JP6040785B2 - Transmission management device, transmission management method and program - Google Patents

Description

  The present invention relates to a transmission management apparatus, a transmission management method, and a program.

  In a remote conference system, a transmission terminal arranged in a conference room or the like captures a user who is a participant in a remote conference, collects user's remarks, etc., converts them into digital data, and transmits to the other party's transmission terminal Send to. The transmission terminal of the other party can create an environment close to an actual meeting by displaying the received image on a display such as a video screen in a conference room or outputting the received sound from a speaker.

  In such a remote conference system, a remote conference can be held between multiple sites by using a transmission management device that manages the connection status of each transmission terminal and a relay device that controls the distribution of image data or sound data between the transmission terminals. Realize.

  On the other hand, in order to prevent unauthorized operation by a third party when a portable device installed in a given place is illegally taken out by someone or where its location is unknown due to loss, There is a technology for stopping the function of a device.

  For example, Patent Document 1 discloses an image forming system that can change the function and security of an image forming apparatus in accordance with the installation location of the apparatus, either automatically or with a small number of work steps.

  When the transmission terminal becomes portable, the user can participate in the remote conference from any place. At this time, depending on the location where the transmission terminal is arranged, the contents of video and audio output from the transmission terminal may be unintentionally transmitted to the surroundings. In particular, if it is possible to connect to a remote conference that handles highly confidential information from a transmission terminal at an arbitrary location, there is a possibility of a security problem.

  Moreover, even if the existing technology is used, the connection cannot be limited based on the installation locations of two or more transmission terminals connected by remote conference.

  In view of such a problem, an object of the present invention is to make it possible to control connection to a remote conference according to the positions of a plurality of transmission terminals.

In order to solve the above problem, a transmission management apparatus according to an embodiment of the present invention
A transmission management device for managing a remote conference session executed by a plurality of transmission terminals,
An acquisition unit for acquiring position information of the transmission terminal;
A specifying unit for specifying a region to which the transmission terminal belongs using the position information;
A determination unit that determines whether or not the session can be connected based on information on a region to which the plurality of transmission terminals specified belong;
Have
If the determination unit determines that the session cannot be connected, the session is not connected.

Also, the transmission management method in one embodiment of the present invention is:
There is a transmission management method for managing a teleconference session executed by a plurality of transmission terminals.
Obtaining the transmission terminal position information; and
Using the location information to identify a region to which the transmission terminal belongs;
A determination step of determining whether or not the session can be connected based on information on a region to which the plurality of transmission terminals specified belong;
Have
If it is determined in the determination unit step that the session cannot be connected, the session is not connected.

  A program according to an embodiment of the present invention causes a computer to execute the above transmission management method.

  As described above, according to an embodiment of the present invention, it is possible to control connection to a remote conference by determining whether or not a remote conference session can be connected based on information on an area to which the transmission terminal belongs. it can.

It is a schematic diagram of the whole position management system concerning an embodiment of the present invention. It is an external appearance block diagram in case an electric equipment is a fluorescent lamp type LED lighting fixture. It is an image figure which shows the state which installed the communication terminal in the management target object. It is a hardware block diagram of the fixture main body in case an electric equipment is a LED lighting fixture. The hardware block diagram of the fluorescent lamp type LED lamp in case an electric equipment is an LED lighting fixture. It is a conceptual diagram of the positional information which a delivery apparatus delivers. It is a hardware block diagram of a communication terminal. It is a conceptual diagram of the format of the data of position information. It is a conceptual diagram which shows the data structure of the data containing position information. It is a hardware block diagram in case a managed object is a mobile telephone. It is a hardware block diagram of a gateway. It is a hardware block diagram of a positional information management system. It is a conceptual diagram of the management information which a positional information management system manages. It is a functional block diagram of a delivery apparatus and a communication terminal. It is a functional block diagram in case a managed object is a mobile telephone or a personal computer. It is a functional block diagram of a gateway and a location information management system. It is the sequence diagram which showed the process which builds a communication network of a ceiling. It is the sequence diagram which showed the process which delivers position information. It is the sequence diagram which showed the process which determines the delivery apparatus used as the transmission destination of a positional information while determining the positional information which a communication terminal uses. It is the flowchart which showed the process after a communication terminal receives position information until it memorize | stores. It is the image figure which showed the communication condition of a delivery apparatus and a communication terminal. It is the flowchart which showed the process which determines a transmission destination. It is the sequence diagram which showed the process which manages position information. It is the figure which showed the example of a screen in a positional information management system. It is the figure which showed the example of a screen in a positional information management system. 1 is a schematic diagram of an entire transmission system according to an embodiment of the present invention. It is the conceptual diagram which showed the state of transmission / reception of the image data in the transmission system which concerns on embodiment of this invention, sound data, and various management information. It is a conceptual diagram for demonstrating the image quality of the image data which concerns on embodiment of this invention. It is an external view of the transmission terminal which concerns on embodiment of this invention. It is a hardware block diagram of the transmission terminal which concerns on embodiment of this invention. It is a hardware block diagram of the transmission management apparatus, relay apparatus, or program provision apparatus which concerns on embodiment of this invention. It is a functional block diagram of the transmission terminal and transmission management apparatus which concern on embodiment of this invention. It is a conceptual diagram of the terminal authentication information managed by the transmission management apparatus which concerns on embodiment of this invention. It is a conceptual diagram of the terminal management information managed by the transmission management apparatus which concerns on embodiment of this invention. It is a conceptual diagram of the management information which a positional information management system manages. It is a conceptual diagram of the destination list information managed by the transmission management apparatus according to the embodiment of the present invention. It is a conceptual diagram of the area | region information managed by the transmission management apparatus which concerns on embodiment of this invention. It is a figure showing the example of the area | region and security level to which each transmission terminal belongs. It is a flowchart showing the security level storage process of the transmission management apparatus which concerns on embodiment of this invention. It is a sequence diagram which shows the preparatory step operation | movement of the transmission system which concerns on embodiment of this invention. It is a sequence diagram which shows the conference participation operation | movement of the transmission system which concerns on embodiment of this invention. It is a sequence diagram which shows the conference participation operation | movement of the transmission system which concerns on embodiment of this invention. It is a flowchart showing the connection decision | availability determination process of the transmission management apparatus which concerns on embodiment of this invention. It is a sequence diagram which shows the data transmission operation | movement of the transmission system which concerns on embodiment of this invention.

(Description of location management system)
First, a location management system for managing location information of a transmission terminal used by a user to participate in a remote conference will be described with reference to FIGS.

  The outline of the present embodiment will be described with reference to FIG. FIG. 1 is a schematic diagram of the entire location management system according to the embodiment of the present invention.

  As shown in FIG. 1, the position management system 1 of the present embodiment includes a plurality of distribution devices (3a, 3b, 3c, 3d, 3e, 3f, 3g, 3h) on the ceiling β side of the indoor α, It is constructed by a plurality of communication terminals (5a, 5b, 5c, 5d, 5e, 5f, 5g, 5h) on the floor side of the indoor α and the position information management system 9.

  In addition, each distribution device (3a, 3b, 3c, 3d, 3e, 3f, 3g, 3h) indicates a position where each distribution apparatus is installed (which means "installed position" after each installation). Position information (Xa, Xb, Xc, Xd, Xe, Xf, Xg, Xh) is stored, and each position information (Xa, Xb, Xc, Xd, Xe, Xf, Xg, Xh) is distributed. Further, each distribution device (3a, 3b, 3c, 3d, 3e, 3f, 3g, 3h) has device identification information (Ba, Bb, Bc, Bd, Be, Bf, Bg, Bh) for identifying each of them. Is remembered.

  Hereinafter, an arbitrary distribution device among the plurality of distribution devices is referred to as “distribution device 3”, and an arbitrary communication terminal among the plurality of communication terminals is referred to as “communication terminal 5”. In addition, arbitrary position information among a plurality of pieces of position information is indicated as “position information X”, and among the plurality of pieces of apparatus identification information, arbitrary apparatus identification information is indicated as “apparatus identification information B”. The device identification information B includes a MAC (Media Access Control) address.

  On the other hand, each communication terminal (5a, 5b, 5c, 5d, 5e, 5f, 5g, 5h) has terminal identification information (Aa, Ab, Ac, Ad, Ae, Af, Ag, Ah) for identifying each communication terminal. Is remembered. Note that arbitrary terminal identification information among a plurality of terminal identification information is indicated as “terminal identification information A”. The terminal identification information A includes a MAC address. When each communication terminal 5 receives the position information X from the distribution device 3, it transmits the position information X together with its own terminal identification information A to the distribution device 3.

  In addition, each distribution device 3 is built in an electrical device (2a, 2b, 2c, 2d, 2e, 2f, 2g, 2h) installed on the ceiling β of the indoor α, or attached to each of these external devices. ing. Hereinafter, an arbitrary electric device among the plurality of electric devices is referred to as “electric device 2”.

  Each electric device 2 supplies power to each distribution device 3. Among these, the electric equipment 2a is a fluorescent lamp type LED (Light Emitting Diode) lighting fixture. The electric device 2b is a ventilation fan. The electric device 2c is an access point for a wireless local area network (LAN). The electric device 2d is a speaker. The electric device 2e is an emergency light. The electric device 2f is a fire alarm or a smoke alarm. The electric device 2g is a surveillance camera. The electric device 2h is an air conditioner.

  Each electrical device 2 may be other than the one shown in FIG. 1 as long as it can supply power to each distribution device 3. For example, in addition to the example of the electric device 2, a general fluorescent or incandescent lighting fixture that is not an LED, a security sensor that detects an intruder from the outside, and the like can be given.

  On the other hand, each communication terminal 5 is attached to the outside of the management object (4a, 4b, 4c, 4d, 4e) whose position is managed by the position information management system 9, respectively.

  Among these, the management target 4a is a bag. The management object 4b is a table. The managed object 4c is a projector. The managed object 4d is a video conference terminal. The management target 4e is an MFP (Multi Function Product) including a copy function. The management object 4f is a broom.

  Moreover, since the management target 4g is a personal computer and the function of the communication terminal 5 is installed in the personal computer, it is also the communication terminal 5g in this case. Furthermore, the management target 4h is a mobile phone such as a smartphone, and since the function of the communication terminal 5 is installed in the mobile phone, it is also the communication terminal 5h in this case. Hereinafter, an arbitrary management object among the plurality of management objects will be referred to as “management object 4”.

  Further, each management object 4 may be other than the object shown in FIG. For example, as other examples of the management object 4, a facsimile machine, a scanner, a printer, a copier, an electronic blackboard, an air cleaner, a shredder, a vending machine, a wristwatch, a camera, a game machine, a wheelchair, an endoscope, etc. Medical equipment.

  Next, an outline of an example of a location information management method using the location management system 1 will be described. In the present embodiment, for example, the distribution device 3a installed on the ceiling β of the indoor α distributes position information Xa indicating the position where the distribution device 3a is installed by wireless communication. Thereby, the communication terminal 5a receives the position information Xa. Next, the communication terminal 5a transmits terminal identification information Aa and position information Xa for identifying the communication terminal 5a to the distribution device 3a by wireless communication. In this case, the communication terminal 5a sends back the position information Xa received from the distribution device 3a to the distribution device 3a.

  Thereby, the distribution apparatus 3a receives the terminal identification information Aa and the position information Xa. Next, the distribution device 3a transmits the terminal identification information Aa and the position information Xa to the gateway 7 by wireless communication. Then, the gateway 7 transmits the terminal identification information Aa and the position information Xa to the position information management system 9 via the LAN 8e. In the position information management system 9, by managing the terminal identification information Aa and the position information Xa, the administrator of the position information management system 9 can grasp the position of the communication terminal 5a (managed object 4a) in the indoor α. it can.

  In addition, as shown in FIG. 1, communication terminals (5g, 5h) among the communication terminals 5 are radio signals (time information, orbit information, etc.) from a GPS (Global Positioning System) satellite 999 in the outdoor γ. And the position on the earth can be calculated. Then, the communication terminals (5g, 5h) use a mobile communication system such as 3G (3rd Generation), 4G (4th generation), etc. to make a base station 8a, a mobile communication network 8b, a gateway 8c, the Internet 8d, and a LAN 8e. The terminal identification information (Ag, Ah) and the position information (Xg, Xh) for identifying each of the communication terminals (5g, 5h) can be transmitted to the position information management system 9 via.

  A communication network 8 is constructed by the base station 8a, the mobile communication network 8b, the gateway 8c, the Internet 8d, the LAN 8e, and the gateway 7. In addition, in order to measure the latitude and longitude on the earth, at least three GPS satellites are required (four are required when the altitude is included). Show.

  Next, as an example of the electric device 2, an external configuration of the electric device 2a as a fluorescent lamp type LED lighting apparatus will be described with reference to FIG. In addition, FIG. 2 is an external appearance block diagram in case an electric equipment is a fluorescent lamp type LED lighting fixture.

  As shown in FIG. 2, the electric apparatus 2a as a fluorescent lamp type LED lighting fixture is a straight tube type lamp, and the apparatus main body 120 attached to the ceiling β of the indoor α shown in FIG. The LED lamp 130 is attached to the apparatus main body 120.

  A socket 121a and a socket 121b are provided at both ends of the apparatus main body 120, respectively. Among these, the socket 121a has power supply terminals (124a1, 124a2) for supplying power to the LED lamp 130. The socket 121b also has power supply terminals (124b1, 124b2) for supplying power to the LED lamp 130. As a result, the apparatus main body 120 can supply power from the power supply 1000 described later to the LED lamp 130.

  On the other hand, the LED lamp 130 includes a translucent cover 131, bases (132 a and 132 b) provided at both ends of the translucent cover 131, and a distribution device 3 a inside the translucent cover 131. Among these, the translucent cover 131 is formed, for example with resin materials, such as an acrylic resin, and is provided so that an internal light source may be covered.

  Further, the base 132a is provided with terminal pins (152a1, 152a2) connected to the power supply terminals (124a1, 124a2) of the socket 121a, respectively. The base 132b is provided with terminal pins (152b1, 152b2) connected to the power supply terminals (124b1, 124b2) of the socket 121b, respectively. Then, the LED lamp 130 is mounted on the apparatus main body 120, so that each terminal pin (152a1, 152a2, 152b1, 152b2) from the apparatus main body 120 via each power supply terminal (124a1, 124a2, 124b1, 124b2). Electric power can be supplied. Thereby, the LED lamp 130 irradiates light to the outside through the translucent cover 131. Further, the distribution device 3a operates with power supplied from the device main body 120.

  Next, a state in which the communication terminal 5b is placed on the upper surface of the management target 4b as a table will be described as an example of the management target 4 with reference to FIG. FIG. 3 is an image diagram illustrating a state in which a communication terminal is installed on the management target.

  As shown in FIG. 3, the communication terminal 5b is attached to the upper surface of the management object 4b. For example, the communication terminal 5b can be attached to the management object 4b by double-sided tape, but it may be simply placed on the management object 4c.

  Subsequently, a hardware configuration in the case where the electric apparatus is an LED lighting apparatus will be described with reference to FIGS. 4 and 5. FIG. 4 is a hardware configuration diagram of the fixture body when the electrical device is an LED lighting fixture. FIG. 5 is a hardware configuration diagram of a fluorescent lamp type LED lamp when the electric device is an LED lighting apparatus.

  As shown in FIG. 4, the apparatus main body 120 is mainly configured by a ballast 122, lead wires (123a, 123b), and power supply terminals (124a1, 124a2, 124b1, 124b2).

  Among these, the ballast 122 controls the current supplied from the external power supply 1000. The ballast 122 and the power supply terminals (124a1, 124a2, 124b1, 124b2) are electrically connected by lead wires (123a, 123b). Accordingly, stable power can be supplied from the ballast 122 to the power supply terminals (124a1, 124a2, 124b1, 124b2) via the lead wires (123a, 123b).

  As shown in FIG. 5, the LED lamp 130 mainly includes a power control unit 140, lead wires (151a, 151b), terminal pins (152a1, 152a2, 152b1, 152b2), lead wires 153, leads. It is comprised by the wire | line 154, the lead wire 155, and the delivery apparatus 3a. Among these, the power supply control unit 140 controls a current output from the power supply 1000 and is mainly configured by a current monitoring circuit 141 and a smoothing circuit 142. The current monitoring circuit 141 receives the current output from the power supply 1000 and rectifies it. The smoothing circuit 142 smoothes the current rectified by the current monitoring circuit 141, and supplies power to each terminal pin (152a1, 152a2, 152b1, 152b2) via the lead wires (151a, 151b).

  Further, the power supply control unit 140 and the terminal pins (152a1, 152a2, 152b1, 152b2) are electrically connected by lead wires (151a, 151b). The power control unit 140 and the distribution device 3a are electrically connected by a lead wire 154. Note that only one LED 160 is shown in FIG. 5 because of the area of the paper surface, but a plurality of LEDs are actually attached. Moreover, the structure shown in FIG. 5 is the same as that of a general LED lamp except for the distribution device 3a.

  Next, the distribution device 3a will be described. The distribution device 3a includes a voltage converter 100, a lead wire 155, a control unit 11, a position information distribution unit 12, and a wireless communication unit 13. The voltage converter 100 is electrically connected to the control unit 11, the position information distribution unit 12, and the wireless communication unit 13 via the lead wire 155.

  Among these, the voltage converter 100 converts the voltage of the electric power supplied from the power supply control unit 140 into a driving voltage of the distribution device 3 a and supplies the converted voltage to the control unit 11, the position information distribution unit 12, and the wireless communication unit 13. It is an electronic component.

  The control unit 11 includes a CPU (Central Processing Unit) 101 that controls the operation of the entire control unit 11, a ROM (Read Only Memory) 102 that stores basic input / output programs, and a RAM (Random) that is used as a work area for the CPU 101. Access Memory) 103, I / F (108a, 108b) for transmitting / receiving signals to / from the position information distribution unit 12 and the wireless communication unit 13, and an address bus, a data bus, etc. for electrically connecting the above units A bus line 109 is provided.

  The position information distribution unit 12 includes a CPU 201 that controls the operation of the entire position information distribution unit 12, a ROM 202 that stores basic input / output programs and position information Xa, a communication circuit 204 that distributes the position information Xa, an antenna 204a, and a control unit. 11, an I / F 208 for transmitting and receiving signals to and from the bus, and a bus line 209 such as an address bus and a data bus for electrically connecting the above-described units.

  Among these, the communication circuit 204 uses IMES which is one of indoor positioning techniques called indoor GPS, and distributes the positional information Xa by the antenna 204a. In FIG. 1, the reachable range (distributable range) of the position information X is virtually represented by a broken line. In the IMES of this embodiment, when the ceiling height of the indoor α is about 3 m, the transmission output is set so that the radius of the reachable virtual circle of the position information X represented on the floor of the indoor α is about 5 m. Is done. However, if this transmission output setting is changed, it can be made smaller than 5 m, and can be made larger.

  The position information Xa indicates the position where the electric device 2a, which is a fluorescent lamp type LED lighting apparatus, is installed, and includes items of floor number, latitude, longitude, and building number as shown in FIG. FIG. 6 is a conceptual diagram of position information distributed by the distribution apparatus.

  Of these, the number of floors represents the number of floors of the building in which the electrical equipment 2a is installed. The latitude and longitude represent the latitude and longitude of the position where the electric device 2a is installed. The building number represents the building number of the building where the electrical equipment 2a is installed. In the example shown in FIG. 6, it is shown that the electrical equipment 2a is installed on the 16th floor of a building C, at a latitude of 35.459555 degrees north latitude and 139.387110 degrees longitude longitude. Has been. The latitude may be represented by the south latitude and the longitude may be represented by the west longitude.

  Returning to FIG. 5, the wireless communication unit 13 includes a CPU 301 that controls the operation of the entire wireless communication unit 13, a ROM 302 that stores basic input / output programs and device identification information Ba, and a RAM 303 that is used as a work area for the CPU 301. The communication circuit 304 and the antenna 304a that receive the position information Xa and the terminal identification information Aa and transmit them to the gateway 7, the I / F 308 that transmits and receives signals to and from the control unit 11, and the addresses for electrically connecting the above-described units A bus line 309 such as a bus or a data bus is provided.

  The wireless communication unit 13 transmits and receives data using the 920 MHz band. Since the radio wave reachability of the 920 MHz band is high, data can be transmitted from the distribution device 3a to the gateway 7 even when a pillar or wall of a building exists between the distribution device 3a and the gateway 7. There is an effect that can be done.

  Further, the communication circuit 304 uses at least the physical layer (layer) standard among the IEEE802.15.4 standard architecture model, and transmits and receives data by the antenna 304a. In this case, a MAC address can be used as the device identification information B for identifying the distribution device 3 (wireless communication unit 13).

  Note that ZigBee (registered trademark) that employs the physical layer and the MAC layer in the architecture model of the IEEE802.15.4 standard may be used. In this case, the distribution device 3 uses the 800 MHz band, the 900 MHz band, or the 2.4 GHz band according to the usage region such as Japan, the United States, and Europe, and passes through the other distribution devices 3 adjacent to the gateway 7. Can send data to. If multi-hop communication that transmits data via another distribution device 3 is used in this way, the wireless communication unit 13 of each distribution device 3 takes time for the routing process, but data is transmitted to the nearest distribution device 3. Therefore, there is an advantage that it can be driven with power saving.

  Further, the position information Xa may be stored in the storage unit 29 by the manufacturer before the delivery apparatus 3a is shipped from the factory, or when the electric device 2a is installed on the ceiling β after the delivery apparatus 3a is shipped from the factory. May be stored. Further, the positional information Xa is received by the communication circuit 304 of the wireless communication unit 13 from an external device such as the positional information management system 9 by wireless communication via the gateway 7, and the positional information distribution unit via the control unit 11. It may be stored in the 12 ROMs 202.

  Next, the hardware configuration of the communication terminal 5 will be described with reference to FIG. FIG. 7 is a hardware configuration diagram of the communication terminal.

  As shown in FIG. 7, the communication terminal 5 includes a control unit 14 and a wireless communication unit 15.

  Among them, the control unit 14 includes a CPU 401 that controls the operation of the entire control unit 14, a ROM 402 that stores basic input / output programs, a RAM 403 that is used as a work area of the CPU 401, a communication circuit 404 that receives position information X, and an antenna 404a. , An acceleration sensor 405 that detects acceleration, an I / F 408 that transmits and receives signals to and from the wireless communication unit 15, and a bus line 409 such as an address bus and a data bus for electrically connecting the respective units. The control unit 14 is also provided with a button battery 406 and is driven by the button battery 406. In the present embodiment, the case where the button battery 406 is used will be described. However, the battery is not limited to the button type, and may be a dry battery such as AA, AAA, or a battery dedicated to the communication terminal 5.

  The communication circuit 404 receives the position information X distributed using IMES by the antenna 404a. Further, the control unit 14 supplies power of the button battery 406 to the wireless communication unit 15 via the connector 409a. Furthermore, the control unit 14 transmits and receives data (signals) to and from the wireless communication unit 15 via the connector 409b from the I / F 408.

  The acceleration sensor 405 detects a change in acceleration of the communication terminal 5. The change in acceleration is detected, for example, when the communication terminal 5 starts moving, when the communication terminal 5 stops moving, or when the communication terminal 5 tilts. When the process of the CPU 401 is stopped, when the acceleration sensor 405 detects a change in acceleration, the CPU 401 transmits a signal for starting the process to the CPU 401. As a result, the CPU 401 starts its own process and transmits a signal for starting the process to the communication circuit 404. Therefore, when the position information X is distributed from the distribution device 3, the communication circuit 404 of the communication terminal 5 can start receiving the position information X via the antenna 404a.

  On the other hand, the wireless communication unit 15 basically has the same configuration as the wireless communication unit 13 and transmits / receives data to / from the wireless communication unit 13 of the distribution device 3 using the same band as the wireless communication unit 13. Can do. As shown in FIG. 7, the wireless communication unit 15 is used as a work area for the CPU 501 that controls the overall operation of the wireless communication unit 15, the ROM 502 that stores the basic input / output program and the terminal identification information A, and the CPU 501. RAM 503, communication circuit 504 and antenna 504a for transmitting position information X and terminal identification information A, I / F 508 for transmitting and receiving signals to and from the control unit 14, and an address bus for electrically connecting the above units, A bus line 509 such as a data bus is provided. Note that the radio communication unit 15 may also use ZigBee.

  Further, the communication circuit 504 acquires the position information X stored in the RAM 403 of the control unit 14 via the connector 409b in accordance with a command from the CPU 501. Further, the communication circuit 504 reads the terminal identification information A stored in the ROM 502 and transmits it together with the acquired position information X to the distribution device 3 via the antenna 504a.

  Further, the data of the position information X transmitted by the communication circuit 504 has a format as shown in FIG. FIG. 8 is a conceptual diagram of a format of position information data. In the example of FIG. 8, the floor, latitude, longitude, and building number fields are represented by 9 bits, 21 bits, 21 bits, and 8 bits, respectively, and the representation format of each field conforms to the IMES standard. Actually, in addition to this format, headers and checksum information defined by the communication method are added, and as shown in FIG. 9, the transmission destination, transmission source, and data contents (position information X, etc.) It is included. FIG. 9 is a conceptual diagram showing a data structure of data including position information.

  Next, a hardware configuration of a mobile phone that is the management target 4h (communication terminal 5h) will be described with reference to FIG. FIG. 10 is a hardware configuration diagram when the management target is a mobile phone.

  As shown in FIG. 10, the management object 4h (communication terminal 5h) includes a CPU 601 that controls the operation of the entire communication terminal 5h, a ROM (Read Only Memory) 602 that stores basic input / output programs, and a work of the CPU 601. A RAM 603 used as an area, an EEPROM (Electrically Erasable and Programmable ROM) 604 that reads and writes data according to the control of the CPU 601, and a CMOS (Complementary Metal Oxide Semiconductor) sensor 605 that captures an image of the subject and obtains image data under the control of the CPU 601. , An electronic magnetic compass for detecting geomagnetism, a gyrocompass, various acceleration / direction sensors 606 such as an acceleration sensor, and a media drive 608 for controlling reading / writing (storage) of data to / from a recording medium 607 such as a flash memory.Then, under the control of the media drive 608, the recording medium 607 in which the already recorded data is read or the data is newly written and stored is detachable.

  The EEPROM 604 stores an operating system (OS) executed by the CPU 601, other programs, and various data. The CMOS sensor 605 is a charge-coupled device that converts light into electric charges and digitizes the image of the subject. If the subject can be imaged, the CMOS sensor 605 is not limited to the CMOS sensor but is a CCD (Charge Coupled Device) sensor. May be.

  Furthermore, the management object 4h (communication terminal 5h) includes a voice input unit 611 that converts voice into a voice signal, a voice output unit 612 that converts voice signal into voice, an antenna 613a, and a wireless communication signal using the antenna 613a. , A communication unit 613 that communicates with the nearest base station 8a, a GPS reception unit 614 that receives a GPS signal from a GPS satellite 999, a display 615 such as a liquid crystal or organic EL that displays an image of a subject, various icons, and the like, and this display Touch panel 616 that is mounted on 615 and configured by a pressure-sensitive or electrostatic panel and detects a touch position on display 615 by touching with a finger, a touch pen, or the like, and an address for electrically connecting the above-described units A bus line 610 such as a bus or a data bus is provided. The management object 4h (communication terminal 5h) is also provided with a dedicated battery 617, and is driven by the battery 617. Note that the voice input unit 611 includes a microphone that inputs voice, and the voice output unit 612 includes a speaker that outputs voice.

  Further, the GPS receiving unit 614 of the management object 4h (communication terminal 5h) is the same as the GPS receiving unit of a general mobile phone. However, the firmware in the program stored in the ROM 602 is finely adjusted, and data can be received seamlessly from the indoor α distribution device 3 and the outdoor γ GPS satellite. The acceleration / orientation sensor 606 functions including the processing of the acceleration sensor 605 in FIG.

  The hardware configuration of the personal computer that is the management object 4g (communication terminal 5g) is basically the same as that of the location information management system 9 shown in FIG. However, in the case of a personal computer that is the management target 4g (communication terminal 5g), a GPS antenna is connected to an external device I / F 916 such as a USB (Universal Serial Bus) connector shown in FIG. Some personal computers are equipped with a GPS antenna. In this case, it is not necessary to connect the GPS antenna to the external device I / F 916.

  Next, the hardware configuration of the gateway 7 will be described with reference to FIG. FIG. 11 is a hardware configuration diagram of the gateway.

  As illustrated in FIG. 11, the gateway 7 includes a wireless communication unit 17 and a wired communication unit 18.

  Among these, the wireless communication unit 17 has basically the same configuration as the wireless communication unit 13 and transmits / receives data to / from the wireless communication unit 13 of the distribution device 3 using the same band as the wireless communication unit 13. be able to. As shown in FIG. 11, the wireless communication unit 17 is used as a work area for the CPU 701 that controls the overall operation of the wireless communication unit 17, the ROM 702 that stores basic input / output programs and device identification information C, and the CPU 701. RAM 703, communication circuit 704 for transmitting position information X and the like, antenna 704a, I / F 708 for transmitting / receiving signals to / from wired communication unit 18, and buses such as an address bus and a data bus for electrically connecting the above-described units A line 709 is provided. The wireless communication unit 17 transmits and receives signals to and from the wired communication unit 18 via the connector 709a from the I / F 708.

  Note that the radio communication unit 17 may also use ZigBee. The device identification information C is unique information for identifying the gateway 7 (wireless communication unit 17). Examples of the device identification information C include a MAC address.

  On the other hand, as shown in FIG. 11, the wired communication unit 18 is used as a work area for the CPU 801 that controls the operation of the entire wired communication unit 18, the ROM 802 that stores basic input / output programs and device identification information D, and the CPU 801. RAM 803, Ethernet controller 805, I / F 808 a that transmits / receives signals to / from the wireless communication unit 17, I / F 808 b that transmits / receives data (signals) to / from the LAN 8 e via the cable 809, and the above components are electrically connected For this purpose, a bus line 809 such as an address bus or a data bus is provided.

  Here, the CPU 801 and the Ethernet controller 805 convert the communication method (communication protocol) compliant with IEEE802.15.4 to the communication method (communication protocol) compliant with IEEE802.3, and are sent from the distribution device 3. Various data (information) is controlled so that Ethernet (registered trademark) packet communication can be performed.

  Furthermore, the device identification information D is unique information for identifying the gateway 7 (wired communication unit 18). Examples of the device identification information D include an IP (Internet Protocol Address) address. Note that the ROM 802 also stores a MAC address, but a description thereof is omitted to simplify the communication with the location information management system 9.

  Next, the hardware configuration of the location information management system 9 will be described with reference to FIG. FIG. 12 is a hardware configuration diagram of the location information management system.

  The location information management system 9 is configured by a computer. The location information management system 9 is used as a work area for the CPU 901 that controls the overall operation of the location information management system 9, a ROM 902 that stores programs used to drive the CPU 901 such as an IPL (Initial Program Loader), and the CPU 901. RAM 903, HD 904 for storing various data such as programs for the position information management system 9 and system identification information E, HDD (Hard Disk Drive) 905 for controlling reading or writing of various data to the HD 904 according to the control of the CPU 901, flash memory A media drive 907 for controlling reading or writing (storage) of data with respect to the recording medium 906, a display 908 for displaying various information such as a cursor, a menu, a window, a character, or an image, a communication network Network I / F 909 for data communication using a computer, a keyboard 911 having a plurality of keys for inputting characters, numerical values, various instructions, selection and execution of various instructions, selection of a processing target, movement of a cursor A CD-ROM drive 914 that controls reading or writing of various data to a CD-ROM (Compact Disc Read Only Memory) 913 as an example of a removable recording medium, a communication circuit 915 that performs wireless communication, and the like An antenna 915a, an external device I / F 916 for connecting an external device, and a bus line 910 such as an address bus and a data bus for electrically connecting the above components are provided.

  Further, the system identification information E is unique information for identifying the position information management system 9. An example of the system identification information E is an IP address. The ROM 902 also stores a MAC address, but a description thereof will be omitted to simplify the communication with the gateway 7.

  Further, the HD 904 manages management information F as shown in FIG. 13 and layout information G such as a specific floor as shown in FIG. FIG. 13 is a conceptual diagram of management information managed by the location information management system.

  As illustrated in FIG. 13, the management information F is information in which terminal identification information A, a device name, an owner name (administrator name), position information X, and various types of information such as reception date and time are associated.

  Among these, the terminal identification information A is information for identifying the communication terminal 5 as described above. The device name is the name of the management object 4 or the name of the communication terminal 5. The owner name (manager name) is the name of the owner or manager of the communication terminal 5. The position information X is information shown in FIG. The reception date and time is the reception date and time when the position information management system 9 receives the position information X and the like from the gateway 7.

  The terminal identification information A, the device name, and the owner name (administrator name) are managed in advance in association with the location information management system 9. The location information management system 9 receives the location information X and the terminal identification information A from the gateway 7, thereby adding the location information X and the reception date and time to the record portion including the same terminal identification information A in the management information F.

  Further, when the location information management system 9 has already managed the location information X and the reception date and time and newly received the location information X and the terminal identification information A from the gateway 7, the location information management system 9 already manages the location information. The information X and the reception date and time are overwritten.

  The position information management system 9 may create a new record and perform additional writing without overwriting the position information X and the reception date and time.

  Next, the functional configuration of the location management system 1 according to the present embodiment will be described with reference to FIGS. 14 to 16. When the functional configuration is described with reference to FIGS. 14 to 16, the relationship with the hardware configuration shown in FIGS. 5, 7, 10, 11, and 12 will be briefly described.

  FIG. 14 is a functional block diagram of the distribution device and the communication terminal. As illustrated in FIG. 14, the distribution device 3 includes a conversion unit 10, a distribution control unit 20, and a wireless communication control unit 30 as functions or means. Among these, the conversion part 10 is a function or means implement | achieved when the voltage converter 100 shown by FIG. 5 operate | moves.

  The distribution control unit 20 is a function or means realized by the operation of the control unit 11 and the position information distribution unit 12 illustrated in FIG. Furthermore, the wireless communication control unit 30 is a function or means realized by the operation of the control unit 11 and the wireless communication unit 13 illustrated in FIG.

  The distribution control unit 20 has a storage unit 29 constructed by the ROM 202 shown in FIG. The storage unit 29 stores the position information X described above. Further, the distribution control unit 20 includes a distribution unit 21, a communication unit 27, and a storage / reading unit 28.

  Among these, the distribution unit 21 is realized mainly by the processing of the CPU 201 and the communication circuit 204 illustrated in FIG. 5, and distributes the position information X within a distributable range.

  The communication unit 27 is mainly realized by the processing of the CPU (101, 201) shown in FIG. 5 and the I / F (108a, 208) and the bus (109, 209). Data (signal) communication with.

  The storage / reading unit 28 is realized by processing of the CPU (101, 201), stores various data in the storage unit 29, and reads out various data from the storage unit 29. For example, the storage / reading unit 28 stores and reads data of the position information X.

  Further, the wireless communication control unit 30 has a storage unit 39 constructed by the RAM 303 shown in FIG. The storage unit 39 stores the device identification information B described above.

  The transmission / reception unit 31 is realized mainly by the processing of the CPU 301 and the communication circuit 304 shown in FIG. 5, and transmits and receives various data to and from the communication terminal 5 or the gateway 7 by wireless communication.

  The communication unit 37 is realized mainly by the processing of the CPU (101, 301) and the I / F (108B, 308) and the bus (109, 309), and performs data (signal) communication with the distribution control unit 20. .

  The storage / reading unit 38 stores various data in the storage unit 39 and reads various data from the storage unit 39.

  Next, the functional configuration of the communication terminal 5 will be described.

  The communication terminal 5 includes a reception control unit 40 and a wireless communication control unit 50 as functions or means.

  The reception control unit 40 has a storage unit 49 constructed by the RAM 403 shown in FIG. The storage unit 49 can store the position information X distributed from the distribution device 3. Further, the reception control unit 40 includes a reception unit 41, a detection unit 42, a determination unit 43, a measurement unit 44, a communication unit 47, and a storage / readout unit 48.

  Among these, the receiving unit 41 is mainly realized by the processing of the CPU 401 and the communication circuit 404 illustrated in FIG. 7, and receives the position information X distributed from the distribution device 3. In addition, the receiving unit 41 may be able to receive the position information X or may not be able to receive the position information X.

  The detection unit 42 is realized mainly by the processing of the CPU 401 and the acceleration sensor 405 illustrated in FIG. 7, detects the movement (including tilt) of the communication terminal 5, and causes the reception unit 41 to start the processing. Note that the detection unit 42 may be realized by a motion sensor using inertial force or magnetism instead of the acceleration sensor 405.

  The determination unit 43 is realized mainly by the processing of the CPU 401 illustrated in FIG. 7, and determines whether or not the reception unit 41 has received at least one piece of position information X. Further, the determination unit 43 determines whether the reception unit 41 has received the respective position information X from the plurality of distribution devices 3. In this case, the position information X distributed from the same distribution device 3 is treated as one no matter how many times it is received within a predetermined time described later.

  The measurement unit 44 is mainly realized by the processing of the CPU 401 illustrated in FIG. 7, and when the determination unit 43 determines that each position information X has been received from the plurality of distribution devices 3, The signal intensity relating to each position information X is measured.

  The communication unit 47 is mainly realized by the processing of the CPU 401 shown in FIG. 7, the I / F 408 and the bus 409, and performs data (signal) communication with the wireless communication control unit 50.

  The storage / reading unit 48 is realized by processing of the CPU 401, stores various data in the storage unit 49, and reads various data from the storage unit 49. For example, the storage / extraction unit 48 stores and reads out the data of the position information X.

  The wireless communication control unit 50 includes a storage unit 59 constructed by the RAM 503 shown in FIG. The storage unit 59 stores the terminal identification information A described above. The wireless communication control unit 50 further includes a transmission / reception unit 1051, a determination unit 53, a measurement unit 54, a communication unit 57, and a storage / reading unit 58.

  The transmission / reception unit 1051 is realized mainly by the processing of the CPU 501 and the communication circuit 504 illustrated in FIG. 7, and transmits / receives various data to / from the distribution device 3 through wireless communication.

  The determination unit 53 is realized mainly by the processing of the CPU 501 illustrated in FIG. 7, and determines whether the reception unit 51 has received at least one device identification information B. Further, the determination unit 53 determines whether the reception unit 51 has received the respective device identification information B from the plurality of distribution devices 3. In this case, the device identification information B transmitted from the same distribution device 3 is treated as one no matter how many times it is received within a predetermined time described later.

  The measurement unit 54 is realized mainly by the processing of the CPU 501 shown in FIG. 7, and when the determination unit 53 determines that each device identification information B has been received from the plurality of distribution devices 3. Then, the signal intensity related to each device identification information B is measured.

  The communication unit 57 is realized mainly by the processing of the CPU 501 shown in FIG. 7, the I / F 508 and the bus 509, and performs data (signal) communication with the reception control unit 40.

  The storage / reading unit 58 is realized mainly by the processing of the CPU 501 shown in FIG. 7, stores various data in the storage unit 59, and reads out various data from the storage unit 59. For example, the storage / extraction unit 58 stores and reads data of the device identification information (A, B).

  Next, the functional configuration in the case of the management object (4g, 4h) will be described with reference to FIG. FIG. 15 is a functional block diagram when the management target is a mobile phone or a personal computer.

  As shown in FIG. 15, the management object (4g, 4h) is stored in the EEPROM 604 shown in FIG. 10 or the RAM 903 and HD (Hard Disk) 904 shown in FIG. A portion 69 is provided. Furthermore, the management object (4g, 4h) includes a receiving unit 61, a detecting unit 62, a determining unit 63, a measuring unit 64, a transmitting / receiving unit 65, a determining unit 66, a measuring unit 67, and a storage / reading unit 68. Yes.

  Among them, the receiving unit 61 mainly processes the CPU 601 and the GPS receiving unit 614 shown in FIG. 10 or the processing of the GPS antenna connected to the CPU 901 and the external device I / F 916 shown in FIG. And has the same function as the receiving unit 41.

  The detection unit 62 is realized mainly by the processing of the CPU 601 and the acceleration / direction sensor 606 shown in FIG. 10 or the processing of the acceleration sensor connected to the CPU 901 and the external device 1 / F 916 shown in FIG. And has the same function as the detection unit 42.

  The determination unit 63 is mainly realized by the processing of the CPU 601 illustrated in FIG. 10 or the CPU 901 illustrated in FIG. 12, and has the same function as the determination unit 43.

  The measurement unit 64 is mainly realized by the processing of the CPU 601 shown in FIG. 10 or the processing of the CPU 901 shown in FIG. 12, and has the same function as the measurement unit 44.

  The transmission / reception unit 65 is realized mainly by the processing of the CPU 601 and the communication unit 613 shown in FIG. 10 or the processing of the CPU 901 and the communication circuit 915 shown in FIG. 12, and has the same function as the transmission / reception unit 1051. Have.

  The determination unit 66 is realized mainly by the processing of the CPU 601 illustrated in FIG. 10 or the processing of the CPU 901 illustrated in FIG. 12, and has the same function as the determination unit 53.

  The measurement unit 67 is realized mainly by the processing of the CPU 601 shown in FIG. 10 or the processing of the CPU 901 shown in FIG. 12, and has the same function as the measurement unit 54.

  The storage / reading unit 68 is realized mainly by the processing of the CPU 601 shown in FIG. 10 or the processing of the CPU 901 shown in FIG. 12, and is similar to the storage / reading unit 48 or the storage / reading unit 58. It has a function.

  Next, the functional configuration of the gateway 7 will be described with reference to FIG. FIG. 16 is a functional block diagram of the gateway and location information management system.

  The gateway 7 has a wireless communication control unit 70 and a wired communication control unit 80 as functions or means.

  The wireless communication control unit 70 is realized by the processing of the wireless communication unit 17 illustrated in FIG. 11 and basically has the same function as the wireless communication control unit 30 of the distribution device 3.

  Specifically, the wireless communication control unit 70 has a storage unit 79 constructed by the RAM 703 shown in FIG. The storage unit 79 stores the device identification information C described above. The wireless communication control unit 70 includes a transmission / reception unit 71, a communication unit 77, and a storage / reading unit 78.

  Among these, the transmission / reception part 71 is mainly implement | achieved by the process of CPU701 and the communication circuit 704 shown by FIG. 11, and transmits / receives various data with the delivery apparatus 3 by radio | wireless communication.

  The communication unit 77 is realized mainly by the processing of the CPU 701, the I / F 708 and the bus 709, and performs data (signal) communication with the wired communication control unit 80.

  The storage / reading unit 78 is realized mainly by the processing of the CPU 801, stores various data in the storage unit 79, and reads out various data from the storage unit 79.

  The wired communication control unit 80 is realized by the processing of the wired communication unit 18 shown in FIG. The wired communication control unit 80 has a storage unit 89 constructed by the RAM 803 shown in FIG. The storage unit 89 stores the device identification information D described above. The wired communication control unit 80 further includes a transmission / reception unit 81, a conversion unit 82, a communication unit 87, and a storage / reading unit 88.

  Among them, the transmission / reception unit 81 is realized mainly by the processing of the CPU 801 and the I / F 808b shown in FIG. 11, and transmits / receives various data to / from the location information management system 9 by wired communication.

  The conversion unit 82 is realized mainly by the processing of the CPU 801 and the Ethernet controller 805 shown in FIG. 11, and converts various communication data ( Information) is controlled so that Ethernet packet communication is possible.

  The communication unit 87 is mainly realized by the processing of the CPU 801 and the I / F 808a and the bus 809, and performs data (signal) communication with the wireless communication control unit 70.

  The storage / reading unit 98 is realized mainly by the processing of the CPU 801, stores various data in the storage unit 89, and reads out various data from the storage unit 89.

  Next, the functional configuration of the location information management system 9 will be described with reference to FIG.

  The location information management system 9 has a storage unit 99 constructed by the RAM 903 and the HD 904 shown in FIG. The storage unit 99 stores the above-described system identification information E, management information F, and layout information G. The location information management system 9 includes a transmission / reception unit 91, an operation input reception unit 92, a search unit 93, a display control unit 94, and a storage / reading unit 98.

  Among them, the transmission / reception unit 91 is mainly realized by the processing of the CPU 901 shown in FIG. 12 and the network I / F 909 or the communication circuit 915, and transmits / receives various data to / from the gateway 7 by wired communication or wireless communication. Do. Further, the transmission / reception unit 91 transmits / receives various data via the communication network 8 from the communication terminal 5h in the outdoor γ.

  The operation input receiving unit 92 is realized mainly by the processing of the CPU 901, the keyboard 911, and the mouse 912, and receives various selections or inputs from the administrator.

  The search unit 93 is realized mainly by the processing of the CPU 901, and searches the management information F in the storage unit 99 via the storage / reading unit 98 based on the search condition received by the operation input receiving unit 92. Is output.

  The display control unit 94 is realized mainly by the processing of the CPU 901 and performs control for displaying various images, characters, and the like on the display 908.

  The storage / reading unit 98 is realized mainly by the processing of the CPU 901, stores various data in the storage unit 99, and reads various data from the storage unit 99.

  Subsequently, the operation of the present embodiment will be described with reference to FIGS. 17 and 25.

  First, a process for constructing a communication network on the ceiling β of the indoor α will be described with reference to FIG. Note that. FIG. 17 is a sequence diagram illustrating a process of constructing a ceiling communication network.

  First, when the user turns on the power of each electrical appliance 2 in the indoor α, the storage / readout unit 38 (see FIG. 14) in the wireless communication control unit 30 of each distribution device 3 reads each device identification information from each storage unit 39. B is read (step S1). Then, each transmitting / receiving unit 31 makes a participation request including its own device identification information B to the gateway 7 (step S2). Thereby, the transmission / reception unit 71 in the wireless communication control unit 70 of the gateway 7 receives the participation request.

  Next, the storage / reading unit 78 of the wireless communication control unit 70 reads the device identification information C from the storage unit 79 (step S3). And the transmission / reception part 71 performs the participation response containing apparatus identification information (B, C) with respect to the delivery apparatus 3 (step S4). Thereby, the transmission / reception unit 31 in the wireless communication control unit 30 of the distribution apparatus 3 receives the participation response. In this case, since the participation response includes the device identification information B transmitted in step S2, the wireless communication control unit 30 performs the reception process in step S4 as the process related to step S2. Do. Then, the storage / reading unit 38 stores the device identification information C in the storage unit 39 (step S5). Thus, the communication network between the distribution device 3 and the gateway 7 is constructed by storing the device identification information C of the gateway 7 on the distribution device 3 side.

  Next, a process of distributing position information from the distribution device 3 of the ceiling α of the indoor α shown in FIG. 1 to the floor will be described with reference to FIG. FIG. 18 is a sequence diagram showing a process for distributing position information. In FIG. 18, for the sake of simplicity, a case will be described in which a distribution system 6 constructed by two distribution devices (3a, 3b) is used. Here, the distribution apparatus 3a distributes the position information Xa, and the distribution apparatus 3b distributes the position information Xb. FIG. 18 illustrates a case where the communication terminal 5 exists within a range in which the distribution devices (3a, 3b) can distribute the position information (Xa, Xb).

  First, the storage / reading unit 28 in the distribution control unit 20 of the distribution apparatus 3a reads its own position information Xa from the storage unit 29 (step S23-1). And the delivery part 21 in the delivery control part 20 of the delivery apparatus 3a delivers the positional information Xa within the range which can be delivered (step S24-1). Similarly, the storage / reading unit 28 in the distribution control unit 20 of the distribution device 3b reads the position information Xb of itself from the storage unit 29 (step S23-2). And the delivery part 21 in the delivery control part 20 of the delivery apparatus 3b delivers the positional information Xb within the range which can be delivered (step S24-2). Even if the position information (Xa, Xb) is distributed, the communication terminal 5 cannot receive the position information (Xa, Xb) unless the receiving unit 41 is started.

  Next, a process of determining the position information X used by the communication terminal 5 and determining the distribution device 3 that is the transmission destination of the position information X will be described with reference to FIG. FIG. 19 is a sequence diagram illustrating processing for determining location information used by a communication terminal and determining a distribution device that is a destination of location information. FIG. 19 shows a case where the communication terminal 5 receives the position information Xa from the distribution device 3a, and transmits this position information Xa to the distribution device 3b instead of the transmission device 3a as the transmission source.

  First, as shown in FIG. 19, the storage / reading unit 48 in the reception control unit 40 of the communication terminal 5 performs the positional information Xa distributed from the distribution device 3a and the positional information Xb distributed from the distribution device 3b. Among them, the one having the highest signal strength when received by the communication terminal 5 is stored in the storage unit 49 (step S41). As a result, the position indicated by the stored position information X is managed by the position information management system 9 later as the position of the communication terminal 5.

  Here, the step S41 will be described in more detail with reference to FIG. FIG. 20 is a flowchart illustrating processing from when the communication terminal receives the position information until it is stored.

  First, the detection unit 42 in the reception control unit 40 of the communication terminal 5 continues to detect the start of movement of the communication terminal 5 (NO in steps S41-1 and S41-2). If the detection unit 42 detects the start of movement of the communication terminal 5 (YES in step S41-2), the detection unit 42 continues to detect the stop of movement of the communication terminal 5 (step S41-3). , S41-4 NO). More specifically, when the process of the CPU 401 shown in FIG. 7 is stopped, the acceleration sensor 405 starts moving the communication terminal 5 with respect to the CPU 401 based on detecting a change in acceleration. A signal indicating that the processing of the CPU 401 is to be started is transmitted. As a result, the CPU 401 starts its own processing. Then, the CPU 401 maintains the state where its own processing is started until it receives a signal from the acceleration sensor 405 indicating that the movement of the communication terminal 5 has stopped. Note that the movement of the communication terminal 5 in this case includes a case where the communication terminal 5 is tilted.

  Next, when the detection unit 42 detects the stop of the movement of the communication terminal 5 in step S41-4 (YES in step S41-4), the reception unit 41 is further distributed from the distribution device 3. The received position information X can be received (step S41-5). More specifically, when the CPU 401 shown in FIG. 7 receives a signal indicating that the movement of the communication terminal 5 has stopped from the acceleration sensor 405, the CPU 401 causes the communication circuit 404 to start processing of the communication circuit 404. Send a signal for. As a result, the communication circuit 404 starts its own processing. Here, when the position information (Xa, Xb) is distributed from each distribution device (3a, 3b), the communication circuit 404 in the control unit 14 of the communication terminal 5 receives the position information (Xa, Xb) via the antenna 404a. Reception of Xb) can be started.

  Next, the determination unit 43 determines whether or not at least one position information X has been received within a predetermined time (for example, within 5 seconds) after the reception unit 41 becomes ready to receive the position information X (for example, within 5 seconds). Step S41-6). Here, a case where two pieces of position information (Xa, Xb) are received within a predetermined time will be further described.

  In step S41-6, if the determination unit 43 determines that at least one piece of position information X has been received (YES), the determination unit 43 further determines whether a plurality of pieces of position information X have been received. Judgment is made (step S41-7).

  Next, in step S41-7, when it is determined that a plurality of pieces of position information X have been received (YES), the measurement unit 44 determines the signal intensity associated with each piece of position information X when received by the reception unit 41. Is measured (step S41-8). Here, the case where the signal intensity of the position information Xa is higher than the signal intensity of the position information Xb as a result of the measurement will be further described.

  Next, the storage / reading unit 48 stores the position information X having the highest signal intensity in the storage unit 49 by the measurement in step S41-8 (step S41-9). Here, the position information Xa is stored.

  On the other hand, when the determination unit 43 determines in step S41-6 that at least one position information X has not been received within a predetermined time (NO), the storage / reading unit 48 stores the storage unit 49 in the storage unit 49. Failure information indicating that reception has failed is stored (step S41-10).

  If the determination unit 43 determines in step S41-7 that a plurality of pieces of position information X have not been received within a predetermined time (NO), the storage / reading unit 48 receives only the received position information. X is stored (step S41-11).

  And after the process of said step S41-9, 10, 11, 11, the receiving part 41 will be in the state which cannot receive the positional infomation X by stopping a process (step S41-12). More specifically, the CPU 401 illustrated in FIG. 7 transmits a signal for stopping the processing of the communication circuit 404 to the communication circuit 404. As described above, since the process of receiving the position information X is performed only when the communication terminal 5 stops after moving, even if a battery with a small capacity such as the button battery 406 is used. Thus, the frequency of battery replacement can be reduced as much as possible, and it is possible to contribute to power saving (energy saving).

  In the above description, after the movement of the communication terminal 5 is started (YES in step S41-2), the receiving unit 41 can receive the position information X by stopping the movement of the communication terminal 5 (YES in step S41-4). It will be in a state (step S41-5). That is, both the start of movement and the stop of movement are triggers that enable the reception unit 41 to receive the position information X. However, it is not restricted to this, For example, the receiving part 41 may be in the state which can receive the positional information X by the start of the movement of the communication terminal 5 (YES of step S41-2). That is, the step S41-3, 4 may be omitted, and the start of movement may be a trigger for the reception unit 41 to be able to receive the position information X. Further, for example, the steps S41-1 and S41-2 may be omitted, and the stop of movement may be a trigger for the reception unit 41 to be able to receive the position information X.

  Subsequently, returning to FIG. 19, the communication unit 47 of the reception control unit 40 instructs the wireless communication control unit 50 to start the operation (step S42). Thereby, the communication part 57 of the wireless communication control part 50 starts the process shown below by receiving the command which starts operation | movement.

  First, the storage / reading unit 58 in the wireless communication control unit 50 of the communication terminal 5 reads out its own terminal identification information A from the storage unit 59 (step S43). Then, the transmission / reception unit 1051 makes a participation request including the terminal identification information A to the distribution devices (3a, 3b) (step S44). Thereby, the distribution apparatuses (3a, 3b) each accept a participation request from the communication terminal 5.

  Next, the storage / reading unit 38 in the wireless communication control unit 30 of the distribution device 3a reads its own device identification information Ba from the storage unit 39 (step S45-1). And the transmission / reception part 31 of the delivery apparatus 3a performs the participation response including the terminal identification information A and the apparatus identification information Ba with respect to the communication terminal 5 (step S46-1). Thereby, the transmission / reception unit 1051 in the wireless communication control unit 50 of the communication terminal 5 receives the participation response. In this case, since the participation response includes the terminal identification information A transmitted in step S44, the communication terminal 5 performs the reception process in step S46-1 as the process related to step S44. Do. Then, the storage / reading unit 58 in the wireless communication control unit 50 of the communication device 5 stores the device identification information Ba in the storage unit 59 (step S47-1).

  On the other hand, similarly on the distribution device 3b side, the storage / reading unit 38 in the wireless communication control unit 30 of the distribution device 3b reads out its own device identification information Bb from the storage unit 39 (step S45-2). Further, the transmission / reception unit 31 of the distribution device 3b makes a participation response including the terminal identification information A and the device identification information Bb to the communication terminal 5 (step S46-2). Thereby, the transmission / reception unit 1051 in the wireless communication control unit 50 of the communication terminal 5 receives the participation response. And the memory | storage / reading part 58 in the radio | wireless communication control part 50 of the communication apparatus 5 memorize | stores apparatus identification information Bb in the memory | storage part 59 (step S47-2).

  Next, the wireless communication control unit 50 performs a process of determining the distribution device 3 that is the transmission destination of the position information X received from the distribution device 3 and its own terminal identification information A (step S48). Here, the process of step S48 will be described in detail with reference to FIG. 22, but before that, the background for performing the process of step S48 will be described with reference to FIGS. 5, 14, and 21. FIG. 21 is an image diagram showing a communication status between the distribution apparatus and the communication terminal.

  As illustrated in FIG. 14, communication between the distribution control unit 20 of the distribution device 3 and the reception control unit 40 of the communication terminal 5 is performed by wireless communication between the wireless communication control unit 30 of the distribution device 3 and the communication terminal 5. It is independent of communication with the control unit 50. The reception control unit 40 receives the position information X from the distribution device 3 as a distribution source, while the wireless communication control unit 50 sends the position information X back to the distribution device 3 together with its own terminal identification information A.

  However, if the distribution control unit 20 and the wireless communication control unit 30 are to be provided in all the distribution devices 3, if the floor area of the indoor α is large, a large number of distribution devices 3 are installed. May be very high (Pattern 1).

  The distribution device 3a can distribute the position information Xa. However, since the wireless communication control unit 30 of the distribution device 3a is out of order, the terminal identification information A and the position information Xa can be received from the communication terminal 5. It may not be possible (Pattern 2).

  Further, when a plurality of distribution devices 3 are installed on the ceiling β, depending on the position of the communication terminal 5 in the indoor α, the distribution device 3a distributes more than the distribution control unit 20 (see step S24-2) of the distribution device 3b. Although the signal strength of the data of the position information X received from the control unit 20 (see step S24-1) is high, the radio of the distribution device 3b is more wireless than the radio communication control unit 30 (step S46-1) of the distribution device 3a. The signal strength of the participation response data received from the communication control unit 30 (step S46-2) may be high (pattern 3).

  In the case of each of the above patterns 1 to 3, as shown in FIG. 21, the communication terminal 5h receives the position information Xa from the distribution device 3a that is the distribution source, but as a transmission destination that is different from the distribution device 3a. The position information Xa is transmitted together with its own terminal identification information A to the distribution device 3b. Below, the example in the case where such a delivery source and a transmission destination differ is demonstrated using FIG.14 and FIG.20. FIG. 22 is a flowchart showing processing for determining a transmission destination.

  The determination unit 53 in the wireless communication control unit 50 of the communication terminal 5 shown in FIG. 14 is within a predetermined time (for example, after the transmission / reception unit 1051 makes a participation request to each distribution device (3a, 3b) in step S44). Within 5 seconds), it is determined whether at least one participation response has been received (step S48-1). That is, the determination unit 53 determines whether at least one device identification information B has been received within a predetermined time after the transmission of the terminal identification information A is started.

  Next, in step S48-1, when the determination unit 53 determines that at least one participation response has been received (YES), the determination unit 53 further determines whether a plurality of participation responses have been received. (Step S48-2). That is, the determination unit 53 determines whether a plurality of device identification information B has been received within a predetermined time after the transmission of the terminal identification information A is started.

  Next, when it is determined in step S48-2 that a plurality of participation responses have been received (YES), the measurement unit 54 measures the signal strength related to the participation response when received by the transmission / reception unit 1051. (Step S48-3). Here, in steps S46-1 and S46-2, the wireless communication control unit 50 of the communication terminal 5 receives the participation response from each distribution device (3a, 3b), and therefore executes the process of step S48-3. .

  Next, the case where the signal strength of the participation response from the distribution device 3b is higher than the signal strength of the participation response from the distribution device 3a as a result of the measurement by the process of step S48-3 will be further described. As shown in FIG. 22, the storage / read-out unit 58 includes the device identification information B (here, the signal strength measured in step S48-3) included in the participation response, which is the maximum signal strength. Then, the device identification information Bb) is stored in the storage unit 59 (step S48-4).

  If the determination unit 53 determines in step S48-1 that at least one participation response has not been received within a predetermined time (NO), the process of determining the transmission destination ends. If the determination unit 53 determines in step S48-2 that a plurality of participation responses have not been received (NO), the storage / readout unit 58 receives the only received participation response in the storage unit 59. Is stored (step S48-5).

  As described above, the distribution device 5 indicated by the device identification information B stored in the storage / reading unit 58 is determined as the transmission destination of the communication terminal 5.

  Then, after the processing of steps S48-4 and 5, the transmission / reception unit 1051 creates a data structure of information as shown in FIG. 9 for the transmission destination determined in step S48 (step S49). ). The data structure in this case includes the device identification information Bb of the distribution device 3b as the transmission destination, the terminal identification information Ah of the communication terminal 5h as the transmission source, and the data contents (here, the position of the distribution device 3a as the distribution source) Information Xa) is arranged in order.

  Next, the transmission / reception unit 1051 transmits the data structure information created in step S49 to the distribution device 3b (step S50). As a result, the wireless communication control unit 30 of the distribution device 3b receives the information transmitted from the communication terminal 5h.

  In the communication terminal 5h, the processing of the transmission / reception unit 1051, the determination unit 53, the measurement unit 54, the communication unit 57, and the storage / reading unit 58 of the wireless communication control unit 50 is stopped (step S51). As described above, when the transmission / reception unit 1051 finishes transmitting the information such as the position information X to the distribution device 3, the processing of each component of the wireless communication control unit 50 is stopped, thereby realizing energy saving. There is an effect that can be. Each component of the wireless communication control unit 50 can be restarted by receiving a new start command from the reception control unit 40 in step S42.

  Next, a process from when the information including the position information X is received by the distribution apparatus 3 until being managed as the management information F by the position information management system 9 will be described with reference to FIG. FIG. 23 is a sequence diagram showing processing for managing position information.

  As shown in FIG. 23, first, the wireless communication control unit 30 of the distribution apparatus 3b creates a data structure of information to be transmitted to the gateway 7 as in the process of step S49 (step S61). The data structure in this case includes the device identification information C of the gateway 7 that is the transmission destination, the device identification information Bb of the distribution device 3b that is the transmission source, and the data contents (position information Xa and position of the distribution device 3a that is the distribution source) The terminal identification information A) of the communication terminal 5 that is the transmission source of the information Xa is arranged in order.

  Next, the transmission / reception unit 31 in the wireless communication control unit 30 of the distribution device 3b transmits the data structure information created in step S61 to the gateway 7 (step S62). Thereby, the transmission / reception unit 71 in the wireless communication control unit 70 of the gateway 7 receives the information transmitted from the distribution device 3b.

  Next, the communication unit 77 of the wireless communication control unit 70 transfers the information received in step S62 to the communication unit 87 of the gateway 7 (step S63). Thereby, the wired communication control unit 80 receives the information transferred from the wireless communication control unit 70.

  Next, the conversion unit 82 of the wired communication control unit 80 converts the communication method compliant with IEEE802.15.4 into a communication method compliant with IEEE802.3, and converts the information sent from the distribution device 3b to the Ethernet. To enable packet communication. And the transmission / reception part 81 of the wired communication control part 80 produces the data structure of the information transmitted to the positional infomation management system 9 like the process of said step S61 (step S65). The data structure in this case is the system identification information E of the location information management system 9 that is the transmission destination, the device identification information D of the gateway 7 that is the transmission source, and the data content (position information Xa of the distribution device 3a that is the distribution source). In addition, the terminal identification information A) of the communication terminal 5 that is the transmission source of the position information Xa is sequentially arranged.

  Next, the transmission / reception unit 81 in the wired communication control unit 80 of the gateway 7 transmits information on the data structure created in step S65 to the position information management system 9 (step S66). As a result, the transmission / reception unit 91 of the location information management system 9 receives the information transmitted from the gateway 7.

  Next, the storage / reading unit 98 of the positional information management system 9 associates the terminal identification information A stored in advance in the storage unit 99 with the information on the reception date and time when the positional information X is received and the positional information Xa. By storing as management information F as shown in FIG. 13, management processing of position information is performed (step S67).

  As described above, the management of the management information F by the location information management system 9 enables the administrator of the location information management system 9 to perform a search as shown in FIGS. 24 and 25 are diagrams showing examples of screens in the position information management system.

  For example, when the administrator operates the keyboard 911 and the mouse 912 shown in FIG. 12, the operation input receiving unit 92 receives the operation input, and the display control unit 94 receives the management information F via the storage / reading unit 98. Reading and displaying a search screen as shown in FIG. 24 on the display 908. On this search screen, a search list in which device names are shown for each owner name (or administrator name) is displayed. A check box is displayed on the right side of the device name. Further, a “search execution” button for executing a search is displayed at the lower right of the search list. The search screen shown in FIG. 24 shows a case where, for example, the position of the device “UCS P3000” owned by the owner “Sales Division 1” is searched.

  Then, when the administrator operates the keyboard 911, the mouse 912, and the like to add a check mark to the check box in the device name of the device (management target object 4) whose position is to be known, the operation input receiving unit 92 inputs the check. Accept. Then, after checking the checkboxes in the device names of all the devices for which the administrator wants to know the location and pressing the “Search Execution” button, the operation input receiving unit 92 receives the search execution, and the search unit 93 By searching the management information F stored in the storage unit 99 based on the device name with the check mark, a part of the management information F including the corresponding position information X and the position information X Layout information G indicating a floor including the position is extracted.

  Then, the display control unit 94 displays a search result screen as shown in FIG. 25 on the display 908 based on the management information F and the layout information G. In this search result screen, a layout diagram of the floor “Building A 4th floor” where the device “UCS P3000” is located, position information X in the management information F, and information on the reception date and time are shown. As a result, the administrator can visually grasp the position of the management object 4 (communication terminal 5).

  As described above, according to the present embodiment, the distribution device 3 includes the transmission / reception unit 31 as well as the distribution unit 21. That is, the communication terminal 5 existing within the range where the position information X distributed from the distribution device 3 arrives only needs to transmit the position information X and the terminal identification information A to the distribution device 3 within this range. Only minimal power consumption is required. Therefore, there is an effect that the distribution device can contribute to power saving of the communication terminal.

  In addition, since the process of receiving the position information X is started only when the communication terminal 5 stops after moving, it can contribute to power saving (energy saving) by suppressing the consumption of the battery capacity. There is an effect. Furthermore, when the transmission / reception unit 1051 finishes transmitting information such as the position information X to the distribution device 3, the processing of each component of the wireless communication control unit 50 is stopped, thereby realizing power saving. There is an effect that can be. By contributing to power saving, the frequency of battery replacement can be reduced as much as possible even when a battery with a small capacity such as the button battery 406 is used. There is also an effect that can be done.

  Further, as shown in FIG. 21, the distribution device 3b can receive the position information Xa and the terminal identification information A from the communication terminal 5 in place of the distribution device 3a. The effect that it can suppress can be produced (corresponding to the above pattern 1). Even if the wireless communication control unit 30 breaks down, the distribution system 6 can obtain the position information Xa and the terminal identification information A from the communication terminal 5 (corresponding to the pattern 2 described above). Furthermore, since the communication terminal 5 can transmit the position information X and the terminal identification information A to the distribution device 3 capable of performing communication with higher signal strength, the distribution system 6 includes the communication terminal 5. Therefore, it is possible to receive the position information X and the terminal identification information A more reliably (corresponding to the pattern 3).

  The location information management system 9 may be constructed by a single computer, or may be constructed by a plurality of computers arbitrarily assigned by dividing each unit (function, means, or storage unit). .

  In addition, a recording medium such as a CD-ROM in which the programs of the above-described embodiments are stored, and a hard disk in which these programs are stored may be provided as a program product (Program Product) domestically or abroad. it can.

  In addition, a recording medium such as a CD-ROM in which the programs of the above-described embodiments are stored, and a hard disk in which these programs are stored may be provided as a program product (Program Product) domestically or abroad. it can.

  Furthermore, the determination unit 63 as a specific example of the first determination unit may include a determination unit 53 as a specific example of the second determination unit. That is, the first determination unit and the second determination unit may be the same unit or different units. Similarly, the measurement unit 64 as a specific example of the first measurement unit may include a measurement unit 67 as a specific example of the second measurement unit. That is, the first measuring means and the second measuring means may be the same means or different means.

(Outline of transmission system)
As described above, in the position management system 1 described with reference to FIGS. 1 to 25, the position information of the transmission terminal used by the user to participate in the remote conference is managed. Hereinafter, a transmission system for performing a remote conference using this position information will be described with reference to FIGS.

  FIG. 26 is a schematic diagram of a transmission system 1000 according to the embodiment of the present invention. FIG. 27 is a conceptual diagram showing a state of transmission / reception of image data, sound data, and various management information in the transmission system. FIG. 28 is a conceptual diagram illustrating the image quality of image data.

  In addition, the transmission system includes a data providing system that transmits content data in one direction from one transmission terminal to a plurality of transmission terminals via a transmission management device, and information between a plurality of transmission terminals via a transmission management device. Includes a communication system that communicates emotions and the like. The communication system is a system for mutually transmitting information, emotions, etc. between a plurality of communication terminals (corresponding to “transmission terminals”) via a communication management apparatus (corresponding to “transmission management apparatus”). Examples include systems and video telephone systems.

  In the present embodiment, a video conference system as an example of a communication system, a video conference management device as an example of a communication management device, and a video conference terminal as an example of a communication terminal are assumed. The terminal will be described. That is, the transmission terminal and the transmission management apparatus of the present invention are not only applied to a video conference system but also applied to a communication system or a data transmission system.

  26, the transmission system 1000 includes a plurality of transmission terminals 1010aa, 1010ab,..., Displays 1120aa, 1120ab,... For the transmission terminals 1010aa, 1010ab,. And a transmission management device 1050 and a program providing device 1090. The transmission terminals 1010aa, 1010ab,... Are configured to transmit, for example, image data and sound data as content data.

  In the following description, an arbitrary transmission terminal among a plurality of transmission terminals 1010aa, 1010ab,... Is represented as “transmission terminal 1010”, and an arbitrary one of a plurality of displays 1120aa, 1120ab,. This display is represented as “display 1120”. Also, the requesting transmission terminal 1010 requesting the start of the video conference is represented as “requesting terminal”, and the requesting transmission terminal 1010 is represented as “destination terminal”.

  As described above, the transmission terminals 1010aa, 1010ab,... Having the position information transmission / reception function as communication terminals receive the position information distributed from the distribution devices 3ac, 3ab,. Then, the received position information and its own identification information are returned to the position information management system 9 via the distribution devices 3ac, 3ab,... And the gateways 7a, 7b,. As shown in FIG. 26, the communication path for identification information and position information may be different from the communication path for content data. However, when each transmission terminal and the location information management system 9 can communicate with each other via the communication network 1002, the communication path of the identification information and the location information may be the same communication path as the content data. Good.

  The location information of the transmission terminal 1010 acquired by the location information management system 9 is referred to as needed by the transmission management device 1050 via the communication network 1002. Then, the transmission management apparatus 1050 identifies the area to which the transmission terminal belongs using the area information 5006 illustrated in FIG. A region is defined by a certain latitude, longitude, floor number and / or building. According to this table, for example, the “Tokyo Office General Conference Room” has a latitude in the range of “35.410000 degrees north to 35.410049 degrees north latitude” and a longitude “139.400000 degrees to 139.40400049 degrees east longitude”. In the range, it can be seen that the floor is “4” and the ridge is an area represented by “A”.

  As shown in FIG. 37, a security level (hereinafter referred to as a level) is set in each area, and the transmission management apparatus 1050 identifies each transmission terminal by specifying the area to which each transmission terminal belongs. Determine the current security level. The transmission management apparatus 1050 in one embodiment of the present invention does not connect a conference session between transmission terminals whose security levels do not match. As a result, it is possible to prevent information from leaking outside through a transmission terminal having a low security level. As illustrated in FIG. 37, the security level can be represented by a numerical value representing a plurality of stages (however, an arbitrary expression format can be used).

  As shown in FIG. 27, in the transmission system 1000, a management information session sei for transmitting and receiving various types of management information is established between the request source terminal and the destination terminal via the transmission management device 1050.

  Further, between the transmission terminals 1010 in which the management information session sei has been established, four pieces of data of high resolution image data, medium resolution image data, low resolution image data, and sound data are transmitted and received via the relay device 1030. Four sessions are established. In the present embodiment, these four sessions are collectively represented as “image / sound data session sed”.

  Here, the image data handled in the present embodiment is encoded in a scalable manner. For example, as shown in FIG. 28A, the image data handled in the present embodiment is composed of 320 pixels in the horizontal direction and 180 pixels in the vertical direction, and low-resolution image data serving as a base image, and FIG. As shown in FIG. 28, medium-resolution image data composed of 640 pixels in the horizontal direction and 360 pixels in the vertical direction, and high-resolution image data composed of 1280 pixels in the horizontal direction and 720 pixels in the vertical direction as shown in FIG. There is.

  Here, when the band through which the image data is transmitted is narrow, only the low-resolution image data serving as the base image is transmitted, and the transmission terminal 1010 on the receiving side is based on the transmitted low-resolution image data. Thus, only low-quality images can be displayed.

  When the band through which the image data is transmitted is relatively wide, low-resolution image data and medium-resolution image data serving as a base image are transmitted, and the transmission terminal 1010 on the reception side transmits the transmitted low-resolution image data. A medium quality image can be displayed based on the resolution image data and the medium resolution image data.

  In addition, when the band through which image data is transmitted is very wide, low-resolution image data, medium-resolution image data, and high-resolution image data serving as the base image quality are transmitted. 1010 can display a high-quality image based on the transmitted low-resolution image data, intermediate-resolution image data, and high-resolution image data.

  In FIG. 26, the relay device 1030 is configured to relay content data between a plurality of transmission terminals 1010. The transmission management apparatus 1050 is configured to centrally manage login authentication from the transmission terminal 1010, management of the transmission state of the transmission terminal 1010, management of the destination list, transmission status of the relay apparatus 1030, and the like. The image represented by the image data may be a moving image or a still image, or may be both a moving image and a still image.

  The plurality of routers 1070a, 1070b, 1070c, 1070d, 1070ab, and 1070cd select an optimum route for image data and sound data. In the following description, an arbitrary router among the routers 1070a, 1070b, 1070c, 1070d, 1070ab, and 1070cd is represented as “router 1070”.

  The program providing apparatus 1090 is configured by a computer and includes an HD (Hard Disk), stores a transmission terminal control program for causing the transmission terminal 1010 to realize various functions, and transmits the transmission terminal control program to the transmission terminal 1010. can do.

  The HD of the program providing apparatus 1090 also stores a relay apparatus program for causing the relay apparatus 1030 to realize various functions, and can transmit the relay apparatus program to the relay apparatus 1030.

  Further, the HD of the program providing apparatus 1090 also stores a transmission management program for causing the transmission management apparatus 1050 to implement various functions, and can transmit the transmission management program to the transmission management apparatus 1050.

  The transmission terminals 1010aa, 1010ab, 1010ac,... And the router 1070a are connected by a LAN 1002a so that transmission is possible. The transmission terminals 1010ba, 1010bb, 1010bc,... And the router 1070b are connected by a LAN 1002b so that transmission is possible.

  The LAN 1002a and the LAN 1002b are connected by a dedicated line 1002ab including a router 1070ab so as to be able to transmit, and are provided in a predetermined area A. For example, the region A is Japan, the LAN 1002a is provided in the Tokyo office, and the LAN 1002b is provided in the Osaka office.

  On the other hand, the transmission terminals 1010ca, 1010cb, 1010cc,... And the router 1070c are connected by a LAN 1002c so that transmission is possible. The transmission terminals 1010da, 1010db, 1010dc,... And the router 1070d are connected by a LAN 1002d so that transmission is possible.

  In addition, the LAN 1002c and the LAN 1002d are connected by a dedicated line 1002cd including the router 1070cd so as to be able to transmit, and are provided in a predetermined area B. For example, area B is the United States of America, LAN 1002c is located in a New York office, and LAN 1002d is Washington D.C. C. Is established in the office. Area A and area B are connected to each other via routers 1070ab and 1070cd, respectively, via the Internet 1002i.

  The relay device 1030, the transmission management device 1050, and the program providing device 1090 are connected to each transmission terminal 1010 via the Internet 1002i so as to be able to transmit. Here, the relay device 1030, the transmission management device 1050, and the program providing device 1090 may be installed in the region A or the region B, or may be installed in a region other than these.

  In this embodiment, the LAN 1002a, the LAN 1002b, the dedicated line 1002ab, the Internet 1002i, the dedicated line 1002cd, the LAN 1002c, and the LAN 1002d constitute the transmission network 1002 of the present embodiment. The transmission network 1002 may include a place where wireless transmission is performed, such as WiFi (Wireless Fidelity) and Bluetooth (registered trademark), as well as wired communication.

  In FIG. 1, four sets of numbers shown below each transmission terminal 1010, relay device 1030, transmission management device 1050, each router 1070, and program providing device 1090 are simplified IP addresses in general IPv4. Is shown. For example, the IP address of the transmission terminal 1010aa is “1.2.1.3”. In addition, IPv6 may be used instead of IPv4, but IPv4 will be used for the sake of simplicity.

  Each transmission terminal 1010 may be used not only for video conferencing between a plurality of business establishments, but also for video conferencing in the same room, as well as video conferencing between different rooms in the same office.

(Hardware configuration)
Next, the hardware configuration of the transmission terminal 1010 and the transmission management apparatus 1050 according to an embodiment of the present invention will be described with reference to FIGS.

(Hardware configuration of transmission terminal)
FIG. 29 shows the appearance of the transmission terminal 1010. As already described with reference to FIG. 10, the transmission terminal 1010 includes hardware for functioning as the communication terminal 5 and, as illustrated in FIG. 29, hardware that is convenient for executing a remote conference. Wear is further provided.

  As shown in FIG. 29, the transmission terminal 1010 includes a casing 11021, an arm 11074, and a camera housing 11075. Here, the front wall (right rear in FIG. 29) of the housing 11021 is represented as a front side wall 11021a, and the rear wall (left front in FIG. 29) is represented as a rear side wall 11021b. Further, the left wall as viewed from the front of the housing 11021 is referred to as a left wall 11021c.

  A plurality of intake holes (not shown) are formed in the front side wall 11021a of the casing 11021, and a plurality of exhaust holes 11121 are formed in the rear side wall 11021b of the casing 11021. As a result, the transmission terminal 1010 is driven by a cooling fan built in the housing 11021 to take in the outside air in front of the transmission terminal 1010 through the intake hole and to the rear of the transmission terminal 1010 through the exhaust hole 11121. Can be exhausted.

  A sound collecting hole 11131 is formed in the front side wall 11021a, and sounds such as voice, sound, noise can be collected by a built-in sound input unit (microphone) 1114 described later.

  An operation panel 11022 is formed on the top surface of the housing 11021. The operation panel 11022 has an operation button 1108, a power switch 1109, an alarm lamp 11119, and a plurality of sound output holes 11151 through which an output sound from a built-in sound output unit (speaker) 1115 described later passes. Yes.

  Further, a housing portion 11160 as a recess for housing the arm 11074 and the camera housing 11075 is formed on the upper surface of the housing 11021. The arm 11074 is attached to the housing 11021 via a torque hinge 11073. For example, the arm 11074 has a click sensation when tilted approximately 45 degrees within a range of a pan angle θ1 of ± 180 degrees and a tilt angle θ2 of 90 degrees when the front is 0 degrees with respect to the housing 11021. It is attached so that it can rotate in the vertical and horizontal directions.

  The camera housing 11075 is provided with a built-in camera 1112 to be described later, and can image a user, a room, and the like. The camera housing 11075 has a torque hinge 11075a. The camera housing 11075 is attached to the arm 11074 via a torque hinge 11075a. For example, the camera housing 11075 has a tilt angle θ3 in a range of approximately 100 degrees on the front side of the transmission terminal 1010 and approximately 90 degrees on the rear side of the transmission terminal 1010 when the state of being linear with the arm 11074 is 0 degrees. Is attached to the arm 11074 so as to be rotatable.

  The left side wall 11021c is provided with a plurality of connection ports 11132 for connecting an external device such as a USB or IEEE1394.

  As shown in FIG. 30, the transmission terminal 1010 includes a CPU (Central Processing Unit) 1101 that controls the operation of the transmission terminal 1010 as a whole, and a ROM (ROM) that stores programs used to drive the CPU 1101 such as an IPL (Initial Program Loader). Read Only Memory (1102), RAM (Random Access Memory) 1103 used as a work area of the CPU 1101, a flash memory 1104 for storing various data such as a transmission terminal control program, image data and sound data, and control of the CPU 1101 Therefore, an SSD (Solid State Drive) 1105 that controls reading or writing of various data with respect to the flash memory 1104, a media drive 1107 that controls reading or writing (storage) of data with respect to a recording medium 1106 such as a flash memory, An operation button 1108 operated when selecting a destination of the transmission terminal 1010, a power switch 1109 for switching on / off the power supply of the transmission terminal 1010, and data transmission using the transmission network 1002 Network I / F (Interface) 1111.

  Further, the transmission terminal 1010 outputs a sound by a built-in CMOS 1112 that captures an image of a subject under the control of the CPU 1101 and obtains image data, a voice input unit (microphone) 1114 as a built-in sound collector for inputting sound, and the like. Built-in audio output unit (speaker) 1115, external device connection I / F 1118 for connecting various external devices, and buses such as an address bus and a data bus for electrically connecting the above-described components Line 1110.

  The display 1120 constitutes a display device composed of a liquid crystal or an organic EL that displays an image of a subject, an operation icon, and the like. The display 1120 is connected to a display I / F (not shown) by a cable (not shown). The cable may be an analog RGB (VGA) signal cable, a component video cable, an HDMI (High-Definition Multimedia Interface) or a DVI (Digital Video Interactive) signal cable. It may be.

  The CMOS 1112 is a camera that employs a complementary metal oxide semiconductor (CMOS) as a solid-state imaging device. A CCD (Charge Coupled Device) may be used as the solid-state imaging device.

  External devices such as an external camera, an external microphone, and an external speaker can be connected to the external device connection I / F 1118 by a USB (Universal Serial Bus) cable or the like.

  When an external camera is connected to the external device connection I / F 1118, the CPU 1101 drives the external camera in preference to the built-in CMOS 1112. When an external microphone or an external speaker is connected to the external device connection I / F 1118, the CPU 1101 has priority over the internal audio input unit 1114 and the internal audio output unit 1115, respectively. It is designed to drive a microphone and an external speaker.

  Note that the recording medium 1106 is configured to be detachable from the transmission terminal 1010. The transmission terminal 1010 may use an EEPROM (Electrically Erasable and Programmable ROM) or the like instead of the flash memory 1104 as long as it is a non-volatile memory that reads or writes data according to the control of the CPU 1101.

The transmission terminal control program may be a file in an installable format or an executable format, and may be recorded and distributed on a computer-readable recording medium such as the recording medium 1106. The transmission terminal control program may be stored in the ROM 1102 instead of the flash memory 1104.

  Note that the acceleration / direction sensor 1113, the communication unit 1116, the antenna 1117, the GPS reception unit 1119, the touch panel 1121, and the battery 1122 have the same functions as the device of the same name of the communication terminal 5 shown in FIG.

(Hardware configuration of transmission management device)
Next, the hardware configuration of the transmission management apparatus 1050 will be described with reference to FIG.

  As shown in FIG. 31, the transmission management device 1050 is used as a work area for the CPU 1201 that controls the overall operation of the transmission management device 1050, a ROM 1202 that stores programs used to drive the CPU 1201, such as IPL, and the CPU 1201. RAM 1203, HD 1204 for storing various data such as a transmission management program, HDD (Hard Disk Drive) 1205 for controlling reading or writing of various data to / from the HD 1204 under the control of the CPU 1201, and data for a recording medium 1206 such as a flash memory A media drive 1207 for controlling reading or writing (storage) of data, a display 1208 for displaying various information such as a cursor, menu, window, character, or image, and the transmission network 100 A network I / F 1209 for transmitting data using a keyboard, a keyboard 1211 having a plurality of keys for inputting characters, numerical values, and various instructions, selection and execution of various instructions, selection of a processing target, A mouse 1212 for moving a cursor, a CD-ROM drive 1214 for controlling reading or writing of various data with respect to a CD-ROM (Compact Disc Read Only Memory) 1213 as an example of a detachable recording medium, and each of the above components A bus line 1210 such as an address bus or a data bus for electrically connecting elements is provided.

  The transmission management program may be recorded in a computer-readable recording medium such as the recording medium 1206 or the CD-ROM 1213 and distributed as a file in an installable or executable format. The transmission management program may be stored in the ROM 1202 instead of the HD 1204.

  The relay device 1030 has the same hardware configuration as that of the transmission management device 1050, and thus description thereof is omitted. However, the relay device program for controlling the relay device 1030 is recorded in the HD 1204.

  In this case as well, the relay device program may be installed in an installable or executable format, recorded on a computer-readable recording medium such as the recording medium 1206 or the CD-ROM 1213, and distributed. . The relay device program may be stored in the ROM 1202 instead of the HD 1204.

  Further, since the program providing apparatus 1090 has the same hardware configuration as the transmission management apparatus 1050, description thereof is omitted. However, the program providing apparatus program for controlling the program providing apparatus 1090 is recorded in the HD 1204.

  Also in this case, the program providing apparatus program is a file in an installable or executable format, and is recorded on a computer-readable recording medium such as the recording medium 1206 or the CD-ROM 1213 for distribution. Good. Further, the program providing apparatus program may be stored in the ROM 202 instead of the HD 204.

As a computer-readable recording medium described above, a CD-R (Compact Di)
sc Recordable), DVD (Digital Versatile Disk), Blu-ray Disc, etc. may be applied.

(Functional configuration)
Next, the functional configuration of the transmission terminal 1010 and the transmission management apparatus 1050 according to an embodiment of the present invention will be described mainly using FIG. As shown in FIG. 32, the transmission terminal 1010, the relay device 1030, and the transmission management device 1050 are connected so as to be able to transmit data via the transmission network 1002. Note that the program providing apparatus 1090 illustrated in FIG. 26 is not directly related to the transmission of data related to the video conference, and thus is not illustrated in FIG.

  The transmission management apparatus 1050 is connected to the location information management system 9 via the transmission network 1002 and can refer to the location information of the transmission terminal 1010 stored in the system. For this reason, the location information management system 9 provides an interface or a service for providing location information of the terminal to an external device via the network.

(Functional configuration of transmission terminal)
The transmission terminal 1010 includes a transmission / reception unit 1011, an operation input reception unit 1012, a login request unit 1013, an imaging unit 1014, a sound input unit 1015a, a sound output unit 1015b, a display control unit 1017, and a storage / readout unit 1019. These units are functions realized by the CPU 1101 that executes the transmission terminal control program developed from the flash memory 1104 onto the RAM 1103. Further, the transmission terminal 1010 has a storage unit 1016 configured by a RAM 1103 and a flash memory 1104.

  Further, as described with reference to FIG. 15, the transmission terminal 1010 receives the position information X distributed from the distribution apparatus 3 and transmits the position information X and the terminal identification information A to the distribution apparatus 3. It has a function. The position information transmission / reception function is realized by each functional block shown in FIG. 15. In FIG. 32, these functional blocks are collectively expressed as a position information transmission / reception unit 1020. Note that the storage / reading unit 1019 and the storage unit 1016 may be integrated with a functional block of the same name included in the position information transmission / reception unit 1020. As already described, the position information X and the terminal identification information A processed by the position information transmitting / receiving unit 1020 are transmitted to the position information management system 9 via the distribution device 3 and the gateway 7 (not shown).

  The transmission / reception unit 1011 includes a CPU 1101 and a network I / F 1111, and transmits / receives various data and information to / from other transmission terminals 1010 or devices 1030, 1050, 1090 via the transmission network 102.

  The transmission / reception unit 1011 starts reception of status information indicating the status of each transmission terminal 1010 as a candidate for a video conference connection destination from the transmission management device 1050 before starting a video conference with a desired destination terminal. It has become.

  The status information represents not only the operating status of each transmission terminal 1010 online or offline, but also the detailed operating status such as whether transmission is possible online or online transmission.

  The status information includes not only the operating status of each transmission terminal 1010 but also the cable at the transmission terminal 1010 being disconnected from the transmission terminal 1010, outputting sound but not outputting an image, or outputting sound. Although various states such as (MUTE) are represented, in the following description, in order to facilitate understanding of the present invention, a case where the state information represents the operating state of each transmission terminal 1010 will be described.

  The operation input receiving unit 1012 includes a CPU 1101, operation buttons 1108, and a power switch 1109, and receives various inputs from the user. For example, when the user turns on the power switch 1109, the operation input receiving unit 1012 receives the power ON and turns on the power of the transmission terminal 1010.

  The login request unit 1013 is configured by the CPU 1101, and triggered by acceptance of power ON, login request information indicating that a login is requested from the transmission / reception unit 1011 to the transmission management apparatus 1050 via the transmission network 1002, and the current local terminal The IP address is sent.

  Further, when the user turns the power switch 1109 from the ON state to the OFF state, the operation input receiving unit 1012 transmits the state information indicating that the power is turned off to the transmission management device 1050, and then the operation input receiving unit 1012 transmits the transmission terminal 1010. The power is turned off completely. As a result, the transmission management apparatus 1050 side can grasp that the transmission terminal 1010 has been turned off from being turned on.

  The imaging unit 1014 includes a CPU 1101 and a CMOS 1112, images a subject, and outputs image data obtained by imaging to the transmission / reception unit 1011.

  The sound input unit 1015a includes a CPU 1101 and a voice input unit 1114. The sound input unit 1015a receives a sound signal representing the sound collected by the sound input unit 1114 and converts the input sound signal into sound data.

  The sound output unit 1015b includes a CPU 1101 and an audio output unit 1115. The sound output unit 1015b converts sound data into a sound signal and outputs the converted sound signal to the sound output unit 1115, thereby outputting an audible sound.

  The display control unit 1017 includes a CPU 1101 and a display 1120. The display control unit 1017 combines image data with different resolutions received by the transmission / reception unit 1011 and displays the combined image data on the display 1120.

  Further, the display control unit 1017 transmits the destination list information received from the transmission management apparatus 1050 by the transmission / reception unit 1011 to the display 1120, thereby causing the display 1120 to display the destination list.

  The storage / reading unit 1019 includes a CPU 1101 and an SSD 1105, and stores various data in the storage unit 1016 and reads out various data stored in the storage unit 1016.

  The storage unit 1016 stores an identifier for identifying the transmission terminal 1010, a password, and the like. The identifier can be expressed by an arbitrary number, character, or a combination thereof for uniquely identifying the transmission terminal 1010. In this embodiment, the terminal identification information A used in the above-described location management system is used. Further, the storage unit 1016 is also used as a reception buffer for image data and sound data received when a video conference is performed with the destination terminal.

(Functional configuration of transmission management device)
The transmission management device 1050 includes a transmission / reception unit 1051, a terminal authentication unit 1052, a state management unit 1053, a terminal extraction unit 1054, a terminal state acquisition unit 1055, and a storage / reading unit 1056. These units are functions realized by the CPU 1201 that executes a transmission management program developed from the HD 1204 onto the RAM 1203. Further, the transmission management apparatus 1050 includes a storage unit 1057 configured by the HD 1204.

(Device authentication information)
In the storage unit 1057, terminal authentication information 5002 stored in a table as shown in FIG. 33 is constructed. In the terminal authentication information, each password is associated with each terminal identification information A of all transmission terminals 1010 managed by the transmission management device 1050 and managed. For example, the terminal authentication information illustrated in FIG. 33 indicates that the password of the transmission terminal 1010aa whose terminal identification information is “01234abc10aa” is “aaaa”.

  The terminal authentication information further includes an item “lock state”. When the “lock state” becomes valid (that is, when the “lock state” is “1”), the transmission terminal 1010 cannot log in. The “locked state” is effective when, for example, passwords that do not match are continuously input at the transmission terminal 1010 a predetermined number of times or more. Thereby, it is possible to prevent further unauthorized access attempts from being continued using the transmission terminal 1010. In addition to the case where wrong passwords are continuously input, the lock state may be set when set by an administrator or when a predetermined valid period is exceeded.

(Device management information)
In the storage unit 1057, terminal management information 5003 stored in a table as shown in FIG.

  In the terminal management information, for each terminal identification information A of each transmission terminal 1010, the device name of each transmission terminal 1010, the operating state of each transmission terminal 1010, and login request information for logging in to the transmission system 1001 are included in the transmission management device. The reception date and time received at 1050, the transmission terminal 1010 IP address, the position information X (latitude, longitude, floor number and building) of each transmission terminal 1010 acquired via the position information management system 9, and the area to which the transmission terminal 1010 belongs Are managed in association with each other.

  For example, in the terminal management information shown in FIG. 34, the terminal name is “Japan Tokyo office AA terminal” and the operation status is “online (transmittable)” for the transmission terminal 1010aa whose terminal identification information A is “01234abc10aa”. "The date and time when the login request information is received by the transmission management device 1050 is" 10:00:00 on October 22, 2012 "and the IP address of the transmission terminal 1010aa is" 1.2.1.3 " The latitude at which the transmission terminal 1010aa is located is “35.410000”, the longitude is “139.400000”, the floor is “4”, the building is “A”, and the security level of the transmission terminal 1010aa is “2”. Represents.

  Here, “terminal identification information A” of the transmission terminal 1010 corresponds to “terminal identification information A” used in the location management system 1. Further, the “device name” of the terminal management information corresponds to the “device name” used in the location management system 1, similarly to the terminal identification information A. However, unlike the “terminal identification information A”, the “device name” may not correspond to that used in the location management system 1. For example, a name different from the position management system 1 may be registered as the “device name” by the administrator of the transmission management apparatus 1050. The terminal name may be changed according to a request made from the transmission terminal 1010 to the transmission management apparatus 1050.

  Further, the “location information X” included in the terminal management information 5003 corresponds to, for example, the management information F held by the location information management system 9 illustrated in FIG. As described above, the terminal management information 1 and the transmission system 1001 use the terminal identification information A to uniquely identify the terminal. Therefore, the transmission management apparatus 1050 can acquire the position information of the desired terminal from the position information management system 9 using the terminal identification information A. For example, the position information of the transmission terminal 1010aa is the position information X (latitude “35.410000”, longitude “139.400000”, floor number “4”, building “A”) of the management information F in FIG. Similarly, the device name of each terminal can be acquired from the management information F of the location information management system 9.

  In FIG. 35, the symbol “-” is stored in the items of the location information X and the reception date and time of the transmission terminal 1010da. This represents a state in which the position information cannot be acquired because the transmission terminal 1010da is in a location where positioning is not possible. Therefore, also in the corresponding terminal management information 5003 (FIG. 34), the symbol “-” indicating that the location information could not be received is stored in the location information item of the transmission terminal 1010da.

  The “operating state” is “online (transmittable)” indicates that the transmission terminal 1010 is logged into the transmission system 1001 and is not participating in the video conference. "Means that the transmission terminal 1010 is logged in to the transmission system 1001 and is participating in a video conference, and the operating state is" offline "means that the transmission terminal 1010 has logged into the transmission system 1. It means that it is not in the state.

(Destination list information)
Furthermore, destination list information 5004 stored in a table as shown in FIG.

  In the destination list information, the terminal identification information of the destination terminal registered as a destination terminal candidate is managed in association with the terminal identification information of the request source terminal that requests the start of the video conference.

For example, in the destination list information shown in FIG. 36, the candidate destination terminal that requests the start of the video conference from the transmission terminal 1010aa whose terminal identification information is “01234abc10aa” is:
-Transmission terminal 1010ba whose terminal identification information is "01234abc10ba"
-Transmission terminal 1010bb whose terminal identification information is "01234abc10bb"
-Transmission terminal 1010ca whose terminal identification information is "01234abc10ca"
-Transmission terminal 1010cb whose terminal identification information is "01234abc10cb"
-Transmission terminal 1010da whose terminal identification information is "01234abc10da"
-Transmission terminal 1010db whose terminal identification information is "01234abc10db"
It is shown that. Destination terminal candidates are added or deleted in response to a request made from the transmission terminal 1010 to the transmission management apparatus 1050.

(Region information)
Furthermore, area information 5006 stored in a table as shown in FIG.

  In the area information, for example, a predetermined area in an office or the like (for example, “Tokyo Office General Conference Room”) is defined by latitude, longitude, floor number, and / or building information. In order to define a region, latitude and longitude are defined by a certain range. In each area, an area name is defined so that the area can be uniquely identified. For example, “Tokyo Office General Conference Room” has a latitude in the range of “35.410000 degrees to 35.410049 degrees north”, a longitude in the range of “139.400000 degrees to 139.40400049 degrees”, and a floor number of “ 4 ”, and the ridge is an area represented by“ A ”.

  A security level is set for each area. The security level is used by the transmission management apparatus 1050 to determine whether or not a conference session can be connected between transmission terminals. That is, the transmission management apparatus 1050 according to the embodiment of the present invention determines that a conference session by transmission terminals having different security levels cannot be connected. As a result, it is possible to prevent information from leaking outside through a transmission terminal having a low security level.

  As illustrated in FIG. 37, the security level can be represented by a numerical value representing a plurality of stages (however, an arbitrary expression format can be used). Here, a value with a small security level indicates a high degree of security (high confidentiality). Also, a special security level (here, “6”, for example) assigned to an area other than the area defined by the area information may be defined. Also, a special security level (for example, “6”) assigned to a transmission terminal whose position information cannot be acquired correctly, such as the transmission terminal 1010da of FIG. 35, may be defined.

(Functional configuration of transmission management device)
The transmission / reception unit 1051 is configured by a CPU 1201 and a network I / F 1209, and the other transmission terminal 1010, devices 1030, 1090, or the position information management system 9 of the position management system 1, various data and information via the transmission network 1002. It is designed to send and receive.

  The terminal authentication unit 1052 is configured by the CPU 1201 and searches the terminal authentication information 5002 in the storage unit 1057 using the terminal identification information A and the password included in the login request information received via the transmission / reception unit 1051 as search keys. . Then, it is determined whether the same terminal identification information A and password are managed in the terminal authentication information 5002. If the passwords match, it is determined that the authentication has succeeded, and otherwise, it is determined that the authentication has failed. In addition, the terminal authentication unit 1052 verifies whether the corresponding transmission terminal is in a locked state, and determines that the authentication has failed when the transmission terminal is in a locked state (in the example of FIG. 33, the transmission terminal is in the locked state “1”). .

  The state management unit 1053 is configured by the CPU 1201, and in order to manage the operating state of the request source terminal that has requested the login, the terminal management information 5003 (see FIG. 34) indicates the operating status for the terminal identification information of the request source terminal. The transmission management device 1050 stores and manages the reception date and time when the login request information is received and the IP address in association with each other.

  In addition, the state management unit 1053 is configured so that the user turns the power switch 1109 of the transmission terminal 1010 from the ON state to the OFF state, based on the state information indicating that the power source is turned off, sent from the transmission terminal 1010. The operating state of the transmission terminal 1010 in the terminal management information 5003 (see FIG. 34) is changed from online to offline.

  The terminal extraction unit 1054 is configured by the CPU 1201, searches the destination list information 5004 (see FIG. 36) using the terminal identification information A of the request source terminal that requested the login as a search key, and is a candidate destination terminal for the request source terminal. Identification information is extracted.

  Further, the terminal extraction unit 1054 searches the destination list information 5004 (see FIG. 36) using the terminal identification information A of the request source terminal that has requested the login as a search key, and uses the terminal identification information A of the request source terminal as the destination terminal information. Terminal identification information A of other request source terminals registered as candidates is also extracted.

  The terminal status acquisition unit 1055 is configured by the CPU 1201 and searches the terminal management information 5003 (see FIG. 34) using the terminal identification information A of the destination terminal candidate extracted by the terminal extraction unit 1054 as a search key. The operating state is read for each terminal identification information.

  Thereby, the terminal status acquisition unit 1055 can acquire the operating status of the destination terminal candidate for the request source terminal that has requested the login. Also, the terminal status acquisition unit 1055 searches the terminal management information 5003 using the terminal identification information A extracted by the terminal extraction unit 1054 as a search key, and acquires the operating status of the request source terminal that has requested the login. ing.

  The storage / reading unit 1056 includes a CPU 1201 and an HDD 1205, and stores various data in the storage unit 1057 and reads various data stored in the storage unit 1057.

  The position information acquisition unit 1058 is configured by the CPU 1201, accesses the position information management system 9 of the position management system 1 through the transmission / reception unit 1051, and uses the terminal identification information A of the transmission terminal 1010 as a key to position information of each transmission terminal 1010. To get. The transmission terminal 1010 from which position information is acquired may be all or a part of the transmission terminals 1010 having entries in the terminal management information of FIG. The manager of the transmission management apparatus 1050 can arbitrarily determine which transmission terminal 1010 position information is to be acquired. For example, among the transmission terminals 1010, the location information of the transmission terminals whose terminal status is “online (during transmission)” or “online (transmission possible)” may be acquired. The acquired location information of the transmission terminal 1010 is stored in the terminal management information 5003 shown in FIG.

  The position information acquisition unit 1058 may acquire the position information of each transmission terminal 1010 from the position information management system 9 at an arbitrary timing. Further, the position information acquisition unit 1058 may be configured to passively acquire the position information of the transmission terminal 1010 whose position information has changed from the position information management system 9 by push distribution. Further, the position information acquisition unit 1058 may acquire a set of terminal identification information A, device name, and owner name information that is stored as management information F together with the position information X.

  The determination unit 1059 is configured by the CPU 1201 and determines whether or not the connection is possible based on the security level of each transmission terminal in response to a conference session start request with another transmission terminal transmitted from a certain transmission terminal. . The determination unit 1059 acquires the security level of the transmission terminal that has transmitted the conference start request and the security level of the destination terminal specified as the connection destination of the conference, which are stored in the terminal management information 5003. And when both security levels correspond, it determines with the said connection being possible. On the other hand, if the security levels of the two do not match, it is determined that the connection is impossible. When it is determined that the connection is impossible, the subsequent conference session establishment process is interrupted.

  The area specifying unit 1060 is configured by the CPU 1201 and specifies an area to which the transmission terminal 1010 belongs. The area specifying unit 1060 uses the area information 5006 illustrated in FIG. 37 to specify the area to which each terminal belongs corresponding to the position information of each transmission terminal 1010 acquired by the position information acquiring unit 1058. Then, after specifying the area to which each transmission terminal belongs, the area specifying unit 1060 stores the security level set in the area in the terminal management information 5003.

  Here, when the location information acquisition unit 1058 acquires the location information of the transmission terminals 1010aa, 1010ab, 1010ba, 1010bb derived from FIG. 35, an example of the result of specifying the area and security level to which each terminal belongs, As shown in FIG. FIG. 38 shows the result of specifying the area name of the area to which the transmission terminal belongs and its security level for each terminal identification information. For example, the position information of the transmission terminal 1010aa is latitude “35.410000”, longitude “139.400000”, floor number “4”, and building “A”. Therefore, it can be seen from the area information 5006 in FIG. 37 that the transmission terminal 1010aa belongs to the area name “Tokyo Office General Conference Room” and its security level is “2”. Similarly, area names and security levels of other transmission terminals are specified. As described above, the security level specified for each transmission terminal is later stored in the terminal management information 5003 (FIG. 34).

  Note that the area specifying unit 1061 cannot specify an area to which the transmission terminal belongs for a transmission terminal for which position information has not been acquired. In that case, the lowest security level defined (for example, “6” in this embodiment) may be stored in the security level of the transmission terminal.

(Security level storage processing)
Next, the operation of the transmission system 1001 according to this embodiment will be described. FIG. 39 is a flowchart illustrating processing in which the transmission management apparatus 1050 determines and stores the security level of each transmission terminal based on the area to which each transmission terminal belongs.

  First, the position information acquisition unit 1058 of the transmission management apparatus acquires the position information X of the transmission terminal 1010 managed by the terminal management information 5003 from the position information management system 9 using the terminal identification information A (step S111). . Next, the location information acquisition unit 1058 stores the acquired location information X of the transmission terminal 1010 in the terminal management information 5003 (step S112). Next, the area specifying unit 1060 specifies the area to which the transmission terminal that acquired the position information belongs (step S113). The method for specifying the region is as described above.

  Next, the area specifying unit 1060 stores the security level of the specified area as the security level of the transmission terminal in the terminal management information 5003 (step S114). Then, when the process is completed for all the transmission terminals, the process is terminated (Y in step S115). Otherwise, the process returns to step S111, and the process for other transmission terminals is continued (N in step S115).

  For example, when each transmission terminal has the position information X shown in FIG. 35, the area specifying unit 1060 specifies the area and security level of each transmission terminal as shown in FIG. Then, the identified security level of each transmission terminal is stored in terminal management information 5003 in FIG.

  The processes in steps S111 to S115 shown in FIG. 39 may be repeatedly executed at an arbitrary timing. Moreover, although the process of step S111-S115 demonstrated the example processed for every single transmission terminal in order to demonstrate easily, a process may be performed simultaneously with respect to several transmission terminal.

(Transmission terminal login process)
Next, the operation of the transmission system 1001 according to this embodiment will be described. FIG. 40 is a sequence diagram illustrating a preparation stage operation until the transmission terminal 1010 enters a preparation state for participation in a video conference. FIG. 40 shows an example in which the transmission terminal 1010aa is in a ready state. In the preparation stage operation, various types of information are transmitted and received in the management information session sei (see FIG. 27).

  First, when the user of the transmission terminal 1010aa turns on the power switch 1109 of the transmission terminal 1010aa, the operation input reception unit 1012 receives the power ON and turns on the power (step S121). Then, the login request unit 1013 transmits login request information representing a login request from the transmission / reception unit 1011 of the transmission terminal 1010aa to the transmission management apparatus 1050 via the transmission network 1002 in response to reception of power ON (step S122).

  The login request information includes terminal identification information A and a password for identifying the transmission terminal 1010aa as the login request source. The terminal identification information A and the password are read from the storage unit 1000 by the storage / reading unit 1019.

  When the log-in request information transmitted from the transmission terminal 1010aa is received by the transmission management apparatus 1050, the transmission management apparatus 1050 can grasp the IP address of the transmission terminal 1010aa on the transmission side.

  Next, the terminal authentication unit 1052 of the transmission management apparatus 1050 uses the terminal identification information A and password included in the login request information received via the transmission / reception unit 1051 as search keys, and the terminal authentication information 5002 ( 33) and terminal authentication is performed by determining whether or not the terminal identification information A and password identical to the search key are managed in the terminal authentication information 5002 (step S123).

  Here, if the terminal authentication unit 1052 determines that the same terminal identification information A and password as the search key are not managed, that is, it is determined that the request is not a log-in request from the transmission terminal 1010 having a valid use authority. In this case, the transmission / reception unit 1051 transmits the authentication result information representing the authentication result obtained by the terminal authentication unit 1052 to the transmission terminal 1010aa that has made a login request via the transmission network 1002, and the operation in the preparation stage ends. It will be.

  Further, the terminal authentication unit 1052 also performs the terminal authentication even when the lock state of the terminal identification information A that is the same as the search key is “1”, that is, when the corresponding transmission terminal is in the lock state. The authentication result information representing the authentication result obtained by the unit 1052 is transmitted via the transmission network 1002 to the transmission terminal 1010aa that has made a login request, and the operation in the preparation stage ends.

  On the other hand, when it is determined by the terminal authentication unit 1052 that the same terminal identification information A and password as the search key are managed, that is, it is determined that the request is a login request from the transmission terminal 10 having a valid use authority. In this case, the state management unit 1053 adds the terminal identification information A of the transmission terminal 1010aa, the operation state, the reception date and time when the login request information is received, and the IP address of the transmission terminal 1010aa to the terminal management information 5003 (see FIG. 34). Are stored in association with each other (step S124).

  Accordingly, as shown in FIG. 34, the terminal management table includes the terminal identification information A “01234abc10aa”, the operation state “online (transmittable)”, the reception date and time “12/10/22 10:10:00” and the transmission terminal. The IP address “1.2.1.3” of 10aa is associated and managed.

  Next, the transmission / reception unit 1051 of the transmission management apparatus 1050 transmits the authentication result information representing the authentication result obtained by the terminal authentication unit 1052 to the transmission terminal 1010aa that has requested the login via the transmission network 1002 (step S125).

  Next, the terminal extraction unit 1054 of the transmission management apparatus 1050 searches the destination list information 5004 (see FIG. 36) using the terminal identification information A “01234abc10aa” of the transmission terminal 1010aa that has requested the login as a search key, and transmits the transmission terminal 1010aa. The terminal identification information A as a destination terminal candidate is extracted (step S126).

  Here, the terminal identification information A “01234abc10ba”, “01234abc10bb”, “01234abc10ca” of each of the transmission terminals 10ba, 10bb, 10ca, 10cb, 10da, and 10db that are destination terminals for the terminal identification information A “01234abc10aa” of the transmission terminal 1010aa , “01234abc10cb”, “01234abc10da”, and “01234abc10db” are extracted.

  Next, the terminal status acquisition unit 1055 of the transmission management apparatus 1050 includes terminal identification information A “01234abc10ba”, “01234abc10bb”, “01234abc10ca”, “01234abc10cb”, “01234abc10da” of the destination terminal candidates extracted by the terminal extraction unit 1054. ”,“ 01234abc10db ”as a search key, the terminal management information 5003 (see FIG. 34) is searched, and the operation status“ offline ”and“ online (transmittable) ”for each terminal identification information A extracted by the terminal extraction unit 1054 By reading “online (during transmission)”, the operating states of the transmission terminals 10ba, 10bb, 10ca, 10cb, 10da, and 10db are acquired (step S127).

  Next, the transmission / reception unit 1051 of the transmission management apparatus 1050 uses the terminal identification information A “01234abc10ba”, “01234abc10bb”, “01234abc10ca”, “01234abc10cb”, “01234abc10da”, “01234abc10db” as the search keys used in step S127. Destination state information including the operation states “offline”, “online (transmittable)”, and “online (during transmission)” of the corresponding transmission terminals 10ab, 10ba, and 10db via the transmission network 1002 To the transmission terminal 1010aa (step S128).

  As a result, the transmission terminal 1010aa has the current operating states “offline”, “online (transmittable)”, “online (transmission) of the transmission terminals 10ba, 10bb, 10ca, 10cb, 10da, and 10db that are candidates for the destination terminal. Middle) ”.

  Further, the terminal extraction unit 1054 of the transmission management apparatus 1050 searches the destination list information 5004 (see FIG. 36) using the terminal identification information A “01234abc10aa” of the transmission terminal 1010aa that has requested the login as a search key, and the transmission terminal 1010aa The terminal identification information A of another transmission terminal in which the terminal identification information A “01234abc10aa” is registered as a destination terminal candidate is extracted (step S129). For example, in the destination list information shown in FIG. 36, the extracted terminal identification information A is “01234abc10ca” and “01234abc10db”.

  Next, the state management unit 1053 of the transmission management apparatus 1050 searches the terminal management information 5003 (see FIG. 34) using the terminal identification information A “01234abc10aa” of the transmission terminal 1010aa that has requested the login as a search key, and logs in. The requested operating state “online (transmittable)” of the transmission terminal 1010aa that has requested is acquired (step S130).

  Next, the transmission / reception unit 1051 of the transmission management apparatus 1050 operates with the terminal management information 5003 (see FIG. 34) among the transmission terminals identified by the terminal identification information A “01234abc10ca” and “01234abc10db” extracted in step S129. The transmission terminal whose status is “online” (that is, both the transmission terminals 10ca and 10db here) and the terminal identification information A “01234abc10aa” of the transmission terminal 1010aa acquired in step S130 and the operation status “online ( Destination state information including “transmissible)” is transmitted (steps S131-1, 2).

  When transmitting the destination state information to the transmission terminals 1010ca and 1010db, the transmission / reception unit 1051 is managed by the terminal management information shown in FIG. 34 based on the terminal identification information A “01234abc10ca” and “01234abc10db”. Refers to the IP address of the transmission terminal.

  As a result, the terminal identification information A “01234abc10aa” of the transmission terminal 1010aa that requested the login and the operation state “online (transmittable)” are transmitted to the transmission terminals 1010ab and 1010ca that can transmit the transmission terminal 1010aa that has requested the login as a destination. Can be communicated.

  Further, when step S128 of the preparatory stage operation is completed, the display 1120 of the transmission terminal 1010aa shows from the displayed destination list information that the terminal participating in the video conference, that is, the operating state is “online (during transmission)”. ”Or“ online (transmittable) ”information of the transmission terminal 1010db is highlighted, and the user can recognize the transmission terminal 1010 participating in the video conference or the transmission terminal 1010 that can participate.

(Session establishment processing between transmission terminals)
FIG. 41 is a sequence diagram illustrating a conference participation operation until the transmission terminal 1010 enters a participation state for participating in a video conference. Note that FIG. 41 illustrates an example in which the transmission terminal 1010aa enters the participation state. In the conference participation operation, various types of information are transmitted and received in the management information session sei (see FIG. 27).

  First, when the user presses the operation button 1108 to select participation in the video conference, the operation input reception unit 1012 receives a request to participate in the video conference of the transmission terminal 1010db (step S141).

  In response to this request, the transmission / reception unit 1051 of the transmission terminal 1010aa includes the terminal identification information A “01234abc10aa” of the transmission terminal 1010aa and the terminal identification information A “01234abc10db” of the transmission terminal 1010db, indicating that it participates in the video conference. The start request information is transmitted to the transmission management device 1050 (step S142).

  As a result, the transmission / reception unit 1051 of the transmission management apparatus 1050 can receive the participation request information and confirm the IP address “1.2.1.3” of the transmission terminal 1010aa that is the transmission source.

  Next, the state management unit 1053 of the transmission management apparatus 1050 searches the terminal management information 5003 using the terminal identification information A “01234abc10aa” of the transmission terminal 1010aa included in the participation request information as a search key, and the transmission terminal that has requested participation The operation state of 1010aa is set to “online (during transmission)” (step S143).

  Next, the determination unit 1059 of the transmission management apparatus 1050 identifies the transmission request by transmitting the participation request information based on the security level of the transmission terminal identified by the request source terminal identification information and the destination terminal identification information of the participation destination. Compare the security level of the transmission terminal to be used. Then, it accepts the participation request and determines whether or not the conference session can be connected (step S144).

  Here, FIG. 43 shows a flowchart showing in detail the flow of processing executed by the determination unit 1059 in step S144.

  First, the determination unit 1059 reads the terminal identification information of the requesting transmission terminal and the terminal identification information of the destination transmission terminal, which are included in the participation request information received from the transmission terminal (step S144-1). Next, the determination unit 1059 refers to the terminal management information 5003 illustrated in FIG. 34 and acquires the security level of each transmission terminal (step S144-2). Next, when both security levels are the same (Y in step S144-3), the determination unit 1059 determines that the connection is possible (step S144-4). On the other hand, when both security levels are not the same (N in step S144-3), it is determined that the connection is impossible (step S144-5).

  For example, in the example shown in FIG. 41, when the requesting transmission terminal is the transmission terminal 1010aa and the destination transmission terminal is the transmission terminal 1010bb, the security level of both is determined from the terminal management information 5003 in FIG. “2”. Therefore, it is determined that the connection is “connectable”.

  Returning to FIG. 41, next, the transmission / reception unit 1051 of the transmission management apparatus 1050 transmits connection permission / inhibition information (here, “connection is possible”) including the determination result in step S144 to the transmission terminal 1010aa via the transmission network 1002. (Step S145).

  Next, the transmission / reception unit 1051 of the transmission management apparatus 1050 transmits start request information including the terminal identification information A “01234abc10aa” of the transmission terminal 1010aa to the transmission terminal 1010db via the transmission network 1002 (step S146). Thereby, the transmission terminal 1010db can grasp which transmission terminal 1010 has requested to participate in the video conference.

  Next, the transmission terminal 1010db transmits reception completion information indicating that reception of the start request information is completed from the transmission / reception unit 1051 to the transmission management apparatus 1050 via the transmission network 1002 (step S147).

  Next, the transmission / reception unit 1051 of the transmission management device 1050 transmits relay start request information indicating a request to start relaying to the relay device 1030 via the transmission network 1002 (step S148). The relay start request information includes the IP addresses “1.2.1.3” and “1.3.2.4” of the transmission terminal 1010aa and the transmission terminal 1010db.

  Thereby, the relay apparatus 1030 establishes a session for transmitting the three pieces of image data of low resolution, medium resolution, and high resolution and the sound data between the transmission terminals 1010aa and 1010db (step S149). In this way, the transmission terminal 1010aa can participate in a video conference with the transmission terminal 1010db.

  On the other hand, the transmission / reception unit 1051 of the transmission system 1050 transmits terminal status change information including the terminal identification information A “01234abc10aa” of the transmission terminal 1010aa and the operation status “online (during transmission)” to the terminal management information 5003 (FIG. 34). (Refer to step S150). Thereby, each transmission terminal that has received the terminal state change information can store and display the operating state of the transmission terminal 1010aa of the terminal identification information A “01234abc10aa” as necessary.

  In the above example, the operation example of the transmission terminal 1010aa and the transmission terminal 1010bb that have the same security level and can be connected to the conference session has been described. In contrast, FIG. 42 illustrates an example in which the transmission terminal 1010aa transmits a participation request to the transmission terminal 1010ab whose security levels are not the same.

  Steps S151 to S153 are the same as steps S141 to S143 in FIG. In step S154, the determination unit 1059 of the transmission management apparatus 1050 executes the process illustrated in FIG. Here, the requesting transmission terminal is the transmission terminal 1010aa, and the destination transmission terminal is the transmission terminal 1010ba. Therefore, from the terminal management information 5003 in FIG. 34, the former security level is “2”, while the latter security level is “1”. Therefore, the determination unit 1059 determines that the security levels of the request source and the destination are not the same (N in step S144-3 in FIG. 43), and determines that connection is not possible (step S144-5).

  As a result, in step S155 of FIG. 42, the transmission / reception unit 1051 of the transmission management apparatus 1050 transmits connection permission / rejection information indicating “not connectable” to the transmission terminal 1010aa via the transmission network 1002 (step S145). The conference participation operation ends.

(Data transmission processing between transmission terminals)
FIG. 44 is a sequence diagram illustrating a data transmission operation between the transmission terminals 1010. In the data transmission operation shown in FIG. 44, image data and sound data are transmitted and received in the image / sound data session sed (see FIG. 27).

  As described using FIG. 44, when the session between the transmission terminals 1010aa and 10db is established, the transmission terminal 1010aa receives the image data obtained by the imaging unit 1014 and the sound input unit 1015a. The sound data obtained by converting the sound signal is transmitted to the relay device 1030 via the transmission / reception unit 1011 (step S160).

  The relay apparatus 1030 that has received the image data and sound data from the transmission terminal 1010aa transmits the received image data and sound data to each of the transmission terminals 1010aa and 10db participating in the video conference (steps S161-1, 161-). 2).

  The transmission terminals 1010aa and 10db that have received the image data and the sound data from the relay device 1030 display the image represented by the received image data on the display 1120, and the sound represented by the received sound data is sounded by the sound output unit 1015b. The output is performed by the output unit 1115 (steps S162-1, S162-2).

  Next, the transmission terminal 1010db transmits the image data obtained by imaging by the imaging unit 14 and the sound data obtained by converting the sound signal input to the sound input unit 1015a to the relay device 1030 via the transmission / reception unit 1011. Transmit (step S163).

  The relay apparatus 1030 that has received the image data and sound data from the transmission terminal 1010db transmits the received image data and sound data to each of the transmission terminals 1010aa and 10db participating in the video conference (steps S164-1 and S164-). 2).

  The transmission terminals 1010aa and 10db that have received the image data and the sound data from the relay device 1030 display the image represented by the received image data on the display 1120, and the sound output unit 1015b outputs the sound represented by the received sound data by the sound output unit 1015b. Output to the unit 1115 (steps S165-1, S165-2).

  Thus, the transmission terminals 1010aa and 10db can hold a video conference via the relay device 1030. In FIG. 44, in order to facilitate understanding of the present invention, the transmission terminals 1010 participating in the video conference are two transmission terminals 1010aa and 10db, but the transmission terminals 1010 participating in the video conference are Even if there are three or more, the image data and the sound data are transmitted in the same manner as the data transmission operation shown in FIG.

  As described above, the transmission management apparatus 1050 determines the security level of the transmission terminal based on the area to which the transmission management apparatus 1050 belongs. If the security levels do not match, the transmission management apparatus 1050 does not permit the conference connection, thereby leaking highly confidential information. Can be prevented.

DESCRIPTION OF SYMBOLS 1 Position management system 2 Electric equipment 3 Distribution apparatus 4 Management object 5 Communication terminal 6 Distribution system 7 Gateway 8 Communication network 9 Position information management system 1001 Transmission system 1002 Communication network 1010 Transmission terminal 1030 Relay apparatus 1050 Transmission management apparatus 1090 Program provision apparatus 1051 Transmission / Reception Unit 1052 Terminal Authentication Unit 1053 Status Management Unit 1054 Terminal Extraction Unit 1055 Terminal Status Acquisition Unit 1056 Storage / Readout Unit 1057 Storage Unit 1058 Location Information Acquisition Unit 1059 Judgment Unit 1060 Area Identification Unit

JP 2006-005590 A

Claims (6)

A transmission management device for managing a remote conference session executed by a plurality of transmission terminals,
An acquisition unit for acquiring position information of the transmission terminal;
A specifying unit for specifying a region to which the transmission terminal belongs using the position information;
A determination unit that determines whether or not the session can be connected based on information on a region to which the plurality of transmission terminals specified belong;
Have
If the determination unit determines that the session is not connectable, the session is not connected.
Transmission management device. The area information is a security level set in the area.
The transmission management apparatus according to claim 1. The determination unit determines that the session is connectable when security levels of areas to which the plurality of transmission terminals belong are the same, and cannot connect the session when the security level is not the same. To determine,
The transmission management apparatus according to claim 2. The location information of the transmission terminal is represented by background coordinates representing the indoor location, floor number and / or building information.
The transmission management apparatus according to any one of claims 1 to 3. There is a transmission management method for managing a teleconference session executed by a plurality of transmission terminals.
Obtaining the transmission terminal position information; and
Using the location information to identify a region to which the transmission terminal belongs;
A determination step of determining whether or not the session can be connected based on information on a region to which the plurality of transmission terminals specified belong;
Have
In the determination unit step, if it is determined that the session is not connectable, the session is not connected.
Transmission management method.   A program for causing a computer to execute the transmission management method according to claim 5.

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