JP7118942B2 - DISASTER RESPONSE SERVER, DISASTER RESPONSE METHOD AND PROGRAM - Google Patents

Description

The present invention relates to a disaster response server, a disaster response method, and a program.

BACKGROUND ART Conventionally, captioned information urging people to evacuate from a disaster or the like is displayed on a television screen. By the way, caption information for urging people to evacuate regarding a disaster or the like displayed on a television screen is usually for each municipality. In other words, municipalities where residents are urged to evacuate in relation to disasters (municipalities marked with signs that disasters, etc. may occur) are limited to areas where there is a genuine risk of disasters, etc. It is possible that there are areas where there is almost no risk of disasters occurring.
Therefore, depending only on the caption information displayed on the TV screen, for example, after the disaster occurred, it was not possible to determine whether the damaged house was in an area where there was a real risk of a disaster, etc., or whether a disaster, etc. could occur. It is not possible to accurately grasp whether it was included in an area where it is thought that there is almost no
Therefore, when a plurality of houses are damaged, it is not possible to appropriately determine which house should be prioritized for restoration (response) based only on the caption information displayed on the television screen.

Conventionally, for example, sediment disaster warning information announced by the Meteorological Agency, sediment disaster warning determination mesh information (information that displays the increasing risk of sediment disaster occurrence due to heavy rain in five stages by color for each 5 km square mesh area) Detailed information is provided indicating the warning areas for weather or disasters, such as. If landslide warning judgment mesh information is provided to each resident of a municipality where evacuation is being urged, each resident will be able to determine whether or not their home belongs to an area where they really need to evacuate. , whether or not the home belongs to an area that does not require evacuation can be accurately determined based on the landslide warning determination mesh information.
However, many of the residents of municipalities that were urged to evacuate in the past did not know that detailed information such as landslide warning information and sediment disaster warning judgment mesh information had been announced by the Japan Meteorological Agency, and did not use such detailed information. The fact is that there is no experience of using it.
In addition, even after a disaster occurs, mesh information (detailed information) such as landslide warning determination mesh information is used to determine which of the damaged houses should be prioritized for restoration (response). The fact is that it is not used.

Patent Literature 1 describes a disaster activity support device that supports determination of matters to be dealt with with priority according to information such as events, accidents, situations, etc. in disaster activities. The technology described in Patent Literature 1 accumulates disaster information indicating the prediction or occurrence of a disaster. In addition, each disaster information is given a first priority indicating the extent to which countermeasures should be prioritized, and a second priority that increases as time elapses from the point at which the disaster information is accumulated in the accumulation means. Moreover, disaster information having a large product of the first priority and the second priority is preferentially targeted for countermeasures.
By the way, in the technique described in Patent Literature 1, for example, even information verbally conveyed by a resident or the like via a telephone is used as disaster information.
In addition, in the technique described in Patent Document 1, the disaster information used to determine the priority of countermeasures is not detailed information for each mesh area, such as landslide warning determination mesh information.
Therefore, according to the technique described in Patent Literature 1, after a disaster occurs, it is not possible to appropriately determine which of the damaged houses should be prioritized for handling (restoration).

Patent Document 2 discloses a recovery support system that reduces the anxiety of the owner or user of an elevator by notifying in advance the scheduled time for a visit by an engineer of a maintenance company of the elevator to the building where the elevator is installed. A device is described. In the technique described in Patent Document 2, the scheduled restoration patrol time for the elevator system is determined based on the information on the scale of the earthquake transmitted from the remote monitoring device of the elevator system and the work schedule of the engineer at the time of the earthquake. Calculated.
By the way, in the technique described in Patent Literature 2, the information used for calculating the scheduled recovery patrol time is not detailed information for each mesh area, such as landslide warning determination mesh information.
Therefore, according to the technique described in Patent Literature 2, it is not possible to appropriately determine which of the plurality of damaged elevator apparatuses should be prioritized for restoration (response) after a disaster occurs.

Patent Literature 3 describes a disaster recovery system that broadly sets predicted disaster areas so as to include actual disaster areas, and aims to grasp specific disaster conditions. In the technique described in Patent Literature 3, a damaged building prediction means refers to a customer information database and outputs a customer list of the corresponding area. Also, the information about the structure of the building in the customer list is collated, and the damaged part of the corresponding customer's building is predicted.
By the way, in the technique described in Patent Literature 3, the information used for predicting the damaged part of the building is not objective information such as landslide warning determination mesh information.
Therefore, according to the technique described in Patent Literature 3, it is not possible to appropriately determine which of the damaged buildings should be prioritized for restoration (response) after a disaster occurs.

Patent Literature 4 describes a disaster recovery support system that restores power with proper priority according to the situation of consumers. The technology described in Patent Literature 4 acquires disaster information including the date and time, content, and scale of a disaster. Consumer information is also stored in the database. In addition, priority consumers, including consumers who are expected to be affected by the disaster and consumers who are expected to be in danger of life, are identified, and the recovery priority of these priority consumers is determined. Highly formulated.
By the way, in the technique described in Patent Literature 4, the information used for formulating the restoration priority is not detailed information for each mesh area, such as landslide warning determination mesh information.
Therefore, according to the technique described in Patent Document 4, after a disaster occurs, it is not possible to appropriately determine which customer should be prioritized for power restoration (response) among a plurality of affected customers.

Patent Literature 5 describes a wide-area disaster recovery support system for elevators. In the technique described in Patent Literature 5, observation site information is acquired from an earthquake seismic intensity information distribution service and used.
By the way, Patent Literature 5 does not describe which of the plurality of elevator devices should be prioritized for recovery when a plurality of elevator devices are damaged (stopped).
Therefore, according to the technique described in Patent Document 5, after a disaster occurs, it is not possible to appropriately determine which elevator apparatus should be prioritized for restoration (response) among the plurality of damaged elevator apparatuses.

JP 2011-197978 A Japanese Patent Application Laid-Open No. 2007-126260 JP 2003-173384 A JP 2015-177665 A JP 2015-131728 A

In view of the above-described problems, the present invention provides a disaster response system capable of appropriately determining, after a disaster, which of a plurality of user homes whose severity of damage exceeds a certain level should be prioritized. The purpose is to provide a server, a disaster response method and a program.

One aspect of the present invention includes a weather disaster information acquisition unit that acquires weather disaster information that is information indicating a warning target area regarding weather or a disaster, and user information that includes address information or location information of the user's residence. a determination unit that determines whether or not the user's home is included in the warning target area based on the weather disaster information acquired by the weather disaster information acquisition unit; and a disaster response unit that determines the severity of damage to the user's home when the determining unit determines that the area is included in the weather disaster information; is information indicating the degree of risk of each mesh area, the determination unit determines whether or not the user's house is included in any one of the plurality of mesh areas, and the weather disaster information includes landslide disaster Disaster response including at least one of warning determination area information, flood damage warning determination area information, flood damage warning determination area information, earthquake information indicating an earthquake warning area, and wind damage information indicating a wind speed warning area is the server.

In the disaster response server according to one aspect of the present invention, the disaster response unit is configured to, when a plurality of user homes are included in any one of the plurality of mesh areas and the disaster severity of the plurality of user homes reaches a certain level. It may be possible to generate and output a priority list that determines the order of priority of correspondence of the plurality of user homes when the number of users' homes is exceeded.

In the disaster response server according to one aspect of the present invention, the disaster response unit is configured to perform the following when a plurality of user homes are included in any one of the plurality of mesh areas, and the disaster severity of the plurality of user homes is the fixed level. When the level is exceeded, a response schedule indicating the order of response to the plurality of user's homes may be formulated, and the response schedule may be formulated based on the disaster severity of each of the plurality of user's homes.

In the disaster response server according to one aspect of the present invention, the disaster response unit includes a disaster severity calculation unit, and the disaster severity calculation unit reflects a time-based weight on the disaster risk of each user's home. Damage severity may be calculated.

In the disaster response server of one aspect of the present invention, the disaster severity calculation unit may calculate a product of a disaster risk level of each user's home and time as the disaster severity.

In the disaster response server of one aspect of the present invention, the disaster risk level may be set based on the weather disaster information indicating the risk level of each mesh area acquired by the weather disaster information acquisition unit.

In the disaster response server of one aspect of the present invention, the disaster response unit includes a disaster degree map generation unit, and the disaster degree map generation unit generates a list of the plurality of user homes whose disaster severity exceeds the predetermined level. The disaster user home list is generated by sorting the disaster severity calculated for each user home by the disaster severity calculation unit in descending order of the disaster severity. may

In the disaster response server of one aspect of the present invention, the disaster degree map generation unit may generate a disaster degree map indicating at least the positions and densities of the homes of the plurality of users whose disaster severity exceeds the predetermined level. good.

In the disaster response server of one aspect of the present invention, the disaster response unit includes a response schedule formulation unit, and the response schedule formulation unit generates the disaster user home list generated by the disaster degree map generation unit. The response schedule may be formulated in descending order of disaster severity.

In the disaster response server of one aspect of the present invention, when the plurality of user homes whose disaster severity exceeds the predetermined level are included in a plurality of response areas, the disaster user home list is sorted by response area. may be generated for each corresponding area.

In the disaster response server according to one aspect of the present invention, the priority list that determines the order of priority of responses to the plurality of user homes is generated based on the degree of importance of each of the plurality of user homes. may include at least a degree based on whether or not the house has been damaged in the past.

In the disaster response server according to one aspect of the present invention, the priority list that determines the priority of responses to the plurality of user homes is generated based on the attributes of each resident of each of the plurality of user homes. attributes may include age of the resident and/or health of the resident.

In the disaster response server according to one aspect of the present invention, the sediment disaster warning determination area information includes sediment disaster warning determination mesh information, and the determination unit determines whether the user's home is located in the sediment disaster warning determination mesh information. It may be determined whether or not the area is included in any one of the plurality of mesh areas displayed on the map as the caution area.

The disaster response server of one aspect of the present invention may include a storage unit that stores the user information.

In the disaster response server of one aspect of the present invention, an administrator of the disaster response server may be a company that has contracted construction of the user's house.

According to one aspect of the present invention, a weather disaster information acquiring step of acquiring weather disaster information, which is information indicating an area to be alerted regarding weather or a disaster, and user information including address information or location information of the user's residence, a determining step of determining whether or not the user's home is included in the warning target area based on the weather disaster information acquired in the weather disaster information acquiring step; and and a disaster response step of determining the severity of damage to the user's home when it is determined in the determination step that the warning target area is composed of a plurality of mesh areas, and the weather disaster information is information indicating the degree of risk of each mesh area; in the determination step, it is determined whether or not the user's home is included in any of the plurality of mesh areas; Disaster response including at least one of warning determination area information, flood damage warning determination area information, flood damage warning determination area information, earthquake information indicating an earthquake warning area, and wind damage information indicating a wind speed warning area The method.

According to one aspect of the present invention, the computer includes a weather disaster information obtaining step of obtaining weather disaster information, which is information indicating an area to be warned about weather or a disaster, and address information or position information of the user's house, which is the user's house. a determination step of determining whether or not the user's home is included in the warning target area based on the user information and the weather disaster information acquired in the weather disaster information acquisition step; and a disaster response step of determining the severity of damage to the user's home when it is determined in the determination step that the user's home is included in the target area, wherein the warning target area comprises a plurality of mesh areas. The weather disaster information is information indicating the degree of risk of each mesh area, and in the determination step, it is determined whether or not the user's home is included in any one of the plurality of mesh areas. The meteorological disaster information includes sediment disaster warning determination area information, flood damage warning determination area information, flood damage warning determination area information, earthquake information indicating an earthquake warning area, and wind damage information indicating a wind speed warning area. A program that includes at least one of

According to the present invention, after a disaster occurs, a disaster response server and a disaster response method are capable of appropriately determining which of a plurality of user homes whose severity of damage exceeds a certain level should be prioritized. and programs can be provided.

It is a figure which shows an example of the disaster response server of 1st Embodiment. FIG. 10 is a diagram showing an example of a disaster user home list generated by a disaster degree map generation unit; It is a figure which shows an example of the damage degree map produced|generated by the damage degree map production|generation part. 4 is a flowchart for explaining an example of processing executed in the disaster response server of the first embodiment; It is a figure which shows the 1st example of application of the disaster-response server of 1st Embodiment. FIG. 3 is a diagram showing an example of a plurality of mesh areas displayed on a map as a warning target area in the landslide warning determination mesh information; FIG. 4 is a diagram for explaining an example of alert content generation by a content generation unit of the disaster response server according to the first embodiment; It is a figure which shows the 2nd example of application of the disaster-response server of 1st Embodiment. It is a figure which shows the other example of the disaster-response server of 1st Embodiment. FIG. 3 is a diagram for explaining a mesh area including a user's home, surrounding mesh areas positioned around the mesh area including the user's home, and the like; FIG. 10 is a diagram showing a third application example, which is an application example of the disaster response server of the first embodiment shown in FIG. 9; FIG. 10 is a diagram showing a fourth application example, which is another application example of the disaster response server of the first embodiment shown in FIG. 9; FIG. 11 is a diagram for explaining an example of alert content generation by a content generation unit of a disaster response server according to the second embodiment; It is a figure which shows the 1st example of application of the disaster-response server of 3rd Embodiment.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of a disaster response server, a disaster response method, and a program according to the present invention will be described with reference to the accompanying drawings.

<First embodiment>
FIG. 1 is a diagram showing an example of a disaster response server 1 according to the first embodiment.
In the example shown in FIG. 1, the disaster response server 1 includes, for example, a weather disaster information acquisition unit 11, a user information storage unit 12, a first determination unit 13, a content generation unit 14, a content distribution unit 15, a disaster response a portion 18;
In the example shown in FIG. 1, the disaster response server 1 includes the content generation unit 14 and the content distribution unit 15, but in other examples, the disaster response server 1 does not include the content generation unit 14 and the content distribution unit 15. may

In the example shown in FIG. 1, the meteorological disaster information acquisition unit 11 acquires meteorological disaster information, which is information indicating a warning target area regarding weather or disasters, from outside the disaster response server 1 . Meteorological disaster information includes, for example, sediment disaster warning determination area information, flood damage warning determination area information, flood damage warning determination area information, earthquake information indicating earthquake warning areas, and wind damage information indicating wind speed warning areas. is included.
The sediment disaster warning determination area information includes, for example, "heavy rain warning (landslide disaster) risk distribution" announced by the Meteorological Agency, and "sediment disaster warning determination mesh information" announced by the Meteorological Agency.
The flood damage warning determination area information includes, for example, the "heavy rain warning (flood damage) risk distribution" announced by the Meteorological Agency, and the "flood forecast area map" announced by the Bureau of Construction of the Tokyo Metropolitan Government.
The flood warning determination area information includes, for example, "flood warning risk distribution" announced by the Meteorological Agency.
The earthquake information indicating earthquake warning areas includes, for example, an "estimated seismic intensity distribution map" announced by the Meteorological Agency.
The wind damage information indicating the warning target area regarding wind speed includes, for example, the "period maximum wind speed distribution map" announced by the Meteorological Agency, the "period maximum instantaneous wind speed distribution map" announced by the Meteorological Agency, and the like.

Warning areas are, for example, warning target areas of landslide warning judgment mesh information announced by the Meteorological Agency, warning target areas of information on the risk distribution of heavy rain warnings (flood damage) (yellow, red, light purple, dark purple danger It is composed of a plurality of mesh areas such as the area where the degree appears).
For example, the meteorological disaster information acquiring unit 11 provides information indicating the degree of risk of each mesh area, such as landslide warning determination mesh information and heavy rain warning (flood damage) risk distribution information announced by the Meteorological Agency. The acquired weather disaster information is information indicating the degree of risk of each mesh area.

In the example shown in FIG. 1, the user information storage unit 12 stores user information including address information or position information of the user's residence. The position information is information (coordinate information) such as latitude and longitude, for example. If the point indicating the latitude and longitude is a point on the site of the user's house, for example, the center point of the site, such as a point on the perimeter of the site, or the area center of gravity of the site, such as the intersection of the diagonal lines of a rectangular site. , at any point on the site.
In the example shown in FIG. 1, the administrator of the disaster response server 1 is the company that has contracted the building of the user's house. The user information storage unit 12 stores user information including address information or position information of a plurality of user homes for which the administrator of the disaster response server 1 has contracted construction. In another example, the administrator of the disaster response server 1 may not be the company that contracted the construction of the user's house.

In the example shown in FIG. 1, the user information stored in the user information storage unit 12 includes, for example, information (first information) obtained by surveying the construction site and its surroundings before starting construction work on the user's house. be The first information includes, for example, the height difference of the site and its surroundings, the angle of the slope, and the like. Also, the first information includes geology, groundwater level, ground strength, and the like. The first information also includes the state of structures such as earth retaining walls and retaining walls. The first information also includes the state and depth of gutters, waterways, and the like.
The user information stored in the user information storage unit 12 includes, for example, information (second information) such as the building, site, attached structures, etc. at the time of completion of construction of the user's house. The second information includes, for example, information such as the shape of the building, form (number of floors, presence or absence of roof, etc.), layout, basic specifications, and the like. In addition, the second information includes height difference between the site and the surroundings. The second information also includes information on newly installed earth retaining walls, retaining walls, fences, and the like.
Further, the user information stored in the user information storage unit 12 includes, for example, information (third information) after handover of the user's home. The third information includes, for example, information such as renovation of a building. Also, the third information includes information on damage conditions and recovery from past disasters.
Further, the user information stored in the user information storage unit 12 includes, for example, information (fourth information) regarding residents of the user's house. The fourth information includes, for example, the user's (resident's residence) gender, age, place of work, destination of school/kindergarten, health condition (degree of health), room in which he/she sleeps, and the like.
The user information stored in the user information storage unit 12 can be used, for example, for predicting damage and prioritizing rescue when the user's home is damaged.

In the example shown in FIG. 1, the first determination unit 13 determines whether the user's home is on alert based on the weather disaster information acquired by the weather disaster information acquisition unit 11 and the user information stored in the user information storage unit 12. Determine whether or not it is included in the target area. Specifically, the first determination unit 13 determines whether or not the user's home is included in any of a plurality of mesh areas that constitute the warning target area indicated by the weather disaster information acquired by the weather disaster information acquisition unit 11. judge.
In another example, the first determination unit 13 determines that the user's home is a warning target based on the weather disaster information acquired by the weather disaster information acquisition unit 11 and, for example, user information directly input to the first determination unit 13. You may determine whether it is contained in an area.

In the example shown in FIG. 1, when the first determination unit 13 determines that the user's home is included in the warning target area, the content generation unit 14 generates a warning based on the weather disaster information acquired by the weather disaster information acquisition unit 11. to generate alert content. Specifically, if the user's house is included in any of a plurality of mesh areas that constitute the warning target area indicated by the weather disaster information acquired by the weather disaster information acquisition unit 11, the content generation unit 14 generates the user's house. Generate alert content that indicates the danger of mesh areas containing
The content generator 14 has a customizer 14A. The customizing unit 14A customizes a map in which a plurality of mesh areas are displayed, for example, sediment disaster alert determination mesh information and heavy rain warning (flood damage) risk distribution information announced by the Meteorological Agency.
The content delivery unit 15 delivers alert content generated by the content generation unit 14 . Specifically, the content distribution unit 15 distributes alert content to terminal devices used by users (for example, each of the residents of the user's house).

In the example shown in FIG. 1, the disaster response unit 18 determines the degree of damage to the user's home. Specifically, when the first determination unit 13 determines that the user's home is included in one of a plurality of mesh areas that constitute the warning target area, the disaster response unit 18 determines the degree of damage to the user's home. conduct. The disaster response unit 18 includes a disaster severity calculation unit 18A, a sediment disaster risk information collection unit 18B, a damaged housing extraction unit 18C, a damage degree map generation unit 18D, and a response schedule formulation unit 18E.
The disaster severity calculation unit 18A calculates, for each user's home, a disaster severity that is obtained by reflecting a time-based weight on the disaster risk of each user's home. The degree of disaster risk is set based on weather disaster information indicating the degree of risk of each mesh area acquired by the weather disaster information acquisition unit 11 .
For example, "extremely dangerous" out of five levels such as landslide warning determination mesh information and heavy rain warning (flood damage) risk distribution information announced by the Meteorological Agency corresponds to "disaster risk level 10". "Very dangerous" out of five levels, such as sediment disaster warning determination mesh information and heavy rain warning (flood damage) risk distribution information, corresponds to "disaster risk level 7". Among the five levels of information such as sediment disaster warning determination mesh information and risk distribution information for heavy rain warnings (flood damage), "warning" corresponds to "disaster risk level 3". "Caution" out of five levels, such as landslide warning determination mesh information and heavy rain warning (flood damage) risk distribution information, corresponds to "disaster risk level 1". Of the five levels, such as landslide warning determination mesh information and heavy rain warning (flood damage) risk distribution information, "pay attention to future information" corresponds to "disaster risk 0".
In another example, instead of the disaster risk mentioned above, for example, the maximum disaster risk reached by the user's house may be used.

Specifically, in the example shown in FIG. 1, the disaster severity calculation unit 18A calculates the product of the disaster risk of each user's home and the time as the disaster severity.
In another example, the disaster severity calculation unit 18A may calculate a disaster severity other than the product of the disaster risk level of each user's home and the time. For example, the disaster severity calculation unit 18A calculates the product of the disaster risk level of each user's house and (time) ^1/2 as the disaster severity. In this example as well, the disaster severity increases with the passage of time.

In the example shown in FIG. 1, the sediment disaster risk information collection unit 18B acquires the sediment disaster risk information nationwide and the risk distribution of heavy rain warnings (flood damage) from the weather disaster information acquired by the weather disaster information acquisition unit 11. information, etc., as list data at regular intervals.
While referring to the user information stored in the user information storage unit 12, the damaged house extraction unit 18C extracts the sediment disaster risk information and the risk of heavy rain warning (flood damage) collected by the sediment disaster risk information collection unit 18B. Information such as degree distribution is converted for each user's house and stored.
Based on the information accumulated by the damaged house extraction unit 18C, the damage degree map generation unit 18D identifies user homes whose damage severity calculated by the damage severity calculation unit 18A exceeds a certain level (that is, damaged user homes). ), which is a list of damaged user homes. The disaster user's home list is generated by sorting the disaster severity calculated for each user's home by the disaster severity calculator 18A in descending order of disaster severity.

FIG. 2 is a diagram showing an example of a disaster user home list generated by the disaster degree map generation unit 18D.
In the example shown in FIG. 2, the damaged user home list includes the order of disaster severity (“No.”), the damaged user home (“mansion”), the “address” of the damaged user home, and the “severity of damage”. degree” is stated.
Specifically, in the disaster user's home list, it is described that the damage severity of OO residence, which has the highest disaster severity (“No.”=“1”), is “120”. Next, the damage severity is the second highest (“No.”=“2”) ▽▽ It is described that the damage severity of the mansion is “118”. Next, it is described that the damage severity of the ◇◇ residence is the third highest (“No.”=“3”) and that the damage severity is “110”.
In addition, in the disaster user's house list, it is described that the disaster severity of the XX residence is "80", which is the 70th highest disaster severity ("No." = "70"). Next, it is described that the damage severity of □□ residence, which has the 71st highest disaster severity (“No.”=“71”), is “79”. Next, it is described that the damage severity of △△ residence is the 72nd highest (“No.”=“72”), and that the damage severity is “77”.

In the example shown in FIG. 1, the damage degree map generation unit 18D generates the damage degree map based on the information accumulated by the damaged house extraction unit 18C. The disaster degree map is a map that indicates the location, density, etc. of user homes whose degree of damage exceeds a certain level.

FIG. 3 is a diagram showing an example of a disaster degree map generated by the disaster degree map generation unit 18D.
In the example shown in FIG. 3, the damaged user's home is located in western Japan. In addition, the density of damaged user homes is high in the vicinity of Osaka City and Nagoya City.

In the example shown in FIG. 1, when a plurality of user homes are damaged, the response schedule formulation unit 18E can generate and output a priority list that determines the priority of response to the damaged user homes. For example, when the disaster severity of multiple user homes exceeds a certain level, the response schedule formulation unit 18E determines that the plurality of user homes with the disaster severity exceeding the certain level constitute the warning target area. A priority list can be generated and output if it is included in any of the mesh regions of .
The priority list generated by the correspondence schedule formulation unit 18E includes, for example, information such as an ID such as the user's contract number, the owner name of the user's home, the address of the user's home, the user's telephone number, the user's e-mail address, and the like. be
The disaster response unit 18 has a function of generating a map linked to the priority list generated by the response schedule formulation unit 18E, a function of making the map viewable, a function of outputting the map, and the like.
For example, the administrator of the disaster response server 1 (the company that has contracted the construction of the user's house) prepares a response schedule based on the priority list generated by the response schedule formulation unit 18E, the map linked to the priority list, and the like. can be created and started responding to each user's home.

In another example, when a plurality of user homes are damaged, the response schedule formulating unit 18E may formulate a response schedule indicating the order of responding to the disaster-affected user homes. For example, when the disaster severity of multiple user homes exceeds a certain level, the response schedule formulation unit 18E determines that the plurality of user homes with the disaster severity exceeding the certain level constitute the warning target area. formulate a response schedule if it is included in any of the mesh areas of
The response schedule is formulated based on the severity of damage to each of the multiple user homes whose severity of damage has exceeded a certain level. Specifically, the response schedule is formulated in descending order of severity of damage to user homes based on the list of damaged user homes generated by the disaster degree map generation unit 18D.
For example, based on the list of damaged user homes shown in FIG. The response order for the ▽ mansion is second, the response order for the ◇◇ mansion with a disaster severity of "110" is third, and the XX mansion with a disaster severity of "80" is the 70th. , the □□ residence with a disaster severity of "79" is the 71st response order, and the △△ residence with a disaster severity of "77" is the 72nd response schedule.
In the example shown in FIG. 1, the administrator of the disaster response server 1 (the company that undertook construction of the user's home) supports the damaged user's home based on the response schedule formulated by the response schedule formulation unit 18E. .

Specifically, the administrator of the disaster response server 1 (the company that has contracted the construction of the user's home) calls the user's home in an area that has been damaged by a typhoon, flood, or the like to hear about the damage situation. conduct. Also, the administrator of the disaster response server 1 confirms whether or not there is a service call from the user's home and the content of the service call. In addition, the administrator of the disaster response server 1 takes into account public disaster-level information (announcement of warnings and warnings, evacuation orders, infrastructure stoppage information, etc.), etc. , determine whether insurance is applicable, repair work, etc.
In the example shown in FIG. 1, the criteria for determining whether or not to carry out these actions are "what level of landslide disaster risk has the user's house reached?" Have you reached?” is used.
On the website operated by the administrator of the disaster response server 1, information is sorted out based on the degree of damage listed in the disaster user home list described above, and calls (inquiries) are received from users with a high degree of damage. takes precedence. Frequently Asked Questions (FAQs) are preferentially introduced to user homes with a low degree of disaster severity.
For example, the disaster user's home list generated by the disaster degree map generation unit 18D, the response schedule formulated by the response schedule generation unit 18E, and the like are effectively utilized from the day following the occurrence of the disaster. Human resources are efficiently utilized with support according to the severity of the disaster. For example, based on the damage degree map generated by the damage degree map generation unit 18D, areas to be handled are assigned, and within each area, the residences with the highest severity of damage are dealt with in order.

Depending on the weather or disaster, a plurality of user homes (that is, a plurality of damaged user homes) whose disaster severity calculated by the disaster severity calculator 18A exceeds a certain level may be included in a plurality of response areas. be.
In such a case, the disaster degree map generation unit 18D generates a disaster user home list for each corresponding area. Specifically, the list of damaged user's homes in each corresponding area is generated by sorting the disaster severity calculated for each user's home by the disaster severity calculator 18A in descending order of disaster severity. That is, a plurality of disaster severity levels included in the disaster user home list are sorted for each corresponding area.
Therefore, for example, the administrator of the disaster response server 1 can easily grasp the human resources required for response, the period required for response, and the like for each response area.

In the disaster response server 1 of the first embodiment, the size of the response area described above can be set to any size. For example, at the same time as setting the size of the corresponding area to the size of each municipality, it is also possible to set the size of the corresponding area to the size of each prefecture including a plurality of municipalities. In this example, the disaster severity is sorted for each corresponding area with a size of municipalities, and the damage severity is sorted for each corresponding area with a size of prefectures. By using such as, it is possible to create statistical data relating to damaged user homes, severity of damage, and the like.

In addition, the disaster response server 1 of the first embodiment sets a threshold value for determining whether or not to carry out a hearing on the damage situation by calling, by creating statistical data on the homes of affected users in the entire response area, the severity of damage, and the like. , the setting of a threshold for whether or not to conduct a field survey of a disaster user's home, the setting of a threshold for whether or not to perform restoration work on a disaster user's home, and the like can be performed easily and appropriately.

Furthermore, in the disaster response server 1 of the first embodiment, priority is given to responding to multiple user homes (that is, multiple damaged user homes) whose disaster severity calculated by the disaster severity calculator 18A exceeds a certain level. A prioritized list is generated based on the importance of each user's home.
For example, the importance of each user's home may be defined as a user's home whose disaster severity calculated by the disaster severity calculation unit 18A exceeds a certain level (that is, a user's home that has been damaged by a disaster in the past). It includes the degree based on whether it is a residence or not. For example, if a user's home for which the disaster severity calculated by the disaster severity calculation unit 18A in the current disaster exceeds a certain level is also a home that has been damaged in past disasters, etc., the importance of the user's home becomes a high value, and the priority of the correspondence of the user's house becomes high.

In addition, in the disaster response server 1 of the first embodiment, a priority list that determines the order of priority of responses to multiple user homes whose disaster severity calculated by the disaster severity calculation unit 18A exceeds a certain level is provided to each user. Generated based on the attributes of the occupants of the house.
The attributes of the residents of each user's home include the age, health condition (degree of health), and the like of the residents of each user's home. For example, when elderly people are included in the residents of user homes whose disaster severity exceeds a certain level, it is more likely that elderly people are not included in the residents of user homes whose disaster severity exceeds a certain level. , the priority of the response at the user's home is increased. For example, when a disabled person is included in the residents of a user's home whose disaster severity exceeds a certain level, the number of residents of a user's home whose disaster severity exceeds a certain level does not include a disabled person. , the priority of the response at the user's home is increased.

FIG. 4 is a flowchart for explaining an example of processing executed in the disaster response server 1 of the first embodiment.
In the example shown in FIG. 4, in step S1, the meteorological disaster information acquisition unit 11 acquires meteorological disaster information, which is information indicating a warning target area regarding weather or disasters.
Further, in step S2, the user information storage unit 12 stores user information including address information or position information of the user's residence.
Next, in step S3, the first determination unit 13 determines whether or not the user's home is included in the warning target area based on the weather disaster information acquired in step S1 and the user information stored in step S2. judge. Specifically, in step S3, the first determination unit 13 determines whether or not the user's house is included in any one of a plurality of mesh areas forming the warning target area.
If it is determined in step S3 that the user's home is included in the warning target area, and if the user's home is actually damaged, in step S4, the disaster response unit 18 determines the degree of damage to the damaged user's home. conduct.
Specifically, when a plurality of user homes are included in one of a plurality of mesh areas forming a warning target area, and when a plurality of user homes are affected by a disaster, the disaster response unit 18 Formulate a response schedule that indicates the order in which homes should be addressed.

Specifically, in the example shown in FIG. 4, in step S41, the disaster severity calculation unit 18A calculates the disaster severity, which is the product of the disaster risk and time for each of a plurality of damaged user homes.
Also, in step S42, the sediment disaster risk information collecting unit 18B collects the sediment disaster risk information nationwide as list data at regular time intervals from the weather disaster information acquired in step S1.
Next, in step S43, the damaged house extraction unit 18C refers to the user information stored in step S2, converts the sediment disaster risk information collected in step S42 for each user house, and stores the information.
Next, in step S44, the disaster degree map generation unit 18D generates a disaster user home list and a disaster degree map based on the information accumulated in step S43.
Next, in step S45, the response schedule formulation unit 18E formulates a response schedule in descending order of severity of damage to damaged user homes based on the disaster user home list generated in step S44.

FIG. 5 is a diagram showing a first application example of the disaster response server 1 of the first embodiment.
In the example shown in FIG. 5, a disaster response system X includes a disaster response server 1, a weather disaster information announcement unit A1, and a weather disaster information data distribution unit A2.
For example, the meteorological disaster information announcement unit A1 such as the Japan Meteorological Agency provides, for example, sediment disaster warning determination area information, flood damage warning determination area information, flood damage warning determination area information, earthquake information indicating a warning target area regarding earthquakes, and wind speed Announcing weather hazard information, such as wind damage information indicating warning areas.
For example, a weather disaster information data distribution unit A2 such as a weather data providing service company distributes the weather disaster information data announced by the weather disaster information announcement unit A1 in a usable (processed) format.
The meteorological disaster information acquisition unit 11 (see FIG. 1) of the disaster response server 1 receives the meteorological disaster information data (for example, landslide warning determination mesh information, heavy rain warning (flood damage) information) distributed by the meteorological disaster information data distribution unit A2. data, such as risk distribution information). For example, in the landslide warning determination mesh information and the risk distribution information for heavy rain warnings (flood damage), warning target areas (areas with increased risk) are displayed on a map by a plurality of mesh areas.

FIG. 6 is a diagram showing an example of a plurality of mesh areas displayed on a map as a warning target area in the landslide warning determination mesh information.
In the example shown in FIG. 6(A), as the warning target area, six mesh areas corresponding to "extremely dangerous" for the increased risk of sediment disasters due to heavy rain are displayed on the map of the sediment disaster warning determination mesh information. is displayed in The user's home of the disaster response server 1 is included in the rightmost and lower mesh area corresponding to "very dangerous" in FIG. 6(A).

In the example shown in FIGS. 5 and 6A, the first determination unit 13 (see FIG. 1) of the disaster response server 1 determines that the user's home is a warning target area (FIG. 6A) in the sediment disaster warning determination mesh information. any of the six mesh areas shown in ). Specifically, the first determination unit 13 determines that the user's home is included in a mesh area corresponding to "very dangerous".
Therefore, based on the weather disaster information acquired by the weather disaster information acquisition unit 11, the content generation unit 14 (see FIG. 1) of the disaster response server 1 (more specifically, the mesh area including the user's home is Alert content is generated based on the information indicating that the mesh area corresponds to "dangerous".

FIG. 7 is a diagram for explaining an example of alert content generation by the content generation unit 14 of the disaster response server 1 of the first embodiment.
In the example shown in FIG. 7(A), the content generator 14 of the disaster response server 1 creates a mesh area (corresponding to "very dangerous" in FIG. 6(A)) including the user's home (see FIG. 6(A)). An e-mail indicating the degree of danger ("extremely dangerous") of the rightmost and lower mesh area of the six mesh areas to be detected is generated as alert content.
The content distribution unit 15 (see FIG. 1) of the disaster response server 1 transmits the e-mail generated by the content generation unit 14 to the terminal device B1 used by the user.
In the example shown in FIG. 7, the terminal device B1 used by the user is a terminal device carried by the user, such as a smart phone. In another example, the terminal device B1 may be a mobile terminal device other than a smart phone.

In the example shown in FIG. 7A, the e-mail generated by the content generation unit 14 and transmitted to the user's terminal device B1 by the content distribution unit 15 indicates that the risk level in the landslide warning determination mesh information is "emergency." It is described that the user's home is included in the mesh area corresponding to "dangerous to". The e-mail also includes a URL (Uniform Resource Locator) for the user to view a custom map, which will be described later. The user can grasp the distribution of the custom map by viewing the URL for viewing the custom map described in the e-mail.
As described above, the customization unit 14A of the content generation unit 14 of the disaster response server 1 can be used to create a plurality of meshes for sediment disaster alert determination mesh information, heavy rain warning (flood damage) risk distribution information, etc. announced by the Meteorological Agency, for example. Perform customization of the map on which the regions are displayed. In the example shown in FIGS. 6A and 6B, the customization unit 14A customizes the map shown in FIG. 6A to generate the custom map shown in FIG. 6B.
As shown in FIGS. 6A and 6B, in the custom map shown in FIG. 6B, the user's house in the map shown in FIG. 6A is located on the custom map shown in FIG. is moved to a position (more specifically, the center position) other than the periphery of the . In another example, on the custom map, the user's home may be moved to a position other than the center position of the custom map. Also in this example, the user's home is moved to a position other than the perimeter of the custom map, and 8 mesh regions located around the mesh region containing the user's home (surrounding mesh regions) are also included in the custom map. . That is, the map shown in FIG. 6A may be used as it is as the custom map.
In the example shown in FIG. 7B, the content delivery unit 15 delivers a custom map (see FIG. 6B) generated by the customization unit 14A and displayable by the terminal device B1.
In the example shown in FIG. 7, a disaster response system X includes a disaster response server 1 and a terminal device B1.

As described above, in the examples shown in FIGS. 1 to 7, as shown in FIG. 7A, the user understands that the risk level of the mesh area including the user's home corresponds to "very dangerous". be able to. As a result, the user can accurately judge the situation, such as whether or not it is really necessary to evacuate. Specifically, the user can make real-time situational judgments without delaying announcements by the Japan Meteorological Agency, for example.
In addition, in the examples shown in FIGS. 1 to 7, as shown in FIGS. 6(B) and 7(B), the user selects the mesh area including the user's home instead of the risk level of the municipality including the user's home. (an area narrower than the municipality) corresponds to "very dangerous".
In the examples shown in FIGS. 1 to 7, as shown in FIGS. 7A and 7B, the user indicates meteorological disaster information such as landslide warning decision mesh information announced by the Meteorological Agency. It is possible to grasp from the e-mail that the risk level of the mesh area including the user's home corresponds to "very dangerous" without having to browse the home page.
Further, in the examples shown in FIGS. 1 to 7, as shown in FIGS. 6B and 7B, the user sets the risk level of the mesh area including the user's house to "very dangerous" by using the custom map. Correspondence can be visually grasped.
In addition, in the examples shown in FIGS. 1 to 7, as shown in FIGS. 7A and 7B, an alert indicating that the risk level of the mesh area including the user's home corresponds to "very dangerous" The content is delivered to the terminal device B1 carried by the user. Therefore, even when the user is outside the user's home, the user can understand that the risk level of the mesh area including the user's home corresponds to "very dangerous". As a result, the user outside the user's home can notify the user inside the user's home of the danger in the user's home, and urge them to take measures such as evacuation. In addition, the user outside the user's home can determine whether or not to avoid returning home to the user's home.
Further, in the examples shown in FIGS. 1 to 7, as described above, the administrator of the disaster response server 1 is the company that has contracted the construction of the user's house. Therefore, the disaster response server 1 can utilize the user information obtained at the time of construction of the user's house and appropriately provide the user with information such as the degree of danger of the mesh area including the user's house.

In the examples shown in FIGS. 1 to 7, as described above, the address information or location information of the user's home is provided by the administrator of the disaster response server 1 (the company that performed the construction contract for the user's home), and the user information is stored. Although stored in the unit 12 , in another example, address information or location information of the user's home may be acquired by equipment installed at the user's home and stored in the user information storage unit 12 . In this example, by using GPS (Global Positioning System), Internet location information, LTE (Long Term Evolution) connection base station information, or the like, address information or location information of the user's home is acquired.
In addition, in the examples shown in FIGS. 1 to 7, the disaster response server 1 is arranged outside the user's home. Specifically, the disaster response server 1 is located in an area other than the Kanto region. In another example, part or all of the disaster response server 1 may be located on the cloud.
In addition, in the examples shown in FIGS. 1 to 7, the disaster response server 1 includes an emergency power source and a vibration isolator. Each component of the disaster response server 1 is located within the same data center and within the same firewall. Therefore, the crisis management and backup system of the disaster response server 1 can be improved.

In the examples shown in FIGS. 1 to 7, as described above, the weather or disaster warning area is information indicating the degree of risk of each of a plurality of mesh areas that make up the warning area. Disaster information is acquired by the weather disaster information acquisition unit 11 . Further, when the first determination unit 13 determines that a plurality of user homes are included in the warning target area, and when the plurality of user homes are damaged, the disaster response unit 18 determines whether the plurality of user homes are severely damaged. Then, based on the degree of disaster severity of each of the user's homes, a response schedule indicating the order of response to the plurality of user's homes is formulated.
Therefore, in the examples shown in FIGS. 1 to 7, the disaster response unit 18 appropriately determines the response order of the damaged user homes based on the weather disaster information indicating the degree of risk of each of the multiple mesh areas. be able to.
In other words, in the examples shown in FIGS. 1 to 7, the disaster response unit 18 can more appropriately determine the response order of the damaged user homes than when the degree of risk of each of the multiple mesh areas is not taken into consideration. can.

Further, in the examples shown in FIGS. 1 to 7, as described above, the disaster severity calculation unit 18A calculates the disaster severity, which is the product of the disaster risk and time for each of a plurality of users' homes. Therefore, in the examples shown in FIGS. 1 to 7, it is possible to take appropriate disaster measures in consideration of the elapsed time from the occurrence of the disaster.
Specifically, in the examples shown in FIGS. 1 to 7, the disaster risk is set based on the weather disaster information indicating the risk of each mesh area acquired by the weather disaster information acquisition unit 11. FIG. Therefore, in the examples shown in FIGS. 1 to 7, mesh information (detailed information) such as landslide warning determination mesh information can be effectively utilized for disaster response after the occurrence of a disaster.

FIG. 8 is a diagram showing a second application example of the disaster response server 1 of the first embodiment.
In the example shown in FIG. 8, a disaster response system X includes a disaster response server 1, a weather disaster information announcement unit A1, a weather disaster information data distribution unit A2, and a terminal device B2.
In the example shown in FIG. 8A, similarly to the example shown in FIG. Weather disaster information such as earthquake information indicating warning areas for wind speed and wind damage information indicating warning areas for wind speed. The weather disaster information data distribution unit A2 distributes the weather disaster information data announced by the weather disaster information announcement unit A1 in a usable (processable) format.
The meteorological disaster information acquisition unit 11 (see FIG. 1) of the disaster response server 1 receives the meteorological disaster information data (for example, landslide warning determination mesh information, heavy rain warning (flood damage) information) distributed by the meteorological disaster information data distribution unit A2. data, such as risk distribution information).
The first determination unit 13 (see FIG. 1) of the disaster response server 1 determines whether the user's home is a warning target area (for example, FIG. 6 (see FIG. 6 ( It is determined whether it is included in any of the 6 mesh areas corresponding to "very dangerous" shown in A).
When the user's home is included in the warning target area, the content generation unit 14 (see FIG. 1) of the disaster response server 1 generates alert content based on the weather disaster information acquired by the weather disaster information acquisition unit 11. do.

In the example shown in FIG. 8B, the content generation unit 14 of the disaster response server 1 sends an e-mail stating that the danger level of the mesh area including the user's home is "extremely dangerous" as the alert content. Generate.
The content distribution unit 15 (see FIG. 1) of the disaster response server 1 transmits the e-mail generated by the content generation unit 14 to the terminal device B2 used by the user.
In the example shown in FIG. 8, the terminal device B2 used by the user is a terminal device such as a personal computer located in the user's home. In another example, the terminal device B2 may be a terminal device other than a personal computer (for example, a device such as a television that can be connected to the Internet).

In the example shown in FIG. 8B, the e-mail sent by the content delivery unit 15 to the user's terminal device B2 includes a URL for the user to view the custom map.
In the example shown in FIG. 8(C), the content distribution unit 15 distributes a custom map (for example, see FIG. 6(B)) generated by the customization unit 14A and displayable by the terminal device B2.

In the examples shown in FIGS. 8(B) and 8(C), unlike the examples shown in FIGS. 7(A) and 7(B), the alert content is distributed to the terminal device B2 located at the user's home. be. Therefore, in the example shown in FIG. 8, the user at the user's home can understand that the risk level of the mesh area including the user's home is "very dangerous".

FIG. 9 is a diagram showing another example of the disaster response server 1 of the first embodiment.
In the example shown in FIG. 9, the disaster response server 1 includes, for example, a weather disaster information acquisition unit 11, a user information storage unit 12, a first determination unit 13, a content generation unit 14, a content distribution unit 15, a second It has a determination unit 16 , a determination result transmission unit 17 , and a disaster response unit 18 .
In the example shown in FIG. 9, the disaster response server 1 includes the content generation unit 14 and the content distribution unit 15, but in other examples, the disaster response server 1 does not include the content generation unit 14 and the content distribution unit 15. may

In the example shown in FIG. 9, the second determination unit 16 determines the user information stored in the user information storage unit 12, the degree of risk of the mesh area including the user's house, and the degree of risk of the mesh area including the user's house. Based on the degree of risk of the surrounding mesh area, which is a mesh area, it is determined whether the user in the user's home should evacuate outside the user's home or whether the user in the user's home should stay in the user's home.
The determination result transmission unit 17 allows the user to use the determination result of the second determination unit 16 as to whether the user in the user's home should evacuate outside the user's home or whether the user in the user's home should stay in the user's home. Send to the terminal device B1.

FIG. 10 is a diagram for explaining the mesh area MU including the user's home, the surrounding mesh areas MS1 to MS8 positioned around the mesh area MU including the user's home, and the like.
In the example shown in FIG. 10(A), six mesh areas M1, M2, MS1, MS2, MS4, and MU, where the increased risk of sediment-related disasters due to heavy rain corresponds to "extremely dangerous", are the warning target areas. is displayed on the map of the landslide warning determination mesh information. The user's home of the disaster response server 1 is included in the mesh area MU.
Among the surrounding mesh areas MS1 to MS8 surrounding the mesh area MU including the user's home, a surrounding mesh area MS1 located on the northwest side of the mesh area MU and a surrounding mesh area MS2 located on the north side of the mesh area MU. , and the surrounding mesh area MS4 located on the west side of the mesh area MU correspond to the degree of danger of "very dangerous".
Of the surrounding mesh areas MS1 to MS8, a surrounding mesh area MS3 located on the northeast side of the mesh area MU, a surrounding mesh area MS5 located on the east side of the mesh area MU, and a surrounding mesh area located on the southwest side of the mesh area MU. The region MS6, the surrounding mesh region MS7 located on the south side of the mesh region MU, and the surrounding mesh region MS8 located on the southeast side of the mesh region MU correspond to the risk level of "pay attention to future information". .
In the example shown in FIGS. 9 and 10A, the second determination unit 16 determines that the user in the user's home is a surrounding mesh area whose risk level corresponds to "pay attention to future information, etc." It is determined that users in the user's home should evacuate to a surrounding mesh area MS8, which is a surrounding mesh area away from the mesh areas M1, M2, MS1, MS2, and MS4 corresponding to "very dangerous".

FIG. 11 is a diagram showing a third application example, which is an application example of the disaster response server 1 of the first embodiment shown in FIG.
In the example shown in FIG. 11, a disaster response system X includes a disaster response server 1, a weather disaster information announcement unit A1, a weather disaster information data distribution unit A2, and a terminal device B1.
In the example shown in FIG. 11, similarly to the example shown in FIG. It publishes weather hazard information such as earthquake information indicating areas and wind damage information indicating warning areas for wind speed. The weather disaster information data distribution unit A2 distributes the weather disaster information data announced by the weather disaster information announcement unit A1 in a usable (processable) format.
The meteorological disaster information acquisition unit 11 (see FIG. 9) of the disaster response server 1 receives meteorological disaster information data (for example, landslide warning determination mesh information, heavy rain warning (flood damage) information) distributed by the meteorological disaster information data distribution unit A2. data, such as risk distribution information).
The first determination unit 13 (see FIG. 9) of the disaster response server 1 determines whether the user's home is a warning target area (for example, FIG. 10 (see FIG. 10 ( It is determined whether or not it is included in any of the six mesh areas M1, M2, MS1, MS2, MS4, and MU shown in A).
When the user's home is included in the warning target area, the content generation unit 14 (see FIG. 9) of the disaster response server 1 generates alert content based on the weather disaster information acquired by the weather disaster information acquisition unit 11. do.

In the example shown in FIG. 11(A), the content generation unit 14 of the disaster response server 1, for example, sets the risk level of the mesh area MU including the user's home to "very dangerous" and the surrounding mesh area located on the northwest side of the mesh area MU. The risk level of the area MS1 is "very dangerous", the risk level of the surrounding mesh area MS2 located on the north side of the mesh area MU is "very dangerous", and the risk level of the surrounding mesh area MS3 located on the northeast side of the mesh area MU. The risk level of the surrounding mesh area MS4 located on the west side of the mesh area MU is "extremely dangerous", and the risk level of the surrounding mesh area MS5 located on the east side of the mesh area MU is "future information". The risk level of the surrounding mesh area MS6 located on the southwest side of the mesh area MU, "Pay attention to future information, etc.", and the risk level of the surrounding mesh area MS7 located on the south side of the mesh area MU, "Future and "Pay attention to future information" of the surrounding mesh area MS8 located on the southeast side of the mesh area MU.
The content delivery unit 15 (see FIG. 9) of the disaster response server 1 transmits the e-mail generated by the content generation unit 14 to the terminal device B1 used by the user.
In the example shown in FIG. 11, the terminal device B1 used by the user is a terminal device carried by the user, such as a smart phone. In another example, the terminal device B1 may be a mobile terminal device other than a smart phone.

In the example shown in FIG. 11A, the user browses the custom map shown in FIG. The URL for The user can grasp the distribution of the custom map by viewing the URL for viewing the custom map described in the e-mail.
In the example shown in FIGS. 10A and 10B, the customizing unit 14A (see FIG. 9) customizes the map shown in FIG. Generate a map.
As shown in FIGS. 10A and 10B, on the custom map shown in FIG. 10B, the user's house in the map shown in FIG. 10A is located on the custom map shown in FIG. 10B. is moved to a position (more specifically, the center position) other than the periphery of the . In another example, on the custom map, the user's home may be moved to a position other than the center position of the custom map. Also in this example, the user's home is moved to a position other than the perimeter of the custom map, and 8 mesh regions located around the mesh region containing the user's home (surrounding mesh regions) are also included in the custom map. . That is, the map shown in FIG. 10A may be used as it is as the custom map.
In the example shown in FIG. 11B, the content distribution unit 15 distributes a custom map (see FIG. 10B) generated by the customization unit 14A and displayable by the terminal device B1.

As described above, in the examples shown in FIGS. 9 to 11, the content generation unit 14 determines that the risk level of the mesh area MU including the user's house is "very dangerous" and that the mesh area MU including the user's house is located around the MU. An e-mail is generated indicating the degree of danger of the surrounding mesh areas MS1, MS2 and MS4 and the degree of danger of the surrounding mesh areas MS3, MS5, MS6, MS7 and MS8 and paying attention to future information.
Therefore, in the examples shown in FIGS. 9 to 11, the user not only selects the "very dangerous" risk level of the mesh area MU including the user's home, but also the "very dangerous" risk level of the surrounding mesh areas MS1, MS2, and MS4. By grasping the risk levels of "pay attention to future information, etc." of the surrounding mesh areas MS3, MS5, MS6, MS7, and MS8, the risk levels of the surrounding mesh areas MS1, MS2, and MS4 of "very dangerous" and the surrounding mesh areas A more appropriate evacuation route from the user's home can be considered than when the risk level "pay attention to future information" of MS3, MS5, MS6, MS7, and MS8 is not grasped.

In the example shown in FIGS. 9 to 11, the custom map shown in FIG. 10B indicates that the mesh area MU including the user's home has a risk level of "very dangerous" and the surrounding mesh areas MS1, MS2, and MS4 have a risk level of "high risk". "Very dangerous" and the degree of danger of the surrounding mesh areas MS3, MS5, MS6, MS7 and MS8 "Pay attention to future information". Also, the custom map shown in FIG. 10B is distributed by the content distribution unit 15 and displayed by the user's terminal device B1.
Therefore, in the examples shown in FIGS. 9 to 11, the user uses the custom map shown in FIG. , and the risk levels of the surrounding mesh areas MS3, MS5, MS6, MS7, and MS8, "Pay attention to future information".

In the examples shown in FIGS. 9 to 11, as described above, the second determination unit 16 determines whether the user in the user's home should evacuate outside the user's home or whether the user in the user's home should stay in the user's home. The result is transmitted to the terminal device B1 of the user by the determination result transmission unit 17. FIG.
Therefore, in the examples shown in FIGS. 9 to 11, the user can use the determination result transmitted by the determination result transmission unit 17 as a criterion for deciding whether to evacuate outside the user's home or stay inside the user's home. can.

FIG. 12 is a diagram showing a fourth application example, which is another application example of the disaster response server 1 of the first embodiment shown in FIG.
In the example shown in FIG. 12, a disaster response system X includes a disaster response server 1, a weather disaster information announcement unit A1, a weather disaster information data distribution unit A2, and a terminal device B2.
In the example shown in FIG. 12A, the meteorological disaster information announcement unit A1, for example, landslide warning determination area information, flood damage warning determination area information, flood damage warning determination area information, earthquake information indicating an earthquake warning target area, And, it publishes weather hazard information such as wind damage information indicating warning areas for wind speed. The weather disaster information data distribution unit A2 distributes the weather disaster information data announced by the weather disaster information announcement unit A1 in a usable (processable) format.
The meteorological disaster information acquisition unit 11 (see FIG. 9) of the disaster response server 1 receives meteorological disaster information data (for example, landslide warning determination mesh information, heavy rain warning (flood damage) information) distributed by the meteorological disaster information data distribution unit A2. data, such as risk distribution information).
The first determination unit 13 (see FIG. 9) of the disaster response server 1 determines whether the user's home is a warning target area (for example, FIG. 10 (see FIG. 10 ( It is determined whether or not it is included in any of the six mesh areas M1, M2, MS1, MS2, MS4, and MU shown in A).
When the user's home is included in the warning target area, the content generation unit 14 (see FIG. 9) of the disaster response server 1 generates alert content based on the weather disaster information acquired by the weather disaster information acquisition unit 11. do.

In the example shown in FIG. 12(B), the content generation unit 14 of the disaster response server 1, for example, sets the risk level of the mesh area MU including the user's home to "very dangerous" and the risk levels of the surrounding mesh areas MS1, MS2, and MS4. An e-mail is generated as an alert content that describes "extremely dangerous" and the degree of danger of the surrounding mesh areas MS3, MS5, MS6, MS7, and MS8, "pay attention to future information, etc.".
The content distribution unit 15 (see FIG. 9) of the disaster response server 1 transmits the e-mail generated by the content generation unit 14 to the terminal device B2 used by the user.
In the example shown in FIG. 12, the terminal device B2 used by the user is a terminal device such as a personal computer located in the user's home. In another example, the terminal device B2 may be a terminal device other than a personal computer (for example, a device such as a television that can be connected to the Internet).

In the example shown in FIG. 12B, the e-mail sent by the content distribution unit 15 to the user's terminal device B2 includes a URL for the user to view the custom map.
In the example shown in FIG. 12(C), the content distribution unit 15 distributes a custom map (for example, see FIG. 10(B)) generated by the customization unit 14A and displayable by the terminal device B2.

Further, in the example shown in FIG. 12, the determination result transmission unit 17 (see FIG. 9) of the disaster response server 1 determines whether the user in the user's home should evacuate outside the user's home, or whether the user in the user's home should evacuate to the user's home. The determination result of the second determination unit 16 (see FIG. 9) as to whether to stay is transmitted to the user's terminal device B2.

In the example described above, the customization unit 14A customizes a map in which a plurality of mesh areas are displayed, such as sediment disaster caution determination mesh information and heavy rain warning (flood damage) risk distribution information announced by the Meteorological Agency. .
In another example, the customizing unit 14A uses information other than the landslide warning determination mesh information and heavy rain warning (flood damage) risk distribution information, such as flood warning risk distribution announced by the Meteorological Agency ( For example, map customization may be performed in which multiple mesh areas are displayed, such as information indicating alert areas regarding earthquakes, wind speeds, etc.).

<Second embodiment>
A second embodiment of the disaster response server, disaster response method, and program of the present invention will be described below.
The disaster response server 1 of the second embodiment is configured in the same manner as the disaster response server 1 of the first embodiment described above, except for points to be described later. Therefore, according to the disaster response server 1 of the second embodiment, the same effects as those of the disaster response server 1 of the first embodiment described above can be obtained except for the points described later.

The disaster response server 1 of the second embodiment is configured similarly to the disaster response server 1 of the first embodiment shown in FIG.
In the first application example of the disaster response server 1 of the second embodiment, the meteorological disaster information announcement part A1 (see FIG. 5), for example, sediment disaster warning determination area information, flood damage warning determination area information, flood damage warning determination area information , earthquake information indicating alert areas for earthquakes, and wind damage information indicating alert areas for wind speed. The weather disaster information data distribution unit A2 (see FIG. 5) distributes the weather disaster information data announced by the weather disaster information announcement unit A1 in a usable (processed) format.
The meteorological disaster information acquisition unit 11 (see FIG. 1) of the disaster response server 1 receives the meteorological disaster information data (for example, landslide warning determination mesh information, heavy rain warning (flood damage) information) distributed by the meteorological disaster information data distribution unit A2. data, such as risk distribution information).

In the first application example of the disaster response server 1 of the second embodiment, the first determination unit 13 (see FIG. 1) of the disaster response server 1 determines whether the user's home has sediment disaster warning determination mesh information, heavy rain warning (flood damage), It is determined whether or not it is included in the warning target area (for example, any one of the six mesh areas shown in FIG. 6A) in the risk distribution information.
When the first determination unit 13 determines that the user's home is included in the warning target area, the content generation unit 14 (see FIG. 1) of the disaster response server 1 generates the weather disaster information acquired by the weather disaster information acquisition unit 11. Generate alert content based on information. The content generator 14 includes a customizer 14A (see FIG. 1). The customizing unit 14A customizes a map in which a plurality of mesh areas are displayed in sediment disaster warning determination mesh information and heavy rain warning (flood damage) risk distribution information announced by the Meteorological Agency, for example, and customizes the custom map (Fig. 6(B)).
The content delivery unit 15 (see FIG. 1) of the disaster response server 1 delivers a custom map or the like as alert content generated by the content generation unit 14 .

FIG. 13 is a diagram for explaining an example of alert content generation by the content generation unit 14 of the disaster response server 1 according to the second embodiment.
In the example shown in FIG. 13, a disaster response system X includes a disaster response server 1, a weather disaster information announcement unit A1, a weather disaster information data distribution unit A2, and a terminal device B1.
In the example shown in FIG. 13A, if the user's house is included in the warning target area in sediment disaster warning determination mesh information, heavy rain warning (flood damage) risk distribution information, earthquake information, wind speed information, etc., 1 determination unit 13, the content delivery unit 15 of the disaster response server 1 transmits a push notification to the terminal device (smartphone) B1 carried by the user. The push notification transmitted by the content delivery unit 15 is a notification prompting the user to display a custom map (see FIG. 6B) in the dedicated application of the terminal device (smartphone) B1.
In the example shown in FIG. 13B, the content distribution unit 15 distributes a custom map generated by the customization unit 14A and displayed by the terminal device (smartphone) B1.

As described above, in the first application example of the disaster response server 1 of the second embodiment, a push notification prompting display of a custom map is sent from the disaster response server 1 to the terminal device (smartphone) B1 carried by the user. be. Therefore, it is possible to suppress the possibility that the user will not perform the display operation of the custom map, as compared with the case where the push notification is not sent.

In another example of the disaster response server 1 of the second embodiment, the disaster response server 1 is configured similarly to the disaster response server 1 shown in FIG. In this example, the second determination unit 16 determines the user information stored in the user information storage unit 12, the degree of risk of the mesh area including the user's home, and the mesh areas located around the mesh area including the user's home. Based on the degree of danger of a certain surrounding mesh area, it is determined whether the user in the user's home should evacuate outside the user's home or whether the user in the user's home should stay in the user's home.
Also, in this example, the determination result transmission unit 17 transmits the determination result by the second determination unit 16 as to whether the user in the user's home should evacuate outside the user's home or whether the user in the user's home should stay in the user's home. , to the terminal device (smartphone) B1 used by the user.

In the second application example of the disaster response server 1 of the second embodiment, the first determination unit 13 (see FIG. 9) of the disaster response server 1 determines whether the user's home has sediment disaster warning determination mesh information, heavy rain warning (flood damage). It is determined whether or not the .
When the first determination unit 13 determines that the user's home is included in the warning target area, the content generation unit 14 (see FIG. 9) of the disaster response server 1 generates the weather disaster information acquired by the weather disaster information acquisition unit 11. Generate alert content based on information. The content generator 14 has a customizer 14A (see FIG. 9). The customizing unit 14A can customize a map (see FIG. 10A) in which a plurality of mesh areas are displayed in sediment disaster caution determination mesh information, heavy rain warning (flood damage) risk distribution information, etc. announced by the Meteorological Agency, for example. Execute customization to generate a custom map (see FIG. 10(B)).
The content delivery unit 15 (see FIG. 9) of the disaster response server 1 delivers a custom map or the like as alert content generated by the content generation unit 14 .

As described above, in the first application example and the second application example of the disaster response server 1 of the second embodiment, the customizing unit 14A uses the sediment disaster caution determination mesh information and the heavy rain warning (flood damage) announced by the Meteorological Agency. Perform map customization where multiple mesh areas are displayed, such as risk distribution information.
In the third application example of the disaster response server 1 of the second embodiment, the customizing unit 14A provides landslide warning determination mesh information and heavy rain warnings (flood damage) such as the risk distribution of flood warnings announced by the Meteorological Agency. ) (for example, information indicating a warning target area related to earthquakes, wind speeds, etc.) other than the risk distribution information (for example, information indicating a warning target area regarding earthquakes, wind speeds, etc.) may be customized to display a plurality of mesh areas.

<Third Embodiment>
A third embodiment of the disaster response server, disaster response method, and program of the present invention will be described below.
The disaster response server 1 of the third embodiment is configured in the same manner as the disaster response server 1 of the first embodiment described above, except for points to be described later. Therefore, according to the disaster response server 1 of the third embodiment, the same effects as those of the disaster response server 1 of the first embodiment described above can be obtained except for the points described later.

A disaster response server 1 according to the third embodiment is configured in substantially the same manner as the disaster response server 1 according to the first embodiment shown in FIG.
FIG. 14 is a diagram showing a first application example of the disaster response server 1 of the third embodiment.
In the example shown in FIG. 14, a disaster response system X includes a disaster response server 1, a weather disaster information announcement unit A1, a weather disaster information data distribution unit A2, and a terminal device B3.
In the example shown in FIG. 14, the meteorological disaster information announcement unit A1 generates, for example, sediment disaster warning determination area information, flood damage warning determination area information, flood damage warning determination area information, earthquake information indicating an earthquake warning target area, and wind speed Announcing weather hazard information such as wind damage information indicating warning areas for The weather disaster information data distribution unit A2 distributes the weather disaster information data announced by the weather disaster information announcement unit A1 in a usable (processable) format.
The meteorological disaster information acquisition unit 11 (see FIG. 1) of the disaster response server 1 receives the meteorological disaster information data (for example, landslide warning determination mesh information, heavy rain warning (flood damage) information) distributed by the meteorological disaster information data distribution unit A2. data, such as risk distribution information).

In the example shown in FIG. 14 , the first determination unit 13 (see FIG. 1 ) of the disaster response server 1 determines whether the user's home is alerted based on sediment disaster warning determination mesh information, heavy rain warning (flood damage) risk distribution information, and the like. It is determined whether or not it is included in the target area (for example, one of the six mesh areas shown in FIG. 6A).
When the first determination unit 13 determines that the user's home is included in the warning target area, the content generation unit 14 (see FIG. 1) of the disaster response server 1 generates the weather disaster information acquired by the weather disaster information acquisition unit 11. Generate alert content based on information. Specifically, the content generation unit 14 generates an automatic voice message indicating the degree of danger of the mesh area including the user's house (see FIG. 6A), which is "extremely dangerous", as the alert content.
The content delivery unit 15 (see FIG. 1) of the disaster response server 1 transmits the automatic voice message as alert content generated by the content generation unit 14 to the terminal device (telephone) B3 used by the user.

As described above, in the first application example of the disaster response server 1 of the third embodiment, when the user's home is included in the warning target area, an automatic voice message indicating the degree of risk of the mesh area including the user's home is sent to the user. is transmitted to the terminal device (telephone) B3 used by the . Therefore, in the first application example of the disaster response server 1 of the third embodiment, even if the user cannot operate a smart phone, a personal computer, or the like, the user can grasp the degree of danger of the mesh area including the user's home. .

As described above, in the first application example of the disaster response server 1 of the third embodiment, the first determination unit 13 determines whether the user's home has sediment disaster warning determination mesh information and heavy rain warning (flood damage) risk distribution. It is determined whether or not the area is included in the warning target area in the information.
In the second application example of the disaster response server 1 of the third embodiment, the first determination unit 13 generates landslide warning determination mesh information and heavy rain warning ( It may be determined whether or not the user's home is included in the warning target area in information other than the risk distribution information (for example, information indicating a warning target area related to earthquakes, wind speeds, etc.).

As described above, the mode for carrying out the present invention has been described using the embodiments, but the present invention is not limited to such embodiments at all, and various modifications and replacements can be made without departing from the scope of the present invention. can be added. You may combine suitably the structure described in each embodiment and each example which were mentioned above.

All or part of the functions of the units provided in the disaster response system X in the above-described embodiment are recorded on a computer-readable recording medium by recording a program for realizing these functions. It may be realized by loading the program into a computer system and executing it. It should be noted that the "computer system" referred to here includes hardware such as an OS and peripheral devices.
The term "computer-readable recording medium" refers to portable media such as flexible discs, magneto-optical discs, ROMs and CD-ROMs, and storage units such as hard discs incorporated in computer systems. Furthermore, "computer-readable recording medium" means a medium that dynamically retains a program for a short period of time, like a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line. It may also include a device that holds a program for a certain period of time, such as a volatile memory inside a computer system that serves as a server or client in that case. Further, the program may be for realizing part of the functions described above, or may be capable of realizing the functions described above in combination with a program already recorded in the computer system.

REFERENCE SIGNS LIST 1 disaster response server 11 meteorological disaster information acquisition unit 12 user information storage unit 13 first determination unit 14 content generation unit 14A customization unit 15 content distribution unit 16 second determination Part 17... Judgment result transmission part 18... Disaster response part 18A... Disaster severity calculation part 18B... Landslide disaster risk information collection part 18C... Damaged house extraction part 18D... Damage degree map generation part 18E... Response schedule formulation unit X... Disaster response system A1... Weather disaster information announcement unit A2... Weather disaster information data distribution unit B1... Terminal device B2... Terminal device B3... Terminal device

Claims (14)

a meteorological disaster information acquisition unit that acquires meteorological disaster information that is information indicating a warning target area regarding weather or a disaster;
Whether the user's home is included in the warning target area based on user information including address information or location information of the user's home, and the weather disaster information acquired by the weather disaster information acquisition unit A determination unit that determines whether or not
a disaster response unit that determines the severity of damage to the user's home when the determination unit determines that the user's home is included in the warning target area;
The warning target area is composed of a plurality of mesh areas,
The weather disaster information is information indicating the degree of risk of each mesh area,
The determining unit determines whether the user's home is included in any one of the plurality of mesh areas,
The meteorological disaster information includes sediment disaster warning determination area information, flood damage warning determination area information, flood damage warning determination area information, earthquake information indicating an earthquake warning area, and wind damage information indicating a wind speed warning area. includes at least one of
The disaster response unit, when a plurality of user homes are included in any one of the plurality of mesh areas and when the disaster severity of the plurality of user homes exceeds a certain level, A priority list that defines the priority of correspondence can be generated and output,
The priority list that defines the order of priority for correspondence of the plurality of user homes is generated based on the importance of each of the plurality of user homes;
The degree of importance of each of the plurality of user homes includes at least a degree based on whether or not the home has been damaged in the past.
Disaster response server. The disaster handling unit, when a plurality of user homes are included in any one of the plurality of mesh areas and when the disaster severity of the plurality of user homes exceeds the predetermined level, Formulate a response schedule that indicates the order in which to respond to each home,
The response schedule is formulated based on the disaster severity of each of the plurality of user homes,
The disaster response server according to claim 1. The disaster response unit includes a disaster severity calculation unit,
The disaster severity calculation unit calculates the disaster severity that reflects the weight of time on the disaster risk of each user's home.
The disaster response server according to claim 2. The disaster severity calculation unit calculates, as the disaster severity, the product of the disaster risk level of each user's home and the time,
The disaster risk level is set based on the weather disaster information indicating the risk level of each mesh area acquired by the weather disaster information acquisition unit,
A disaster response server according to claim 3. The disaster response unit includes a disaster degree map generation unit,
The disaster degree map generation unit generates a disaster user home list, which is a list of the plurality of user homes whose disaster severity exceeds the predetermined level,
The disaster user home list is generated by sorting the disaster severity calculated for each user home by the disaster severity calculation unit in descending order of the disaster severity.
The disaster response server according to claim 3 or 4 . The disaster degree map generation unit generates a disaster degree map indicating at least the positions and densities of the homes of the plurality of users whose disaster severity exceeds the certain level.
The disaster response server according to claim 5 . the disaster response department comprises a response scheduling department;
The response schedule formulation unit formulates the response schedule in descending order of disaster severity, based on the disaster user home list generated by the disaster degree map generation unit.
The disaster response server according to claim 5 or claim 6 . When the plurality of user homes whose disaster severity exceeds the certain level are included in a plurality of response areas,
The disaster user home list is generated for each corresponding area by sorting for each corresponding area.
The disaster response server according to claim 5 . The priority list that defines the order of priority for correspondence of the plurality of user homes is generated based on the attributes of each resident of the plurality of user homes;
The attributes of the resident include at least one of the resident's age and the resident's health condition;
The disaster response server according to claim 1 . The landslide warning determination area information includes landslide warning determination mesh information,
The determination unit determines whether or not the user's house is included in any one of the plurality of mesh areas displayed on the map as the warning target area in the sediment disaster warning determination mesh information.
The disaster response server according to any one of claims 1 to 9 . A storage unit that stores the user information,
The disaster response server according to any one of claims 1 to 10 . The administrator of the disaster response server is the company that contracted the construction of the user's house,
The disaster response server according to any one of claims 1 to 11 . a meteorological disaster information acquisition step in which the disaster response server acquires meteorological disaster information, which is information indicating a warning target area regarding weather or disaster;
Based on user information including address information or location information of the user's house, which is the user's residence, and the weather disaster information acquired in the weather disaster information acquisition step, the disaster response server determines whether the user's house is on the alert. a determination step of determining whether or not it is included in the target area;
a disaster response step in which, when the determination step determines that the user's home is included in the warning target area, the disaster response server determines the severity of damage to the user's home;
The warning target area is composed of a plurality of mesh areas,
The weather disaster information is information indicating the degree of risk of each mesh area,
In the determining step, it is determined whether or not the user's home is included in any one of the plurality of mesh areas;
The meteorological disaster information includes sediment disaster warning determination area information, flood damage warning determination area information, flood damage warning determination area information, earthquake information indicating an earthquake warning area, and wind damage information indicating a wind speed warning area. includes at least one of
In the disaster response step, when a plurality of user homes are included in any one of the plurality of mesh areas and when disaster severity of the plurality of user homes exceeds a certain level, a priority list is generated and printable that defines the priority of correspondence;
The priority list that defines the order of priority for correspondence of the plurality of user homes is generated based on the importance of each of the plurality of user homes;
The degree of importance of each of the plurality of user homes includes at least a degree based on whether or not the home has been damaged in the past.
Disaster response method. to the computer,
a meteorological disaster information acquisition step of acquiring meteorological disaster information, which is information indicating a warning target area regarding weather or disaster;
Whether the user's home is included in the warning target area based on user information including address information or location information of the user's home, and the weather disaster information obtained in the weather disaster information obtaining step a determination step of determining whether or not
a disaster response step of determining the severity of damage to the user's home when it is determined in the determining step that the user's home is included in the warning target area;
A program for executing
The warning target area is composed of a plurality of mesh areas,
The weather disaster information is information indicating the degree of risk of each mesh area,
In the determining step, it is determined whether or not the user's home is included in any one of the plurality of mesh areas;
The meteorological disaster information includes sediment disaster warning determination area information, flood damage warning determination area information, flood damage warning determination area information, earthquake information indicating an earthquake warning area, and wind damage information indicating a wind speed warning area. includes at least one of
In the disaster response step, when a plurality of user homes are included in any one of the plurality of mesh areas and when disaster severity of the plurality of user homes exceeds a certain level, a priority list is generated and printable that defines the priority of correspondence;
The priority list that defines the order of priority for correspondence of the plurality of user homes is generated based on the importance of each of the plurality of user homes;
The degree of importance of each of the plurality of user homes includes at least a degree based on whether or not the home has been damaged in the past.
program.

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