JP2010045641A - Disaster information distribution server, disaster information distribution method, disaster information distribution program and disaster information distribution system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a disaster information distribution server suppressing the application of loads to a network when notifying the occurrence of disaster. <P>SOLUTION: The disaster information distribution server 20 includes: a disaster information acquisition part 210 for acquiring earthquake information indicating the occurrence of the earthquake and a center position of the occurrence of the earthquake; a priority order determination part 230 for determining the priority order of users to which the occurrence of the earthquake is to be notified out of a plurality of users based on the occurrence of the earthquake center position in which the earthquake occurs and present positions of the plurality of users registered beforehand; and a disaster information notification part 240 for transmitting the information indicating the occurrence of the earthquake to user terminals owned by respective users on the basis of the priority order determined by the priority order determination part 230. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a disaster information distribution server, a disaster information distribution method, a disaster information distribution program, and a disaster information distribution system.

  For example, Patent Document 1 discloses a disaster-related information processing method as a disaster notification for reporting a disaster to a user in a disaster occurrence area in response to the occurrence of a disaster. The disaster-related information processing method described in Patent Document 1 receives information on a disaster occurrence area and information on a subscriber in the disaster occurrence area, and transmits a disaster report to a subscriber terminal in the disaster occurrence area. . Then, when receiving the position of the subscriber terminal or the voluntary safety confirmation response from the subscriber terminal in the disaster occurrence area, it is determined that the subscriber is in a safe state, and the determination result is stored in the disaster area subscriber table storage unit. It comes to store.

Japanese Patent Laid-Open No. 2003-248885

  However, in the disaster-related information processing method described in Patent Document 1, disaster notifications are broadcast to all users in the disaster occurrence area. For this reason, the server in charge of the disaster occurrence area has been subjected to simultaneous delivery of disaster notifications, which places a load on the network and causes communication congestion.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a disaster information distribution server and a disaster information distribution that can suppress the load on the network when notifying the occurrence of a disaster. A method, a disaster information distribution program, and a disaster information distribution system are provided.

According to the present invention, disaster information acquisition means for acquiring disaster information indicating that a disaster has occurred and the disaster occurrence center,
Based on the disaster occurrence center where the disaster occurred and the current positions of a plurality of users registered in advance, the priority order of the users who notify the occurrence of the disaster among the plurality of users is determined. Prioritization means for
Disaster information notifying means for transmitting information indicating that the disaster has occurred to a user terminal of the user based on the priority determined by the priority determining means;
A disaster information distribution server characterized by comprising:

According to the present invention, there is a disaster information distribution method performed by a disaster information distribution server that notifies that a disaster has occurred,
The disaster information distribution server
A disaster information acquisition step for acquiring disaster information indicating that a disaster has occurred and the center of the disaster;
Based on the disaster occurrence center where the disaster occurred and the current positions of a plurality of users registered in advance, the priority order of the users who notify the occurrence of the disaster among the plurality of users is determined. Prioritization step to
A disaster information notifying step of transmitting information indicating that the disaster has occurred to a user terminal of the user based on the priority determined in the priority determining step;
The disaster information delivery method characterized by including this is provided.

According to the present invention, a disaster information distribution program performed by a disaster information distribution server for notifying that a disaster has occurred,
A disaster information acquisition procedure for acquiring disaster information indicating that a disaster has occurred and the center of the disaster;
Based on the disaster occurrence center where the disaster occurred and the current positions of a plurality of users registered in advance, the priority order of the users who notify the occurrence of the disaster among the plurality of users is determined. Prioritization procedure to
A disaster information notification procedure for transmitting information indicating that the disaster has occurred to a user terminal of the user based on the priority determined by the priority determination procedure;
A disaster information distribution program characterized by causing a computer to execute is provided.

According to the present invention, a disaster information distribution system comprising a disaster information distribution server and a user terminal connected to the disaster distribution server,
The disaster information distribution server
Disaster information acquisition means for acquiring disaster information indicating that a disaster has occurred and the center of the disaster occurrence;
Based on the disaster occurrence center where the disaster occurred and the current positions of a plurality of users registered in advance, the priority order of the users who notify the occurrence of the disaster among the plurality of users is determined. Prioritization means for
Disaster information notifying means for transmitting information indicating that the disaster has occurred to the user terminal based on the priority order determined by the priority order determining means,
The user terminal is
There is provided a disaster information distribution system comprising disaster information receiving means for receiving the information in which the disaster has occurred.

  ADVANTAGE OF THE INVENTION According to this invention, when notifying the occurrence of a disaster, it can suppress that load is added to a network.

(First embodiment)
Hereinafter, embodiments of the present invention will be described with reference to the drawings. In all the drawings, the same reference numerals are given to the same components, and the description will be omitted as appropriate.

  FIG. 1 is a schematic configuration diagram showing a schematic configuration of a disaster information distribution system 100 according to the present embodiment.

  A disaster information distribution system 100 shown in FIG. 1 includes a disaster information distribution server 20, a mobile phone 50, a personal computer 60, and a position acquisition server 70.

  When the disaster information distribution server 20 receives from the earthquake early warning server 10 the time when the earthquake occurred and the estimated epicenter and magnitude of the earthquake, a plurality of users registered in advance will be notified by the occurrence of the earthquake. Estimate the earthquake arrival time and seismic intensity. The disaster information distribution server 20 transmits the estimated arrival time and seismic intensity of the earthquake to each location to each registered user. The disaster information distribution server 20 acquires the current position information of the user who uses the personal computer 60 or the mobile phone 50 from the position acquisition server 70.

  The mobile phone 50 performs data communication with the disaster information distribution server 20 via the network 30 by the radio base station 40 relaying, or the disaster information distribution server 20 via the voice network 90 and the gateway exchange 110. Voice communication. Further, the mobile phone 50 has a GPS (Global Positioning System) function, calculates position information (for example, latitude and longitude) of the mobile phone 50 using radio waves from an artificial satellite, and uses the position information as a wireless signal. The data is transmitted to the position acquisition server 70 via the base station 80.

  The personal computer 60 is connected to the disaster information distribution server 20 via the network 30. The personal computer 60 is also connected to the position acquisition server 70. The personal computer 60 transmits presence information indicating that the user is working in the company to the position acquisition server 70 when the user performs the operation. In addition, the personal computer 60 is configured such that a scheduler (not shown) receives a schedule input by the user, and transmits the received schedule to the position acquisition server 70 as schedule information. Note that the schedule information indicating the schedule indicates the user's action schedule, and includes the date and location as elements, and the user is scheduled to be at the location at that date and time.

  The position acquisition server 70 acquires presence information indicating whether the user is working in the company or outside the company from the personal computer 60, and determines the location of the user in real time. Further, the position acquisition server 70 receives user schedule information from the personal computer 60. The location acquisition server 70 is connected to the mobile phone 50 via the radio base station 80 and acquires the current location information (for example, the latitude and longitude described above) of the mobile phone 50 from the mobile phone 50. Since the position acquisition server 70 can acquire the current position information of the user who uses the personal computer 60 or the mobile phone 50, the current position information of each user is transmitted to the disaster information distribution server 20 in real time. In addition, the location acquisition server 70 uses the received schedule information to set the date / time and location information indicating the current action schedule (for example, in-house meetings and business negotiations) according to the schedule of the user who uses the personal computer 60 as disaster information. It transmits to the distribution server 20.

  The earthquake early warning server 10 is installed in, for example, an earthquake monitoring center that monitors the occurrence of earthquakes throughout the country. presume. Then, the earthquake early warning server 10 transmits the earthquake occurrence time, the estimated epicenter and the magnitude of the earthquake to the disaster information distribution server 20.

  The network 30 is a network that connects the disaster information distribution server 20 and the mobile phone 50 or the personal computer 60 to perform data communication with each other. It is assumed that the network 30 is connected by wireless communication via the wireless base station 40 when connected to the mobile phone 50.

  The radio base station 40 is connected to a voice network 90 that performs voice communication with the disaster information distribution server 20, and is connected to the disaster information distribution server 20 via the voice network 90 and the gateway exchange 110.

  The voice network 90 is a network for calls that allows the disaster information distribution server 20 and the mobile phone 50 to communicate with each other via the gateway exchange 110 and the radio base station 40.

  The gateway exchange 110 is an exchange for connecting the voice network 90 and the network 30. The gateway exchange 110 may be connected to a gateway device (not shown) that changes a protocol for each voice or data decision.

  The radio base station 80 is a radio base station that wirelessly connects the mobile phone 50 and the position acquisition server 70.

  Next, the disaster information distribution server 20 according to the present embodiment will be described in detail with reference to the drawings.

  FIG. 2 is a block diagram showing a configuration of the disaster information distribution server 20 according to the present embodiment. The disaster information distribution server 20 includes a disaster information acquisition unit 210, a priority order determination unit 230, and a disaster information notification unit 240.

  The disaster information acquisition unit 210 acquires an emergency earthquake bulletin indicating that an earthquake has occurred and the center of the occurrence of the earthquake. In addition, the disaster information acquisition unit 210 sends the acquired information about the earthquake occurrence center and the magnitude of the earthquake to the priority determination unit 230.

  The priority determination unit 230 acquires information on the earthquake occurrence center and the magnitude of the earthquake from the disaster information acquisition unit 210, and the earthquake occurrence center where the earthquake occurred and the current positions of each of a plurality of users registered in advance. Based on the above, the priority order of users who notify that an earthquake has occurred among a plurality of users is determined. The priority order determination unit 230 sends the determined priority order to the disaster information notification unit 240. The priority order determination unit 230 reads the current position information of each user from the user information database 220 when acquiring the current position of each of a plurality of users registered in advance, and determines the priority order. The priority order table of the priority order database 270 is read and referred to.

  The disaster information notification unit 240 acquires the priority order determined from the priority order determination unit 230, and based on the acquired priority order, the mobile phone 50 or personal computer 60 in which the user has earthquake information indicating that an earthquake has occurred. Send to.

  2 includes a position information acquisition unit 400, a user information database 220, a safety information reception unit 250, a safety information database 260, and a priority order database 270.

  The location information acquisition unit 400 acquires location information of the mobile phone 50, presence information or schedule information of the personal computer 60 from the location acquisition server 70. The position information acquisition unit 400 updates the item “state” in the user information table (FIG. 3) of the user information database 220 based on the acquired position information, presence information, or schedule information.

  Note that the place information in the schedule information is not limited to the place name, but may be a company name or an office name. In this case, when a location such as a company or office is registered in advance in the schedule information, the registered location is updated as location information. If the location of the company or business location is not registered in the schedule information, the location information acquisition unit 400 uses the company name or business site name as a keyword as a search system that can be used by the location information acquisition unit 400 ( Information indicating the location is acquired using a registration information database (not shown) and a registration information database (not shown). Since the location information acquisition unit 400 can search for information indicating a location using a search system using a keyword or a registration information database, even if the location of the company is not registered, for example, Minato-ku, Tokyo Information indicating the location of the lawn can be acquired, and the “location” in the user information table shown in FIG. 3 can be updated. The present embodiment is not limited to the case where the position information acquisition unit 400 uses a search system or a registration information database. For example, the location acquisition server 70 searches the information indicating the location from the company name, the office name, etc. using the search system and the registration information database, and transmits the searched information to the location information acquisition unit 400. Anyway.

  The user information database 220 has a user information table that stores information on each user registered in advance.

  FIG. 3 is a diagram illustrating an example of a user information table included in the user information database 220. In the user information table of the user information database 220, for each user ID (Identification), the employee name, the employee's mobile number, the employee's e-mail address, the user's status, and the current user's current status are displayed. The location indicating the location is associated with the priority item. That is, the employee “A” whose user ID is “0123” has the mobile phone number “090-0001-001”, the mail address “a@xyz.com”, and the employee “A”. The current state is “at home” and the location is “Kanagawa”. The priority of the user for the employee “A” is associated with “medium”. Therefore, employee “A” is sent to “090-0001-001” when an earthquake is notified by a mobile phone call based on the priority, and mail is sent to the personal computer. Is transmitted to “a@xyz.com”.

  The item “state” is updated in real time as the position information acquisition unit 400 acquires the current state and schedule information of each user acquired from the position acquisition server 70.

  In addition, the “priority order” item stores the priority order determined by the priority order determination unit 230 referring to the priority order table of the priority order database 270.

  The priority database 270 has a priority table that determines the priority based on the distance from the epicenter to the current position of the user.

  FIG. 4 is a diagram showing an example of a priority table that the priority database 270 has. In the priority table of the priority database 270, the distance from the epicenter and items of priority are described. In FIG. 4, priority is assigned according to the distance from the epicenter. For example, when the distance from the epicenter is within “5 km”, “1” having the highest priority is assigned, and from the epicenter. Is less than “10 km”, “2” having the second highest priority is assigned. In the present embodiment, when the distance between the earthquake occurrence center where the earthquake occurred and the current location of the user registered in advance is relatively close to the earthquake occurrence center, the priority is determined to be relatively high. When the distance between the earthquake occurrence center where the earthquake occurred and the current location of the user registered in advance is relatively far from the earthquake occurrence center, the priority is determined to be relatively low.

  Thereby, the priority order determination part 230 can determine a priority order based on the distance of a user's present position from an epicenter.

  When the safety information of the user having the mobile phone 50 or the personal computer 60 is transmitted from the position acquisition server 70, the safety information receiving unit 250 receives the safety information. The safety information receiving unit 250 sends the received safety information to the safety information database 260, and updates the safety information table included in the safety information database 260.

  The safety information database 260 has a safety information table for confirming safety information based on the user ID registered in the user information database 220 and the priority order.

  FIG. 5 is a diagram illustrating an example of a safety information table included in the safety information database 260. The safety information table of the safety information database 260 describes user ID, priority, and safety confirmation items. In FIG. 5, for example, the employee A with the user ID “0123” is assigned the priority shown in FIG. 4 to “3”, and the disaster information distribution server 20 notifies the employee A of the earthquake early warning. “○” indicating that safety confirmation has been obtained is described. In addition, regarding the description method of the safety confirmation, it will be described as “◯” when the safety confirmation is obtained, and “△” when the confirmation has not been obtained yet.

  Further, in the present embodiment, the earthquake information is repeatedly notified from the disaster information notification unit 240 until a safety information response is received from the user. Therefore, when the disaster information distribution server 20 can confirm the safety of all the users registered in the user information database 220, all the items of “safety confirmation” in the safety information table shown in FIG. It will be.

  Next, the overall operation of the disaster information distribution system 100 according to the present embodiment will be described using the drawings.

  FIG. 6 is a sequence diagram showing the overall operation of the disaster information distribution system 100 according to the present embodiment. In the sequence diagram of the disaster information distribution system 100, the mobile phone 50 periodically transmits location information to the location acquisition server 70 via the radio base station 80 (FIG. 1) (step S10).

  Further, the personal computer 60 generates presence information indicating that the user is working in the office by using the personal computer 60, and transmits the presence information to the position acquisition server 70 (step S20). .

  When the location acquisition server 70 periodically receives location information from the mobile phone 50 or periodically receives presence information from the personal computer 60, the location acquisition server 70 periodically transmits the received location information to the disaster information distribution server 20. (Step S30).

  Thereby, the disaster information distribution server 20 can update the state of the user information table of the user information database 220 in real time.

  Then, when an earthquake occurs, the earthquake early warning server 10 transmits the time when the earthquake occurred, the estimated epicenter and the magnitude of the earthquake to the disaster information distribution server 20 (step S40).

  When the disaster information distribution server 20 receives from the earthquake early warning server 10 the time when the earthquake occurred and the estimated epicenter and magnitude of the earthquake, the arrival time and the seismic intensity of the earthquake due to the occurrence of the earthquake. The process which estimates is performed. The priority determination unit 230 of the disaster information distribution server 20 calculates the distance between the epicenter and each registered user, refers to the priority table of the priority database 270 based on the calculated distance, A process of determining the priority of the user notifying the user of the occurrence is performed (this is referred to as the priority determining process in step S50).

  For example, referring to FIG. 4, when the distance from the epicenter is within 5 km, the highest priority is set to “1”, and when the distance from the epicenter is within 10 km, the second highest priority is “2”. "Is set.

  Then, based on the set priority order, the priority order determination unit 230 reads out the mobile phone number, e-mail address, and the like that are the notification destinations of the mobile phone 50 and the personal computer 60 from the user information table of the user information database 220. The priority order determination unit 230 sends the notification destination such as the read mobile number and mail address to the disaster information notification unit 240.

  When the disaster information notification unit 240 obtains a notification destination such as a mobile number or an email address from the priority order determination unit 230, the disaster information notification unit 240 notifies the user terminal of each user of the earthquake early warning. For example, the disaster information notification unit 240 notifies the radio base station 40 that an earthquake has occurred via the network 30 (step S60), and the radio base station 40 notifies the mobile phone 50 that an earthquake has occurred. (Step S70). The disaster information notification unit 240 notifies the personal computer 60 via the network 30 that an earthquake has occurred using e-mail, IM (Instant Messenger), or the like (step S80).

  In the present embodiment, the method of notifying the mobile phone 50 that an earthquake has occurred may be notified using an electronic mail by the network 30, and voice is sent via the voice network 90 and the gateway exchange 110. You may make it notify by communication.

  Thus, since the disaster information distribution server 20 can notify each user that an earthquake has occurred, a user who uses the mobile phone 50 or a user who uses the personal computer 60 will know that an earthquake has occurred. I can know.

  And the user who uses the mobile phone 50 reports the safety confirmation to the disaster information distribution server 20 by responding to the disaster information distribution server 20 via the radio base station 40 (steps S90 and S100). be able to. The user who uses the personal computer 60 can also report safety confirmation to the disaster information distribution server 20 by responding to the disaster information distribution server 20 with safety information (step S110).

  When receiving the response of the safety information from the mobile phone 50 or the personal computer 60, the safety information receiving unit 250 updates the safety information table of the safety information database 260 (FIG. 5). Thus, in this Embodiment, safety confirmation can be performed.

  In the overall operation of the disaster information distribution system 100 described above, the presence information of the user has been described as a specific example for the personal computer 60. However, the present embodiment is not limited to this, and the earthquake information is based on the schedule information of the user. An embodiment for notifying occurrence may be used or may be used in combination.

  Next, the priority determination process of the disaster information distribution server 20 in the disaster information distribution system 100 according to the present embodiment will be described with reference to the drawings.

  FIG. 7 is a flowchart showing a single operation of the disaster information distribution server 20 in the disaster information distribution system 100.

  In the flowchart shown in FIG. 7, when receiving the earthquake occurrence time and the estimated epicenter and the magnitude of the earthquake from the disaster information acquisition unit 210, the priority determination unit 230 calculates the distance from the epicenter to the registered user. Calculation is performed to estimate the earthquake arrival time and seismic intensity at the location of each user (step S200).

  The priority determination unit 230 refers to the priority database 270 to determine the priority based on the distance from the epicenter to each user, and the distance from the epicenter calculated in step S200 to the user's current position. The priority order of the users to be notified is determined in the order of close (step S210).

  Then, the priority order determination unit 230 sends the determined priority order to the disaster information notification unit 240. When the disaster information notification unit 240 acquires the priority order determined from the priority order determination unit 230, the disaster information notification unit 240 notifies the user terminal that an earthquake has occurred based on the priority order.

  As described above, in the present embodiment, the priority order determination unit 230 calculates the distance from the epicenter to each user and refers to the priority database 270 to determine the priority order of the user to be notified. The disaster information notification unit 240 notifies each user terminal of earthquake information based on the determined priority order.

  For this reason, according to this Embodiment, it can suppress that a load is added to a network by the notification of earthquake information.

  As mentioned above, although embodiment of this invention was described with reference to drawings, these are the illustrations of this invention, Various structures other than the above are also employable.

(Second Embodiment)
For example, in the first embodiment described above, the priority order determination unit 230 refers to the priority order database 270 and determines the priority order of users to be notified based on the distance from the epicenter to each user. However, the present embodiment is not limited to this, and the priority order of the user may be determined based on the risk level of the user.

  FIG. 8 is a block diagram in which the disaster information distribution server 20 of the first embodiment is further provided with a risk database 280 as the second embodiment. The risk database 280 shown in FIG. 8 estimates the degree of danger (risk level) in the user's own body according to the current situation of the user at a predetermined distance or a predetermined location such as 10 km from the epicenter, for example, Based on the estimated risk level, a risk level information table for determining the priority order of the user to notify the user is provided.

  An example of the risk information table included in the risk database 280 shown in FIG. 8 is shown in FIG. The risk level information table shown in FIG. 9 includes items of user status, risk level, and priority. Therefore, the priority order determination unit 230 can acquire the risk level based on the user's situation by referring to the risk level database 280, and can determine the priority level based on the risk level.

  In this case, for example, if the situation of the user uses “transportation”, it is estimated that the “risk” is very high (that is, the state of E), and the highest priority is given. A high “1” can be assigned. On the other hand, if the user's situation corresponds to “Lower floor (in-house)” and the company is working on a lower floor in the company, the “risk” is very low (that is, state A). It is possible to guess and assign “5” having the lowest priority.

  Note that the overall operation of the disaster information distribution system 100 in the second embodiment is the same as the sequence diagram of FIG. 6 shown in the first embodiment, and a description thereof will be omitted.

  Next, as a second embodiment, a flowchart when the disaster information distribution server 20 refers to the risk database 280 is shown in FIG.

  The flowchart shown in FIG. 10 differs from the flowchart shown in FIG. 7 in that the priority order determination process (step S300) based on the risk shown in FIG. 10 is performed based on the risk. That is, in step S300 illustrated in FIG. 10, the priority order determination unit 230 of the disaster information distribution server 20 refers to the risk database 280 and determines the priority order according to the user's situation.

  Thereby, the disaster information distribution server 20 can preferentially notify the earthquake to the user who is actually facing a dangerous situation, not the distance from the epicenter.

  Further, as a third embodiment according to the present invention, a notification method may be selected for the user according to the priority order or the distance from the epicenter.

(Third embodiment)
FIG. 11 is a block diagram in which the disaster information distribution server 20 according to the first embodiment is further provided with a notification method selection unit 290 and a selection method database 300 as the third embodiment. The selection method database 300 shown in FIG. 11 has a selection method table used when notifying the user that an earthquake has occurred.

  An example of the selection method table included in the selection method database 300 shown in FIG. 11 is shown in FIG. The selection method table shown in FIG. 12 includes items for selecting the distance from the epicenter, the priority order, and the notification method. Therefore, the notification method selection unit 290 can select the notification method corresponding to the priority order based on the distance from the epicenter by referring to the selection method database 300.

  In this case, for example, when the “distance from the epicenter” is within 5 km, “1” having the highest priority is assigned and “phone call by mobile phone” capable of emergency contact can be selected. . On the other hand, when the “distance from the epicenter” is within 20 km, the fourth highest priority “4” is assigned, and the personal computer 60 used by the user is sent an e-mail or IM (with the aforementioned instant messenger). Can be notified by. In other words, when the priority is determined to be relatively high, an earthquake is notified by a mobile phone call held by the user, and when the priority is determined to be relatively low, An earthquake can be selected to be sent by e-mail or IM that can be sent.

  Note that the overall operation of the disaster information distribution system 100 in the third embodiment is the same as the sequence diagram of FIG. 6 shown in the first embodiment, and a description thereof will be omitted.

  Next, as a third embodiment, a flowchart when the notification method selection unit 290 refers to the selection method database 300 is shown in FIG.

  The flowchart shown in FIG. 13 differs from the flowchart shown in FIG. 7 in that the notification method selection process (step S400) based on the priority order shown in FIG. 13 selects a notification method. That is, in step S400 shown in FIG. 13, the notification method selection unit 290 of the disaster information distribution server 20 refers to the selection method database 300 and selects a notification method based on the priority order.

  Thereby, the disaster information distribution server 20 can select the notification method of notifying the user of the earthquake based on the priority order based on the distance from the epicenter. In this case, for example, a user with a higher priority can select a notification method with a higher degree of urgency, so that an earthquake can be accurately notified.

  In addition, as the third embodiment, the notification method selection unit 290 (FIG. 11) has been described with reference to the priority order of the selection method table in the selection method database 300, but the third embodiment is not limited to this. The call method may be selected based on the distance from the epicenter calculated by the priority determination unit 230.

(Fourth embodiment)
FIG. 14 is a block diagram in which the disaster information distribution server 20 according to the first embodiment is further provided with a notification method selection unit 290 and a distance selection database 310 as the fourth embodiment. The distance selection database 310 shown in FIG. 14 has a distance selection table used when notifying the user that an earthquake has occurred.

  An example of the distance selection table included in the distance selection database 310 shown in FIG. 14 is shown in FIG. The distance selection table shown in FIG. 15 includes items for selecting the distance from the epicenter and the notification method. Therefore, the notification method selection unit 290 acquires the distance from the epicenter calculated by the priority determination unit 230, and refers to the distance selection database 310 based on the acquired distance, thereby corresponding to the distance from the epicenter. The notification method to be selected can be selected.

  In this case, for example, when the “distance from the epicenter” is within 10 km, the user can be notified of the earthquake by “mail by mobile phone”. On the other hand, when the “distance from the epicenter” is within 20 km, “E-mail / IM” is selected, and the mobile phone 50 or the personal computer 60 as the user terminal is notified of the earthquake by e-mail or IM. Can do.

  Note that the overall operation of the disaster information distribution system 100 in the fourth embodiment is the same as the sequence diagram of FIG. 6 shown in the first embodiment, and a description thereof will be omitted.

  Next, as a fourth embodiment, a flowchart when the notification method selection unit 290 refers to the distance selection database 310 is shown in FIG.

  The flowchart shown in FIG. 16 is different from the flowchart shown in FIG. 7 in that the calling method selection processing based on distance (step S500) in FIG. 16 selects a notification method depending on the distance. That is, in step S500 shown in FIG. 16, the notification method selection unit 290 of the disaster information distribution server 20 acquires the distance from the epicenter calculated from the priority order determination unit 230, and the distance selection database 310 based on the distance. To select the notification method to the user.

  Thereby, the disaster information distribution server 20 can select a notification method for notifying the user of an earthquake based on the distance from the epicenter. In this case, as described above, the user who has a shorter distance from the epicenter can select a call method with a higher degree of urgency, and thus can accurately notify the earthquake.

  In the first to fourth embodiments, the location information of the mobile phone 50 and the presence information or schedule information of the personal computer 60 are periodically transmitted from the location acquisition server 70 to the disaster information distribution server 20. However, the present embodiment is not limited to this. For example, the disaster information distribution server 20 may transmit a status request command for requesting the status of each user to the location acquisition server 70. good.

  In the present embodiment, the mobile phone 50 acquires the current position by the GPS function. However, the present embodiment is not limited to this, and acquires position information from a wireless local area network (LAN). Form may be sufficient.

  Moreover, although the disaster information distribution system 100 of this Embodiment demonstrated in the example of the earthquake, this Embodiment is not restricted to this, For example, it applies also at the time of disaster occurrence, such as a typhoon, a tsunami, and a train accident. Can do.

It is the schematic block diagram which showed the schematic structure of the disaster information delivery system which concerns on this Embodiment. It is the block diagram which showed the structure of the disaster information delivery server which concerns on this Embodiment. It is the figure which showed an example of the user information table which the user information database which concerns on this Embodiment has. It is the figure which showed an example of the priority table which the priority database which concerns on this Embodiment has. It is the figure which showed an example of the safety information table which the safety information database which concerns on this Embodiment has. It is the sequence diagram which showed the whole operation | movement of the disaster information delivery system which concerns on this Embodiment. It is the flowchart which showed the independent operation | movement of the disaster information delivery server in the disaster information delivery system which concerns on this Embodiment. As a second embodiment, the disaster information distribution server of the first embodiment is a block diagram further provided with a risk database. It is the figure which showed an example of the risk information table which a risk database has as 2nd Embodiment. It is a flowchart when a disaster information delivery server processes with reference to a risk database as 2nd Embodiment. As a third embodiment, the disaster information distribution server of the first embodiment is a block diagram further including a selection method database. It is a figure showing an example of a selection method table which a selection method database has as a 3rd embodiment. It is a flowchart when a disaster information delivery server processes with reference to a selection method database as 3rd Embodiment. As a fourth embodiment, the disaster information distribution server of the first embodiment is a block diagram further provided with a distance selection database. It is the figure which showed an example of the distance selection table which a distance selection database has as 4th Embodiment. It is a flowchart when a disaster information delivery server refers to a distance selection database and processes as 4th Embodiment.

Explanation of symbols

10 Earthquake Early Warning Server 20 Disaster Information Distribution Server 30 Network Network 40 Wireless Base Station 50 Mobile Phone 60 Personal Computer 70 Location Acquisition Server 80 Wireless Base Station 90 Voice Network 100 Disaster Information Distribution System 110 Gateway Switch 210 Disaster Information Acquisition Unit 220 User Information Database 230 Priority determining unit 240 Disaster information notifying unit 250 Safety information receiving unit 260 Safety information database 270 Priority database 280 Risk database 290 Notification method selection unit 300 Selection method database 310 Distance selection database 400 Location information acquisition unit

Claims (12)

Disaster information acquisition means for acquiring disaster information indicating that a disaster has occurred and the center of the disaster occurrence;
Based on the disaster occurrence center where the disaster occurred and the current positions of a plurality of users registered in advance, the priority order of the users who notify the occurrence of the disaster among the plurality of users is determined. Prioritization means for
Disaster information notifying means for transmitting information indicating that the disaster has occurred to a user terminal of the user based on the priority determined by the priority determining means;
A disaster information distribution server comprising: The priority determining means includes
The disaster information distribution server according to claim 1, wherein the priority order is determined based on a distance between the disaster occurrence center and the current positions of the plurality of users. The priority determining means includes
A risk indicating the degree of danger to the user himself / herself when a plurality of users are set in the same area based on the distance from the disaster occurrence center or the magnitude of the disaster. The disaster information distribution server according to claim 1 or 2, wherein the priority is determined according to a degree. As a notification method for notifying the user terminal, a mobile phone notification method for notifying the user of the occurrence of the disaster by a mobile phone call, and an e-mail notification method for notifying the user of the occurrence of the disaster by e-mail And at least
The notification method selection means for selecting the notification method to be notified to the user based on the priority determined by the priority determination means. Disaster information distribution server. Terminal position information acquisition means for acquiring position information of the user terminal from the user terminal,
The priority determining means includes
The disaster information distribution server according to claim 2, wherein the position indicated by the position information is used as the current position of the user. The priority determining means includes
The disaster information distribution server according to claim 4, wherein the priority order is determined based on presence information indicating whether the user is located inside or outside the company. The notification method selection means includes:
If the priority is determined to be relatively high, the disaster is notified by a mobile phone call that the user has,
5. The disaster information distribution according to claim 4, wherein when the priority is determined to be relatively low, the disaster is notified by e-mail that can be transmitted to the user. server. If the distance between the disaster occurrence center and the current location of the user registered in advance is relatively close to the disaster occurrence center, the priority is determined to be relatively high,
The priority is determined to be relatively low when the distance between the disaster occurrence center and the current location of the user registered in advance is relatively far from the disaster occurrence center. The disaster information distribution server according to any one of 1 to 7.   The disaster information distribution server according to any one of claims 1 to 8, further comprising a safety response receiving unit that receives a safety response to the occurrence of a disaster notified by the disaster information notification unit. A disaster information distribution method performed by a disaster information distribution server for notifying that a disaster has occurred,
The disaster information distribution server
A disaster information acquisition step for acquiring disaster information indicating that a disaster has occurred and the center of the disaster;
Based on the disaster occurrence center where the disaster occurred and the current positions of a plurality of users registered in advance, the priority order of the users who notify the occurrence of the disaster among the plurality of users is determined. Prioritization step to
A disaster information notifying step of transmitting information indicating that the disaster has occurred to a user terminal of the user based on the priority determined in the priority determining step;
A disaster information delivery method comprising: A disaster information distribution program executed by a disaster information distribution server for notifying that a disaster has occurred,
A disaster information acquisition procedure for acquiring disaster information indicating that a disaster has occurred and the center of the disaster;
Based on the disaster occurrence center where the disaster occurred and the current positions of a plurality of users registered in advance, the priority order of the users who notify the occurrence of the disaster among the plurality of users is determined. Prioritization procedure to
A disaster information notification procedure for transmitting information indicating that the disaster has occurred to a user terminal of the user based on the priority determined by the priority determination procedure;
A disaster information distribution program characterized by causing a computer to execute. A disaster information distribution system comprising a disaster information distribution server and a user terminal connected to the disaster distribution server,
The disaster information distribution server
Disaster information acquisition means for acquiring disaster information indicating that a disaster has occurred and the center of the disaster occurrence;
Based on the disaster occurrence center where the disaster occurred and the current positions of a plurality of users registered in advance, the priority order of the users who notify the occurrence of the disaster among the plurality of users is determined. Prioritization means for
Disaster information notifying means for transmitting information indicating that the disaster has occurred to the user terminal based on the priority order determined by the priority order determining means,
The user terminal is
A disaster information distribution system comprising disaster information receiving means for receiving the information in which the disaster has occurred.

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