JP2020193935A - Evaluation system and evaluation program - Google Patents

Abstract

To improve the evaluation accuracy of earthquake shaking.SOLUTION: A server device 2 for evaluating earthquake shaking in an evaluation target includes: an acquisition unit 231 that acquires first information indicating the shaking of an earthquake specified by a terminal device 1 provided in the evaluation target and indicating the shaking of the earthquake in the evaluation target, and second information indicating the shaking of the earthquake and different from the first information; and an evaluation unit 232 that evaluates the shaking of the earthquake in the evaluation target based on the first information and the second information acquired by the acquisition unit 231. The acquisition unit 231 acquires information indicating the shaking of the earthquake output by an external device 3 as the second information, and the acquisition unit 231 acquires information indicating the shaking of the earthquake around the evaluation target specified by the terminal device 1 provided around the evaluation target as the second information.SELECTED DRAWING: Figure 1

Description

The present invention relates to an evaluation system and an evaluation program.

Conventionally, as an evaluation of earthquake shaking, a technique for evaluating seismic performance of a building has been known (see Patent Document 1).

JP-A-2017-58373

In the technique of Patent Document 1, the seismic performance of a building is evaluated as an evaluation of earthquake shaking using the detection value of an acceleration sensor installed in the building to be evaluated, and the evaluation is based on one type of information. There was room to improve the accuracy of earthquake-related evaluations because it was only done.

The present invention has been made in view of the above problems, and an object of the present invention is to improve the evaluation accuracy regarding the shaking of an earthquake.

In order to solve the above-mentioned problems and achieve the object, the evaluation system according to claim 1 is an evaluation system for evaluating the shaking of an earthquake in the evaluation target, and the first evaluation system provided in the evaluation target. The first information indicating the shaking of the earthquake specified by the device, the first information indicating the shaking of the earthquake in the evaluation target, and the second information indicating the shaking of the earthquake, the first information is It includes an acquisition means for acquiring different second information, and an evaluation means for evaluating the shaking of the earthquake in the evaluation target based on the first information and the second information acquired by the acquisition means. ..

Further, the evaluation system according to claim 2 is the evaluation system according to claim 1, wherein the acquisition means acquires information indicating the shaking of the earthquake output by the external system as the second information.

Further, the evaluation system according to claim 3 is the evaluation system according to claim 1 or 2, wherein the acquisition means is around the evaluation target specified by a second device provided around the evaluation target. Information indicating the shaking of the earthquake in the above is acquired as the second information.

Further, the evaluation system according to claim 4 is the evaluation system according to any one of claims 1 to 3, wherein the evaluation target is at least a building provided with the first apparatus. The evaluation means evaluates the seismic performance of the building in which the first device is installed.

Further, the evaluation system according to claim 5 is the evaluation system according to claim 1 or 2, wherein the evaluation target is at least a place where a plurality of the first devices are provided, and the evaluation means is , The magnitude of the shaking in the earthquake at each of the places where the plurality of first devices are provided is evaluated.

The evaluation system according to claim 6 is the evaluation system according to any one of claims 1 to 5, wherein the first device is a mobile terminal.

Further, the evaluation program according to claim 7 is an evaluation program that evaluates the shaking of an earthquake in the evaluation target, and uses a computer to evaluate the shaking of the earthquake specified by the first device provided in the evaluation target. The first information to be shown and the first information indicating the shaking of the earthquake in the evaluation target and the second information to be the second information showing the shaking of the earthquake and different from the first information are acquired. It functions as an acquisition means and an evaluation means for evaluating the shaking of the earthquake in the evaluation target based on the first information and the second information acquired by the acquisition means.

According to the evaluation system according to claim 1 and the evaluation program according to claim 7, by evaluating the shaking of the earthquake in the evaluation target based on the first information and the second information, for example, mutually. It is possible to improve the evaluation accuracy regarding the shaking of an earthquake by using different first information and second information.

According to the evaluation system according to claim 2, by acquiring the information indicating the shaking of the earthquake output by the external system as the second information, for example, the evaluation is performed in consideration of the information from other than the first device. Therefore, it is possible to perform multifaceted evaluation and improve the evaluation accuracy regarding the shaking of an earthquake.

According to the evaluation system according to claim 3, by acquiring the information indicating the shaking of the earthquake around the evaluation target as the second information, for example, the evaluation can be performed in consideration of the shaking around the evaluation target. Therefore, it is possible to improve the evaluation accuracy regarding the shaking of the earthquake.

According to the evaluation system according to claim 4, it is possible to improve the evaluation accuracy of seismic performance in a building, for example, by evaluating the seismic performance in the building.

According to the evaluation system according to claim 5, for example, by evaluating the magnitude of shaking in an earthquake at each place where the first device is provided, for example, evaluation of the magnitude of shaking in an earthquake at various places. It is possible to improve the evaluation accuracy of.

According to the evaluation system according to claim 6, since the first device is a mobile terminal, for example, the first device can be used to acquire the first information at various places, so that the shaking of the earthquake It is possible to further improve the evaluation accuracy of.

It is a block diagram of the information system which concerns on this embodiment. It is a figure which shows the area to which an information system is applied. It is a figure which illustrated the vibration information on a terminal side. It is a figure which illustrated the earthquake information. It is a figure which illustrated the user seismic information. It is a figure which illustrated the vibration information on a server side. It is a flowchart of the terminal side storage process. It is a flowchart of evaluation process. It is a flowchart of a place evaluation process. It is a figure which illustrated the evaluation screen.

Hereinafter, embodiments of the evaluation system and the evaluation program according to the present invention will be described in detail with reference to the drawings. The present invention is not limited to this embodiment.

[Basic concept of the embodiment]
First, the basic concept of the embodiment will be described. The embodiments are generally related to an evaluation system.

Here, the "evaluation system" is a system that evaluates the shaking of an earthquake in the evaluation target, and is, for example, a system configured as a dedicated system for evaluating the shaking of an earthquake, or a general-purpose system (for example,). , A server device, a personal computer, a tablet terminal, etc.), which is a concept including a system configured by implementing a function for evaluating the shaking of an earthquake. This "evaluation system" includes, for example, an acquisition means and an evaluation means.

The "evaluation target" is a target for which an evaluation regarding the shaking of an earthquake is performed, and is a concept including, for example, an object (for example, a building, a vehicle, etc.) and a place where the first device is provided. The term "place" includes, for example, a concept indicating one point having no spread, and also includes a concept indicating a region having a spread.

The "evaluation of earthquake shaking" is an arbitrary evaluation related to earthquake shaking, and is a concept including, for example, evaluation of seismic performance of a building, evaluation of the magnitude of shaking in an earthquake, and the like. "Evaluation of seismic performance of a building" is a concept including, for example, specifying whether or not the seismic performance of a building satisfies a standard. "Evaluation of the magnitude of shaking in an earthquake" means, for example, identifying a place where the shaking is larger than that of other places, or that the shaking of any designated place is compared to the shaking of other places. It is a concept that includes specifying whether or not it will grow.

The "acquisition means" is the first information indicating the shaking of the earthquake specified by the first device provided in the evaluation target, the first information indicating the shaking of the earthquake in the evaluation target, and the first information indicating the shaking of the earthquake. It is a means for acquiring the second information which is the second information and is different from the first information, and is a concept including, for example, a means for acquiring the information indicating the shaking of the earthquake output by the external system as the second information. Further, the concept includes means for acquiring information indicating the shaking of the earthquake around the evaluation target specified by the second device provided around the evaluation target as the second information.

The "first information" is information indicating the shaking of the earthquake specified by the first device provided in the evaluation target, specifically, information indicating the shaking of the earthquake in the evaluation target, for example, the first information. 1 It is a concept that includes information about vibration detected by the device.

The "second information" is information indicating the shaking of an earthquake, and specifically, is information different from the first information. Note that "different from the first information" is a concept including, for example, that the type of information is different from the first information, and that the device for detecting the information is different from the first information. It is a concept that includes. Further, the "second information" is a concept including, for example, information indicating the shaking of an earthquake output by an external system. Further, the "second information" is a concept including, for example, information indicating the shaking of an earthquake around the evaluation target specified by the second device provided around the evaluation target, and as an example, the first 2 It is a concept that includes information about vibration detected by the device.

The "first device" is a device provided for evaluation, specifically, a device capable of detecting information on earthquake shaking, and is a concept including, for example, a device for detecting information on vibration. Is. The specific type and configuration of the "first device" is arbitrary, but it is realized by, for example, implementing a function for detecting vibration in a dedicated device for detecting vibration or a general-purpose device. It is a concept including a device and the like, and one example is a concept including a mobile terminal (for example, a smartphone, a tablet terminal, etc.) that can be carried by a user, or a vibration measuring device that is fixedly installed. The "device provided in the evaluation target" is, for example, held by a device fixed to the evaluation target, a device placed in the evaluation target, or a user existing at the position of the evaluation target. It is a concept that includes devices and the like.

The "second device" is a device provided around the evaluation target, specifically, a device capable of detecting information on the shaking of an earthquake, for example, a device for detecting information on vibration. It is a concept that includes. The specific type and configuration of the "second device" is arbitrary, but for example, it is the same as the first device, and is for detecting vibration in a dedicated device for detecting vibration or a general-purpose device. It is a concept including devices realized by implementing the functions of, and as an example, a mobile terminal (for example, a smartphone, a tablet terminal, etc.) that can be carried by a user, a vibration measuring device that is fixedly installed, or the like. It is a concept that includes. The "devices provided around the evaluation target" are, for example, devices fixed to the surroundings of the evaluation target, devices placed around the evaluation target, and positions around the evaluation target. It is a concept including a device and the like held by an existing user.

The "external system" is a system different from the first device and the second device, and is a concept including, for example, a device that outputs information managed by a predetermined organization. As an example, it is managed by the Japan Meteorological Agency. It is a concept that includes a device that outputs information on the seismic intensity of the earthquake (that is, the degree of shaking intensity of the earthquake).

The "evaluation means" is a means for evaluating the shaking of an earthquake in an evaluation target based on the first information and the second information acquired by the acquisition means. For example, seismic resistance in a building provided with the first device. It is a concept including means for evaluating performance and the like, and also a concept including means for evaluating the magnitude of shaking in each place where a plurality of first devices are provided.

Then, in the embodiment shown below, a case where the "evaluation target" is a building provided with the first device and the "evaluation means" evaluates the seismic performance of the building will be described.

[Specific contents of the embodiment]
Next, the specific contents of the embodiment will be described.

(Constitution)
First, the configuration of the information system according to the present embodiment will be described. FIG. 1 is a block diagram of an information system according to the present embodiment. The number of terminal devices included in the information system 900 of FIG. 1 is arbitrary, but here, for convenience of explanation, three terminal devices 101 to 103 will be illustrated and described. Further, for example, it is assumed that the terminal devices 101 to 103 are owned by each user and are configured in the same manner as each other, and each part of the terminal device 101 will be specifically illustrated and described. Further, for example, when it is not necessary to distinguish each terminal device included in the information system 900 from each other, the terminal devices 1 will be generically described.

(Configuration-Information system)
The information system 900 of FIG. 1 is a system including an evaluation system, and includes, for example, a terminal device 1, a server device 2, and an external device 3 capable of communicating with each other via a communication network (not shown).

(Configuration-Information system-Terminal device)
The terminal device 1 is a mobile terminal held by each user of the information system 900. The specific content and configuration of the terminal device 1 are arbitrary, but for example, a known smartphone or tablet terminal can be used, and as an example, the communication unit 11, the touch pad 12, the display 13, and the detection can be used. A unit 14, a recording unit 15, and a control unit 16 are provided.

(Configuration-Information system-Terminal device-Communication unit)
The communication unit 11 is a communication means for communicating with another device (for example, a server device 2 or the like) via a network. The specific type and configuration of the communication unit 11 is arbitrary, but it can be configured by using, for example, a known communication circuit or the like.

(Configuration-Information system-Terminal device-Touch pad)
The touch pad 12 is an operation means for receiving various operation inputs from the user by being pressed by a user's finger or the like. The specific configuration of the touch pad 12 is arbitrary, but for example, a known one provided with an operation position detecting means by a resistance film method, a capacitance method, or the like can be used.

(Configuration-Information system-Terminal device-Display)
The display 13 is a display means for displaying various images under the control of the control unit 16. The specific configuration of the display 13 is arbitrary, but for example, a flat panel display such as a known liquid crystal display or an organic EL display can be used. The touch pad 12 and the display 13 may be superimposed on each other to form a touch panel integrally.

(Configuration-Information system-Terminal device-Detector)
The detection unit 14 is a detection means for detecting or specifying various information. The specific type and configuration of the detection unit 14 are arbitrary, but for example, a vibration detection device (including an acceleration sensor or the like) for detecting the vibration of the terminal device 1 itself, a position of the terminal device 1 itself can be determined. A device for specifying a position (including, for example, a device that receives a signal from GPS (Global Positioning System) and identifies its own position based on the received signal), and the current date and time. It can be configured to include a timekeeping device (for example, a timer or the like) that specifies the date and time. The position specifying device is configured to specify the position of the terminal device 1 itself as coordinates based on an arbitrary reference (for example, longitude and latitude). As an example, a map information database (described later) will be used. Hereinafter, it will be described as being configured so that the position of the terminal device 1 itself can be specified on the map specified by the map information stored in 151 (the "database" is referred to as "DB"). .. Then, the control unit 16 of the terminal device 1 appropriately accesses the vibration detection device, the position identification device, and the timekeeping device of the detection unit 14, so that the vibration of the terminal device 1 itself and the position of the terminal device 1 itself can be determined. And it becomes possible to specify the current date and time.

(Configuration-Information system-Terminal device-Recording unit)
The recording unit 15 is a recording means for recording a program and various data necessary for the operation of the terminal device 1, and is configured by using, for example, a hard disk (not shown) as an external recording device. However, instead of or in combination with the hard disk, any other recording medium, including a magnetic recording medium such as a magnetic disk or an optical recording medium such as a DVD or Blu-ray disc, can be used (recording by another device). The same applies to the department).

Further, the recording unit 15 includes, for example, a map information DB 151 and a terminal-side vibration information DB 152.

(Configuration-Information system-Terminal device-Recording unit-Map information DB)
The map information DB 151 is a map information storage means for storing map information. Here, the "map information" is information that identifies a map including an area to which the information system is applied. FIG. 2 is a diagram showing an area to which the information system is applied. The map information stored in the map information DB 151 includes information for specifying the position (that is, coordinates) of a feature such as a building 5 shown in FIG. 2, the position of a road, or the like, and the map. It will be described as being able to identify the map shown in FIG. 2 by referring to the information. Here, for example, the building 5 in FIG. 2 indicates the home building of each user of the terminal devices 101 to 103. For example, the building 51 is the home of the user of the terminal device 101 and the building 51 is concerned. Is the coordinate of "(x51, y51)", and the building 52 is the home of the user of the terminal device 102, and the position of the building 52 is the coordinate of "(x52, y52)". Will be described below assuming that is the home of the user of the terminal device 103 and the position of the building 53 is the coordinates of "(x53, y53)". The specific notation of these coordinates is for convenience of explanation. Then, such map information is recorded by an arbitrary method, but for example, it is recorded by inputting through a predetermined recording medium, or information distributed from a distribution center (not shown) is received. It is recorded by.

(Configuration-Information system-Terminal device-Recording unit-Terminal side vibration information DB)
The terminal-side vibration information DB 152 is a terminal-side vibration information storage means for storing terminal-side vibration information. FIG. 3 is a diagram illustrating vibration information on the terminal side. The "terminal side vibration information" is information related to vibration recorded on the terminal device 1 side. For example, as shown in FIG. 2, the item "vibration information", the item "terminal position information", and the item "date and time" Information is information in which "information" and information corresponding to each item are associated with each other. The information corresponding to the item "vibration information" is vibration information for specifying the vibration detected by the terminal device 1 itself, and is, for example, information for specifying the vibration detected by the vibration detection device of the detection unit 14. As specific vibration information, waveform information including arbitrary information such as amplitude or period is used, and in FIG. 3, for convenience of explanation, the waveform information will be referred to as “Dv011” or the like. The information corresponding to the item "terminal position information" is the terminal position specifying information for specifying the position of the terminal device 1 (in FIG. 3, the coordinates of the position specified by the position specifying device of the detection unit 14 are "(x51). , Y51) "etc.). The information corresponding to the item "date and time information" is the date and time information for specifying the date and time when the terminal side vibration information was recorded (in FIG. 3, "20190221045" for specifying 10:45 on February 02, 2019). Then, such terminal-side vibration information is recorded by an arbitrary method, and is recorded, for example, by executing a terminal-side storage process described later.

(Configuration-Information system-Terminal device-Control unit)
The control unit 16 is a control means for controlling the terminal device 1, and specifically, the CPU, various programs interpreted and executed on the CPU (basic control programs such as an OS, and specific functions started on the OS). It is a computer configured with an internal memory such as a RAM for storing a program and various data (including an application program that realizes the above) (the same applies to the control unit of other devices). In particular, the program according to the embodiment is installed in the terminal device 1 via an arbitrary recording medium or network to substantially configure each part of the control unit 16 (the same applies to the control units of other devices). To do). The processing performed by each unit of the control unit 16 will be described later.

(Configuration-Information system-Server device)
The server device 2 is an evaluation system, and includes, for example, a communication unit 21, a recording unit 22, and a control unit 23.

(Configuration-Information system-Server device-Communication unit)
The communication unit 21 is a communication means for communicating with other devices (for example, a terminal device 1, an external device 3, etc.) via a network. The specific type and configuration of the communication unit 21 is arbitrary, but it can be configured in the same manner as the communication unit 11 of the terminal device 1, for example.

(Configuration-Information system-Server device-Recording unit)
The recording unit 22 is a recording means for recording programs and various data necessary for the operation of the server device 2. For example, map information DB221, earthquake information DB222, seismic reference information DB223, user seismic information DB224, and server-side vibration. Information DB 225 is provided.

(Configuration-Information system-Server device-Recording unit-Map information DB)
The map information DB 221 is a map information storage means for storing map information, and stores the same map information as the map information DB 151 of the terminal device 1.

(Configuration-Information system-Server device-Recording unit-Earthquake information DB)
The earthquake information DB 222 is an earthquake information storage means for storing earthquake information. FIG. 4 is a diagram illustrating earthquake information. The "earthquake information" is information output by the external device 3 of FIG. 1 and indicates the shaking of the earthquake. For example, as shown in FIG. 4, the item "earthquake date and time information" and the item "regional information". , And the item "seismic intensity information" and the information corresponding to each item are associated with each other. The information corresponding to the item "earthquake date and time information" is the earthquake date and time information that specifies the date and time when the earthquake occurred (in FIG. 4, the information has the same format as the date and time information in FIG. 3, such as "20190221045"). The information corresponding to the item "regional information" is regional information that identifies the region (in FIG. 4, the name of the municipality, etc., and the name of the region shown in FIG. 2, "Ar1", etc.). It should be noted that this "Ar1" and the like are described for convenience of explanation, and the area on the map specified by the area information can be specified by referring to the map information of the above-mentioned map information DB221. It will be described below as being configured. The information corresponding to the item "seismic intensity information" is seismic intensity information that specifies the seismic intensity of the earthquake (in FIG. 4, "3" that specifies the seismic intensity 3 and the like).

Then, such earthquake information is recorded by an arbitrary method, but for example, when an earthquake occurs, an arbitrary method (for example, measurement results of seismographs installed in each area) is used on the external device 3 side. The seismic intensity of each area is measured by a known method for measuring the seismic intensity, etc.), and the external device 3 provides information for specifying the date and time of the earthquake, information for specifying the area, and information for specifying the seismic intensity measured for the area. It will be output. Then, the control unit 23 of the server device 2 receives each of these information and records the earthquake information corresponding to each of the received information. Here, for example, an earthquake occurred at 10:45 on February 02, 2019, and the seismic intensity in each area such as "Ar1", "Ar2", and "Ar5" is seismic intensity 3, seismic intensity 3, and seismic intensity 5. In the case of the above, the control unit 23 of the server device 2 receives each information output from the external device 3 and displays each information associated with "earthquake date and time information" = "20190221045" in FIG. It will be recorded.

(Configuration-Information system-Server device-Recording unit-Seismic standard information DB)
The seismic standard information DB 223 is a seismic standard information storage means for storing seismic standard information. The “seismic standard information” is, for example, seismic standard information for specifying a standard for evaluating the seismic performance of the building 5. Then, for such seismic standard information, any standard such as information determined based on a predetermined law or information independently determined by the user shall be used, and the user shall use an input means (not shown). It is recorded by inputting to the server device 2.

(Configuration-Information system-Server device-Recording unit-User seismic information DB)
The user seismic information DB 224 is a user seismic information storage means for storing user seismic information. FIG. 5 is a diagram illustrating user seismic information. The "user seismic information" is information that specifies the evaluation of seismic performance, for example, as shown in FIG. 5, the item "user ID", the item "authentication information", the item "building location information", and the item " This is information in which the items "building information", the item "residential floor information", and the item "seismic evaluation information" are associated with the information corresponding to each item. The information corresponding to the item "user ID" is user identification information that uniquely identifies the user of the terminal device 1 (hereinafter, "identification information" is referred to as "ID") (in FIG. 5, the user of the terminal device 101). The ID "IDu1", the user ID of the terminal device 102 "IDu2", the user ID of the terminal device 103 "IDu3", etc.). The information corresponding to the item "authentication information" is the authentication information used to authenticate each user (in FIG. 5, it is a password, such as "Pass1"). The information corresponding to the item "building position information" is the building position information that specifies the position of the building 5 in which each user lives (in FIG. 5, it is the same information as the terminal position information in FIG. 3 and is shown in FIG. The position of the building 51 of 2 is "(x51, y51)", the position of the building 52 is "(x52, y52)", and the position of the building 53 is "(x53, y53)").

The information corresponding to the item "building information" is building information that specifies the characteristics of the building 5 in which each user lives. Arbitrary information can be used as the building information, but in FIG. 5, the information for specifying the building year, the information for specifying the building structure, and the information for specifying the building category are separated by "," in this order. The case where the information is used will be described as an example. The “year of construction” specifies the number of years that have passed since the building 5 was completed, and in FIG. 5, it is “8” or the like that specifies 8 years. The "building structure" specifies the structure of the building 5, and in FIG. 5, it is "iron" that specifies that it is made of reinforced steel, "wood" that specifies that it is made of wood, and the like. The "building category" specifies the type of building, and in FIG. 5, "ma" for specifying an apartment, "door" for specifying a detached house, and "a" for specifying an apartment, which is not shown. Is.

The information corresponding to the item "residential floor information" is the residential floor information that specifies the number of floors in which the user resides (in FIG. 5, the number of floors in which the user resides and the total number of floors of the building 5 are "/". It is separated by, and "3/10" etc. that specifies that you live on the 3rd floor of a 10-story building). It should be noted that no specific information is recorded for the residential floor information corresponding to the building information including the "door" in FIG. 5 (that is, corresponding to the detached house). The information corresponding to the item "Seismic evaluation information" is seismic evaluation information that specifies the evaluation result regarding the seismic performance of the building 5 (in FIG. 5, "good" that specifies that the seismic performance meets the criteria, and FIG. 5 Although not shown in the above, it is "not" to specify that seismic performance does not meet the standard).

Then, such user seismic information is recorded by an arbitrary method. For example, among the user seismic information, the user ID, the authentication information, the building position information, the building information, and the residential floor information are recorded. Is that the user inputs information via the touch pad 12 of his / her own terminal device 1, the control unit 16 of the terminal device 1 transmits this input information to the server device 2, and the control unit 23 of the server device 2 sends the input information to the server device 2. , Receive and record the transmitted information. Further, among each information of the user seismic information, the seismic evaluation information is recorded by executing the evaluation process described later.

(Configuration-Information system-Server device-Recording unit-Server side vibration information DB)
The server-side vibration information DB 225 is a server-side vibration information storage means for storing server-side vibration information. FIG. 6 is a diagram illustrating vibration information on the server side. The "server-side vibration information" is information related to vibration recorded on the server device 2 side, and specifically, is information including information related to vibration detected by a plurality of terminal devices 1, for example, FIG. As shown in the above, the item "user ID", the item "vibration information", the item "terminal position information", and the item "date and time information" are information in which the information corresponding to each item is associated with each other. The information corresponding to the item "user ID" is the same as the information of the item having the same name in FIG. Further, the information corresponding to the item "vibration information", the information corresponding to the item "terminal position information", and the information corresponding to the item "date and time information" are the same as the information of the item having the same name in FIG. Then, such server-side vibration information is recorded by an arbitrary method, and is recorded, for example, by executing a server-side storage process described later.

(Configuration-Information system-Server device-Control unit)
The control unit 23 is a control means for controlling the server device 2, and for example, functionally conceptually, includes an acquisition unit 231 and an evaluation unit 232. The acquisition unit 231 includes first information indicating the shaking of the earthquake specified by the terminal device 1 provided in the building 5 to be evaluated, and first information indicating the shaking of the earthquake in the building 5 to be evaluated. It is an acquisition means for acquiring the second information indicating the shaking of the earthquake and the second information different from the first information. The evaluation unit 232 is an evaluation means for evaluating the shaking of the earthquake in the building 5 to be evaluated based on the first information and the second information acquired by the acquisition unit 231. The specific processing executed by each unit of the control unit 23 will be described later.

(Configuration-Information system-External device)
The external device 3 is the above-mentioned external system. The specific type and configuration of the external device 3 is arbitrary, but for example, it can be configured by using any device managed by the Japan Meteorological Agency.

(processing)
Next, the processing executed by the information system 900 configured in this way will be described. Specifically, the terminal-side storage process, the terminal-side transmission process, the server-side storage process, and the evaluation process will be described. Each user of the terminal device 1 first installs an application for evaluating the shaking of the earthquake in the evaluation target on the terminal device 1, and then uses the terminal device 1 to perform his / her own user ID and authentication in FIG. Information, building location information, building information, and residential floor information are transmitted and recorded, and then the user ID of the user is input in the installed application, and then the application is always operated on the terminal device 1. Will be described below. Here, for example, a user of the terminal devices 101 to 103 inputs "IDu1", "IDu2", and "IDu3" as his / her user ID to the application of his / her terminal devices 101 to 103. It is explained as.

(Processing-Terminal side storage processing)
First, the terminal-side storage process will be described. FIG. 7 is a flowchart of the terminal side storage process (hereinafter, each step is referred to as “S”). The "terminal-side storage process" is roughly a process executed by the terminal device 1, and specifically, a process of storing the terminal-side vibration information of FIG. The timing of executing this terminal-side storage process is arbitrary, but for example, after the above-mentioned application starts operating on the terminal device 1, it is assumed that the start is repeatedly started at predetermined time intervals, and the start is started. This will be described below.

In SA1, the control unit 16 of the terminal device 1 acquires vibration waveform information, current position information, and current date and time information. The "vibration waveform information" is, for example, waveform information indicating the vibration of the terminal device 1 itself, and the "current position information" is information indicating the current position of the terminal device 1 itself. The "current date and time information" is information indicating the current date and time.

Specifically, it is optional, but first, regarding the vibration waveform information, for example, the vibration detection device of the detection unit 14 is accessed, and the waveform information corresponding to the output from the acceleration sensor detected by the vibration detection device is obtained. , It is specified and acquired as vibration waveform information indicating the vibration of the terminal device 1 itself. Here, the output from the acceleration sensor is subjected to arbitrary calibration (for example, calibration that accurately represents the acceleration of the three axes by removing the influence of gravitational acceleration), and then waveform information based on the information after calibration. May be configured to obtain and measure. Here, for example, the terminal devices 101 to 103 of FIG. 1 measure and acquire their own vibration waveform information.

Further, regarding the current position information, for example, the position specifying device of the detection unit 14 is accessed, and the information for specifying the position specified by the position specifying device is acquired as the current position information. Here, for example, it is assumed that the terminal devices 101 to 103 of FIG. 1 are provided in the buildings 51 to 53 of FIG. 2, and the current position information is "(x51, y51)", "(x52, y52)". Acquire "(x53, y53)".

Further, regarding the current date and time information, for example, the timekeeping device of the detection unit 14 is accessed, and information for specifying the date and time that the timekeeping device is timing is acquired as the current date and time information. Here, for example, the terminal devices 101 to 103 of FIG. 1 acquire information for specifying "February 02, 2019 10:45" as the current date and time information.

In SA2, the control unit 16 of the terminal device 1 determines whether or not the vibration waveform information acquired in SA1 indicates vibration due to an earthquake. Specifically, although it is arbitrary, for example, the terminal device 1 may be held by the user and vibrate according to the movement of the user, so that the vibration waveform information measured and acquired by the SA1 is used by the user. It is determined whether the vibration caused by the movement or the vibration caused by the earthquake shows only the vibration caused by the movement of the user or the vibration caused by the earthquake.

The determination method here is arbitrary, but for example, the characteristics of the vibration waveform information indicating the vibration caused by the movement of the user and the vibration waveform information indicating the vibration caused by the movement of the earthquake (for example, the characteristics related to the amplitude or the period) are arbitrarily specified in advance. (For example, a method of performing an experiment or a simulation, etc.), and a method of making a judgment based on the grasped result may be used, or a model (vibration waveform information) for making the judgment may be used. A model that outputs whether it shows only the vibration caused by the user's movement or the vibration caused by the earthquake when input) is generated in advance by performing machine learning, and the judgment is made using the model. It may be configured as.

Specifically, for example, the vibration waveform information acquired by SA1 is acquired, and the acquired vibration waveform information is determined by the above-mentioned determination method. Then, when it is determined that the vibration waveform information acquired by SA1 indicates only the vibration due to the movement of the user, it is determined that the vibration waveform information acquired by SA1 does not indicate the vibration due to the earthquake (NO of SA2). , End the process. If it is determined that the vibration waveform information acquired by SA1 also indicates vibration due to an earthquake, it is determined that the vibration waveform information acquired by SA1 indicates vibration due to an earthquake (YES in SA2), and SA3 is set. Transition. Here, for example, it is assumed that an earthquake occurs at “10:45 on February 02, 2019” and the terminal devices 101 to 103 are shaken by the earthquake. In this case, the terminal devices 101 to 103 determine that the vibration waveform information acquired by SA1 indicates vibration due to an earthquake.

In SA3, the control unit 16 of the terminal device 1 stores the terminal side vibration information. Specifically, although it is arbitrary, for example, the vibration waveform information, the current position information, and the current date and time information acquired by SA1 are acquired, and the acquired vibration waveform information, the current position information, and the information corresponding to the current date and time information are obtained. Is stored as the vibration information, the terminal position information, and the date and time information of FIG.

Here, for example, the terminal device 101 has FIG. 3 as information corresponding to the vibration waveform information acquired by SA1, "(x51, y51)", and "information specifying" February 02, 2019, 10:45 ". "Vibration information" = "Dv011", "terminal position information" = "(x51, y51)", "date and time information" = "20190221045" is stored. Further, for example, the terminal device 102, like the terminal device 101, has "vibration information" = "Dv021" and "terminal position information" = "(x52, y52) as its own terminal-side vibration information, although not shown. ) ”,“ Date and time information ”=“ 20190221045 ”is stored. Further, for example, the terminal device 103, like the terminal device 101, has "vibration information" = "Dv031" and "terminal position information" = "(x53, y53) as its own terminal-side vibration information, although not shown. ) ”,“ Date and time information ”=“ 20190221045 ”is stored. In this way, the terminal side vibration information is stored. This ends the terminal-side storage process.

In FIG. 3, "(x121, y121)" or "(x991, y991)" is stored as the terminal position information, but the terminal device 101 is provided at an arbitrary place other than the building 51 when an earthquake occurs. It is due to the fact that it was done. Further, since the above-mentioned SA2 processing is performed, each information at the time of an earthquake is stored as terminal-side vibration information.

(Processing-Terminal side transmission processing)
Next, the terminal-side transmission process will be described. The "terminal-side transmission process" is generally a process executed by the terminal device 1, and specifically, a process of transmitting the terminal-side vibration information of FIG. 3 to the server device 2. The control unit 16 of the terminal device 1 sets the recording unit 15 at an arbitrary timing (for example, every fixed period (1 to 3 days, etc.) or every time the terminal side vibration information of FIG. 3 is newly recorded). With reference, FIG. 3 which has not yet been transmitted by an arbitrary method (for example, a method in which a flag information indicating that the information has been transmitted is attached to the transmitted information and the determination is made by paying attention to the flag information). It is determined whether or not the terminal side vibration information exists, and if it is determined that the terminal side vibration information exists, the terminal side vibration information that has not yet been transmitted is acquired, and the user ID input to the above-mentioned application is acquired. , The acquired user ID and the vibration information on the terminal side are associated with each other and transmitted to the server device 2.

Here, for example, the terminal device 101 acquires the top-level information and "IDu1" when the top-level information specifically displayed in FIG. 3 has not yet been transmitted, and these acquired information. Are associated with each other and transmitted to the server device 2. The terminal devices 102 and 103 also perform the same processing as the terminal device 101. This ends the terminal-side transmission process.

(Processing-Server side storage processing)
Next, the server-side storage process will be described. The "server-side storage process" is generally a process executed by the server device 2, and specifically, is a process for storing the server-side vibration information of FIG. The timing for executing this server-side storage process is arbitrary, but for example, after the power of the server device 2 is turned on, the start is repeatedly started at predetermined time intervals, and the following description will be made from the start.

The acquisition unit 231 of the server device 2 monitors the communication unit 21 and determines whether or not the user ID and the terminal side vibration information from the terminal device 1 have been received. The user ID and the terminal side vibration information (that is, vibration information, terminal position information, date and time information) are acquired, and the acquired information is stored as each information of the server side vibration information of FIG. Here, for example, when "IDu1" and the top-level information specifically displayed in FIG. 3 are received from the terminal device 101, the top-level information specifically shown in FIG. 6 is stored. Further, based on the information received from the terminal devices 102 and 103, the information specifically displayed in association with the "user ID" = "IDu2" and "IDu3" in FIG. 6 is stored. In this way, the server-side vibration information is stored. This ends the server-side storage process.

(Processing-evaluation processing)
Next, the evaluation process will be described. FIG. 8 is a flowchart of the evaluation process. The "evaluation process" is generally a process executed by the server device 2, and specifically, is a process of storing and outputting seismic evaluation information in the user seismic information of FIG. The timing of executing this evaluation process is arbitrary, but for example, when the terminal device 1 transmits the evaluation request signal to the server device 2 in response to the user's operation and the server device 2 receives the evaluation request signal. It will be started in, and the following will be explained from the point where the start is started.

The "evaluation request signal" is a signal for which the user requests an evaluation of the seismic performance of the building 5 in which the user resides, and is, for example, a signal including a user ID and authentication information. Here, for example, the user of the terminal device 101 inputs "IDu1" which is his / her own user ID and "Pass1" which is the authentication information into the touch pad 12, and the terminal device 101 is evaluated including "IDu1" and "Pass1". The case where the request signal is transmitted, the server device 2 receives the evaluation request signal, and the evaluation process is started will be described as an example.

In SB1 of FIG. 8, the control unit 23 of the server device 2 determines whether or not authentication can be performed. Specifically, although it is optional, the user ID and authentication information included in the evaluation request signal received at the start of the evaluation process are acquired, and the acquired user ID and authentication information are referred to with reference to the user seismic information in FIG. Judgment is made based on whether or not information of the same combination as the combination of is present. Then, if the information of the same combination does not exist, it is determined that the authentication cannot be performed (NO of SB1), and a message such as "Authentication could not be performed" is transmitted to the terminal device 1 side to end the process. Further, when the same combination of information exists, it is determined that the information can be authenticated (YES of SB1), and the process proceeds to SB2.

Here, for example, the evaluation request signal received at the start of the evaluation process includes "IDu1" and "Pass1", but since the combination of these information exists at the top of FIG. 5, it can be authenticated. judge.

In SB2 of FIG. 8, the acquisition unit 231 of the server device 2 acquires information. Specifically, although it is optional, for example, the building 5 to be evaluated (hereinafter, also referred to as “evaluation target building”) is specified, and the vibration information corresponding to the specified “evaluation target building” is acquired. In addition, vibration information corresponding to the building 5 around the "evaluation target building" (hereinafter, "peripheral building") is acquired, and the seismic intensity information of the area including these "evaluation target building" and "peripheral building" is also obtained. To get.

Specifically, first, the user ID included in the evaluation request signal received at the start of the evaluation process is acquired, and the user seismic information of FIG. 5 is referred to, and the building position information and the building information corresponding to the acquired user ID are acquired. , And the residential floor information is specified, the building 5 indicated by the specified information is specified as the "evaluation target building", and the building 5 is specified as the "evaluation target building" by referring to the map information of the map information DB 221 in FIG. The building 5 around the building 5 (for example, the building 5 within a radius of 50 m to 70 m of the building 5 specified as the "evaluation target building") is specified as the "peripheral building" (hereinafter, the first acquisition step). ).

Next, the above-mentioned building position information specified when specifying as the "evaluation target building" in the above-mentioned "first acquisition step" was acquired, and was acquired with reference to the "server-side vibration information" in FIG. The terminal position information corresponding to the building position information is specified, and the vibration information corresponding to the specified terminal position information is acquired as the vibration information corresponding to the "evaluation target building" (hereinafter, evaluation target building vibration information) (hereinafter, evaluation target building vibration information). , Second acquisition step).

Next, with reference to the map information of the map information DB221 of FIG. 1, the position (that is, coordinates) of the "peripheral building" specified in the "first acquisition step" is specified, and the "server side" of FIG. With reference to "vibration information", the vibration information corresponding to the position of the specified "peripheral building" and the date and time information corresponding to the vibration information acquired in the "second acquisition step" corresponds to the "peripheral building". It is acquired as vibration information (hereinafter, surrounding building vibration information) (hereinafter, the third acquisition step).

Next, with reference to the earthquake information of FIG. 4, it is associated with the area information including the "evaluation target building" and the "peripheral building" specified in the "first acquisition step", and is associated with the "second acquisition step". The seismic intensity information associated with the earthquake date and time information corresponding to the date and time information corresponding to the vibration information acquired in the "acquisition step" is acquired (hereinafter, the fourth acquisition step).

Here, for example, in the "first acquisition step", "IDu1" is acquired as the user ID included in the evaluation request signal received at the start of the evaluation process, and the acquisition is performed with reference to the user seismic information of FIG. Identify the building location information "(x51, y51)" corresponding to the user ID "IDu1", the building information "8, iron, ma", and the residential floor information "3/10". , The building 51 of FIG. 2 indicated by these identified information is specified as the "evaluation target building", and the buildings 52 and 52 of FIG. 2 are designated as "peripheral buildings" with reference to the map information of the map information DB 221 of FIG. Identify.

Next, in the "second acquisition step", the object position information "(x51, y51)" specified in the above-mentioned "first acquisition step" is acquired, and the "server-side vibration information" in FIG. 6 is obtained. By referring to it, the terminal position information "(x51, y51)" corresponding to the acquired building position information "(x51, y51)" is specified, and the specified terminal position information "(x51, y51)" is specified. ) ”, Which is the vibration information corresponding to“ Dv011 ”, is acquired as the evaluation target building vibration information. The building vibration information to be evaluated here corresponds to the "first information", and the terminal device 101 that detects the information corresponds to the "first device".

Next, in the "third acquisition step", the positions of the buildings 52 and 53 which are the "peripheral buildings" specified in the "first acquisition step" with reference to the map information of the map information DB221 of FIG. “(X52, y52)” and “(x53, y53)” are specified, and “(x52, y52)” is the position of the specified “peripheral building” with reference to the “server-side vibration information” in FIG. ) ”And“ (x53, y53) ”and“ Dv021 ”and“ Dv031 ”which are vibration information corresponding to“ 20190221045 ”which is the date and time information corresponding to the vibration information acquired in the“ second acquisition step ”. Is acquired as vibration information of surrounding buildings. The surrounding building vibration information here corresponds to the "second information", and the terminal devices 102 and 103 that have detected the information correspond to the "second device".

Next, with reference to the earthquake information of FIG. 4, it is the area information including the building 51 which is the "evaluation target building" and the buildings 52 and 53 which are the "peripheral buildings" specified in the "first acquisition step". "Ar1" is associated with the seismic intensity information associated with the earthquake date and time information corresponding to "20190221045", which is the date and time information corresponding to the vibration information acquired in the "second acquisition step". 3 ”is acquired. The seismic intensity information here also corresponds to the "second information", and the above-mentioned external device 3 that outputs the information also corresponds to the "second device".

In SB3 of FIG. 8, the evaluation unit 232 of the server device 2 evaluates the seismic performance of the “building to be evaluated”. Specifically, although it is optional, the seismic performance can be determined based on the evaluation target building vibration information, surrounding building vibration information, seismic intensity information, and seismic standard information stored in the seismic standard information DB223 in FIG. Evaluate whether the criteria are met.

The specific evaluation method here is arbitrary and variously assumed, but for example, a case of evaluating by focusing on the amplitude of shaking will be described as an example. In particular, the amplitude of the shaking will be described using a numerical value, and it is assumed that the larger the value, the larger the amplitude. In addition, the standard that the building 5 specified in the seismic standard information stored in the seismic standard information DB 223 should meet is "the structure of the building 5 does not shake more than the amplitude corresponding to the seismic intensity indicated by the seismic intensity information" ( Hereinafter, the case of “exemplary evaluation criteria”) will be described as an example. The evaluation method here shows only one example, and is not limited to this evaluation method.

Specifically, first, the seismic standard information stored in the seismic standard information DB 223 is acquired, and based on the acquired seismic standard information, the standard that the seismic performance of the building 5 should satisfy is specified (hereinafter, the first). Evaluation step). Here, for example, "exemplary evaluation criteria" are specified.

Next, the seismic intensity information acquired by SB2 is acquired, and the seismic intensity amplitude, which is the amplitude corresponding to the seismic intensity specified by the acquired seismic intensity information, is specified (hereinafter, the second evaluation step). The specific method for specifying the seismic intensity amplitude here is arbitrary. For example, the seismic intensity amplitude specifying information, which is table information in which the seismic intensity and the seismic intensity amplitude corresponding to the seismic intensity are associated with each other, is recorded in the recording unit 22. The case where the seismic intensity amplitude is specified will be described with reference to this seismic intensity amplitude specifying information. Here, for example, it is assumed that seismic intensity amplitude = "20" for seismic intensity = "2", seismic intensity amplitude = "30" for seismic intensity = "3", and the like are stored as seismic intensity amplitude specific information. In this case, the seismic intensity information acquired by SB2 is acquired, and the seismic intensity amplitude = "30" corresponding to the seismic intensity = "3" specified by the acquired seismic intensity information is specified.

Next, the evaluation target building vibration information and the surrounding building vibration information acquired in SB2 are acquired, and the evaluation target building amplitude, which is the amplitude corresponding to the acquired evaluation target building vibration information, and the acquired peripheral target building vibration information are supported. The amplitude of the surrounding target building, which is the amplitude, is an arbitrary method (for example, a method of specifying the average value of the amplitude in the waveform by focusing on the fact that the vibration information is the information of the waveform indicating the vibration (note that the maximum value of the amplitude) (You may use a method to specify), etc.) (hereinafter, the third evaluation step). Here, for example, the amplitude corresponds to the acquired evaluation target building vibration information "Dv011" acquired by SB2 and the surrounding building vibration information "Dv021" and "Dv031". "42" as the evaluation target building amplitude, "40" for "Dv021" and "41" for "Dv031" as the peripheral target building amplitude, which is the amplitude corresponding to the acquired peripheral target building vibration information, are specified.

Next, using the seismic intensity amplitude specified in the second evaluation step, and the evaluation target building amplitude and surrounding target building amplitude specified in the third evaluation step, the seismic performance of the "evaluation target building" is determined in the first evaluation step. Evaluate whether or not the specified criteria are met (hereinafter referred to as the fourth evaluation step).

Regarding the fourth evaluation step, in detail, first, the seismic intensity amplitude specified in the second evaluation step and the evaluation target building amplitude specified in the third evaluation step are acquired, and the acquired evaluation target building amplitude and seismic intensity amplitude are obtained. The magnitude is determined by comparing with each other (hereinafter, the first determination). Then, in the "first determination", when it is determined that the amplitude of the building to be evaluated is not larger than the seismic intensity amplitude (that is, when it is determined that the amplitude of the building to be evaluated is less than or equal to the seismic intensity amplitude), "the building to be evaluated is evaluated. It is evaluated that the seismic performance of "" meets the criteria specified in the first evaluation step.

In addition, when it is determined in the "first judgment" that the amplitude of the building to be evaluated is larger than the amplitude of the seismic intensity, it is "evaluated" whether the amplitude of the building to be evaluated is large due to the structure of the "building to be evaluated". In order to determine whether the amplitude of the building to be evaluated is large due to the ground on which the "building to be evaluated" is built instead of the structure of the "building to be evaluated", the amplitude of the surrounding buildings specified in the third evaluation step is used. All of them are acquired, and the difference value obtained by subtracting each of the surrounding building amplitudes from the above-mentioned evaluation target building amplitude is calculated for the number of surrounding building amplitudes. Then, it is determined whether or not there are a predetermined number (for example, one or the like) or more of the difference values that are equal to or more than the predetermined values (for example, "5" to "7") among the calculated difference values (hereinafter, the first). Judgment of 2). In the "second determination", when it is determined that there are a predetermined number or more of the calculated difference values that are equal to or greater than the predetermined value, the building amplitude to be evaluated is superior to the amplitude of at least one surrounding building. Therefore, it is judged that the amplitude of the building to be evaluated is large due to the structure of the building to be evaluated, and the seismic performance of the building to be evaluated is the criterion specified in the first evaluation step. Is evaluated as not satisfying.

In addition, in the "second determination", when it is determined that there are no more than a predetermined number of difference values that are equal to or greater than the predetermined value among the calculated difference values (that is, it is equal to or more than the predetermined value among the calculated difference values). If it is determined that the difference value is less than the specified number), the amplitude of the building to be evaluated and the amplitude of the surrounding buildings are both large, so the "building to be evaluated" is built instead of the structure of the "building to be evaluated". It is judged that the amplitude of the building to be evaluated is large due to the existing ground, and it is evaluated that the seismic performance of the “building to be evaluated” meets the criteria specified in the first evaluation step.

Here, for example, in the "first determination", the seismic intensity amplitude = "30" specified in the second evaluation step and the evaluation target building amplitude = "42" specified in the third evaluation step are acquired and evaluated. It is determined that the target building amplitude = "42" is larger than the seismic intensity amplitude = "30". Next, whether the amplitude of the building to be evaluated is large due to the structure of the "building to be evaluated" is evaluated not due to the structure of the "building to be evaluated" but to the ground on which the "building to be evaluated" is built. In order to determine whether the target building amplitude is large, the surrounding building amplitudes = "40" and "41" specified in the third evaluation step are acquired, and the surrounding building amplitudes are obtained from the above-mentioned evaluation target building amplitudes, respectively. Is subtracted from "2" (value obtained by subtracting the surrounding building amplitude = "40" from the evaluation target building amplitude = "42") and "1" (evaluation target building amplitude = "42"). Peripheral building amplitude = "41" minus) is calculated. Next, in the "second determination", the predetermined number of difference values (for example, "5" to "7") or more of the calculated difference values "2" and "1" (for example) Since it is judged that there are no more than one building, the amplitude of the building to be evaluated and the amplitude of the surrounding buildings are both large, so the "building to be evaluated" is built instead of the structure of the "building to be evaluated". It is judged that the amplitude of the building to be evaluated is large due to the existing ground, and it is evaluated that the seismic performance of the "building to be evaluated" satisfies the "exemplary evaluation criteria" specified in the first evaluation step.

In SB4 of FIG. 8, the evaluation unit 232 of the server device 2 stores the seismic evaluation information of FIG. 5 based on the evaluation result of SB3. Specifically, it is optional, but for example, the user ID included in the evaluation request signal received at the start of the evaluation process is acquired, and in the user seismic information of FIG. 5, the seismic resistance associated with the acquired user ID is obtained. Record evaluation information. Specifically, in SB3, "good" is stored when it is evaluated as satisfying the criteria, and "bad" is stored when it is evaluated as not satisfying the criteria.

Here, for example, "IDu1" is acquired as the user ID included in the evaluation request signal received at the start of the evaluation process, and it is evaluated that the SB3 satisfies the "exemplary evaluation criteria". Therefore, the earthquake resistance at the top of FIG. Store "good" as evaluation information.

In SB5 of FIG. 8, the control unit 23 of the server device 2 outputs seismic evaluation information. Specifically, although it is arbitrary, for example, the evaluation result of SB3 is transmitted to the terminal device 1 that has transmitted the evaluation request signal received at the start of the evaluation process, and the evaluation is performed on the display 13 on the terminal device 1. Display and output the result. The specific method of transmitting the evaluation request signal to the terminal device 1 that has transmitted the evaluation request signal is arbitrary, and for example, a known communication method can be used. As an example, the evaluation request signal is transmitted. In this case, the terminal device 1 is configured to include a terminal ID that uniquely identifies itself, and a communication method performed using the terminal ID may be used.

Here, for example, since it was evaluated that the SB3 meets the criteria, a message such as "The seismic performance of your residence meets the criteria" or "Good", which is seismic evaluation information, is output to the terminal device 101. May be displayed and output. If it is evaluated that the SB3 does not meet the standards, a message such as "The seismic performance of your residence does not meet the standards" or "No", which is seismic evaluation information, is output and displayed. May be good.

(Effect of embodiment)
As described above, according to the present embodiment, by evaluating the shaking of the earthquake in the evaluation target based on the first information and the second information, for example, the first information and the second information which are different from each other are used. It is possible to improve the evaluation accuracy regarding the shaking of an earthquake.

Further, by acquiring the information indicating the shaking of the earthquake output by the external device 3 as the second information, for example, the evaluation can be performed in consideration of the information from other than the first device, so that the evaluation can be performed from various aspects. This can be done, and it is possible to improve the evaluation accuracy regarding the shaking of the earthquake.

Further, by acquiring the information indicating the shaking of the earthquake around the building 5 to be evaluated as the second information, for example, the shaking around the building 5 to be evaluated can be taken into consideration for the evaluation. , It is possible to improve the evaluation accuracy regarding the shaking of the earthquake.

Further, by evaluating the seismic performance of the building 5, for example, it is possible to improve the evaluation accuracy of the seismic performance of the building 5.

Further, since the first device is a terminal device 1 (that is, a mobile terminal), for example, the first device can be used to acquire the first information at various places, so that the evaluation accuracy regarding the shaking of the earthquake can be obtained. Can be further improved.

[Modified example with respect to the embodiment]
Although the embodiments according to the present invention have been described above, the specific configuration and means of the present invention may be arbitrarily modified and improved within the scope of the technical idea of each invention described in the claims. Can be done. Hereinafter, such a modification will be described.

(About the problem to be solved and the effect of the invention)
First, the problem to be solved by the invention and the effect of the invention are not limited to the above-mentioned contents, and may differ depending on the implementation environment and the details of the configuration of the invention, and only a part of the above-mentioned problems. May be resolved or only some of the above effects may be achieved.

(About distribution and integration)
Further, the above-described configuration is a functional concept, and does not necessarily have to be physically configured as shown in the figure. That is, the specific form of dispersion or integration of each part is not limited to the one shown in the figure, and all or a part thereof can be functionally or physically dispersed or integrated in any unit. The term "system" in the present application is not limited to a system composed of a plurality of devices, but includes a system composed of a single device. Further, the "device" in the present application is not limited to a device composed of a single device, but includes a device composed of a plurality of devices.

(About evaluation (1))
Further, in the above embodiment, the evaluation may be made in consideration of the building information of FIG. The specific mounting method is arbitrary, but for example, it is assumed that a plurality of seismic standard information stored in the seismic standard information DB 223 is defined according to the building year, the building structure, and the building category of the building 5. , In the first evaluation step of SB3 of FIG. 8, the building information specified in the first acquisition step of SB2 is acquired, and in the seismic standard information DB223, the seismic standard information corresponding to the acquired building information is specified. Based on the identified seismic standard information, the building 5 may be configured to specify the standard to be satisfied by the seismic performance.

(About evaluation (2))
Further, in the above embodiment, the evaluation may be made in consideration of the living floor information of FIG. The specific implementation method is arbitrary, but for example, in the fourth evaluation step of SB3 in FIG. 8, the residential floor information specified in the first acquisition step of SB2 is acquired, and the above-mentioned "first determination" is performed. The amplitude of the building to be evaluated, which is the object of comparison in, may be corrected based on the residential floor information, and the corrected building amplitude to be evaluated may be configured to perform the same processing as in the embodiment. The correction method here is arbitrary, but for example, when it is confirmed by prior experiments or simulations that the higher the number of floors of the building 5, the larger the shaking tends to be, the user can use the amplitude of the building to be evaluated. It is configured to subtract the value according to the number of floors in which the person lives (the higher the number of floors, the larger the value), and use the subtracted building amplitude as the evaluation target building amplitude after correction. You may. By making such a correction, it is possible to correct the shaking depending on the number of floors in which the user resides (that is, the number of floors on which the terminal device 1 is provided).

(About evaluation (3))
Further, in the above embodiment, as the rock mass information for specifying the rock mass in the area of FIG. 2, information indicating the position of the rock mass and the easiness of shaking of the rock mass is recorded in the recording unit 22, and the rock mass information is used. It may be configured to be evaluated. The specific mounting method is arbitrary, but for example, in the same manner as in the case of "(About evaluation (2))", the amplitude of the building to be evaluated that is the target of comparison in the above-mentioned "first judgment". May be corrected based on the rock mass information, and the same processing as in the embodiment may be performed with the corrected building amplitude to be evaluated.

(About location evaluation processing)
Further, in the above embodiment, the case where the evaluation target is the building 5 has been described, but the present invention is not limited to this, and the place evaluation process is implemented so that the evaluation target is the place where the terminal device 1 is provided. May be good. The location evaluation process will be described. FIG. 9 is a flowchart of the location evaluation process. The "location evaluation process" is generally a process executed by the server device 2, and specifically, an evaluation regarding the magnitude of shaking in an earthquake at each place where a plurality of terminal devices 1 are provided. It is a process to perform. The timing of executing this evaluation process is arbitrary, but for example, it is decided that the terminal device 1 transmits a location evaluation request signal that is an evaluation request to the server device 2 in response to a user operation, and the server device 2 sends the location evaluation request signal to the location. It is assumed that the server is activated when the evaluation request signal is received, and the description will be described below from the point where the activation is started.

In SC1 of FIG. 9, the acquisition unit 231 of the server device 2 acquires information. Specifically, although it is arbitrary, focusing on the earthquake date and time information in FIG. 4 and the date and time information in FIG. 6, they are associated with any one earthquake (that is, the earthquake date and time information and the date and time information are the same as each other). (Information) A plurality of combinations of the area information and seismic intensity information of FIG. 4, the vibration information of FIG. 6, and the terminal position information are acquired. In addition, here, the case of acquiring the latest information will be described as an example. Here, for example, the area information and seismic intensity information associated with "earthquake date and time information" = "20190221045" in FIG. 4, and the vibration information and terminals associated with "date and time information" = "20190221045" in FIG. Get location information. The vibration information and the seismic intensity information acquired here correspond to the "first information" and the "second information", and the terminal devices 101 to 103 that have detected the vibration information correspond to the "first device". , The external device 3 that outputs the "seismic intensity information" corresponds to the "second device".

In SC2 of FIG. 9, the evaluation unit 232 of the server device 2 evaluates the magnitude of shaking in an earthquake at each place where a plurality of terminal devices 1 are provided. Specifically, although it is optional, for example, first, in the same manner as the “second evaluation step” described in the embodiment, the seismic intensity amplitude corresponding to the seismic intensity information acquired by SC1 is specified, and the seismic intensity amplitude is also implemented. In the same manner as in the "third evaluation step" described in the embodiment, a plurality of location amplitudes, which are amplitudes corresponding to the plurality of vibration information acquired by SC1, are specified (hereinafter, the first location evaluation step). Next, the seismic intensity amplitude identified in the first location evaluation step is compared with the plurality of location amplitudes, and a location amplitude larger than the seismic intensity amplitude among the plurality of location amplitudes is specified (hereinafter, the second location amplitude). Location evaluation step). Next, in consideration of the combination of the vibration information and the terminal position information of FIG. 6 acquired in SC1 described above, it is associated with the location amplitude specified in the second location evaluation step (that is, the location amplitude larger than the seismic intensity amplitude). The terminal position information is specified, and it is evaluated that the place corresponding to the specified terminal position information is a place that is more likely to shake than the seismic intensity of the earthquake.

In SC3 of FIG. 9, the evaluation unit 232 of the server device 2 outputs information. Specifically, although it is arbitrary, for example, the evaluation result of SC2 is acquired, an evaluation screen is generated based on the acquired evaluation result, and the generated evaluation screen is transmitted to the terminal device 1 and displayed on the display 13. Output. FIG. 10 is a diagram illustrating an evaluation screen. The "evaluation screen" is a screen for specifying the evaluation result by the evaluation unit 232, for example, a screen on which the specific image G1 is superimposed on the map. The "specific image" G1 is an image that identifies a place that is larger than the shaking corresponding to the earthquake output from the external device 3 and is likely to shake. The specific method for generating this evaluation screen is arbitrary, but for example, since many terminal devices 1 actually exist in various places, there are many places specified by SC2 as being prone to shaking. Focusing on the existence, referring to the map information stored in the earthquake information DB 222, the area where the place specified to be liable to shake by SC2 exists with a certain density or more is specified, and the specified area is indicated. A technique for generating an image may be used. Alternatively, when a candidate area for displaying a specific image (for example, an area formed by landfill) is predetermined and there are a certain number or more of places determined to be easily shaken in the area. A method of generating a specific image showing the candidate region may be used. Here, for example, in the region corresponding to the specific image G1 of FIG. 10, there is a place specified to be easily shaken by SC2 at a certain density or more, and in another region (a region outside the region corresponding to the specific image G1). When the place specified by SC2 as liable to shake does not exist at a certain density or more, the evaluation screen of FIG. 10 is generated and displayed. This completes the location evaluation process.

In this configuration, by evaluating the magnitude of the shaking in each place where the terminal device 1 which is the first device is provided, for example, the evaluation of the magnitude of the shaking in the earthquake in various places. It is possible to improve the evaluation accuracy of.

The location evaluation process may be arbitrarily changed. For example, as described in the embodiment, when the terminal device 1 is provided in the building 5 of FIG. 2, it is assumed that the shaking becomes large due to the structure of the building 5, so that in the SC1 When acquiring a plurality of combinations of vibration information and terminal position information in FIG. 6, the information of the combination in which the terminal position information specifies a position other than the position of the building 5 by referring to the map information stored in the earthquake information DB 222. (That is, the combination of information corresponding to the vibration information detected by the terminal device 1 provided in a place other than the building 5) may be acquired.

In addition, the location evaluation process may be configured to be executed for the latest earthquake as described above, or the user may specify the date and time of the earthquake and the information indicating the specified date and time may be used as the location. It may be configured to include it in the evaluation request signal and transmit it to the server device 2 so that the server device 2 performs the above-mentioned processing with respect to the earthquake corresponding to the date and time indicated by the information included in the location evaluation request signal.

(About features)
Further, the features of the above-described embodiment and the features of the modified example may be arbitrarily combined.

(Additional note)
The evaluation system described in Appendix 1 is an evaluation system that evaluates the shaking of an earthquake in the evaluation target, and is the first information indicating the shaking of the earthquake specified by the first device provided in the evaluation target. The acquisition means for acquiring the first information indicating the shaking of the earthquake in the evaluation target, the second information indicating the shaking of the earthquake but different from the first information, and the acquisition. An evaluation means for evaluating the shaking of the earthquake in the evaluation target based on the first information and the second information acquired by the means is provided.

The evaluation system of Appendix 2 is the evaluation system of Appendix 1, wherein the acquisition means acquires information indicating the shaking of the earthquake output by the external system as the second information.

The evaluation system of Appendix 3 is the evaluation system according to Appendix 1 or 2, wherein the acquisition means detects the shaking of the earthquake around the evaluation target specified by the second device provided around the evaluation target. The indicated information is acquired as the second information.

The evaluation system of Appendix 4 is the evaluation system according to any one of Appendix 1 to 3, wherein the evaluation target is at least a building provided with the first apparatus, and the evaluation means is the first. 1 Evaluate seismic performance in buildings equipped with equipment.

The evaluation system of Appendix 5 is the evaluation system according to Appendix 1 or 2, wherein the evaluation target is at least a place where a plurality of the first devices are provided, and the evaluation means is a plurality of the first devices. The magnitude of the shaking in the earthquake at each place where the device is installed is evaluated.

The evaluation system of Appendix 6 is the evaluation system according to any one of Appendix 1 to 5, wherein the first device is a mobile terminal.

The evaluation program of Appendix 7 is an evaluation program for evaluating the shaking of an earthquake in the evaluation target, and is the first information indicating the shaking of the earthquake specified by the first device provided in the evaluation target. The acquisition means for acquiring the first information indicating the shaking of the earthquake in the evaluation target, the second information indicating the shaking of the earthquake but different from the first information, and the above. Based on the first information and the second information acquired by the acquisition means, it functions as an evaluation means for evaluating the shaking of the earthquake in the evaluation target.

(Effect of appendix)
According to the evaluation system described in Appendix 1 and the evaluation program described in Appendix 7, for example, by evaluating the shaking of the earthquake in the evaluation target based on the first information and the second information, the second information is different from each other. It is possible to improve the evaluation accuracy regarding the shaking of the earthquake by using the 1st information and the 2nd information.

According to the evaluation system described in Appendix 2, by acquiring the information indicating the shaking of the earthquake output by the external system as the second information, for example, the evaluation can be performed in consideration of the information from other than the first device. Therefore, it is possible to perform multifaceted evaluation and improve the evaluation accuracy regarding the shaking of an earthquake.

According to the evaluation system described in Appendix 3, by acquiring the information indicating the shaking of the earthquake around the evaluation target as the second information, for example, the evaluation can be performed in consideration of the shaking around the evaluation target. Therefore, it is possible to improve the evaluation accuracy regarding the shaking of the earthquake.

According to the evaluation system described in Appendix 4, it is possible to improve the evaluation accuracy of seismic performance in a building, for example, by evaluating the seismic performance in the building.

According to the evaluation system described in Appendix 5, by evaluating the magnitude of shaking in an earthquake at each location where the first device is installed, for example, evaluation of the magnitude of shaking in an earthquake at various locations can be performed. It is possible to improve the evaluation accuracy.

According to the evaluation system described in Appendix 6, since the first device is a mobile terminal, for example, the first device can be used to acquire the first information at various places, so that the shaking of the earthquake can be obtained. It is possible to further improve the evaluation accuracy.

1 Terminal device 2 Server device 3 External device 5 Building 11 Communication unit 12 Touch pad 13 Display 14 Detection unit 15 Recording unit 16 Control unit 21 Communication unit 22 Recording unit 23 Control unit 51 Building 52 Building 53 Building 101 Terminal device 151 Map information DB
152 Terminal side vibration information DB
102 Terminal device 103 Terminal device 221 Map information DB
222 Earthquake Information DB
223 Seismic standard information DB
224 User seismic information DB
225 Server side vibration information DB
231 Acquisition unit 232 Evaluation unit 900 Information system G1 Specific image

Claims (7)

It is an evaluation system that evaluates the shaking of an earthquake in the evaluation target.
The first information indicating the shaking of the earthquake specified by the first device provided in the evaluation target, the first information indicating the shaking of the earthquake in the evaluation target, and the second information indicating the shaking of the earthquake. An acquisition means for acquiring the second information, which is information and is different from the first information,
Based on the first information and the second information acquired by the acquisition means, the evaluation means for evaluating the shaking of the earthquake in the evaluation target, and the evaluation means.
Evaluation system with. The acquisition means acquires information indicating the shaking of the earthquake output by the external system as the second information.
The evaluation system according to claim 1. The acquisition means acquires as the second information information indicating the shaking of the earthquake around the evaluation target specified by the second device provided around the evaluation target.
The evaluation system according to claim 1 or 2. The evaluation target is at least a building in which the first device is provided.
The evaluation means evaluates seismic performance in a building provided with the first device.
The evaluation system according to any one of claims 1 to 3. The evaluation target is at least a place where a plurality of the first devices are provided.
The evaluation means evaluates the magnitude of shaking in the earthquake at each place where the plurality of first devices are provided.
The evaluation system according to claim 1 or 2. The first device is a mobile terminal.
The evaluation system according to any one of claims 1 to 5. It is an evaluation program that evaluates the shaking of earthquakes in the evaluation target.
Computer,
The first information indicating the shaking of the earthquake specified by the first device provided in the evaluation target, the first information indicating the shaking of the earthquake in the evaluation target, and the second information indicating the shaking of the earthquake. An acquisition means for acquiring the second information, which is information and is different from the first information,
Based on the first information and the second information acquired by the acquisition means, the evaluation means for evaluating the shaking of the earthquake in the evaluation target, and the evaluation means.
An evaluation program that functions as.

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