible. The MEMS type sensor transmits the seismic motion information only when the seismic motion for which the SI value of a predetermined size is calculated is measured. In the case of this embodiment, the transmission condition is the calculation of the SI value corresponding to the seismic intensity of 4 or more. Therefore, depending on the place where the MEMS type sensor is installed, the MEMS type sensor can be used for 10 years or more without replacing the battery.
The MEMS type sensor is also provided with a function of transmitting seismic motion information stored in the memory according to a request from the server 20 or the like. In the memory, not only the latest ground motion but also the information of the past multiple ground motions can be stored. This is because, immediately after the earthquake, there is a possibility that communication may be redone due to a large amount of data flowing into the Internet 40 at once.

Further, the MEMS type sensor is connected to the Internet 40 by direct communication or multi-hop communication. For connection with the Internet 40, for example, PHS (= Personal Handy-phone System), 3rd generation mobile communication system, 4th generation mobile communication system such as LTE (= Long Term Evolution), and 5th generation mobile communication system are used. To do.
The MEMS type sensor is battery operated. Therefore, no power supply work is required when installing the MEMS type sensor, and the management burden can be reduced. As a result, the restrictions on the installation of the MEMS type sensor are less than those of the so-called seismograph.

The MEMS type sensor measures the amount of electricity consumed by the contractor, as well as a gas meter that measures the amount of gas consumed, a gas pressure regulator that adjusts the gas pressure and manages the gas supply in each district (so-called district governor). Power meter, ground equipment used for voltage conversion and switching of electricity supply path, gas pipe, pipe for accommodating electric wire (hereinafter also referred to as "conduit"), pipe for accommodating communication line such as optical fiber (hereinafter "" It is also installed in the ground and its vicinity corresponding to each conduit such as "communication pipe"), water supply and sewer pipe (hereinafter also referred to as "water pipe"), and in a common ditch that accommodates a part or all of them. .. Gas pipes, conduits, communication pipes, water pipes, and utility tunnels are examples of pipelines. The MEMS type sensor can be installed not only at the above-mentioned points but also at buildings, bridges, driveways, sidewalks, gutters, manholes, tunnels, embankments, banks, cliffs, curbs, plantings, underground streets, connecting passages, information boards, etc. is there.

In this way, the MEMS type sensor can be installed in a place where installation itself is difficult with a conventional seismograph.
Basically, the MEMS type sensor is installed on the ground, but it can also be mounted on a wall surface, a pillar, or the like. However, the SI value or the like output from the MEMS type sensor installed on a place other than the ground is different from the value when it is installed on the ground. Therefore, the SI value output by the MEMS type sensor installed on a place other than the ground is corrected and used. The correction process may be performed by the MEMS type sensor or the server 20.

<Server 20>
The server 20 in the present embodiment displays on the screen of the terminal 30 a function of collecting seismic motion information such as an SI value output from the seismic sensor 10 and information including a seismic intensity calculated from the collected SI value. Has the function of The server 20 here is an example of an information processing system.
The server 20 shown in FIG. 1 has a computer 21, a seismic motion DB (= Data Base) 22, a map DB 23, a pipeline DB 24, and a sensor position DB 25.
The computer 21 basically includes a CPU (= Central Processing Unit), a ROM (= Read Only Memory) in which a BIOS (= Basic Input Output System) and the like are stored, and a RAM (= Random Access Memory) used as a work area. It has a hard disk device that stores programs and application programs.

The computer 21 functions as a data acquisition unit 211, a display control unit 212, and a display switching reception unit 213 through the execution of the application program.
The data acquisition unit 211 corresponds to a function of acquiring an SI value or the like corresponding to the seismic sensor 10 from the seismic motion DB 22. The data acquisition unit 211 here is an example of acquisition means. The seismic sensor 10 in the present embodiment is managed by an identification number or the like, and the seismic motion information output from each seismic sensor 10 includes the identification number or the like.
The installation location of the seismic sensor 10 is managed by the sensor position DB 25. The installation location of the seismic sensor 10 may be managed by, for example, a lot number, latitude, longitude, or altitude. However, the installation location of the seismic sensor 10 may be managed as a point on a drawing or a map corresponding to the installation location.

The display control unit 212 corresponds to a function of displaying information such as seismic intensity on the display of the terminal 30. The seismic intensity can be calculated from the SI value. A display control unit 212 and a calculation unit (not shown) are used to calculate the seismic intensity. The content of the information to be displayed on the terminal 30 is received from the terminal 30. The display control unit 212 is an example of the display control means.

The display switching reception unit 213 corresponds to a function of receiving instructions and switching of information to be displayed on the display of the terminal 30. The display switching reception unit 213 is provided with a function of accepting the designation of the area to be displayed on the display through the terminal 30 and a function of accepting a method of displaying the seismic intensity and the like.
In the case of the present embodiment, the method of displaying the seismic intensity and the like includes a method of displaying the seismic intensity corresponding to all the seismic sensors 10 existing in the designated area, the type of pipeline and the installation position specified by the user. There is a method of displaying the seismic intensity corresponding to the seismic sensor 10 on which the two are overlapped.

Here, the seismic sensor 10 whose installation position overlaps with the pipeline may include not only the case where the physical positions overlap, but also the seismic sensor 10 whose distance from the pipeline is within a predetermined distance. ..
The predetermined distance may be given as an initial value on the server 20 side, but may be instructed from the terminal 30. The predetermined distance starts from the surface or the central axis of the pipeline. In the case of the present embodiment, for example, 50 cm and 1 meter are used for the predetermined distance. Needless to say, these numbers are examples and are not intended to be limited to these numbers.

The setting of the distance at which the physical positions are considered to overlap may be applied to the entire pipeline displayed on the display of the terminal 30, but may be limited to a specific area specified by the user.
Incidentally, the distance here has nothing to do with the user's designation, and may be automatically changed according to the scale of the map displayed on the display of the terminal 30. For example, when the scale of the map is large, the distance considered to overlap on the pipeline may be small, and when the scale of the map is small, the distance considered to overlap on the pipeline may be increased. However, if the distance is too large, the original purpose of displaying the seismic intensity of the installation location of the pipeline cannot be achieved. Therefore, when changing the distance considered to overlap on the pipeline according to the scale of the map, it is preferable to set an upper limit value of the distance. As for this upper limit value, the distance specified by the server 20 may be used, or the distance specified by the user may be used.
The display switching reception unit 213 here is an example of the second reception means and an example of the third reception means.

In the case of FIG. 1, four units, a seismic motion DB 22, a map DB 23, a pipeline DB 24, and a sensor position DB 25, are provided in the server 20. However, all or part of the DB may exist outside the server 20. These DBs are composed of, for example, a hard disk device. The seismic motion DB 22, the map DB 23, the pipeline DB 24, and the sensor position DB 25 do not have to be stored in independent hard disk devices, and may be stored in the storage area of one hard disk device in a distributed manner.
In the case of this embodiment, the seismic motion DB 22 stores the seismic motion information collected from the seismic sensor 10 via the Internet 40. Each seismic motion information includes identification information of the seismic sensor 10 which is the measurement source.

The map DB 23 stores map data corresponding to the service provision range provided by the server 20.
The pipeline DB 24 stores a completed drawing and a completed drawing of the pipeline, a ledger of attached equipment, and the like. It is not necessary that all of these drawings and the like are stored in the system managed by the service provider (hereinafter referred to as "service provider"). For example, a part of drawings, etc. may be obtained from a system managed by a business operator who has a capital or personal relationship with the service provider, or the business operator who performed the construction such as installation or the contractor of the construction It may be obtained from a system managed by the local government or from a system managed by the local government.
In the sensor position DB 25, individual identification information of the seismic sensor 10 that collects seismic motion information and information indicating the installation location are stored.

<Terminal 30>
The terminal 30 is a computer operated by a service user or provider. Although the notebook computer is illustrated in FIG. 1, it may be a desktop computer, a tablet computer, a portable computer such as a smartphone, or the like.
In FIG. 1, for convenience of explanation, only one terminal 30 is shown, but in reality, a plurality of terminals 30 are connected to the Internet 40.

<Processing operation>
FIG. 2 is a diagram illustrating a processing operation example of the seismic motion information providing system 1 used in the first embodiment. Note that P shown in the figure means processing.
When the seismic sensor 10 detects the occurrence of an earthquake having a seismic intensity higher than a predetermined seismic intensity through a MEMS type acceleration sensor, it transmits seismic motion information such as SI value to the seismic motion DB 22 (P1). The transmission here is randomly executed by the seismic sensor 10 that enables communication.
The geology and ground of the place where the seismic sensor 10 is installed, the strength of the structure where the seismic sensor 10 is installed, and the like are not uniform. For example, in a place where the ground is improved even on soft ground, the seismic intensity may be smaller than in a place where the ground is not improved. In addition, the seismic intensity may be higher in the place created by embankment than in the place created by cut soil. In addition, the calculated seismic intensity may differ depending on whether it is installed directly on the ground or in a structure such as a utility tunnel.

In the case of FIG. 2, the computer 21 requests data from the ground motion DB 22 immediately after the earthquake (P2), and acquires the data as a response (P3). The acquired data is stored in a hard disk device (not shown) or the like. The request for data from the computer 21 to the seismic motion DB 22 may be triggered by, for example, the input of the seismic motion information from the seismic sensor 10 to the computer 21 or the notification of the collection of the seismic motion information from the seismic motion DB 22. However, the notification of the occurrence of an earthquake from an external device may be used as a trigger. Further, the request for data from the computer 21 to the seismic motion DB 22 may be made at regular intervals, for example, regardless of the occurrence of an earthquake.
After that, the computer 21 receives the designation of the area and the pipeline for displaying the seismic intensity from the terminal 30 (P4). The designation includes the scale of the map to be displayed, the type of pipeline to be displayed, the conditions for displaying the seismic intensity, and the like.
Next, the computer 21 acquires the data of the designated area and the pipeline (P5). The data here is acquired from the map DB23 and the pipeline DB24.
Subsequently, the computer 21 extracts seismic motion information in which the measurement point overlaps the pipeline (P6), generates a map in which the extracted seismic intensity is mapped on the pipeline, and transmits it to the terminal 30 (P7).
The terminal 30 displays the received map on the display.

<Screen example>
In the following, a screen example of seismic motion information displayed on the display 31 of the terminal 30 will be described with reference to FIGS. 3 to 7.
FIG. 3 is a diagram showing an example of a screen displaying the seismic intensity with the seismic sensor 10 installed in the designated area as the measurement point. The circled numbers in the figure represent the seismic intensity. For example, the circled "4" indicates a seismic intensity of 4. The seismic sensor 10 that detected only the SI value corresponding to the seismic intensity of 3 or less does not output seismic motion information such as the SI value in the first place.

In the screen shown in FIG. 3, a gas pipe is designated as a pipe line to be displayed. For this reason, the characters "gas pipe" to be displayed are shown in the upper right corner of the screen. In the case of FIG. 3, the seismic sensor 10 is installed at a ratio of one or more every 10 meters square. Installation at this density is possible by using a MEMS type sensor.
The user is interested in the seismic intensity at the measurement point overlapping the gas pipe, but in the example of the screen shown in FIG. 3, the seismic intensity corresponding to the seismic sensor 10 installed in a place other than the gas pipe is also displayed, and the whole As the visibility is poor. In particular, there is a sense of miscellaneousness due to the large number of indications of seismic intensity that have nothing to do with the pipeline of the gas pipe of interest, and visibility is reduced.

FIG. 4 is a diagram showing an example of a seismic intensity display screen having a seismic sensor 10 installed at a position overlapping a designated pipeline as a measurement point.
In the case of FIG. 4, the measurement point on which the seismic intensity is displayed is limited to the seismic sensor 10 installed at a position overlapping the gas pipe. As a result, the seismic intensity display becomes easier to see, and the actual seismic intensity of the place where the gas pipe is installed can be directly confirmed.
If the MEMS type sensor is not used, there is only one measurement point per kilometer square, so the seismic intensity at the place where the gas pipe is installed is only a predicted value. Moreover, the seismic intensity depends on the conditions such as the ground. Moreover, the condition of the ground and the like cannot be uniform. Therefore, the estimated seismic intensity obtained by calculation is not highly reliable.
On the other hand, in the case of the present embodiment, since the seismic intensity measured at a high density along the gas pipe can be displayed as it is, unlike the estimated value, the damage situation can be predicted based on the actual seismic intensity. It will be easier. For example, even when narrowing down the restoration location, it is possible to intensively inspect the gas pipe at the location where the shaking with a seismic intensity of 6 or higher was measured.

FIG. 5 is a diagram showing another example of a seismic intensity display screen having a seismic sensor 10 installed at a position overlapping a designated pipeline as a measurement point.
In the case of FIG. 4, the gas pipe is targeted for display, but in FIG. 5, the water pipe is targeted for display. Also in the case of FIG. 5, only the seismic intensity with the seismic sensor 10 installed at the position overlapping the actual water pipe line as the measurement point is displayed. This display shows the seismic intensity actually measured at the installation location of the water pipe. Therefore, it becomes easy to identify the place where the water pipe is likely to be damaged.
If other pipelines such as electric wire pipes, communication pipes, utility tunnels, etc. are specified as display targets, the seismic intensity of the installation location of each pipeline can be easily confirmed.

By the way, the installation location of the seismic sensor 10 does not always overlap with the pipeline. For example, the seismic sensor 10 cannot always be installed directly above the pipeline due to restrictions on the installation location.
In this case, it is possible that the seismic intensity can hardly be displayed on the designated pipeline. It may also occur when you want to check the seismic intensity at a higher density.
In preparation for such a case, in the present embodiment, a function of increasing the display of the seismic intensity on the screen is provided by designating a range that can be regarded as overlapping with the position of the pipeline.

FIG. 6 is a diagram showing an example of a seismic intensity display screen having a seismic sensor 10 installed at a position deemed to overlap the designated pipeline as a measurement point. FIG. 6 also targets the gas pipe for display.
In the example of FIG. 6, the display of the seismic intensity of the seismic sensor 10 installed within a predetermined distance with respect to the gas pipe is added. In FIG. 6, a part of the added seismic intensity display is shown by being surrounded by a broken line.
As mentioned above, there may be differences in the way the shaking is transmitted depending on the ground conditions, but by specifying the range of distance that is considered to overlap with the gas pipe, it is necessary to predict the damage situation to some extent before heading to the site. Becomes possible. The range considered to overlap with the gas pipe may be directly input as a numerical value, or may be specified from a plurality of options.

In this case as well, if the seismic intensity of all the measurement points is displayed regardless of the pipeline, the number of seismic intensity indications increases too much, and it may be difficult to confirm the seismic intensity of the pipeline of interest. However, as in the present embodiment, by adding only the seismic intensity with the seismic sensor 10 existing within the range of the distance specified by the user from the pipeline as the measurement point to the display, the seismic intensity in the pipeline of interest can be confirmed. And visibility are compatible.
It should be noted that there is a difference in the display method of the seismic intensity between the seismic sensor 10 installed at the position where it overlaps the pipeline and the seismic sensor 10 installed at the position where it is considered to overlap the pipeline. May be good. For example, the display color, the display size, and the context of the display may be changed.

Basically, the seismic intensity corresponding to the position overlapping with the pipeline may be displayed prominently, and the seismic intensity corresponding to the position deemed to overlap the pipeline may be displayed as a sub-display.
For example, the seismic intensity corresponding to the position overlapping with the pipeline may be displayed on the front side, and the seismic intensity corresponding to the position deemed to overlap the pipeline may be displayed on the back side.
Further, for example, the display size of the seismic intensity corresponding to the position overlapping with the pipeline may be larger than the display size of the seismic intensity corresponding to the position deemed to overlap the pipeline.
Further, for example, the display color of the seismic intensity corresponding to the position overlapping with the pipeline may be displayed in a color or brightness that is more conspicuous than the display color of the seismic intensity corresponding to the position deemed to overlap the pipeline. The color may be changed only with the characters, or the entire mark including the characters may be targeted.
Further, the display may be changed according to the distance from the pipeline even at a position deemed to overlap the pipeline.

By the way, the addition of the seismic intensity display by designating the range deemed to overlap with the gas pipe may be limited to only a part of the gas pipe designated by the user, not the entire screen. The designation of the region is not limited to the two-dimensional direction, and may include the three-dimensional direction.
FIG. 7 is a diagram showing another example of a seismic intensity display screen having a seismic sensor 10 installed at a position deemed to overlap the designated pipeline as a measurement point. In FIG. 7, the display of the seismic intensity is added only to the portion surrounded by the broken line. Designation of this area allows the user to see more information about the pipeline of interest.
In the example of FIG. 7, the area is specified in one place, but a plurality of areas may be specified on the screen. Further, the range of the distance considered to overlap with the gas pipe may be different for each designated area.

<Embodiment 2>
In the case of the first embodiment described above, the processing related to the display of the seismic intensity is executed on the server 20 side, but all or part of the corresponding processing may be executed on the terminal 30 side.
FIG. 8 is a diagram illustrating a configuration example of the seismic motion information providing system 1A used in the second embodiment. In FIG. 8, a reference numeral corresponding to a portion corresponding to that in FIG. 1 is added.
The example shown in FIG. 8 corresponds to the case where the data acquisition unit 211, the display control unit 212, and the display switching reception unit 213 are all executed by the terminal 30. The terminal 30 here is an example of an information processing system.

FIG. 9 is a diagram illustrating a processing operation example of the seismic motion information providing system 1A used in the second embodiment. P shown in the figure means processing.
Also in the case of this embodiment, the seismic sensor 10 that detects the occurrence of an earthquake having a seismic intensity higher than a predetermined seismic intensity through a MEMS type acceleration sensor transmits seismic motion information such as SI value to the seismic motion DB 22 (P1).
In the case of the present embodiment, the processing operation is started when the terminal 30 accepts the designation of the area and the pipeline to be displayed.

First, the terminal 30 transmits the designation of the area and the pipeline to the map DB 23 and the pipeline DB 24 (P11). In response to this, the terminal 30 acquires data on the designated area and pipeline (P12).
Subsequently, the terminal 30 requests the seismic motion DB 22 and the sensor position DB 25 for seismic motion information in which the measurement point overlaps with the pipeline (P13). In response to this, the terminal 30 acquires the corresponding seismic motion information and position information (P14). The terminal 30 calculates the seismic intensity from the acquired seismic motion information.
After that, the terminal 30 generates and displays a map in which the calculated seismic intensity is mapped on the pipeline (P15). The same map or the like as in the first embodiment is displayed on the display.

<Other embodiments>
Although the embodiments of the present invention have been described above, the technical scope of the present invention is not limited to the scope described in the above-described embodiments. It is clear from the description of the scope of claims that the above-described embodiment with various modifications or improvements is also included in the technical scope of the present invention.

In the above-described embodiment, the seismic motion information handled by the server 20 (see FIG. 1) is assumed to be collected from a MEMS type sensor that uses a battery as a power source, but the seismic motion information is output. The sensor 10 may include information output from a seismograph that requires power supply work.
Further, in the above-described embodiment, each of the server 20 and the terminal 30 has been described as an example of the information processing system, but when the functions are distributed and executed by the server 20 and the terminal 30, the server 20 and the terminal 30 are executed. Is an example of an information processing system.

1, 1A ... Seismic motion information providing system, 10 ... Seismic sensor, 20 ... Server, 21 ... Computer, 30 ... Terminal, 31 ... Display, 40 ... Internet, 211 ... Data acquisition unit, 212 ... Display control unit, 213 ... Display Switching reception section

Claims (6)

An acquisition means for acquiring output information of a seismic sensor that detects vibration at the installation position, and
When the output information or the information generated by processing the output information is displayed as the seismic motion information at the position on the map corresponding to the seismic sensor, the position of the pipeline displayed on the map is the relevant. An information processing system having a display control means for controlling the seismic motion information so as not to be displayed at a position other than the pipeline while displaying the seismic motion information. The information processing system according to claim 1, further comprising a receiving means for receiving the designation of the pipeline displayed on the map. The display control means adds the seismic motion information corresponding to the seismic sensor to the display target when the installation position of the seismic sensor is within a predetermined distance from the pipeline, according to claim 1 or 2. The information processing system described. The information processing system according to claim 3, further comprising a second receiving means for receiving the designation of the predetermined distance. The information processing according to claim 3 or 4, further comprising a third receiving means for receiving designation of an area for displaying the seismic motion information corresponding to the seismic sensor located within the predetermined distance from the pipeline. system. On the computer
A function to acquire the output information of the seismic sensor that detects the vibration of the installation position, and
When the output information or the information generated by processing the output information is displayed as the seismic motion information at the position on the map corresponding to the seismic sensor, the position of the pipeline displayed on the map is the relevant. A program that executes a function to display seismic motion information while controlling so that the seismic motion information is not displayed at positions other than the pipeline.