JP5405817B2 - Communication network system - Google Patents

Description

  The present invention relates to a communication network system and, for example, relates to a communication network system that functions as a disaster information collection system that supports quick rescue activities when a large-scale disaster occurs.

When disasters such as earthquakes and typhoons occur, it is important to collect accurate information for quick relief activities and infrastructure restoration activities. In general, when a disaster occurs, a communication system such as a fire fighting radio or a disaster prevention radio is used. Various techniques have been proposed for effective utilization of these systems and for prompt information collection by cooperating with other systems. For example, there is an information transmission system in which a disaster prevention radio system and a mobile phone system are integrated (for example, see Patent Document 1). With this technology, it is possible to effectively transmit emergency information to a person who is in a place where broadcast audio is difficult to reach or a person who is moving by taking advantage of each system.
JP 2006-287771 A

  By the way, when a large-scale disaster occurs, information transmission between the rescue worker at the disaster site and the commander who directs the rescue operation is mainly performed by sound by a fire fighting radio or a disaster prevention radio. Therefore, there has been a problem that the amount of information that can be transmitted to the command headquarters for relief activities at a time is limited. Therefore, since it takes time to grasp the disaster situation in the stricken area, it has been difficult to grasp the location of the victims globally and promptly. Further, when grasping the disaster situation, old and new information may be mixed depending on the location depending on geographical conditions such as whether the disaster area is a densely populated area. As a result, there is a problem that it is very difficult to appropriately arrange and guide a rescue team in a place where relief activities are necessary. Furthermore, when a large-scale disaster occurs, it is assumed that the base station of each system for wireless communication is damaged, but with the technique disclosed in Patent Document 1, it is assumed that the base station is damaged. It was also assumed that when applied as it is, it could not cope sufficiently.

  The present invention has been made in view of such a conventional situation, and an object of the present invention is to solve the above-described problems and provide a technique for quickly grasping a disaster situation when a disaster occurs.

An apparatus according to the present invention comprises a mobile phone communication system comprising a mobile phone network monitoring server that constitutes a mobile phone communication network and monitors the communication network, and constitutes a business radio communication network and monitors the communication network A communication network system comprising a business radio communication system comprising a business radio network management server, wherein the mobile phone communication system and the business radio communication system are connected to transmit and receive data, the mobile phone network monitoring The server identifies a service area of the base station when a failure occurs in a base station constituting the communication network of the mobile phone, and notifies the service radio network management server of information on the identified service area, the business radio network management server receives the information of the service area from the mobile phone network monitoring server, under the management of the business radio network management server Ri, the radio equipment of the business radio communication system having a communicable function to the mobile phone and the other by including and sensor networks PND, said fault via the base station of the business radio communication system notifies the service area of have been identified as occurring the cellular phone, the radio was via the sensor network located in said service area and obtained for a mobile phone constituting the sensor network Information is transmitted to the business radio network management server via the base station of the business radio communication system.
In addition, the number of mobile phones in the specified service area of the base station where the failure collected by the PND has occurred and location information by GPS may be transmitted to the command headquarters via the radio. Good.
In addition, the number of mobile phones in the specified service area of the base station where a failure has occurred may be mapped on an electronic map.
A plurality of wired or wireless multiple lines may be constructed between the mobile phone communication system and the commercial wireless communication system.

  As described above, according to the present invention, it is possible to provide a technique for quickly grasping a disaster situation when a disaster occurs.

  Next, the best mode for carrying out the present invention (hereinafter simply referred to as “embodiment”) will be specifically described with reference to the drawings. In the following embodiments, first, a situation in which the proposed system is applied and an overview of the system at that time will be described, and then a specific configuration, processing, and operation will be described.

  FIG. 1 is a map illustrating an area to which the disaster prevention communication system 10 according to the present embodiment is applied. FIG. 1A is an arbitrarily designated map, and FIG. 1B is a conceptual diagram roughly showing the distribution of victims. In FIG. 1B, the service area of the business radio base station 302 is indicated by a broken line, the service area (cell) of the mobile phone base station 103 is indicated by a hexagon, and the specified mobile phone Are shown in three types, and the service area where the failure has occurred is identifiable. Furthermore, FIG. 2 is a conceptual diagram of the distribution of victims acquired by the sensor network in the area of the mobile phone base station 103 that is not operating. In FIG. 2 and FIG. 3 to be described later, a node A indicated by a double circle indicates a portable radio device 400 for business use of a rescue team serving as a network coordinator. A node B indicated by black is a node (cell phone 200) having position information by GPS, and a node C indicated by a broken line is a node (cell phone 200) having no position information by GPS. Show. A node D indicated by a white circle indicates a node (mobile phone 200) in an adjacent area where the mobile phone base station 103 of the mobile phone communication network 100 is operating. The disaster prevention communication system 10, the mobile phone base station 103, the business radio base station 302, and the like will be described later with reference to FIG.

  When a large-scale disaster occurs, the rescuer selects a desired area as shown in FIG. 1A by using the control room fixed terminal 303 of the firefighting / disaster prevention wireless network 300 described later, and carries it. Based on the user location information confirmed by the telephone communication network 100, the distribution of users existing in the affected area is displayed in service area units (cell units) of the mobile phone base station 103. When the mobile phone base station 103 is not operating due to damage or the like, the base station information cannot be grasped, so that it is not operating is displayed. More specifically, as shown in FIG. 1B, the distribution density of the victims and the unknown location registration information are displayed. Then, in a non-operating area due to damage to the base station 103 for mobile phones, a rescuer carrying the business portable radio 400 used in the firefighting / disaster prevention wireless network 300 goes around the area, The disaster victims existing in the area are detected using the network and reflected in the disaster countermeasure system 350 of the fire fighting / disaster prevention wireless network 300.

  Here, the sensor network refers to a network in which a plurality of sensors (sensor / network communication modules) are grasped as nodes and the sensors are connected to each other in an ad hoc manner without using a relay station. And the position information of each node is estimated by arrange | positioning the node (node provided with the GPS function) with known position information as a landmark in the sensing field. Examples of the sensor network include Bluetooth (registered trademark), ZigBee (registered trademark), and the like. Here, description will be made assuming that the function of ZigBee (registered trademark) is used. Zigbee (registered trademark) is one of the short-range wireless communication standards for home appliances, and has a feature of low power consumption and low cost instead of lower speed and shorter transmission distance than Bluetooth (registered trademark). Therefore, even when power saving is required more than usual, such as when a disaster occurs, it can be used effectively.

  Here, a sensor network utilization method in the present embodiment will be briefly described with reference to FIGS. Here, the state of the service area SA1 shown in FIG. 1B where the mobile phone base station 103 is not operating due to damage or the like is shown. Further, it is assumed that the cellular phone 200 of the disaster victim includes a sensor / network communication module 208 and a GPS module 209. FIG. 3A shows a state in which the nodes that are sensor / network communication modules are not connected to each other (a state in which a sensor network is not established), and FIG. 3B shows that each node is connected. (Sensor network established). FIG. 3 (c) shows the state of FIG. 3 (b) in which the portable radio 400 for business use of the rescue team (node A), which is the network coordinator, is located in the center of the cell and is affected by the sensor network. This shows the state of acquiring the information. As shown in FIG. 3 (c), the business portable wireless device 400 (node A) having the PND 500 of the rescue team moves to the service area SA1 where the mobile phone base station 103 is not operating. The distribution of mobile phone users in the service area SA1 can be grasped and notified to the disaster countermeasure system 350 using the fire fighting / disaster prevention wireless network 300.

Next, a more specific configuration and operation will be described.
FIG. 4 is a diagram illustrating a schematic configuration of the disaster prevention communication system 10. As illustrated, the disaster prevention communication system 10 includes a fire fighting / disaster prevention radio network 300 and a mobile phone operator network 190. The fire-fighting / disaster prevention wireless network 300 and the mobile phone operator network 190 can communicate with each other through a satellite line through one or more of a wired multiple line network, a wireless multiple line network, and a communication satellite 800. Further, GPS position information from the GPS satellite 700 is utilized.

  FIG. 5 is a diagram showing a schematic configuration of the mobile phone operator network 190. The mobile phone operator network 190 includes a mobile phone communication network 100 that communicates with the mobile phone 200 via the mobile phone base station 103, and a mobile phone operator management system 600 that controls the communication. .

  The mobile phone communication network 100 includes a mobile gateway exchange 101, a mobile phone control station 102, a mobile phone base station 103, and a location registration DB 104. The mobile gateway exchange 101 is an apparatus that interconnects with another telecommunication carrier's communication network or connects with another communication processing system. The mobile phone control station 102 notifies the location registration DB (database) 104 of location registration information of all mobile phones 200 existing in the service area of the mobile phone control station 102 at a predetermined time interval or at all times. To do. Further, in the event of a disaster, the mobile phone control station 102 inquires of the mobile phone base station 103 in its service area whether or not a failure has occurred, or performs a self-diagnosis to determine its own failure occurrence, Further, information on the occurrence of the failure and the location registration information recorded in the location registration DB 104 are notified to the communication infrastructure monitoring server 605 of the mobile phone operator management system 600 described later.

  The mobile phone base station 103 normally notifies the mobile phone control station 102 of all location registration information of the mobile phone 200 existing within the service area of the mobile phone base station 103 at a predetermined time interval or at all times. To do. When a disaster occurs, the mobile phone base station 103 performs a self-diagnosis and notifies the mobile phone control station 102 of the determination result.

  The location registration DB 104 receives the notification from the mobile phone control station 102 and updates the location registration information of the mobile phone 200 at predetermined intervals or at all times.

  The mobile phone base station 103 is provided for each cell (service area) as shown in the figure. Here, the first to Nth cells C1 to CN are provided with first to Nth mobile phone base stations 103-1 to 103-N, respectively. First mobile phone base station 103-1 communicates with first to Nth mobile phones 200-1 to 200-N in its own service area. Note that the first to Nth mobile phones 200-1 to 200-N and the P and Qth mobile phones 200-P and 200-Q to be described later are simply described as the mobile phone 200 when not distinguished from each other.

  The mobile phone operator management system 600 includes a communication infrastructure monitoring server 605 connected to the communication line network 610, a location registration history DB 606 connected to the communication infrastructure monitoring server 605, and a failure history DB 607. In addition, the mobile phone operator management system 600 communicates with the fire-fighting / disaster prevention wireless network 300 via the communication satellite 800 and the satellite-based wireless transmission device 608 that is connected to the fire-fighting / disaster prevention wireless network 300 via the communication satellite 800. And a terrestrial wireless transmission device 609 to be connected. Further, the mobile network switch 101 of the mobile phone communication network 100 is connected to the communication line network 610, and a wired multiple line connected to the dedicated digital line network 314 of the fire fighting / disaster prevention radio network 300 is connected. The fire-fighting / disaster prevention wireless network 300 and the mobile phone operator management system 600 perform communication by selecting a satellite line, a wireless multiple line network, or a wired multiple line network according to the disaster situation.

  The communication infrastructure monitoring server 605 records the failure information received from the mobile phone control station 102 in the failure history DB 607 for each service area (cell) of the mobile phone control station 102 or from the mobile phone control station 102. The received location registration information is recorded in the location registration history DB 606 for each service area of the mobile phone control station 102. Furthermore, when a disaster occurs, the communication infrastructure monitoring server 605 considers that a serious failure that cannot be communicated has occurred with respect to the mobile phone control station 102 that does not transmit failure occurrence information even if a predetermined time has elapsed since the start of the inquiry. Is recorded in the failure history DB 607. Further, the communication infrastructure monitoring server 605 inquires the failure history DB 607 for the latest failure status, inquires the location registration history DB 606 for the latest location registration information, and further updates the latest operation status of the mobile phone base station 103. Merge location registration information in cell units.

  Next, the fire fighting / disaster prevention wireless network 300 will be described with reference to FIG. FIG. 6 is a diagram illustrating a schematic configuration of the fire fighting / disaster prevention wireless network 300. The fire fighting / disaster prevention radio network 300 includes a disaster countermeasure system 350 and first to N business radio control stations 301-1 to 301-N, which are connected to a dedicated digital network 314. In addition, a satellite wireless transmission device 312 and a terrestrial wireless transmission device 313 are connected to the dedicated digital network 314. Furthermore, a base station 302 for business radio is connected to the first to N business radio control stations 301-1 to 301-N. Here, a state in which the first to Nth business radio base stations 302-1 to 302-N are connected to the first business radio control station 301-1 is illustrated. The first to Nth business radio base stations 302-1 to 302-N connected to the first business radio control station 301-1 are the first to Nth business portable radio devices. Connect with 400-1 to 400N. Further, when the first to N business radio control stations 301-1 to 301-N are not distinguished, they are simply referred to as “business radio control station 301”. Similarly, when the first to Nth business radio base stations 302-1 to 302-N are not distinguished, they are simply referred to as “business radio base stations 302”. The first to Nth business use portable wireless devices 400-1 to 400-N include first to Nth PNDs 500-1 to 500-N, respectively. In addition, when not distinguishing the first to N-th business portable radios 400-1 to 400N, they are simply referred to as “business-use portable radios 400”, and similarly, the first to N-th PNDs 500-1 to 500-N. When not distinguishing 500-N, it is simply referred to as “PND500”.

  In the disaster countermeasure system 350, the control room fixed terminal 303 connected to the display unit 304 and the operation unit 305, the victim dynamic monitoring server 306, and the rescue team dynamic monitoring server 307 are connected to the dedicated digital network 314. . Furthermore, the disaster countermeasure system 350 includes a resident information DB 308, a disaster victim dynamic information DB 309, a map information DB 310, and a rescue team dynamic information DB 311. The disaster victim dynamic monitoring server 306 accesses the resident information DB 308, the disaster victim dynamic information DB 309, and the map information DB 310, and the rescue team dynamic monitoring server 307 accesses the map information DB 310 and the rescue team dynamic information DB 311 to access each database. Each processing such as registration, update and use of desired information is performed. The display unit 304 is a display unit including, for example, a liquid crystal display. The operation unit 305 is a user interface such as a keyboard, a mouse, and a touch panel configured integrally with the display unit 304. The same applies to the display units 203, 403, and 503 and the operation units 204, 404, and 504 of the mobile phone 200, the commercial portable radio 400, and the PND 500, which will be described later.

Next, the configuration of the mobile phone 200 will be described with reference to FIG.
The mobile phone 200 has a GPS function and a sensor network function as well as a general communication function. Specifically, the mobile phone 200 includes a control unit 250, a communication module 260, a storage module 270, an input / output module 280, a power supply control unit 214, and a rechargeable battery 215. The control unit 250 includes a main control unit 201 and a signal processing unit 202. The communication module 260 includes a sensor / network communication module 208, a GPS module 209, an RF unit 210, and a digital broadcast receiving module 211.

  The main control unit 201 controls the mobile phone 200 in an integrated manner. In addition, the signal processing unit 202 executes various signal processing for encoding / combining processing for communication and execution of applications. The storage module 270 includes a built-in memory 205, a memory card 206, and a UIM (User Identify Module) card 207. The UIM card 207 is an IC card that records contractor information issued by a mobile phone company. The input / output module 280 includes a display unit 203, an operation unit 204, a microphone 212, and a speaker 213.

  Next, with reference to FIG. 8, the configuration of the business portable radio 400 and the PND 500 connected thereto will be described. The commercial portable radio 400 is a general digital radio, and includes a control unit 450, an input / output module 480, an RF unit 405, a built-in memory 406, an interface 411, a power control unit 409, and the like. A rechargeable battery 410; The input / output module 480 includes a display unit 403, an operation unit 404, a microphone 407, and a speaker 408. The control unit 450 includes a main control unit 401 for comprehensively controlling the commercial portable wireless device 400, and a signal processing unit that executes various signal processing for various processing for communication and execution of applications. 402.

  The PND 500 is a small navigation device, and includes a control unit 550, a display unit 503, an operation unit 504, a built-in memory 505, a map storage device 506, a GPS module 507, a sensor network communication module 508, A power supply control unit 509 and a rechargeable battery 510 are provided. Note that the control unit 550 is communicably connected to the business portable wireless device 400 via the interface 411. The control unit 550 includes a main control unit 501 that controls the PND 500 in an integrated manner, and a signal processing unit 502 that performs various signal processing for processing for navigation and communication with the portable radio 400 for business use. Yes.

  The process flow of the disaster prevention communication system 10 having the above configuration will be described with reference to the charts of FIGS. FIG. 9 shows processing in phase 1 which is normal time. 10 to 12 show processing in phase 2 after a disaster such as an earthquake has occurred. Further, FIG. 13 to FIG. 16 show the processing in the phase 3, which is the confirmation work of the victim by the rescue team.

  In the phase 1 state in which no disaster has occurred, the mobile phone 200 notifies location registration information to the mobile phone base station 103 at a predetermined time interval or always (S101). As the location registration information, the control station identification number and base station identification number being captured, and the identification number of the mobile phone 200 (such as the manufacturing number of the UIM card 207) are notified. Then, the mobile phone base station 103 transfers the location registration information of all the mobile phones 200 existing in the service area of the mobile phone base station 103 to the mobile phone control station 102 at a predetermined time interval or always ( S102). Subsequently, the mobile phone control station 102 is in a service area of the mobile phone base station 103 under its control with respect to the mobile phone control station 102 at a predetermined time interval or at all times. The location registration information of 200 is transferred to the location registration DB 104, and the location registration DB 104 updates the transferred location registration information at a predetermined time interval or constantly (S103). Then, the processing shown in steps S101 to S103 is repeatedly executed during normal operation.

  In phase 2, processing for roughly grasping the distribution status of the victims as shown in FIG. 1B is performed. First, with reference to FIG. 10, information collection related to the mobile phone 200 in the mobile phone operator management system 600 will be described. The communication infrastructure monitoring server 605 of the mobile phone operator management system 600 inquires of the mobile phone control station 102 installed in the area where the disaster has occurred whether or not a failure has occurred (S201). Upon receiving the inquiry, the mobile phone control station 102 inquires of the mobile phone base station 103 in the service area of the mobile phone control station 102 whether or not a failure has occurred (S202). Accordingly, the mobile phone base station 103 performs self-diagnosis, determines whether or not a failure has occurred, and notifies the mobile phone control station 102 of the determination result (S203). In addition, the mobile phone control station 102 performs self-diagnosis and determines whether or not a failure has occurred (S204).

  Subsequently, the mobile phone control station 102 transmits the failure occurrence status of the mobile phone base station 103 under its management, its own failure occurrence status, and the location registration information recorded in the location registration DB 104 to the communication infrastructure. The monitoring server 605 is notified (S205). In other words, information items to be transmitted include the transmission time from the mobile phone control station 102, the identification number of the mobile phone control station 102, the identification number of the mobile phone base station 103, whether a failure has occurred, The contents, the number of location registration information, and the identification number of the mobile phone 200.

  When the above information is acquired from the mobile phone control station 102, the communication infrastructure monitoring server 605 sends the fault occurrence status received from the mobile phone control station 102 to the fault history DB 607 for each service area of the mobile phone base station 103. Recording is performed (S206). The items of information recorded in the failure history DB 607 include the transmission time from the mobile phone control station 102, the identification number of the mobile phone control station 102, the identification number of the mobile phone base station 103, whether a failure has occurred, It is the content of the occurrence. Further, the communication infrastructure monitoring server 605 records the location registration information acquired from the mobile phone control station 102 in the location registration history DB 606 for each service area of the mobile phone base station 103 (S207). Information items recorded in the location registration history DB 606 include the transmission time from the mobile phone control station 102, the identification number of the mobile phone control station 102, the identification number of the mobile phone base station 103, and the number of location registration information items. And the identification number of the mobile phone 200.

  The communication infrastructure monitoring server 605 regards the mobile phone control station 102 that does not transmit the failure occurrence information even if a predetermined time has passed since the start of the inquiry as a serious failure that cannot be communicated. Record in the history DB 607 (S208). Then, the communication infrastructure monitoring server 605 repeatedly executes the above S201 to S208 (S209).

Next, processing in the fire fighting / disaster prevention wireless network 300 will be described with reference to FIG.
The victim dynamic monitoring server 306 of the fire fighting / disaster prevention wireless network 300 inquires of the communication infrastructure monitoring server 605 about the operating status and location registration information of the service area of the mobile phone 200 (S210). As described above, data transmission between the fire fighting / disaster prevention radio network 300 and the mobile phone operator management system 600 can be performed using a wired multi-line network such as the Internet, or directly using a radio multi-line network. Transmission, or indirect transmission through a satellite network via a communication satellite 800.

  Next, the communication infrastructure monitoring server 605 inquires of the failure history DB 607 for the latest failure information and inquires of the location registration history DB 606 for the latest location registration information (S211). The failure information and location registration information to be inquired here are information in service area (cell) units.

  The failure history DB 607 that has received the inquiry notifies the communication infrastructure monitoring server 605 of the latest failure information for each service area (S212). The information items notified here include, for example, the transmission time from the mobile phone control station 102, the mobile phone control station 102 identification number, the mobile phone base station 103 identification number, whether a failure has occurred, and the failure occurrence It is the contents of. Further, the location registration history DB 606 notifies the communication infrastructure monitoring server 605 of the latest location registration information for each service area (S213). The information items notified here include the transmission time from the mobile phone control station 102, the mobile phone control station 102 identification number, the mobile phone base station 103 identification number, whether a fault has occurred, and the content of the fault occurrence. , The number of location registration information and the identification number of the mobile phone 200.

  The communication infrastructure monitoring server 605 uses the identification numbers of the mobile phone control station 102 and the mobile phone base station 103 and the transmission time from the mobile phone control station 102 as keys, and the latest operation of the mobile phone base station 103. The situation is merged for each service area (S214). That is, the information from the failure history DB 607 and the information from the location registration history DB 606 are merged into one integrated data.

Next, the explanation of the chart in FIG.
When the integrated data is generated, the communication infrastructure monitoring server 605 transmits the integrated data merged for each service area, that is, the latest operation status and location registration information of the mobile phone base station 103 to the disaster victim monitoring server 306. (S215). Upon receiving the above information, the disaster victim dynamic monitoring server 306 transfers the latest operation status of the mobile phone base station 103 and the mobile phone 200 to the disaster victim dynamic information DB 309. The disaster victim dynamic information DB 309 The location registration information is recorded (S216). The items of information transmitted in S215 and 216 include, for example, the transmission time from the mobile phone control station 102, the mobile phone control station 102 identification number, the mobile phone base station 103 identification number, and the mobile phone base station. The operation status of 103, the presence / absence of a failure, the content of the failure, the number of location registration information, and the identification number of the mobile phone 200.

  Next, the controller who operates the disaster countermeasure system 350 operates the control room fixed terminal 303 via the operation unit 305 and designates an arbitrary area in which the rough distribution of the disaster victim is desired (S217). In response to the operation, the control room fixed terminal 303 inquires of the victim distribution monitoring server 306 about the rough distribution status of the victims (S218). Then, the disaster victim dynamic monitoring server 306 inquires about the operating status and location registration information of the mobile phone base station 103 installed in the designated area in the disaster victim dynamic information DB 309 (S219), and further, the map information DB 310 Is inquired about the map information of the designated area (S220).

  In response to the inquiry from the disaster victim dynamic monitoring server 306, the disaster victim dynamic information DB 309 transmits the operation status and location registration information of the mobile phone base station 103 installed in the designated area to the disaster victim dynamic monitoring server 306. (S221). Similarly, map information DB310 transmits the map information of the designated area to the disaster victim dynamic monitoring server 306 (S222).

  Upon receiving the above information from the disaster victim dynamic information DB 309 and the map information DB 310, the disaster victim dynamic monitoring server 306 maps the operation status of the mobile phone base station 103 and the location registration information regarding the mobile phone 200 on the electronic map, GIS (Geographic Information System) data is created (S223) and transmitted to the control room fixed terminal 303 (S224). Then, the control room fixed terminal 303 displays the rough distribution of the victims via the display unit 304 to the controller (S225). For example, the distribution of victims is shown as shown in FIG.

  Next, phase 3 processing will be described with reference to FIGS. This process is a process at the time of investigating the distribution of victims in the service area of the mobile phone base station 103 that is not in operation. The rescue team carries the business-use portable wireless device 400 equipped with the PND 500 having the GPS function to investigate the disaster area.

  First, the PND 500 having the GPS function shown in FIG. 13 calculates its own position information (latitude and longitude, etc.) from the signal of the GPS satellite 700 at predetermined time intervals (S301a), and is connected to a portable mobile radio for business use. The position information is transmitted to the rescue team dynamic monitoring server 307 via 400 (S301b). At this time, the business portable wireless device 400 adds its own identification number and the identification numbers of the captured business radio control station 301 and the business radio base station 302 to the position information and transmits them.

  Next, the rescue team activity monitoring server 307 records the position information of each PND 500 in the rescue team activity information DB 311 (S302).

Next, description will be given focusing on the processing of the rescue team dynamic monitoring server 307 based on FIG.
The rescue team dynamic monitoring server 307 inquires of the victim dynamic monitoring server 306 about the service area of the mobile phone 200 for which location registration information has not been acquired (S303). Upon receipt of the inquiry, the disaster victim dynamic monitoring server 306 accesses the disaster victim dynamic information DB 309 and searches for the identification number of the mobile phone base station 103 for which location registration information has not been acquired (S304). The victim activity information DB 309 transmits a list of identification numbers of the mobile phone base stations 103 for which location registration information has not been acquired in response to the request to the victim activity monitoring server 306 (S305).

Next, the victim dynamic monitoring server 306 inquires of the map information DB 310 about the range of service areas for which location registration information has not been acquired based on the list of identification numbers of the mobile phone base station 103 (S306). Upon receipt of the inquiry, the map information DB 310 transmits the location information (for example, address and latitude / longitude) of the service area for which location registration information has not been acquired to the victim dynamic monitoring server 306 (S307). Then, the victim dynamic monitoring server 306 transmits the location information of the service area for which location registration information has not been acquired to the rescue team dynamic monitoring server 307 (S308).

  Subsequently, the rescue team dynamic monitoring server 307 inquires the rescue team dynamic information DB 311 about the latest positions of all the PNDs 500 (S309). Upon receiving the inquiry, the rescue team dynamic information DB 311 transmits the list of the latest position information (latitude and longitude) of the total number of PNDs 500 and the identification numbers of the portable portable radio 400 for business to the rescue team dynamic monitoring server 307 (S310). ). Then, the rescue team dynamic monitoring server 307 searches for the PND 500 in the vicinity of the service area where the location registration information is not acquired, and based on the result of collecting information by means such as disaster prevention helicopters or aerial photographs, the optimal travel route Is calculated (S311).

  The rescue team dynamic monitoring server 307 determines the location information and the movement route of the service area for which the location registration information has not been acquired for the searched PND 500 (first to Nth PNDs 500-1 to 500-N with GPS function). Information is transmitted (S312).

  Next, with reference to the chart of FIG. 15, description will be given focusing on the processing of the business portable wireless device 400 that has acquired the above information from the rescue team dynamic monitoring server 307. The main control unit 501 of the PND 500 records the position information and the movement route information of the service area received via the portable portable radio 400 in the built-in memory 505, and the main control unit 501 stores the GPS module 507. By using the position information acquired via the start point as the starting point, the travel route information recorded in the built-in memory 505 is displayed on the display unit 503, thereby guiding the rescue team to the service area where the position registration information has not been acquired (S313).

  While guiding the rescue team, the main control unit 501 of the PND 500 compares the position information acquired via the GPS module 507 with the position information of the service area and is located within the target service area. Are sequentially determined (S314). When the main control unit 501 determines that the target service area has been reached, the main control unit 501 activates the sensor / network communication module 508. The sensor network communication module 508 establishes a mesh-structured communication network (sensor network) as shown in FIG. 3 between the sensor network communication module 208 of the plurality of mobile phones 200 existing in the vicinity. Establish (S315). Taking Zigbee (registered trademark) described above as a sensor network, the sensor network communication module 508 of the PND 500 functions as a network coordinator. The sensor network communication module 208 of the mobile phone 200 functions as a full function device.

  When the sensor network is established, the main control unit 501 of the PND 500 communicates with the sensor network communication module 208 of the mobile phone 200 via its sensor network communication module 508 to identify the identification number (UIM) of the mobile phone 200. The serial number of the card 207) and position information are inquired (S316).

In the plurality of mobile phones 200 constituting the sensor network, the main control unit 201 reads the manufacturing number from the UIM card 207, calculates the position information by the GPS signal, and then the sensor network communication module 208, the sensor The following information 1) to 5) is transmitted via the network communication module 508 (S317).
1) Identification number of mobile phone 200 (manufacture number of UIM card 207)
2) GPS location information 3) Location registration information (identification number of mobile phone control station 102 and mobile phone base station 103)
4) Number of adjacent mobile phones 200 (number of nodes directly linked)
5) Identification number of adjacent mobile phone 200 (manufacture number of UIM card 207)
Note that if the mobile phone 200 is not indoors capable of receiving the GPS satellite 700 signal and cannot calculate the GPS location information, the GPS location information is set to the null value “NULL-A”. Further, when the mobile phone base station 103 is out of the service area, that is, when communication is not possible via the mobile phone base station 103 due to a failure or the like, the location registration information has a null value “ Set to “NULL-B”.

  Subsequently, the main control unit 501 of the PND 500 counts the number of pieces of location registration information having a null value (NULL-B) among the identification information (manufacture number of the UIM card 207) acquired from the mobile phone 200 ( S318), the number of identification numbers of the mobile phone 200 is transmitted to the rescue team dynamic monitoring server 307 (S319). Then, the rescue team dynamic monitoring server 307 transmits the number of received mobile phones 200 to the disaster victim dynamic monitoring server 306 (S320).

Finally, GIS data display on the display unit 304 will be described with reference to FIG.
The victim dynamic monitoring server 306 maps the number of identification numbers of the mobile phone 200 on the electronic map to the location of the service area where the location registration information has not been acquired, and updates the GIS data (S321a). Further, the created GIS data is transmitted to the control room fixed terminal 303 (S321b). The control room fixed terminal 303 displays the updated rough distribution status of the victims via the display unit 304 to the controller (S322).

  As described above, according to the present embodiment, immediately after the occurrence of a disaster such as an earthquake, the latest location registration information of the mobile phone 200 managed by the mobile phone operator is provided to the local government or the fire department or the like that directs the rescue operation. Thus, it is possible to grasp the rough distribution where the victim is located in a short time. In addition, multiple lines such as a wired system or a wireless system are provided between the communication system of the mobile phone carrier (mobile phone carrier network 190) and the communication system of the local government or fire department (firefighting / disaster prevention wireless network 300). By building multiple systems and selecting the line according to the disaster situation, even if one of the multiple lines becomes unusable due to a failure, information can be exchanged between the two, thereby increasing system availability. Become. In addition, a sensor network communication module 208 such as ZigBee (registered trademark) is built in the mobile phone 200 in advance, and similarly, a sensor network is constructed starting from the PND 500 including the sensor network communication module 508. -By examining the number of nodes in the network, the location within the service area covered by the mobile phone base station 103 due to the damage of the mobile phone control station 102 or the mobile phone base station 103 due to the influence of an earthquake, etc. Even when the registration information cannot be acquired, the number of mobile phones 200 (number of disaster victims) present in the service area can be grasped without taking time.

  In addition, it is possible to grasp the location of the mobile phone 200, that is, the distribution of the victims in more detail by sucking up the location information specified by the GPS function etc. possessed by each mobile phone 200 via the sensor network. Can do. By providing an interface for data transfer between the PND 500 and the business portable radio 400, the number of mobile phones 200 in the service area collected by the PND 500 and the positional information by GPS are used for the business portable. Since it can be transmitted to a command headquarters such as a local government or a fire department that directs a rescue operation via the wireless device 400, information with higher density than voice can be transmitted. Furthermore, even if there was an area where the information was missing from the location registration information provided by the mobile phone operator, it was missing by using the sensor network and the business radio system (firefighting / disaster prevention radio network 300). Information can be supplemented. Furthermore, the PND 500 calculates its own position by GPS or the like, and periodically sends its position information (the location of the rescue team) via the fire fighting / disaster prevention radio network 300 to the command headquarters of the fire fighting / disaster prevention radio network 300. To be notified. Upon receiving the notification, the command headquarters selects a rescue team in the vicinity of the area where information collection and relief activities are required, and transmits the destination information to the PND 500 of the selected rescue team through the fire fighting / disaster prevention radio network 300. Thus, the rescue team can be promptly guided to the area. In this way, by exchanging location information data via the fire fighting / disaster prevention wireless network 300, it is possible to appropriately guide and place a rescue team at a place where information collection and rescue activities are required compared to voice exchange. Becomes easy.

The summary of the present embodiment is summarized as follows.
The system of the present embodiment includes a mobile phone communication system including a mobile phone network monitoring server that configures a mobile phone communication network and monitors the communication network, and configures a business radio communication network and monitors the communication network. The present invention relates to a communication network system including a business wireless communication system including a business wireless network management server, wherein the mobile phone communication system and the business wireless communication system are connected to transmit and receive data. In this communication network system, the mobile phone network monitoring server specifies a service area of a mobile phone in which a failure has occurred, notifies the specified service area to the business radio network management server, and manages the business radio network management The server is under the management of the business radio network management server and identifies that the fault has occurred for a radio device having a PND and having a function capable of mutual communication with the mobile phone via a sensor network. The mobile phone is notified of the service area of the mobile phone, and the wireless device is located in the service area and the information acquired about the mobile phone constituting the sensor network via the sensor network is transmitted from the wireless device. get.
In addition, the business radio network management server is configured to obtain the service area in which the failure has occurred based on the information acquired from the wireless device and acquired in relation to the mobile phone constituting the sensor network in the service area in which the failure has occurred. The map information reflecting the information on the mobile phone is output to a predetermined display means.
In addition, the information acquired regarding the mobile phone configuring the sensor network includes location information obtained by the mobile phone based on the GPS function.
In addition, the information acquired regarding the mobile phone constituting the sensor network includes an identification number of the mobile phone number.
Further, when a disaster occurs, the mobile phone communication system notifies the business radio network management server of information related to the location registration information of the mobile phone in the management of the mobile phone communication system.
The mobile phone communication system and the commercial wireless communication system are connected by a plurality of types of communication lines.
Further, the service area where the failure has occurred is grasped in units of control stations or base stations of the mobile phone communication system.

  The invention has been described based on embodiments. This embodiment is an exemplification, and it will be understood by those skilled in the art that various modifications can be made to combinations of these components, and such modifications are also within the scope of the present invention.

It is the map which illustrated the area where the disaster prevention communication system based on embodiment is applied. It is a conceptual diagram of the victim distribution acquired by the sensor network in the area of the base station for mobile phones that is not operating according to the embodiment. It is a figure for demonstrating the utilization method of a sensor network based on embodiment. It is a figure which shows schematic structure of the disaster prevention communication system based on embodiment. It is a figure which shows schematic structure of the mobile telephone provider network based on Embodiment. It is a figure which shows schematic structure of the fire-fighting and disaster prevention wireless network based on embodiment. It is a functional block diagram which shows schematic structure of the mobile telephone based on Embodiment. It is a functional block diagram of the portable portable radio for business use and the PND connected thereto, according to the embodiment. It is the chart which showed the process at the time of the phase 1 which is normal time based on embodiment. It is a chart figure showing the 1st processing at the time of phase 2 which is after a disaster, such as an earthquake, concerning an embodiment occurs. It is a chart figure showing the 2nd processing at the time of phase 2 which is after the occurrence of disasters, such as an earthquake, concerning an embodiment. It is a chart figure showing the 3rd processing at the time of phase 2 which is after the occurrence of disasters, such as an earthquake, concerning an embodiment. It is the chart which showed the 1st process at the time of the phase 3 which is the time of the confirmation work of the disaster victim by a relief group based on embodiment. It is the chart which showed the 2nd process at the time of the phase 3 which is the time of the confirmation work of the disaster victim by the relief group based on embodiment. It is the chart which showed the 3rd process at the time of the phase 3 which is the time of the confirmation work of the disaster victim by the relief group based on embodiment. It is the chart which showed the 4th process at the time of the phase 3 which is the time of the confirmation work of the disaster victim by the relief group based on embodiment.

Explanation of symbols

10 disaster prevention communication system 102 mobile phone control station 103 mobile phone base station 104 location registration DB
190 Cellular phone carrier network 200 Cellular phone 202 Signal processing unit 207 UIM card 208 Sensor network communication module 209 GPS module 301 Business radio control station 302 Business radio base station 303 Control room fixed terminal 306 Disaster victim dynamic monitoring server 307 Rescue team Dynamic monitoring server 308 Resident information DB
309 Disaster victim dynamics information DB
310 Map information DB
311 Relief Team Dynamics Information DB
312 Satellite Radio Transmission Device 313 Terrestrial Radio Transmission Device 350 Disaster Countermeasure System 400 Commercial Portable Radio 402 Signal Processing Unit 500 PND
502 Signal processing unit 505 Built-in memory 506 Map storage device 507 GPS module 508 Sensor network communication module 600 Mobile phone carrier management system 605 Communication infrastructure monitoring server 606 Location registration history DB
607 Failure history DB

Claims (4)

A mobile phone communication system including a mobile phone network monitoring server that configures a mobile phone communication network and monitors the communication network, and a business radio network management server that configures a business radio communication network and monitors the communication network A communication network system comprising a business radio communication system, wherein the mobile phone communication system and the business radio communication system are connected to transmit and receive data;
The mobile phone network monitoring server specifies a service area of the base station when a failure occurs in a base station that constitutes a communication network of the mobile phone, and information on the specified service area is managed by the business radio network management Notify the server,
When the service wireless network management server receives the service area information from the mobile phone network monitoring server, the service wireless network management server is under the control of the service wireless network management server, has a PND, and is mutually connected to the mobile phone by a sensor network. Notifying the wireless device of the commercial wireless communication system having a communicable function of the mobile phone service area identified as having failed through the base station of the commercial wireless communication system and,
The wireless device is configured to acquire information related to a mobile phone that is located in the service area and configures the sensor network via the sensor network via the base station of the commercial wireless communication system. A communication network system characterized by transmitting to a network management server .   Transmitting the number of mobile phones in the specified service area of the base station in which the failure collected by the PND has occurred and position information by GPS to the command headquarters via the radio The communication network system according to claim 1.   The communication network system according to claim 1 or 2, wherein the number of mobile phones in the specified service area of the base station in which a failure occurs is mapped on an electronic map.   The communication network system according to any one of claims 1 to 3, wherein a plurality of wired or wireless multiple lines are constructed between the mobile phone communication system and the commercial wireless communication system.

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