JP2013247418A - Safety information processing system, safety information processing device, safety information processing program, and mobile communication terminal - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the accuracy of creating safety information by eliminating human factors such as disaster victims.SOLUTION: Mobile communication terminals (6-1, 6-2, ---, 6-N) automatically collect terminal information (10) triggered by transmission instructions, and transmit the terminal information (10). Safety information processing means (safety information processing server 4) collects the terminal information (10) from the mobile communication terminals (6-1, 6-2, ---, 6-N) by distributing the transmission instructions, and automatically creates safety information (safety information table 12) with the use of the terminal information.

Description

The present invention relates to a safety information processing system, a safety information processing apparatus, a safety information processing program, and a mobile communication terminal using, for example, broadcast SMS (Short Message Service) of mobile communication such as a mobile communication terminal.

  There is a method of confirming safety at the time of a disaster, in which a disaster victim notifies the safety information by telephone, e-mail or the like to a system managing safety information such as a disaster message board. In addition, there is a method of prompting the victim to confirm safety from the safety confirmation system. As a method for prompting confirmation of safety, there are a method of sending a broadcast mail to a mobile communication terminal such as a mobile phone to be confirmed, a method using a broadcast short message service (SMS), and the like. Broadcast SMS performs broadcast transmission (emergency notification) to mobile communication terminals in a specific area.

  Regarding the collection of safety information by broadcast SMS, it is known to prompt the owner of the mobile communication terminal to operate the button upon reception of an emergency call, and to send an emergency mail to a pre-registered mobile communication terminal (for example, Patent Document 1).

Regarding the setting of urgency and priority using collected information, priority should be given to calls between the caller and the callee by referring to information such as seismic intensity information and housing information on the caller and callees Known (for example, Patent Document 2). Also, an urgency level function is determined, and the calculation result of the urgency level function using information such as vehicle speed and road conditions (for example, accidents and falling object information) is used as an urgency level, and this urgency level is notified to each vehicle. It is known (for example, Patent Document 3).

JP 2009-089091 A JP 2007-124052 A Japanese Patent Laid-Open No. 2004-054369

  By the way, it is difficult for the victim to be notified of the safety information such as the disaster situation, which is difficult. There is a problem that safety information cannot be collected if it is difficult to notify safety information, such as injury due to a disaster, inexperienced operation of a mobile communication terminal, and inability to communicate due to traffic congestion.

  Even if an emergency mail is transmitted to a mobile communication terminal registered in advance, if there is no notification of safety information from the mobile communication terminal, the safety confirmation system transmits an emergency mail. This emergency mail transmission is performed even when there is no disaster or forgetting the notification. For this reason, there is a problem that the safety confirmation system cannot collect accurate safety information.

  In any case, there is a problem that human factors such as victims affect the accuracy of the safety information and the function of the safety confirmation system cannot be performed.

Therefore, in view of the above problems, an object of the present invention is to eliminate human factors such as disaster victims and increase the accuracy of generating safety information.

In order to achieve the above object, in the configuration of the present disclosure, the mobile communication terminal automatically collects terminal information and transmits the terminal information in response to a transmission instruction. The safety information processing means distributes a transmission instruction, collects terminal information from the mobile communication terminal, and automatically generates safety information using the terminal information.

  According to the configuration of the present disclosure, any of the following effects can be obtained.

  (1) Since the terminal information is automatically transmitted to the mobile communication terminal, the terminal information can be collected by removing human factors such as a victim, and the accuracy of the safety information generated from the terminal information can be improved.

  (2) With the collected terminal information, the safety can be confirmed accurately, and the damage situation can be accurately grasped.

  (3) In the safety confirmation at the time of disaster, the urgency can be grasped by the terminal information collected from the mobile communication terminal.

Other objects, features, and advantages of the present invention will become clearer with reference to the accompanying drawings and each embodiment.

It is a figure which shows the safety information processing system which concerns on 1st Embodiment. It is a flowchart which shows the procedure of safety information processing. It is a figure which shows an example of the process sequence of the safety information processing system which concerns on 2nd Embodiment. It is a figure which shows an example of a safety information processing system. It is a figure which shows an example of the safety information processing function of a server. It is a figure which shows an example of the hardware of a server. It is a figure which shows an example of the safety information processing function of a mobile communication terminal. It is a figure which shows an example of the hardware of a mobile communication terminal. It is a flowchart which shows the process sequence of the safety information processing by the server side. It is a figure which shows an example of broadcast SMS. It is a flowchart which shows the process sequence of the terminal information by the side of a mobile communication terminal. It is a flowchart which shows the subroutine of the process sequence of FIG. It is a flowchart which shows the subroutine of the process sequence of FIG. It is a figure which shows an example of a terminal information table. It is a figure which shows the text message of SMS. It is a flowchart which shows the process sequence which produces | generates safety information. It is a figure which shows an example of the safety information table of an information update system. It is a figure which shows transition of safety information. It is a figure which shows an example of a record value-rescue emergency degree table. It is a figure which shows an example of a rescue emergency degree-accommodation area disaster situation relation table. It is a flowchart which shows the process sequence which produces | generates the safety information which concerns on 3rd Embodiment. It is a figure which shows an example of the safety information table of an information storage system.

[First Embodiment]

  FIG. 1 shows a safety information processing system according to the first embodiment. This safety information processing system 2 is an example of the safety information processing system of the present disclosure. As an example, the safety information processing system 2 includes a safety information processing server (hereinafter simply referred to as “server”) 4, a plurality of mobile communication terminals 6, and a base station 8.

  The server 4 is an example of a safety information processing unit or a safety information processing device, and is configured by a computer that controls the safety information processing system 2 of the present disclosure. The server 4 distributes a transmission instruction of the terminal information 10 to the mobile communication terminal 6, collects the terminal information 10 from the mobile communication terminal 6, and generates safety information. The terminal information 10 includes one or more of identification information, operation history information, transmission history information, area information, and position information of the mobile communication terminal 6. Safety information is generated from the collected terminal information 10. The identification information is, for example, a telephone number. The operation history information is an operation history such as operation buttons on the mobile communication terminal 6. The outgoing call history information is a record of telephone calls, packet transmissions such as mails, and execution records of browsers. The area information is an accommodation area of the base station 8 or the like. The position information is information that represents the movement or presence position of the mobile communication terminal 6. For the transmission instruction from the server 4, a mobile communication medium such as broadcast SMS (Short Message Service) is used.

  The mobile communication terminal 6 is a mobile device having a communication function for transmitting and receiving information to and from the server 4 and is configured by a mobile phone, for example. The mobile communication terminal 6 only needs to have a communication function, and may be a tablet terminal or a smartphone, or may be an electronic device such as a camera or a game machine having a communication function. The mobile communication terminal 6 automatically collects the terminal information 10 owned by the terminal itself in response to a transmission instruction for the terminal information 10 distributed from the server 4 and automatically transmits the terminal information 10 to the server 4 as a response to the transmission instruction. . For example, SMS is used to transmit the terminal information 10 from the mobile communication terminal 6.

  The base station 8 is a relay unit between the server 4 and the mobile communication terminal 6 and provides a mobile communication service. The base station 8 has an accommodation area as a service area where mobile communication service is possible. For this accommodation area, the base station 8 provides the mobile communication terminal 6 with area information.

<Safety information processing procedure>

  2A and 2B show the processing procedure of the safety information processing system 2. FIG. The processing procedure shown in FIG. 2A is executed by the server 4.

  The server 4 distributes a transmission instruction of the terminal information 10 to the mobile communication terminal 6 in the accommodation area (S11). This transmission instruction is performed by broadcast SMS, for example.

  Each mobile communication terminal 6 automatically collects terminal information 10 upon receipt of the transmission instruction described above, and performs automatic transmission. Thereby, the server 4 receives the terminal information 10, and collects each terminal information (S12).

  Then, the server 4 automatically generates safety information from the collected terminal information 10 (S13).

  The processing procedure shown in FIG. 2B is executed by the mobile communication terminal 6.

  The mobile communication terminal 6 receives the transmission instruction of the terminal information 10 distributed from the server 4 (S21). Each mobile communication terminal 6 automatically collects the above-described terminal information 10 upon receiving the transmission instruction (S22). Thereby, the mobile communication terminal 6 automatically transmits the collected terminal information 10 to the server 4 (S23).

  As described above, the mobile communication terminal 6 automatically collects the terminal information 10 in response to the transmission instruction from the server 4 and automatically transmits it to the server 4. For this reason, the terminal information 10 is collected by the server 4 regardless of the situation of the victim in the disaster area.

  Since the terminal information 10 is any one or more of identification information, operation history information, transmission history information, area information, and position information of the mobile communication terminal 6, safety information can be automatically generated based on these information. . That is, since the collection and transmission of the terminal information 10 are automatically performed, human influence can be eliminated. Therefore, the generation accuracy of the safety information is enhanced based on the automatic collection and automatic transmission of the terminal information 10 without being affected by human beings such as the disaster victims.

[Second Embodiment]

  FIG. 3 shows a processing sequence of the safety information processing system according to the second embodiment. The configuration illustrated in FIG. 3 is an example, and the configuration of the present disclosure is not limited to such a configuration. The same parts as those in FIG. 1 are denoted by the same reference numerals.

  In the processing sequence illustrated in FIG. 3, the server 4, the plurality of mobile communication terminals 6-1, 6-2 to 6 -N, and the base station 8-1 are illustrated. The base station 8-1 is one of a plurality of base stations 8-1, 8-2, ... 8-N. This base station 8-1 is a relay means for wirelessly connecting the server 4 and each mobile communication terminal 6-1, 6-2,..., 6-N. Therefore, the mobile communication terminals 6-1, 6-2... 6 -N are included in the accommodation area 80-1 (FIG. 4) of the base station 8-1.

  In the safety information processing system 2, the server 4 requests the base station 8-1 to collect the terminal information 10 from the accommodation area 80-1 of the base station 8-1 (S101). The terminal information 10 is an example of information for confirming safety. The broadcast SMS is distributed from the base station 8-1 that has received the message to the mobile communication terminals 6-1, 6-2,..., 6-N (S102). Each of the mobile communication terminals 6-1, 6-2,... 6 -N automatically collects the terminal information 10 when receiving the broadcast SMS (S 103, S 104, S 105, S 106). Each of the mobile communication terminals 6-1, 6-2,... 6-N transmits the collected information to the server 4 (S107, S108, S109, S110). Transmission of each mobile communication terminal 6-1, 6-2... 6 -N is automatically executed without any user operation.

  The server 4 automatically generates the safety information of the user (that is, the owner of the mobile communication terminal) based on the terminal information 10 received from each mobile communication terminal 6-1, 6-2. Each time the information is received from the terminals 6-1, 6-2... 6-N, the safety information is updated (S111, S112, S113, S114).

  The advantages and effects of the safety information processing system 2 are listed below.

  (1) Each mobile communication terminal 6-1, 6-6, 6-N without any user operation of the mobile communication terminal 6-1, 6-2. -2 ... The terminal information 10 automatically transmitted from 6-N can be automatically collected. Thereby, safety information can be generated and the generation accuracy thereof is increased.

  (2) It is limited to communication between the mobile communication terminals 6-1, 6-2... 6 -N and the server 4 that executes the safety information processing system 2. For this reason, priority control of broadcast SMS can be utilized. That is, the communication between the mobile communication terminals 6-1, 6-2... 6 -N and the server 4 can be performed with priority traffic. Thereby, even if traffic congestion occurs at the time of a disaster, the terminal information 10 can be automatically collected from each mobile communication terminal 6-1, 6-2... 6 -N. That is, accurate and reliable terminal information can be generated from the mobile communication terminals 6-1, 6-2 to 6 -N, and safety information can be generated from the terminal information.

<Safety information processing system 2>

  FIG. 4 shows a configuration example of the safety information processing system 2. In FIG. 4, the same parts as those in FIG.

  The safety information processing system 2 includes a server 4, a plurality of mobile communication terminals 6-1, 6-2... 6 -N, and base stations 8-1, 8-2. Each of the base stations 8-1, 8-2,..., 8-N has accommodation areas (that is, service areas) 80-1, 80-2,. A plurality of mobile communication terminals 6-1, 6-2,..., 6-N are included for each of the accommodation areas 80-1, 80-2,. That is, the safety information processing system 2 includes a server 4 having a safety information generation processing function and a plurality of mobile communication terminals 6-1 and 6-2 existing in the base stations 8-1, 8-2,. ... 6-N.

  A safety information table 12 that is an example of a safety information database is set in the memory 38 (FIG. 6) of the server 4. In this safety information table 12, terminal information 10 acquired from each of the mobile communication terminals 6-1, 6-2,..., 6-N, safety information generated from the terminal information 10, and emergency information are registered. .

  A terminal information table 13, which is an example of a database of terminal information 10, is set in the memories of the mobile communication terminals 6-1, 6-2 to 6 -N. Each terminal information table 13 stores terminal information 10. The terminal information 10 includes telephone numbers, operation histories, communication histories, position information, and the like of the mobile communication terminals 6-1, 6-2,.

<Functional Configuration and Hardware of Server 4>

  FIG. 5 shows an example of the functional configuration of the server 4. The server 4 includes an external IF (Interface) function 14, a control function 16, and a safety information generation processing function 18. The external IF function 14 is connected to either the base station 8 or the mobile communication terminals 6-1, 6-2,... 6-N, and transmits and receives information. The control function 16 is interposed between the external IF function 14 and the safety information generation processing function 18 and controls the generation and collection of safety information. The safety information generation processing function 18 performs registration of mobile communication terminal information, safety information, etc., generation of urgency information using the safety information, and registration thereof.

  The external IF function 14 includes an operator input reception IF function 20, a terminal information SMS reception IF function 22, and a broadcast SMS distribution function 24. The operator input reception IF function 20 performs an operator input and other information input. The terminal information SMS reception IF function 22 receives SMS. The broadcast SMS distribution function 24 distributes the broadcast SMS described above.

  The control function 16 includes a safety information generation process control function 26. The safety information generation process control function 26 controls the generation and collection of safety information.

  The safety information generation processing function 18 includes a terminal information setting / updating function 28, a rescue emergency level setting / updating function 30, and the safety information table 12 described above. The terminal information setting / updating function 28 sets and updates terminal information. The rescue emergency level setting / updating function 30 sets and updates emergency level information calculated from the safety information as well as registration of safety information. The function of the safety information table 12 is as described above.

  FIG. 6 shows an example of the hardware of the server 4. The server 4 is a computer that performs the functions described above, and includes an input / output unit 32, an SMS transmission / reception unit 34, a processor 36, and a memory 38.

  The input / output unit 32 is used for input / output of information. The SMS transmission / reception unit 34 is an example of a communication unit, and distributes or receives broadcast SMS under the control of the processor 36.

  The processor 36 is an example of a processing unit, and is composed of, for example, a CPU (Central Processing Unit). The processor 36 executes the safety information generation processing program stored in the memory 38, and executes the above-described external IF function 14, control function 16, and safety information generation processing function 18. By executing each function, collection of safety information, registration of the information in the safety information table 12, determination of urgency, registration of urgency information, and the like are performed.

  The memory 38 is a data storage medium. The memory 38 includes a ROM (Read-Only Memory) and a RAM (Random-Access Memory). Various software programs such as an OS (Operating System) and the above-described safety information generation processing program are stored in the ROM. The RAM constitutes a work area.

  In the safety information processing system 2, the server 4 executes a safety information generation process with the above configuration. The safety information generation process of the server 4 is as follows.

  (a) The server 4 receives various parameters for collecting safety information by the operator input reception IF function 20. Various parameters are input through an input / output screen. This input operation may be performed by an operator, for example.

  (b) The server 4 distributes the broadcast SMS to any one or more of the accommodation areas 80-1, 80-2,... 80-N where safety information is to be generated. This broadcast SMS is distributed from the SMS transmission / reception unit 34 according to the input from the operator by the broadcast SMS distribution function.

  (c) The server 4 receives the terminal information 10 from each mobile communication terminal 6-1, 6-2,... 6 -N that has received the broadcast SMS. The terminal information 10 transmitted by the mobile communication terminals 6-1, 6-2 to 6 -N is received by the SMS transmission / reception unit 34.

  (d) The server 4 registers the received terminal information 10 in the safety information table 12 on the memory 38 by the terminal information setting / updating function 28.

  (e) The server 4 determines the rescue urgency of the terminal owner by the rescue urgency level setting / update function 30 using the terminal information 10 in the safety information table 12. The rescue urgency level that is the determination result is registered in the safety information table 12.

<Functional Configuration and Hardware of Mobile Communication Terminals 6-1, 6-2... 6-N>

  FIG. 7 shows an example of the functional configuration of the mobile communication terminals 6-1, 6-2 to 6 -N. Each of the mobile communication terminals 6-1, 6-2 to 6 -N includes an external IF function 40, a control function 42, and a terminal information collection function 44. The external IF function 40 is connected to the server 4 and transmits / receives information. The control function 42 is interposed between the external IF function 40 and the terminal information collection function 44, and collects and controls terminal information. The terminal information collection function 44 collects information such as an information log function and position information.

  The external IF function 40 includes a broadcast SMS reception IF function 46 and a terminal information SMS transmission function 48. The broadcast SMS reception IF function 46 receives the broadcast SMS distributed from the server 4. The terminal information SMS transmission function 48 corresponds to the distributed broadcast SMS and transmits the terminal information 10 to the server 4 by SMS.

  The control function 42 includes a terminal information collection process control function 50. The terminal information collection processing control function 50 controls collection of the terminal information 10 in response to broadcast SMS from the server 4.

  The terminal information collection function 44 includes an operation log collection function 52, a latitude / longitude information collection function 54, a telephone / packet transmission information collection function 56, and an accommodation area information collection function 58.

  The operation log collection function 52 collects operation log information. The operation history when the user operates the mobile communication terminals 6-1, 6-2,... 6-N is recorded as log information in the mobile communication terminals 6-1, 6-2,. This log information is collected upon reception of broadcast SMS.

  The latitude / longitude information collecting function 54 collects latitude and longitude as position information of the mobile communication terminals 6-1, 6-2,.

  The telephone / packet transmission information collecting function 56 collects telephone / packet transmission information. The transmission history information of the telephone / packet transmitted and received by the user through the mobile communication terminals 6-1, 6-2,..., 6-N is recorded in the mobile communication terminals 6-1, 6-2,. . This information is collected upon reception of broadcast SMS.

  The accommodation area information collection function 58 collects base station information such as the accommodation areas 80-1, 80-2,... 80-N with which the mobile communication terminals 6-1, 6-2,. I do.

  FIG. 8 shows an example of the hardware configuration of the mobile communication terminals 6-1, 6-2 to 6 -N. The mobile communication terminals 6-1, 6-2,... 6 -N are computers that execute the functions described above corresponding to the server 4, and are the packet transmission / reception unit 60, SMS transmission / reception unit 62, processor 64, memory 66, operation An input / output unit 68 and a GPS (Global Positioning System) communication unit 70 are provided.

  The packet transmitting / receiving unit 60 is an example of a communication unit, and transmits / receives packet information under the control of the processor 64. The SMS transmission / reception unit 62 is an example of a communication unit, and performs SMS transmission / reception under the control of the processor 64.

  The processor 64 is composed of, for example, a CPU (Central Processing Unit). The processor 64 executes a terminal-side program of the safety information generation processing program in the memory 66, and collects, registers, and transmits information related to safety information.

  The memory 66 is a data storage medium. The memory 66 includes a ROM (Read-Only Memory) and a RAM (Random-Access Memory). The ROM stores various software programs such as an OS (Operating System) and a terminal-side program of the above-described safety information generation processing program. The RAM constitutes a work area.

  The operation input / output unit 68 is used for information input / output. The GPS communication unit 70 acquires the position information of its own terminal from the GPS under the control of the processor 64.

  The functions of the mobile communication terminals 6-1, 6-2... 6-N are as follows.

  (a) In the mobile communication terminals 6-1, 6-2... 6 -N, the mobile communication terminal information is collected by the control function 42.

  (b) Upon receiving a request for collecting terminal information from the server 4, the broadcast SMS is received using the broadcast SMS reception IF function 46.

  (c) Collect various information triggered by the reception of broadcast SMS.

    (c-1) Collect the operation button press logs. The pressing of the operation button is the action information of the users of the mobile communication terminals 6-1, 6-2 to 6 -N, and is closely related to the safety of the users. This operation button pressing information is performed by the operation log collection function 52 described above.

    (c-2) Collecting telephone / packet transmission history from the memory 66. This outgoing call history is action information of the users of the mobile communication terminals 6-1, 6-2... 6 -N, and is closely related to the safety of the users. This outgoing call history is executed by the telephone / packet outgoing information collection function 56.

    (c-3) Using the latitude / longitude information collection function 54, the location information of each mobile communication terminal 6-1, 6-2, ... 6-N is collected. The collection of the position information is executed by the GPS communication unit 70.

    (c-4) Using the accommodation area information collection function 58, the base station information currently being communicated is collected. The collection of the base station information is performed using the packet transmission / reception unit 60.

  (d) The collected various terminal information is transmitted to the server 4 as SMS using the terminal information SMS transmission function 48.

<Safety information generation process>

  FIG. 9 shows an example of the processing procedure of the safety information generation processing. In this safety information generation process, broadcast SMS distribution and generation of safety information triggered by this distribution are executed. This processing procedure is started by operator input on the server 4 side. S201, S205, and S206 are processes on the server 4 side, and S202, S203, and S204 are processes on the mobile communication terminals 6-1, 6-2,.

  Based on the operator input, broadcast SMS distribution is executed from the server 4 (S201). That is, according to an operator instruction, one or two or more of the accommodation areas 80-1, 80-2,... 80-N where safety information is to be collected is selected, and broadcast SMS is distributed.

  The mobile communication terminals 6-1, 6-2,... 6 -N that have received this broadcast SMS distribution execute broadcast SMS reception processing (S 202). Upon receiving this broadcast SMS, the mobile communication terminals 6-1, 6-2,... 6-N collect the terminal information 10 (S203), and transmit the collected information to the server 4 (S204).

  The server 4 receives the terminal information 10 from the mobile communication terminals 6-1, 6-2,... 6-N as the safety information generation process (S205). The server 4 sets the rescue urgency level based on the received terminal information, generates and updates safety information for each terminal unit (S206).

  Transmission of the terminal information 10 from each mobile communication terminal 6-1, 6-2,... 6 -N is repeated at the number of times designated by the operator. Each time the server 4 receives the terminal information 10 from each mobile communication terminal 6-1, 6-2... 6 -N, the safety information of each mobile communication terminal 6-1, 6-2. Is updated (S203 to S206).

<Broadcast SMS delivery processing>

  In response to the operator instruction, the server 4 transmits a terminal information collection request to the mobile communication terminals 6-1, 6-2 to 6 -N by broadcast SMS. The contents of the operator instruction are any one or more of the accommodating areas 80-1, 80-2,..., 80-N where the terminal information is collected, the number of times the terminal information is collected, and the collection time interval.

  The server 4 generates an SMS based on the content of the operator instruction and the service type indicating the terminal information collection request, and distributes the broadcast SMS to the area where the terminal information is collected. The service type is a service identifier representing a terminal information collection request.

  The mobile communication terminals 6-1, 6-2,... 6 -N that have received the broadcast SMS determine whether or not the service type is a terminal information collection request. If it is a terminal information collection request, the mobile communication terminals 6-1, 6-2 to 6 -N collect terminal information.

  10A and 10B show broadcast SMS. This broadcast SMS 72 is an SMS generated by the server 4 and distributed to the mobile communication terminals 6-1, 6-2 to 6 -N.

  As shown in FIG. 10A, the broadcast SMS 72 includes a service type 74, a distribution destination area code 76, a terminal information collection count 78, and a terminal information collection interval 80. This broadcast SMS 72 is represented by a symbol string shown in FIG. 10B, and is, for example, a 14-digit number string.

  A service type 74 represents a service type representing a terminal information collection request. This service type 74 is composed of the first four digits of the numeric string, for example “1000”.

  The delivery destination area code 76 is an area code representing an area for collecting terminal information. The distribution destination area code 76 is a 5-digit numeric string following the service type 74, for example, “99999”.

  The terminal information collection count 78 is the number of times terminal information is collected (times). The terminal information collection count 78 is a two-digit numeric string following the distribution destination area code 76, for example, “06”.

  The terminal information collection interval 80 is an interval for collecting terminal information. The terminal information collection interval 80 is, for example, “010” in the last three digits of the numeric string.

  A broadcast SMS 72 composed of a numeric string shown in B of FIG. 10 represents that a terminal information collection request is made 6 times at 10-minute intervals for the accommodation area of the area code 99999.

<Processing of Mobile Communication Terminals 6-1, 6-2... 6-N>

  FIG. 11 shows a processing procedure by the mobile communication terminal 6.

  This processing procedure is a process that is automatically executed when the mobile communication terminals 6-1, 6-2,... 6 -N in the standby state receive the broadcast SMS distributed from the server 4. It is. Automatic execution means that terminal information is collected and transmitted without any user operation.

  In this processing procedure, the mobile communication terminals 6-1, 6-2... 6 -N receive the broadcast SMS distributed from the server 4 (S 211). When this broadcast SMS includes a terminal information collection request, the mobile communication terminals 6-1, 6-2,... 6 -N respond to the service type in the broadcast SMS in response to this terminal information collection request. Terminal information collection starts. That is, collection of operation logs of the mobile communication terminals 6-1, 6-2,..., 6-N is started (S212). Based on this start, collection of call / packet transmission information (information b) (S213), collection of accommodation area information (information d) (S214), collection of longitude and latitude information (information e) (S215), operation Log collection (information c) collection (S216) is sequentially executed.

  Based on these pieces of information, an SM is generated based on the terminal information table 13 (S217). This terminal information is transmitted by SMS (S218). After this transmission, it is determined whether the number of collections has expired (S219). If the number of collections has not expired (NO in S219), the collection interval of the operator instruction is waited (S220), and the processes of S213 to S219 are repeated. If the number of collections has expired (YES in S219), the process ends.

  FIG. 12A shows the subroutine of S213. In the collection of telephone or packet transmission information (S213), the telephone or packet transmission history from the previous collection time to the present is searched (S2131), the presence / absence of the transmission history is stored in the terminal information table 13 (S2132), and S213. Return to

  B of FIG. 12 shows the subroutine of S214. In the collection of the accommodation area information (S214), the base station information is acquired from the currently captured base station (S2141), and the ID that uniquely defines the base stations 8-1, 8-2,. The information is stored in the information table 13 (S2142), and the process returns to S214.

  FIG. 13A shows the subroutine of S215. In the latitude and longitude information collection (S215), the latitude and longitude information is acquired by the GPS function as an example of the latitude and longitude information collection function 54 (S2151), and the latitude and longitude information is stored in the terminal information table 13 ( S2152) and returns to S215.

  FIG. 13B shows the subroutine of S216. In the operation log collection (S216), an operation log from the previous time to the present is searched (S2161), the presence / absence of the operation is stored in the terminal information information table 13 (S2162), and the process returns to S216.

  Information automatically collected by the mobile communication terminals 6-1, 6-2... 6 -N by these processing procedures is as follows.

  a) Telephone number: The telephone number identifies mobile communication terminals 6-1, 6-2,... 6 -N, and can be used for information identifying the owner. This telephone number is automatically given to the SMS transmitted from the mobile communication terminals 6-1, 6-2... 6 -N to the server 4.

  b) Call / packet transmission information: Information indicating whether or not the mobile communication terminals 6-1, 6-2... 6 -N have been operated, and identifying the operation. This information refers to the transmission history of telephone and packet communication held by the mobile communication terminals 6-1, 6-2, 6 -N, and the transmission history between the previous collection time and the current time. It can be collected by searching for presence or absence.

  c) Information on pressing of the operation buttons of the mobile communication terminals 6-1, 6-2... 6-N: Information indicating whether or not the mobile communication terminal 6 has been operated, and specifying the presence or absence of the operation. This information can be collected by starting operation log collection triggered by the reception of broadcast SMS and searching for logs from the previous collection time to the present.

  d) Information on accommodation area: Indicates the movement and destination of the mobile communication terminals 6-1, 6-2, ... 6-N, and the mobile communication terminals 6-1, 6-2, ... 6-N by the owner. This information identifies whether or not there is any movement. This information can be collected by acquiring base station information from the currently communicating base station and acquiring an identifier that uniquely identifies the base station.

  e) Information on latitude and longitude: represents the movement and destination of the mobile communication terminals 6-1, 6-2,..., 6-N, and the mobile communication terminals 6-1, 6-2,. This is information for specifying the presence or absence of N movement. This GPS information is information with higher accuracy than the information of d). This information can be collected by obtaining current latitude and longitude information using the GPS function.

  For collecting each information, the mobile communication terminals 6-1, 6-2,... 6-N acquire or collect telephone / packet transmission history, operation log, base station information in communication, and latitude and longitude information by GPS. If it has the function to perform, the information a), b), c), d) and e) can be collected.

  The mobile communication terminals 6-1, 6-2,... 6 -N repeatedly transmit the collected terminal information at regular intervals and at regular intervals. The terminal information transmission frequency and transmission interval are in accordance with the terminal information collection interval and collection frequency included in the broadcast SMS received from the server 4. Information b and c transmit information from the previous transmission to the present, and information d and e transmit information at the current time.

  FIG. 14 shows the terminal information table 13. This terminal information table 13 is set in the memory 66 of the mobile communication terminals 6-1, 6-2 to 6 -N. In this terminal information table 13, information acquired by the mobile communication terminal 6 is stored.

  In the terminal information table 13, a telephone / packet transmission information storage unit 82, a terminal operation information storage unit 84, a storage area information storage unit 86, a latitude information storage unit 88, and a longitude information storage unit 90 are set.

  The telephone / packet transmission information storage unit 82 stores information indicating the presence / absence of transmission of the above-described telephone or packet. For example, “1” is stored if a call or packet is transmitted, and “0” is stored if a call or packet cannot be transmitted.

  The terminal operation information storage unit 84 stores information indicating the presence / absence of operation of the mobile communication terminals 6-1, 6-2 to 6 -N. For example, “1” is stored if there is an operation, and “0” is stored if the operation cannot be performed.

  The accommodation area information storage unit 86 stores base station information of the accommodation areas 80-1, 80-2,... 80-N (FIG. 4). In this example, four-digit numbers (symbols) such as “5555” are stored as base station information.

  The latitude information storage unit 88 stores latitude information. In this example, “35 degrees 34 minutes 52.154 seconds” is stored as latitude information, for example.

  The longitude information storage unit 90 stores longitude information. In this example, “139 degrees 38 minutes 29.306 seconds” is stored as longitude information, for example.

  FIG. 15 shows an example of the SMS 92 generated by each mobile communication terminal 6-1, 6-2... 6 -N. The SMS 92 is generated by the mobile communication terminal 6 based on the information in the terminal information table 13. The generated SMS 92 is transmitted to the server 4.

  The SMS 92 is a symbol string including telephone / packet transmission information 94, terminal operation information 96, accommodation area information 98, and latitude / longitude information 100 as shown in FIG. Composed.

  The telephone / packet transmission information 94 indicates the presence or absence of telephone or packet transmission information, and is set in the first digit of the SMS 92. “1” if there is a telephone or packet transmission, “0” otherwise.

  The terminal operation information 96 indicates the presence / absence of operation button press information, and is set in the second digit following the call / packet transmission information 94. If the operation button is pressed, it is “1”, otherwise it is “0”.

  The accommodation area information 98 represents an identifier representing a base station that covers the accommodation area, and is represented by, for example, the following four-digit number string following the terminal operation information 96. In this example, a numerical string “5555” is shown.

  Latitude / longitude information 100 represents current latitude information and longitude information. The latitude information is, for example, a 9-digit number string following the accommodation area information 98. This number string is a number “3534552154” representing latitude, and is represented in the order of degrees, minutes, and seconds. The longitude information is, for example, a 10-digit number string following the latitude information. This number string is a number “1393829306” representing longitude, and is represented in the order of degrees, minutes, and seconds.

  The SMS 92 shown in FIG. 15B represents the following information. There is a call or packet transmission between the last collection time and the present time. There is a press of an operation button. The current accommodation area is “5555”. The latitude of the current position is “35 degrees 34 minutes 52.154 seconds”. The longitude is “139 degrees 38 minutes 29.306 seconds”.

<Safety information generation process>

  FIG. 16 shows a processing procedure for generating safety information. This processing procedure determines the state of the mobile communication terminals 6-1, 6-2... 6 -N from the previous information and the current information, and updates the past safety information to the current safety information.

  Safety information generation processing is executed by the server 4, and terminal information 10 transmitted from each mobile communication terminal 6-1, 6-2,..., 6-N by SMS is used to generate safety information. The server 4 generates a safety information table 12 (FIG. 4) as a safety information database for managing the terminal information 10 using the telephone numbers of the mobile communication terminals 6-1, 6-2,. And whenever the terminal information 10 is collected, the safety information table 12 is updated.

  In this processing procedure, the terminal information 10 transmitted by SMS from the mobile communication terminal 6 is received (S301). Using the received telephone number in the terminal information 10 as a search key, a record in the safety information table 12 that is a database is searched (S302).

  It is determined whether or not a record having a telephone number in the terminal information 10 exists in the safety information table 12 (S303). If there is no record having the received telephone number in the safety information table 12 (NO in S303), the received terminal information 10 is registered as a new record in the safety information table 12 (S304). In this case, since the information d and e specify whether or not the terminal owner has moved based on the difference from the previous time, the value of the safety information table 12 is set to “×” in the case of new registration, and for the next comparison The current accommodation area information, latitude and longitude information are held (S305). Then, the rescue urgency level is set or updated based on the value of each record (S306), and the process ends.

  If there is a record having the telephone number received from the mobile communication terminals 6-1, 6-2... 6 -N in the safety information table 12 (YES in S 303), the safety information is based on the terminal information 10 received this time. Update the values in table 12. The information b and c determine whether or not the previous value is “x” (S307). If the values up to the previous time are “x” (YES in S307), the values of the safety information table 12 are updated with the current values (S308). If the value up to the previous time is “◯” (NO in S307), since the terminal owner has already confirmed the telephone transmission, packet transmission, or operation button pressing, the value is not updated.

  It is determined whether the information d and e have the value “x” up to the previous time (S309). If the values of the information d and e until the previous time are “x” (YES in S309), it is determined whether the information d and e has a difference from the previous position information (S310). If the values of the information d and e are not “x” (NO in S309), the rescue urgency level is set or updated based on the value of each record (S306), and the process ends.

  If the values of the information d and e are “x” up to the previous time and the information d and e have a difference from the previous position information (YES in S310), the value of the safety information table 12 is updated to “◯”. Then, the rescue urgency is set or updated based on the value of each record (S306), and the process is terminated. That is, when the value up to the previous time is “◯”, the movement of the terminal owner has already been confirmed as in the case of the information b and c, and the value is not updated.

  If there is no difference from the previous position information in the information d and e (NO in S310), the rescue urgency level is set or updated based on the value of each record (S306), and the process ends.

  FIG. 17 shows the data structure of the safety information table 12 which is an information update method database.

  The safety information table 12 includes a telephone number storage unit 104, a telephone / packet information storage unit 106, a terminal operation information storage unit 108, a storage area information storage unit 110, a latitude / longitude information storage unit 112, and a rescue emergency level storage unit 114. Is set.

  The telephone number storage unit 104 stores the telephone numbers of the mobile communication terminals 6-1, 6-2 to 6 -N.

  The telephone / packet information storage unit 106 stores one or both of telephone transmission information and packet transmission information. In this case, if there is a call, “◯” is stored. If there is no outgoing call, “x” is stored.

  The terminal operation information storage unit 108 stores operation information such as operation of operation buttons. If there is an operation, “○” is stored. If there is no operation, “×” is stored.

  The accommodation area information storage unit 110 stores information representing the movement of the accommodation area of the mobile communication terminal 6. If there is a movement, “◯” is stored. If there is no movement, “x” is stored.

  The latitude / longitude information storage unit 112 stores information indicating the presence / absence of movement from the latitude information and longitude information. If there is a movement, “◯” is stored. If there is no movement, “x” is stored.

  The rescue emergency level storage unit 114 stores rescue emergency level information. The rank information is represented by, for example, A, B.

  FIG. 18 shows the transition of safety information. This transition of the safety information indicates a state change due to the reception of the SMS three times.

  In this example, the SMS is received from the mobile communication terminal 6 having the telephone number “090-abcd-efgh”.

  (1) First SMS reception

  The server 4 acquires the terminal information 10 by receiving the first SMS. From the terminal information 10 to the safety information table 12, the telephone number “090-abcd-efgh” is stored in the telephone / packet information storage unit 106, “O” in the terminal operation information storage unit 108, and the accommodation area. The information storage unit 110 stores “x”, the latitude / longitude information storage unit 112 stores “x”, and the rescue emergency level storage unit 114 stores “C”.

  (2) Second SMS reception

  By receiving the second SMS, the server 4 acquires the terminal information 10. From the terminal information 10 to the safety information table 12, the telephone number “090-abcd-efgh” is stored in the telephone / packet information storage unit 106, “O” in the terminal operation information storage unit 108, and the accommodation area. The information storage unit 110 stores “O”, the latitude / longitude information storage unit 112 stores “O”, and the rescue emergency level storage unit 114 stores “E”. That is, the accommodation area information storage unit 110 has been updated from “x” to “◯”. In addition, the latitude / longitude information storage unit 112 is also updated from the previous “×” to “◯”. Thereby, the rank of the rescue emergency level in the rescue emergency level storage unit 114 is changed from “C” to “E”.

  (3) Third SMS reception

  The server 4 acquires the terminal information 10 by receiving the third SMS. From the terminal information 10 to the safety information table 12, the telephone number “090-abcd-efgh” is stored in the telephone / packet information storage unit 106, “O” in the terminal operation information storage unit 108, and the accommodation area. The information storage unit 110 stores “O”, the latitude / longitude information storage unit 112 stores “O”, and the rescue emergency level storage unit 114 stores “E”. That is, it is the same data as the second SMS reception, and there is no change in state. Thereby, the rank of the rescue emergency level in the rescue emergency level storage unit 114 is maintained at “E”.

<Relationship table 116 between each record value and rescue urgency>

  FIG. 19 shows a record value-rescue emergency level relationship table 116.

  The rescue urgency level is calculated from the record value of the safety information table 12 that is a database, and is specifically obtained from the operation system information and the mobile system information of each record value. Therefore, the record value-rescue emergency level relationship table 116 indicates the rescue emergency level together with the operation system information and the mobile system information.

  In the record value-rescue emergency level relation table 116, an operation system information storage unit 118, a mobile system information storage unit 120, and a rescue emergency level storage unit 122 are set. The operation system information storage unit 118 stores the number of “◯” in the information b and c described above. The mobile system information storage unit 120 stores the number of “◯” in the information d and e. The number of “◯” is integrated, and “A, B... E” is stored as rank information in the rescue emergency level storage unit 122.

  By referring to the record value-rescue emergency level relation table 116, the rescue emergency level is set based on the number of “◯” in the information b and c and the number of “O” in the information d and e.

<Damage information generation processing for each accommodation area>

  FIG. 20 shows a disaster situation relation table 124 for each accommodation area.

  In this disaster situation relation table 124, the disaster situation is obtained by integrating the disaster information of a specific area, for example, the accommodation area described above, from the safety information in units of the mobile communication terminals 6-1, 6-2, ... 6-N. Can be requested. In the disaster situation relation table 124, a terminal emergency level storage unit 126 and a disaster situation weight storage unit 128 are set. The terminal emergency level storage unit 126 stores the rank information described above. A weighting coefficient is stored in the weight storage unit 128 of the disaster situation.

  The disaster index can be calculated by the following calculation formula according to the weight for each emergency level from the rescue emergency level of the mobile communication terminals 6-1, 6-2 to 6 -N existing in the specific area.

The damage index α is obtained by multiplying a plurality of urgency levels by a weighting coefficient. For example, the damage index α is
Damage index α = Ratio of urgency A × 100 + Ratio of urgency B × 80
+ Ratio of urgency C × 60 + Ratio of urgency D × 40
+ Ratio of urgency E x 20 (1)
It is. That is, the closer the damage index of a specific area is to 100, the heavier the damage situation in that area is.

<Effect of the invention>

  A) The mobile communication terminals 6-1, 6-2... 6 -N collect terminal information 10 automatically and spontaneously upon reception of broadcast SMS, and transmit the terminal information 10 to the server 4. The mobile communication terminal 6 can generate and transmit terminal information of the terminal owner existing in the accommodation areas 80-1, 80-2,... 80-N without intervention of the owner. As a result, when it is difficult for the user to notify the safety information or when the user forgets to notify the safety information, it is possible to eliminate the human adverse effect and to collect the safety information of the terminal owner accurately and promptly. Is possible.

  B) Communication from the mobile communication terminals 6-1, 6-2,... 6 -N to the server 4 can be performed by priority traffic communication, and safety information is reliably collected even in a state where it is difficult to connect due to traffic congestion at the time of a disaster. It can be performed.

  C) By calculating and analyzing the safety information for each of the mobile communication terminals 6-1, 6-2... 6 -N, it is possible to calculate the damage index for each specific area such as the accommodation area. Thereby, it becomes possible to confirm and analyze the disaster situation for each area from a remote location. Useful information can be obtained, which can contribute to the development of an efficient and accurate rescue plan for the affected areas.

[Third Embodiment]

  FIG. 21 shows a processing procedure for generating safety information according to the third embodiment. This processing procedure stores safety information from the start of receiving terminal information to the current time.

  The safety information generation process is executed by the server 4, and the terminal information 10 transmitted from each mobile communication terminal 6 by SMS is used to generate the safety information. The server 4 generates a safety information table 12 (FIG. 22) which is a database for managing terminal information using the telephone number of the mobile communication terminal 6 as a key. The terminal information 10 is accumulated in the safety information table 12 every time it is collected.

  In this processing procedure, the terminal information 10 transmitted by SMS from the mobile communication terminal 6 is received (S401). A record in the safety information table 12 (FIG. 22) is searched using the received telephone number in the terminal information 10 as a search key (S402).

  It is determined whether a record having a telephone number in the terminal information exists in the safety information table 12 (FIG. 22) (S403). If there is no record having the received telephone number in the safety information table 12 (NO in S403), the received terminal information 10 is registered as a new record in the safety information table 12 (S404). The current time is added to the record (S405). In this case, since the information d and e specify whether or not the terminal owner has moved based on the difference from the previous time, the value of the safety information table 12 is set to “×” in the case of new registration, and for the next comparison The current accommodation area information, latitude and longitude information are held (S406). Then, the rescue urgency is set or updated based on the value of each record (S407), and the process ends.

  If there is a record having the received telephone number in the safety information table 12 (FIG. 22) (YES in S403), the value of the safety information table 12 is updated based on the terminal information received this time. That is, the current value is registered in the information b and c (S408). It is determined whether the values of the information d and e are “x” (S409). If the previous values of the information d and e are not “x” (NO in S409), “◯” is registered in the information d and e (S410). The current time is added to the record (S411), and the process proceeds to the above-described S407. As described above, in S407, the rescue urgency level is set or updated based on the value of each record (S407), and the process ends.

  If the previous values of the information d and e are “x” (YES in S409), it is determined whether there is a difference between the information d and e from the previous time (S412). If there is a difference in the information d and e from the previous time (YES in S412), “o” is registered in the information d and e (S413), the current time is added to the record (S411), and S407 is executed. To finish the process.

  If there is no difference in the information d and e from the previous time (NO in S412), “x” is registered in the information d and e (S414), the current time is added to the record (S411), and S407 is executed. To finish the process.

  In this third embodiment, the current value is registered in the information b and c in S408. Instead, whether or not the previous value of the information b and c is “x” is determined. The determined process may be used. In this case, if the previous value of the information b, c is “x”, the current value is registered in the information b, c, and if the previous value of the information b, c is not “x”, the information b, c “◯” may be registered in c.

  FIG. 22 shows the data structure of the safety information table 12 which is an information storage system database.

  The safety information table 12 shown in FIG. 22 includes a telephone number storage unit 104, a collection time storage unit 105, a telephone / packet information storage unit 106, a terminal operation information storage unit 108, a storage area information storage unit 110, and latitude / longitude information storage. The unit 112 and the rescue emergency level storage unit 114 are set.

  The telephone number storage unit 104 stores the telephone number of the mobile communication terminal 6.

  The collection time storage unit 105 stores the collection time for collecting the above-described information.

  The telephone / packet information storage unit 106 stores one or both of telephone transmission information and packet transmission information for each collection time. In this case, if there is a call, “◯” is stored. If there is no outgoing call, “x” is stored.

  The terminal operation information storage unit 108 stores operation information such as operation button operations for each collection time. If there is an operation, “○” is stored. If there is no operation, “×” is stored.

  The accommodation area information storage unit 110 stores information representing movement of the accommodation area of the mobile communication terminal 6 at each collection time. If there is a movement, “◯” is stored. If there is no movement, “x” is stored.

  The latitude / longitude information storage unit 112 stores information indicating the presence / absence of movement from the latitude information and longitude information for each collection time. If there is a movement, “◯” is stored. If there is no movement, “x” is stored.

  The rescue emergency level storage unit 114 stores rescue emergency level information for each collection time. The rank information is represented by, for example, A, B.

  As in this embodiment, in the information storage type method, the previous information is retained without being updated, and information on the current time is newly added. Thereby, the temporal transition of safety information can be confirmed.

  The server 4 sets and updates the rescue emergency level for each mobile communication terminal 6 based on the value of each record of the generated safety information table 12. The relationship between each record value and the rescue urgency level is determined according to the relationship table 116 (FIG. 19) between each record value and the rescue urgency level based on the number of “◯” of each record generated from the terminal information. Rescue urgency is leveled in five stages from A to E, with A being the highest urgency and E being the lowest urgency. And the server 4 produces | generates the safety information which makes each mobile communication terminal 6-1, 6-2 ... 6-N a unit by the calculated rescue emergency.

[Other Embodiments]

  The terminal information table 13 (FIG. 4) in the first embodiment includes a telephone number storage unit and stores the telephone numbers of the mobile communication terminals 6-1, 6-2,. Similarly, the terminal information table 13 (FIG. 14) of the second embodiment may also include a telephone number storage unit and store identification information such as a telephone number.

As described above, the most preferable embodiment of the present disclosure has been described. The present invention is not limited to the above description. Various modifications and changes can be made by those skilled in the art based on the gist of the invention described in the claims or disclosed in the embodiments for carrying out the invention. It goes without saying that such modifications and changes are included in the scope of the present invention.

2 Safety information processing system 4 Safety information processing server 6, 6-1, 6-2... 6-N Mobile communication terminal 8, 8-1, 8-2... 8-N Base station 10 Terminal information 12 Safety Information table 13 Terminal information table 14 External IF (Interface) function 16 Control function 18 Safety information generation processing function 20 Operator input reception IF function 22 Terminal information SMS reception IF function 24 Broadcast SMS distribution function 26 Safety information generation processing control function 28 Terminal information Setting / Updating Function 30 Rescue Urgency Setting / Updating Function 32 Input / Output Unit 34 SMS Transmit / Receive Unit 36 Processor 38 Memory 40 External IF Function 42 Control Function 44 Terminal Information Collection Function 46 Broadcast SMS Reception IF Function 48 Terminal Information SMS Transmission Function 50 Terminal Information collection processing control function 52 Operation log collection function 54 Degrees and longitude information collection function 56 Telephone packet transmission information collection function 58 containing area information collecting function 60 packet transceiver 62 SMS transceiver 64 processor 66 memory 68 operation input unit 70 GPS (Global Positioning System) communication unit 72 Broadcast SMS
74 Service type 76 Destination area code 78 Terminal information collection count 80 Terminal information collection interval 80-1, 80-2 ... 80-N accommodation area 82 Telephone / packet transmission information storage section 84 Terminal operation information storage section 86 accommodation area Information storage unit 88 Latitude information storage unit 90 Longitude information storage unit 92 SMS
94 Telephone / packet transmission information 96 Terminal operation information 98 Accommodation area information 100 Latitude / longitude information 104 Telephone number storage section 106 Telephone / packet information storage section 108 Terminal operation information storage section 110 Accommodation area information storage section 112 Latitude / longitude information storage Unit 114 Rescue emergency level storage unit 116 Record value-rescue emergency level relation table 118 Operation system information storage unit 120 Mobile system information storage unit 122 Rescue emergency level storage unit 124 Disaster situation relation table 126 Terminal emergency level storage section 128 Weight of disaster situation Storage

Claims (7)

A mobile communication terminal that collects terminal information upon transmission instruction and transmits the terminal information;
Safety information processing means for distributing the transmission instruction, collecting the terminal information from the mobile communication terminal, and generating safety information using the terminal information;
Safety information processing system with The transmission instruction is performed by broadcast SMS (Short Message Service) delivered to the mobile communication terminal by the safety information processing means.
The safety information processing system according to claim 1. The terminal information includes any one or more of identification information, operation history information, transmission history information, area information, position information of the mobile communication terminal,
The safety information processing system according to claim 1. The safety information includes a rescue emergency level determined by the terminal information received from the mobile communication terminal.
The safety information processing system according to claim 1. A communication unit that distributes a terminal information transmission instruction to the mobile communication terminal and receives the terminal information from the mobile communication terminal;
A processing unit that generates safety information using the terminal information received by the communication unit;
A safety information processing apparatus comprising: A safety information processing program executed on a computer,
Generate a terminal information transmission instruction to the mobile communication terminal,
Collect terminal information received from the mobile communication terminal,
A safety information processing program for causing the computer to execute a process of generating safety information using the terminal information. A communication unit that receives a terminal information transmission instruction and transmits the terminal information;
A processing unit that collects the terminal information triggered by the transmission instruction received by the communication unit;
A mobile communication terminal comprising:

Images