JP5899710B2 - Transmission system - Google Patents

Description

  The present invention relates to an invention for reproducing content data based on at least basic data among basic data essential for reproduction of content data and extended data for improving the reproduction quality of the content data.

  An example of a transmission system that transmits and receives content data between a plurality of transmission terminals via a relay device is a video conference system that performs a video conference or the like via a communication network such as the Internet. The necessity of such a video conference system has been improved with the recent reduction in business trip expenses and business trip time. In such a video conference system, a plurality of video conference terminals, which are examples of transmission terminals, are used. A video conference can be realized by transmitting and receiving image data and audio data between these video conference terminals.

  In recent years, video conference systems using H.264 / SVC (Scalable Video Coding), which is a video coding standard, are becoming popular. In the video conference system of the H.264 / SVC standard, the video conference terminal on the transmission side is required to play back basic data of low resolution that is essential for playback of image data and high-resolution extension data to improve the quality of playback of image data. Separately encode. Then, the transmitting-side video conference terminal transmits the basic data and the extended data to one specific relay device via different channels. Thereafter, this single relay device transmits basic data and extension data to the receiving-side video conference terminal using the same channel. Thereby, the video conference terminal on the receiving side decodes and combines the received basic data and extension data to reproduce image data (see Patent Document 1).

  However, even if the video conference system performs the transmission and reception of basic data and extended data in two channels for basic data and extended data, if the relay device itself fails, the receiving side In such a transmission terminal, problems such as delay, interruption or cancellation of content data reproduction occur.

The invention according to claim 1 is a plurality of basic data essential for reproduction of content data and extended data for improving the quality of reproduction of the content data, wherein the content data is reproduced based on at least the basic data. A transmission terminal, a management system for managing a session for transmitting the content data among the plurality of transmission terminals, and a plurality of highly reliable relay apparatuses having an average failure interval of a predetermined time or more. A transmission system having one relay device group and a second relay device group configured by a plurality of relay devices having low reliability whose average failure interval is less than a predetermined time, wherein the plurality of transmission terminals Before any of the transmission terminals receives the basic data and extension data from another transmission terminal as a communication partner. Receiving each first pre-transmission information transmitted from the other transmission terminal via each first relay device of the device group and indicating a transmission time when transmitted from the other transmission terminal; , Each second advance transmitted from the other transmission terminal via each second relay device of the second relay device group and indicated a transmission time when transmitted from the other transmission terminal. For each of the received first pre-transmission information, the pre-reception means for receiving the transmission information, and measuring the reception time when each of the first pre-transmission information is received by the pre-reception means, For each received second pre-transmission information, a measuring means for measuring a reception time when each of the second pre-transmission information is received by the pre-reception means, and a first for which the reception time is measured For each pre-transmission information, the measured reception And the required time from transmission to reception of each first pre-transmission information is calculated based on the difference between the transmission time included in each first pre-transmission information and the reception time is measured. For each second pre-transmission information, reception from the transmission of each second pre-transmission information based on the difference between the measured reception time and the transmission time included in each of the second pre-transmission information Selecting a specific first relay device from the first relay device group based on the calculation means for calculating the required time until the first required time of the first pre-transmission information calculated, Based on the calculated time required for each second pre-transmission information, a selection means for selecting a specific second relay apparatus from the second relay apparatus group, and the first selected by the selection means First relay device identification information for identifying the relay device Transmitting means for transmitting information to the management system, and second relay apparatus identification information for identifying the second relay apparatus selected by the selection means, Based on the first relay device identification information and the second relay device identification information transmitted by the transmission means of the transmission terminal, the basic data is transmitted between the transmission terminal and the other transmission terminal. A session for transmitting the extension data between the transmission terminal and the other transmission terminal is established via the second relay device. A transmission system characterized in that

As described above, according to the present invention, basic data and extended data are received via the first and second different relay apparatuses, and the average failure interval has a high reliability with a predetermined time or more. via the first relay device receives the required basic data for playing content data, via the second relay apparatus MTBF has a low reliability is less than the predetermined time, the content data reproduction Extended data to improve quality was received. Accordingly, the transmission terminal of the reception side, it becomes difficult to occur a situation can not receive basic data, reproduction delay of the content data, an effect that can be significantly overcome problems such as interrupted or stopped .

1 is a schematic diagram of a transmission system according to a first embodiment of the present invention. It is the conceptual diagram which showed the transmission / reception state of the image data in the transmission system, audio | voice data, and various management information. It is a conceptual diagram explaining the image quality of image data. It is an external view of the terminal which concerns on this embodiment. It is a hardware block diagram of the terminal which concerns on this embodiment. It is a hardware block diagram of the management system, relay apparatus, or program provision system which concerns on this embodiment. It is a functional block diagram of each terminal, apparatus, and system which comprise the transmission system which concerns on this embodiment. It is a functional block diagram of the last narrowing-down part. It is a functional block diagram of a primary narrowing-down part. It is a conceptual diagram which shows a change quality management table. It is a conceptual diagram which shows a relay apparatus management table. It is a conceptual diagram which shows a terminal authentication management table. It is a conceptual diagram which shows a terminal management table. It is a conceptual diagram which shows a destination list management table. It is a conceptual diagram which shows a session management table. It is a conceptual diagram which shows an address priority management table. It is a conceptual diagram which shows a transmission rate priority management table. It is a conceptual diagram which shows a quality management table. It is the sequence figure which showed the process which manages the status information which shows the operating state of each relay apparatus. It is the sequence diagram which showed the process of the preparation stage which starts a telephone call between terminals. It is the sequence diagram which showed the process which narrows down a relay apparatus. FIG. 10 is a process flow diagram illustrating a process of narrowing down relay devices. It is the figure which showed the calculation state of the point at the time of performing the narrowing-down process of a relay apparatus. FIG. 10 is a sequence diagram illustrating a part of processing in which a transmission terminal selects a relay device according to the first embodiment of the present invention. FIG. 10 is a sequence diagram illustrating a part of processing in which a transmission terminal selects a relay device according to the first embodiment of the present invention. It is the processing flowchart which showed the process which selects a relay apparatus in a transmission terminal. It is the sequence diagram which showed the process which transmits / receives image data and audio | voice data between transmission terminals. FIG. 10 is a sequence diagram illustrating a part of processing in which a transmission terminal selects a relay device according to a second embodiment of the present invention.

[First Embodiment]
Hereinafter, the first embodiment of the present invention will be described with reference to FIGS.
<< Overall Configuration of Embodiment >>
FIG. 1 is a schematic diagram of a transmission system according to this embodiment of the present invention. FIG. 2 is a conceptual diagram showing a state of transmission / reception of image data, audio data, and various management information in the transmission system. FIG. 3 is a conceptual diagram illustrating the image quality of image data.

  The transmission system includes a data providing system that transmits content data in one direction from one transmission terminal to the other transmission terminal via the transmission management system, and information between a plurality of transmission terminals via the transmission management system. Includes a communication system that communicates emotions and the like. This communication system is a system for mutually transmitting information, emotions and the like between a plurality of communication terminals via a communication management system, and examples thereof include a video conference system and a video phone system.

  In the present embodiment, assuming a video conference system as an example of a communication system, a video conference management system as an example of a communication management system, and a video conference terminal as an example of a communication terminal, a transmission system, a transmission management system, The transmission terminal will be described. That is, this does not mean that the transmission system, transmission management system, and transmission terminal of the present invention are limited to this embodiment. In the present embodiment, “video conference” is described, but it may be called “video conference”, and both have the same content.

  First, the transmission system 1 shown in FIG. 1 includes a plurality of transmission terminals (10aa, 10ab,...), A display (120aa, 120ab,...) For each transmission terminal (10aa, 10ab,. The apparatus (30A, 30B, 30a, 30b, 30c, 30d), the transmission management system 50, the program providing system 90, and the maintenance system 100 are constructed.

  The plurality of terminals 10 perform transmission by transmitting and receiving image data and audio data as an example of content data.

  In the following, “transmission terminal” is simply represented as “terminal”, and “transmission management system” is simply represented as “management system”. Further, an arbitrary terminal among the plurality of terminals (10aa, 10ab,...) Is represented as “terminal 10”, and an arbitrary display among the plurality of displays (120aa, 120ab,...) Is represented as “display 120”. An arbitrary relay device among the plurality of relay devices (30A, 30B, 30a, 30b, 30c, 30d) is represented as “relay device 30”. In the following description, a terminal 10 as a request source that requests the start of a video conference is referred to as a “request source terminal”, and a terminal as a destination that is a request destination is described as a “destination terminal”.

  Further, the transmission system 1 transmits and receives image data using the H.264 / SVC video encoding standard. Specifically, as shown in FIG. 2, in the transmission system 1, for management information for transmitting and receiving various types of management information between the request source terminal and the destination terminal via the management system 50. Session sei is established. In addition, a high-reliability session for transmitting / receiving basic (Base) data (low-resolution image data) between the requesting terminal and the destination terminal via the high-reliability relay device 30. sedH is established. Further, between the request source terminal and the destination terminal, expansion data (medium resolution image data, high resolution image data, audio data) is transmitted via a low reliability relay device 30. A low-reliability session sedL for transmission / reception is established.

  Then, the terminal 10 divides the image data into two parts, basic data and extension data, encodes them, and transmits them to the destination terminal. On the other hand, at the destination terminal, the received basic data and extension data are decoded and combined to reproduce the image data obtained by imaging the subject on the request source terminal side (image display, etc.) can do.

  Here, as shown in FIG. 3A, the basic data is low-resolution image data that is composed of 160 pixels in the horizontal direction and 120 pixels in the vertical direction and serves as a base image during reproduction. As shown in FIG. 3 (b), the extended data includes medium-resolution image data consisting of 320 pixels in the horizontal direction and 240 pixels in the vertical direction during reproduction, and as shown in FIG. 3 (c). During reproduction, both high-resolution image data consisting of 640 pixels in the horizontal direction and 480 pixels in the vertical direction are displayed.

  In addition, among the relay devices 30 illustrated in FIG. 1, the relay devices (30A, 30B) are, for example, highly reliable computers having an average failure interval of 8760 hours (about one year) or more, The basic data transmitted / received between the terminals 10 is relayed. The relay devices (30a, 30b, 30c, 30d) are, for example, low-reliability computers having an average failure interval of less than 8760 hours (about one year), and extended data transmitted / received between a plurality of terminals 10 Relay. The high-reliability relay devices (30A, 30b) have a higher purchase price than the low-reliability relay devices (30a, 30b, 30c, 30d).

  The management system 50 centrally manages the login authentication from the terminal 10, the management of the call status of the terminal 10, the management of the destination list, and the communication status of the relay device 30. The image of the image data may be a moving image or a still image, or may be both a moving image and a still image.

  A plurality of routers (70a, 70b, 70c, 70d, 70ab, 70cd) select an optimum route for image data and audio data. In the following, an arbitrary router among the routers (70a, 70b, 70c, 70d, 70ab, 70cd) is represented as “router 70”.

  The program providing system 90 includes an HD (Hard Disk) 204 described below, and stores a terminal program for causing the terminal 10 to realize various functions (or to cause the terminal 10 to function as various means). The terminal program can be transmitted to The HD 204 of the program providing system 90 also stores a relay device program for causing the relay device 30 to realize various functions (or to cause the relay device 30 to function as various means). The relay device program can be transmitted. Further, the HD 204 of the program providing system 90 also stores a transmission management program for realizing various functions in the management system 50 (or causing the management system 50 to function as various means). A transmission management program can be transmitted.

  The maintenance system 100 is a computer for maintaining, managing, or maintaining at least one of the terminal 10, the relay device 30, the management system 50, the program providing system 90, and the maintenance system 100. For example, when the maintenance system 100 is installed in the country and the terminal 10, the relay device 30, the management system 50, or the program providing system 90 is installed outside the country, the maintenance system 100 is remotely connected via the communication network 2. Maintenance such as maintenance, management, and maintenance of at least one of the terminal 10, the relay device 30, the management system 50, and the program providing system 90 is performed. In addition, the maintenance system 100 does not go through the communication network 2, but includes a model number, a manufacturing number, a sales destination, a maintenance check, at least one of the terminal 10, the relay device 30, the management system 50, and the program providing system 90. Or, maintenance such as failure history management is performed.

  Incidentally, the terminals (10aa, 10ab, 10ac,...), The relay device 30a, and the router 70a are communicably connected by a LAN (Local Area Network) 2a. The terminals (10ba, 10bb, 10bc,...), The relay device 30b, and the router 70b are communicably connected via a LAN 2b. The LAN 2a and the LAN 2b are communicably connected by a dedicated line 2ab including a router 70ab, and are constructed in a predetermined area A. For example, the region A is Japan, the LAN 2a is constructed in a Tokyo office, and the LAN 2b is constructed in an Osaka office.

  On the other hand, the terminals (10ca, 10cb, 10cc,...), The relay device 30c, and the router 70c are communicably connected via a LAN 2c. The terminal 10d (a, 10db, 10dc,...), The relay device 30d, and the router 70d are communicably connected via a LAN 2d. The LAN 2c and the LAN 2d are communicably connected via a dedicated line 2cd including the router 70cd, and are constructed in a predetermined area B. For example, region B is the United States of America, LAN 2c is built in a New York office, and LAN 2d is Washington D.C. C. Is built in the office. Area A and area B are connected to each other via routers (70ab, 70cd) via the Internet 2i.

  Further, the relay devices (30A, 30B), the management system 50, and the program providing system 90 are connected to the terminal 10 and the relay device 30 via the Internet 2i so as to be communicable. The relay devices (30A, 30B), the management system 50, and the program providing system 90 may be installed in the region A or the region B, or may be installed in a region other than these.

  In the present embodiment, the communication network 2 of the present embodiment is constructed by the LAN 2a, the LAN 2b, the dedicated line 2ab, the Internet 2i, the dedicated line 2cd, the LAN 2c, and the LAN 2d. The communication network 2 may have a place where wireless communication such as WiFi (Wireless Fidelity) or Bluetooth (registered trademark) is performed in addition to wired communication.

  Further, in FIG. 1, four sets of numbers shown below each terminal 10, each relay device 30, management system 50, each router 70, and program providing system 90 are simplified IP addresses in general IPv4. Is shown. For example, the IP address of the terminal 10aa is “1.2.1.3”. In addition, IPv6 may be used instead of IPv4, but IPv4 will be used for the sake of simplicity.

In addition, each terminal 10 is not only a call between a plurality of business establishments or a call between different rooms in the same business establishment, but a call within the same room or a call between the outdoors and indoors or outdoors and outdoors. May be used. When each terminal 10 is used outdoors, wireless communication such as a cellular phone communication network is performed.
<< Hardware Configuration of Embodiment >>
Next, the hardware configuration of this embodiment will be described. FIG. 4 is an external view of the terminal 10 according to the present embodiment. Hereinafter, the longitudinal direction of the terminal 10 will be described as the X-axis direction, the direction orthogonal to the X-axis direction in the horizontal plane as the Y-axis direction, and the direction orthogonal to the X-axis direction and the Y-axis direction (vertical direction) as the Z-axis direction.

  As shown in FIG. 4, the terminal 10 includes a housing 1100, an arm 1200, and a camera housing 1300. Among them, the front side wall surface 1110 of the housing 1100 is provided with an air intake surface (not shown) formed by a plurality of air intake holes, and the rear side wall surface 1120 of the housing 1100 is formed with a plurality of exhaust holes. An exhaust surface 1121 is provided. As a result, by driving a cooling fan built in the housing 1100, the outside air behind the terminal 10 can be taken in via an intake surface (not shown) and exhausted to the rear of the terminal 10 via an exhaust surface 1121. A sound collecting hole 1131 is formed in the right wall surface 1130 of the housing 1100, and sounds such as voice, sound, noise can be collected by a built-in microphone 114 described later.

  An operation panel 1150 is formed on the right wall surface 1130 side of the housing 1100. The operation panel 1150 is provided with a plurality of operation buttons (108a to 108e) to be described later, a power switch 109 to be described later, and an alarm lamp 119 to be described later, and outputs sound from a built-in speaker 115 to be described later. A sound output surface 1151 formed by a plurality of sound output holes for passing through is formed. Further, a housing 1160 as a recess for housing the arm 1200 and the camera housing 1300 is formed on the left wall surface 1140 side of the housing 1100. The right side wall surface 1130 of the housing 1100 is provided with a plurality of connection ports (1132a to 1132c) for electrically connecting cables to an external device connection I / F 118 described later. On the other hand, the left wall surface 1140 of the housing 1100 is provided with a connection port (not shown) for electrically connecting the cable 120c for the display 120 to an external device connection I / F 118 described later.

  In the following description, “operation button 108” is used when an arbitrary operation button is indicated among the operation buttons (108a to 108e), and “an arbitrary connection port is indicated among the connection ports (1132a to 1132c)”. This will be described using the connection port 1132 ”.

Next, the arm 1200 is attached to the housing 1100 via a torque hinge 1210, and the arm 1200 is configured to be able to rotate in the vertical direction with respect to the housing 1100 within a tilt angle θ1 of 135 degrees. ing. FIG. 4 shows a state where the tilt angle θ1 is 90 degrees.
The camera housing 1300 is provided with a built-in camera 112 described later, and can capture images of users, documents, rooms, and the like. A torque hinge 1310 is formed in the camera housing 1300. The camera housing 1300 is attached to the arm 1200 via a torque hinge 1310. The camera housing 1300 is attached to the arm 1200 via a torque hinge 1310. The pan angle θ2 of ± 180 degrees is assumed with respect to the arm 1200, with the state shown in FIG. And a tilt angle θ3 of ± 45 degrees can be rotated in the vertical and horizontal directions.

  The relay device 30, the transmission management system 50, the program providing system 90, and the maintenance system 100 are the same as the appearance of a general server computer, and thus the description of the appearance is omitted.

  FIG. 5 is a hardware configuration diagram of the terminal 10 according to the present embodiment. As shown in FIG. 5, the terminal 10 of the present embodiment has programs used for driving the CPU 101 such as a CPU (Central Processing Unit) 101 and IPL (Initial Program Loader) that control the operation of the entire terminal 10. ROM (Read Only Memory) 102, RAM (Random Access Memory) 103 used as a work area for the CPU 101, flash memory 104 for storing various data such as terminal programs, image data, and audio data, and control of the CPU 101 The SSD (Solid State Drive) 105 that controls the reading or writing of various data to the flash memory 104 according to the above, the media drive 107 that controls the reading or writing (storage) of data to the recording medium 106 such as the flash memory, and the destination of the terminal 10 The operation that is performed when selecting An operation button 108, a power switch 109 for switching on / off the power of the terminal 10, and a network I / F (Interface) 111 for data transmission using the communication network 2 are provided.

  The terminal 10 also includes a built-in camera 112 that captures an image of a subject under the control of the CPU 101 to obtain image data, an image sensor I / F 113 that controls driving of the camera 112, a built-in microphone 114 that inputs sound, and sound. The built-in speaker 115 for outputting the sound, the sound input / output I / F 116 for processing the input / output of the sound signal between the microphone 114 and the speaker 115 according to the control of the CPU 101, and the image data on the external display 120 according to the control of the CPU 101. FIG. 5 shows a display I / F 117 for transmission, an external device connection I / F 118 for connecting various external devices, an alarm lamp 119 for notifying abnormality of various functions of the terminal 10, and the above-described components. A bus line 110 such as an address bus or a data bus is provided for electrical connection. To have.

  The display 120 is a display unit configured by a liquid crystal or an organic EL that displays an image of a subject, an operation icon, and the like. The display 120 is connected to the display I / F 117 by a cable 120c. The cable 120c may be an analog RGB (VGA) signal cable, a component video cable, or an HDMI (High-Definition Multimedia Interface) or DVI (Digital Video Interactive) signal. It may be a cable.

  The camera 112 includes a lens and a solid-state image sensor that converts light into electric charges and digitizes a subject image (video). As the solid-state image sensor, a CMOS (Complementary Metal Oxide Semiconductor) or a CCD (Charge Coupled Device) is used. Etc. are used.

  The external device connection I / F 118 includes an external camera, an external microphone, an external speaker, and the like by a USB (Universal Serial Bus) cable or the like inserted into the connection port 1132 of the housing 1100 shown in FIG. Can be electrically connected to each other. When an external camera is connected, the external camera is driven in preference to the built-in camera 112 under the control of the CPU 101. Similarly, when an external microphone is connected or when an external speaker is connected, each of the external microphones and the built-in speaker 115 is given priority over the internal microphone 114 and the internal speaker 115 according to the control of the CPU 101. An external speaker is driven.

  The recording medium 106 is detachable from the terminal 10. Further, as long as it is a non-volatile memory that reads or writes data according to the control of the CPU 101, not only the flash memory 104 but also an EEPROM (Electrically Erasable and Programmable ROM) or the like may be used.

  Furthermore, the terminal program may be recorded and distributed on a computer-readable recording medium (such as the recording medium 106) in a file in an installable or executable format. The terminal program may be stored in the ROM 102 instead of the flash memory 104.

  FIG. 6 is a hardware configuration diagram of the management system according to this embodiment of the present invention. The management system 50 stores various data such as a CPU 201 that controls the operation of the entire management system 50, a ROM 202 that stores programs used to drive the CPU 201 such as an IPL, a RAM 203 that is used as a work area for the CPU 201, and a transmission management program. The HD 204 to be stored, an HDD (Hard Disk Drive) 205 that controls reading or writing of various data to the HD 204 according to the control of the CPU 201, and a media drive 207 that controls reading or writing (storage) of data to a recording medium 206 such as a flash memory. , A display 208 that displays various information such as a cursor, menu, window, character, or image, a network I / F 209 for transmitting data using the communication network 2, characters, numerical values, A keyboard 211 having a plurality of keys for inputting seed instructions, a mouse 212 for selecting and executing various instructions, selecting a processing target, moving a cursor, etc., and a CD-ROM as an example of a removable recording medium (Compact Disc Read Only Memory) 213, a CD-ROM drive 214 for controlling the reading or writing of various data, and an address bus for electrically connecting the above components as shown in FIG. A bus line 210 such as a data bus is provided.

  The transmission management program is a file in an installable or executable format, and may be recorded and distributed on a computer-readable recording medium such as the recording medium 206 or CD-ROM 213. . The transmission management program may be stored in the ROM 202 instead of the HD 204.

  Further, since the relay device 30 has the same hardware configuration as that of the management system 50, the description thereof is omitted. However, a relay device program for controlling the relay device 30 is recorded in the HD 204. Also in this case, the relay device program is a file in an installable or executable format, and is recorded on a computer-readable recording medium such as the recording medium 206 or CD-ROM 213 for distribution. Good. The relay device program may be stored in the ROM 202 instead of the HD 204.

  Further, since the program providing system 90 and the maintenance system 100 have the same hardware configuration as the management system 50, the description thereof is omitted. However, a program providing program for controlling the program providing system 90 is recorded in the HD 204. Also in this case, the program providing program is a file in an installable or executable format, and may be recorded and distributed on a computer-readable recording medium such as the recording medium 206 or the CD-ROM 213. Good. The program providing system program may be stored in the ROM 202 instead of the HD 204.

As another example of the detachable recording medium, the recording medium is provided by being recorded on a computer-readable recording medium such as a CD-R (Compact Disc Recordable), a DVD (Digital Versatile Disk), or a Blu-ray Disc. May be.
<< Functional Configuration of Embodiment >>
Next, the functional configuration of this embodiment will be described. FIG. 7 is a functional block diagram of each terminal, device, and system constituting the transmission system 1 of the present embodiment. In FIG. 7, the terminal 10, the relay device 30, and the management system 50 are connected so that data communication can be performed via the communication network 2. The program providing system 90 shown in FIG. 1 is omitted in FIG. 7 because it is not directly related to the video conference communication.

<Functional configuration of terminal>
The terminal 10 includes a transmission / reception unit 11, an operation input reception unit 12, a login request unit 13, an imaging unit 14, an audio input unit 15a, an audio output unit 15b, a final narrowing unit 16, a display control unit 17, a delay detection unit 18, and A storage / reading processing unit 19 is provided. Each of these units is a function realized by any one of the constituent elements shown in FIG. 5 being operated by a command from the CPU 101 according to the terminal program developed from the flash memory 104 onto the RAM 103, or It is a means to function. Further, the terminal 10 has a storage unit 1000 constructed by the RAM 103 shown in FIG. 5 and the flash memory 104 shown in FIG.

(Functional configuration of terminal)
Next, each functional configuration of the terminal 10 will be described in detail with reference to FIGS. 5, 7, and 8. In the following, in describing each functional configuration of the terminal 10, among the components illustrated in FIG. 5, a relationship with main components for realizing each functional configuration of the terminal 10 will also be described. . FIG. 8 is a functional configuration diagram of the final narrowing unit.

  The transmission / reception unit 11 of the terminal 10 shown in FIG. 7 is realized by a command from the CPU 101 shown in FIG. 5 and the network I / F 111 shown in FIG. Sends and receives various data (information) to and from the terminal, device or system. The transmission / reception unit 11 starts receiving state information indicating the state of each terminal as a destination candidate from the management system 50 before starting a call with a desired destination terminal. This status information includes not only the operating status of each terminal 10 (online or offline status) but also whether it is possible to make a call even when online, whether a call is in progress, or is away from the desk. The detailed state of is shown. In addition, the status information is not limited to the operating status of each terminal 10, but the cable 120 c is disconnected from the terminal 10 at the terminal 10, audio is output but no image is output, or audio is not output. Various states such as (MUTE) are shown. Below, the case where status information shows an operation state is demonstrated as an example.

  The operation input receiving unit 12 is realized by a command from the CPU 101 shown in FIG. 5 and the operation buttons 108 and the power switch 109 shown in FIG. 5 and receives various inputs by the user. For example, when the user turns on the power switch 109 shown in FIG. 5, the operation input accepting unit 12 shown in FIG. 7 accepts power-on and turns on the power.

  The login request unit 13 is realized by a command from the CPU 101 shown in FIG. 5, and requests login from the transmission / reception unit 11 to the management system 50 via the communication network 2 when the power-on is accepted. And the current IP address of the requesting terminal are automatically transmitted. Further, when the user turns off the power switch 109 from the on state, the operation input receiving unit 12 completely turns off the power after the transmission / reception unit 11 transmits state information indicating that the power is off to the management system 50. To do. Thereby, the management system 50 side can grasp that the terminal 10 has been turned off from being turned on.

  The imaging unit 14 is realized by a command from the CPU 101 illustrated in FIG. 5 and the camera 112 and the image sensor I / F 113 illustrated in FIG. 5. Output data.

  The voice input unit 15a is realized by the command from the CPU 101 shown in FIG. 5 and the voice input / output I / F 116 shown in FIG. 5, and the user's voice is converted into a voice signal by the microphone 140. Thereafter, audio data relating to the audio signal is input. The audio output unit 15b is realized by a command from the CPU 101 shown in FIG. 5 and the audio input / output I / F 116 shown in FIG. 5, and outputs an audio signal related to audio data to the speaker 150. To output sound.

  As shown in FIG. 8, the final narrowing unit 16 performs a final narrowing process for finally narrowing down from a plurality of relay devices 30 to one relay device 30, according to a command from the CPU 101 shown in FIG. A measurement unit 16a, a calculation unit 16b, and a final selection unit 16c are realized.

  Among these, the measurement unit 16 a measures the reception date and time when the pre-transmission information is received by the transmission / reception unit 11 for each pre-transmission information described later received by the transmission / reception unit 11. For each pre-transmission information whose reception date and time is measured by the measurement unit 16a, the calculation unit 16b determines the pre-transmission information based on the difference between the measured reception time and the transmission date and time included in the pre-transmission information. The required time (T) from transmission to reception is calculated. The final selection unit 16c finally selects one relay device by selecting the relay device 30 to which the pre-transmission information that required the shortest required time is relayed among the required times calculated by the calculation unit 16b. .

  The display control unit 17 is realized by the command from the CPU 101 shown in FIG. 5 and the display I / F 117 shown in FIG. The data is divided into two parts, that is, data and extended data. The display control unit 17 also performs control for decoding and combining the basic data and extension data received by the transmission / reception unit 11 and transmitting the image data reproduced in combination to the display 120. Furthermore, the display control unit 17 can also send the destination list information received from the management system 50 to the display 120 and cause the display 120 to display the destination list.

  The delay detection unit 18 is realized by a command from the CPU 101 shown in FIG. 5 and detects a delay time (ms) of image data or audio data sent from another terminal 10 via the relay device 30. .

  The storage / reading processing unit 19 is executed by the instruction from the CPU 101 shown in FIG. 5 and the instruction from the SSD 105 shown in FIG. 5 or realized by the instruction from the CPU 101, and stores various data in the storage unit 1000. Processing for reading various data stored in the unit 1000 is performed. The storage unit 1000 stores a terminal ID (Identification) for identifying the terminal 10, a password, and the like. Furthermore, the storage unit 1000 overwrites and stores image data and audio data received when a call is made with the destination terminal. Among these, the image is displayed on the display 120 by the image data before being overwritten, and the sound is output from the speaker 150 by the sound data before being overwritten.

  Note that the terminal ID of the present embodiment and a relay device ID described later indicate identification information such as a language, characters, symbols, or various signs used to uniquely identify the terminal 10 and the relay device 30, respectively. Further, the terminal ID and the relay device ID may be identification information in which at least two of the language, characters, symbols, and various indicia are combined.

<Functional configuration of relay device>
The relay device 30 includes a transmission / reception unit 31, a state detection unit 32, a data quality confirmation unit 33, a change quality management unit 34, a data quality change unit 35, and a storage / read processing unit 39. Each of these units functions or functions realized by any one of the constituent elements shown in FIG. 6 operating according to a command from the CPU 201 according to the relay device program expanded from the HD 204 onto the RAM 203. Means. The relay device 30 includes a storage unit 3000 configured by the RAM 203 illustrated in FIG. 6 and / or the HD 204 illustrated in FIG. FIG. 10 is a conceptual diagram showing the changed quality management table.

(Change quality control table)
In the storage unit 3000, a change quality management DB (Data Base) 3001 configured by a change quality management table as shown in FIG. In the change quality management table, the IP address of the terminal 30 as the relay destination (destination) of the image data and the image quality of the image data relayed by the relay device 30 are associated with the relay destination and managed.

(Each functional configuration of the relay device)
Next, each functional configuration of the relay device 30 will be described in detail. In the following, in describing each functional configuration of the relay device 30, among the components illustrated in FIG. 6, the relationship with the main components for realizing each functional configuration of the relay device 30 is also described. explain.

  The transmission / reception unit 31 of the relay device 30 shown in FIG. 7 is realized by the command from the CPU 201 shown in FIG. 6 and the network I / F 209 shown in FIG. Various data (information) is transmitted / received to / from other terminals, devices, or systems.

  The state detection unit 32 is realized by a command from the CPU 201 illustrated in FIG. 6, and detects an operating state of the relay device 30 having the state detection unit 32. The operating state includes “online”, “offline”, “busy”, or “temporarily interrupted”.

  The data quality confirmation unit 33 is realized by a command from the CPU 201 shown in FIG. 6, searches the change quality management DB 3001 (see FIG. 10) using the IP address of the destination terminal as a search key, and relays correspondingly. The image quality of the relayed image data is confirmed by extracting the image quality of the image data.

  The change quality management unit 34 is realized by a command from the CPU 201 shown in FIG. 6 and changes the contents of the change quality management DB 3001 based on quality information to be described later sent from the management system 50. For example, a video conference is performed by transmitting and receiving high-quality image data between a request source terminal (terminal 10aa) whose terminal ID is “01aa” and a destination terminal (terminal 10db) whose terminal ID is “01db”. While the request is being made, the requesting terminal (terminal 10bb) and the destination terminal (terminal 10ca) that conduct another videoconference start the videoconference via the communication network 2, etc., so that the destination terminal (terminal 10db) When a delay in receiving the image data occurs, the relay device 30 reduces the image quality of the image data that has been relayed from the high image quality to the medium image quality. In such a case, the content of the change quality management DB 3001 is changed so as to lower the image quality of the image data relayed by the relay device 30 from the high image quality to the medium image quality based on the quality information indicating the medium image quality.

  The data quality changing unit 35 is realized by a command from the CPU 201 shown in FIG. 6, and the image quality of the image data sent from the transmission source terminal 10 is based on the contents of the changed change quality management DB 3001. To change.

  The storage / reading processing unit 39 is realized by an instruction from the CPU 201 illustrated in FIG. 6 and the HDD 205 illustrated in FIG. 6. The storage / reading processing unit 39 stores various data in the storage unit 3000 or is stored in the storage unit 3000. To read various data.

<Functional configuration of management system>
The management system 50 includes a transmission / reception unit 51, a terminal authentication unit 52, a state management unit 53, a terminal extraction unit 54, a terminal state acquisition unit 55, a primary narrowing unit 56, a session management unit 57, a quality determination unit 58, and a storage / read process. Unit 59 and delay time management unit 60. Each of these units functions or functions realized by any one of the constituent elements shown in FIG. 6 operating according to a command from the CPU 201 according to the management system program expanded from the HD 204 onto the RAM 203. Means. Further, the management system 50 has a storage unit 5000 constructed by the HD 204 shown in FIG.

  FIG. 9 is a functional configuration diagram of the primary narrowing-down unit. FIG. 11 is a conceptual diagram showing a relay device management table. FIG. 12 is a conceptual diagram showing a terminal authentication management table. FIG. 13 is a conceptual diagram showing a terminal management table. FIG. 14 is a conceptual diagram showing a destination list management table. FIG. 15 is a conceptual diagram showing a session management table. FIG. 16 is a conceptual diagram showing an address priority management table. FIG. 17 is a conceptual diagram showing a transmission rate priority management table. FIG. 18 is a conceptual diagram showing a quality management table.

(Relay device management table)
In the storage unit 5000, a relay device management DB 5001 configured by a relay device management table as shown in FIG. 11 is constructed. In this relay device management table, for each relay device ID of each relay device 30, the management system 50 receives the reliability of each relay device 30, the operating status of each relay device 30, and the status information indicating the operating status. The date and time, the IP address of the relay device 30, and the maximum data transmission rate (Mbps) in the relay device 30 are associated and managed. For example, in the relay device management table shown in FIG. 11, the relay device 30a with the relay device ID “111a” has the reliability “low”, the operation state “online”, and the management system 50 receives the status information. The date and time of the relay device 30a is “13:00 on November 10, 2009”, the IP address of the relay device 30a is “1.2.1.2”, and the maximum data transmission speed in the relay device 30a is 100 Mbps. It is shown.

(Terminal authentication management table)
Furthermore, in the storage unit 5000, a terminal authentication management DB 5002 configured by a terminal authentication management table as shown in FIG. In this terminal authentication management table, each password is associated with each terminal ID of all terminals 10 managed by the management system 50 and managed. For example, the terminal authentication management table shown in FIG. 12 indicates that the terminal ID of the terminal 10aa is “01aa” and the password is “aaaa”.

(Terminal management table)
Further, in the storage unit 5000, a terminal management DB 5003 configured by a terminal management table as shown in FIG. 13 is constructed. In this terminal management table, for each terminal ID of each terminal 10, a destination name when each terminal 10 is a destination, an operating state of each terminal 10, a reception date and time when login request information described later is received by the management system 50, And the IP address of the terminal 10 is managed in association with each other. For example, in the terminal management table shown in FIG. 13, the terminal 10aa with the terminal ID “01aa” has the terminal name “Japan Tokyo Office AA terminal” and the operation state “online (call possible)” It is indicated that the date and time when the login request information is received by the management system 50 is “13:40 on November 10, 2009” and the IP address of this terminal 10aa is “1.2.1.3”. ing.

(Destination list management table)
Furthermore, in the storage unit 5000, a destination list management DB 5004 configured by a destination list management table as shown in FIG. 14 is constructed. In this destination list management table, all terminal IDs of destination terminals registered as destination terminal candidates are managed in association with terminal IDs of request source terminals that request the start of a call in a video conference. For example, in the destination list management table shown in FIG. 14, a destination terminal candidate that can request the start of a call in a video conference from a request source terminal (terminal 10 aa) whose terminal ID is “01aa” is a terminal The terminal 10ab having an ID “01ab”, the terminal 10ba having a terminal ID “01ba”, the terminal 10bb having a terminal ID “01bb”, and the like are illustrated. This destination terminal candidate is updated by being added or deleted in response to a request for addition or deletion from an arbitrary request source terminal to the management system 50.

(Session management table)
In the storage unit 5000, a session management DB 5005 configured by a session management table as shown in FIG. 15 is constructed. In this session management table, for each selection session ID used to execute a session for selecting the relay device 30, the relay device ID of the relay device 30 used for relaying image data and audio data, the request source terminal Management system that receives a terminal ID, a terminal ID of the destination terminal, a reception delay time (ms) when image data is received at the destination terminal, and delay information indicating the delay time from the destination terminal The reception date and time received at 50 is managed in association with each other. For example, in the session management table shown in FIG. 15, the relay device 30A (relay device ID “111A”) and the relay device 30b (relay device) selected in the session executed using the selection session ID “se1”. ID “111b”) relays image data and audio data between a request source terminal (terminal 10aa) whose terminal ID is “01aa” and a destination terminal (terminal 10db) whose terminal ID is “01db”. In the destination terminal (terminal 10db), it is shown that the delay time of the image data is “200 (ms)” at “14:00 on November 10, 2009”. When a video conference is performed between the two terminals 10, the reception date and time of the delay information may be managed based on the delay information transmitted from the request source terminal instead of the destination terminal. However, when a video conference is performed between three or more terminals 10, the reception date and time of delay information is managed based on the delay information transmitted from the terminal 10 on the image data and audio data receiving side.

(Address priority management table)
Furthermore, in the storage unit 5000, a priority management DB 5006 configured by an address priority management table as shown in FIG. 16 is constructed. In this address priority management table, the dot priority of the dot address is set so that the point of the address priority becomes higher as the “same” of the four sets of dot addresses (Dot Address) of the general IPv4 IP addresses increases. The difference and the address priority are managed in association with each other. This “same” means that the dot address portions are the same, and “different” means that the dot address portions are different. For example, in the address priority management table shown in FIG. 16, when three values are the same IP address from the top to the bottom of the dot address, the address priority point is “5”. When the two values are the same IP address from the top to the bottom of the dot address, the address priority point is “3”. In this case, whether the value of the lowest dot address is the same or not is not related to the priority. In the case of IP addresses having the same highest value of dot addresses and different second values from the top, the address priority point is “1”. In this case, whether or not the values of the third and lowest dot addresses from the top are the same has no relation to the priority. In the case of IP addresses having different uppermost values of dot addresses, the address priority point is “0”. In this case, whether or not the values of the second, third, and lowest dot addresses from the top are the same has no relation to the priority.

(Transmission speed priority management table)
The priority management DB 5006 built in the storage unit 5000 also includes a transmission speed priority management table as shown in FIG. In this transmission rate priority management table, the maximum data transmission rate and the transmission rate priority are set such that the higher the maximum data transmission rate (Mbps) value in the relay device 30, the higher the transmission rate priority point. Associated and managed. For example, in the transmission rate priority management table shown in FIG. 17, when the maximum data transmission rate in the relay apparatus 30 is 1000 Mbps or more, the transmission rate priority point is “5”. When the maximum data transmission rate in the relay device 30 is 100 Mbps or more and less than 1000 Mbps, the transmission rate priority point is “3”. When the maximum data transmission rate in the relay device 30 is 10 Mbps or more and less than 100 Mbps, the transmission rate priority point is “1”. When the maximum data transmission rate in the relay device 30 is less than 10 Mbps, the transmission rate priority point is “0”.

(Quality control table)
Furthermore, in the storage unit 5000, a quality management DB 5007 configured by a quality management table as shown in FIG. In this quality management table, the longer the delay time (ms) of the image data at the requesting terminal or the destination terminal, the lower the image data delay time and the image data quality so that the image quality of the image data relayed by the relay device 30 is lowered. (Image quality) and are managed in association with each other.

(Functional configuration of the management system)
Next, each functional configuration of the management system 50 will be described in detail. In the following, in describing each functional configuration of the management system 50, among the components shown in FIG. 6, the relationship with the main components for realizing each functional configuration of the management system 50 is also described. explain.

  The transmission / reception unit 51 is executed by the command from the CPU 201 shown in FIG. 6 and the network I / F 209 shown in FIG. Information).

  The terminal authentication unit 52 is realized by a command from the CPU 102 shown in FIG. 6, and uses the terminal ID and password included in the login request information received via the transmission / reception unit 51 as a search key, and the storage unit 5000. The terminal authentication management DB 5002 is searched, and terminal authentication is performed by determining whether or not the same terminal ID and password are managed in the terminal authentication management DB 5002.

  The state management unit 53 is realized by an instruction from the CPU 102 shown in FIG. 6, and this request source terminal is stored in the terminal management DB 5003 (see FIG. 13) in order to manage the operating state of the request source terminal that has requested login. The terminal ID, the operating state of the request source terminal, the reception date and time when the login request information is received by the management system 50, and the IP address of the request source terminal are stored and managed in association with each other. In addition, the state management unit 53 performs terminal management based on the state information indicating that the power is turned off, which is sent from the terminal 10 when the user turns the power switch 109 of the terminal 10 from on to off. The operation state indicating online of the DB 5003 (see FIG. 13) is changed to offline.

  The terminal extraction unit 54 is realized by an instruction from the CPU 102 shown in FIG. 6, and searches the destination list management DB 5004 (see FIG. 14) using the terminal ID of the request source terminal that requested the login as a key. The terminal ID is extracted by reading the terminal ID of the candidate destination terminal that can make a call. In addition, the terminal extraction unit 54 searches the destination list management DB 5004 (see FIG. 14) using the terminal ID of the request source terminal that has requested the login as a key, and registers the terminal ID of the request source terminal as a destination terminal candidate. The terminal IDs of other request source terminals are also extracted.

  The terminal status acquisition unit 55 is realized by a command from the CPU 102 shown in FIG. 6 and uses the terminal ID of the destination terminal candidate extracted by the terminal extraction unit 54 as a search key as a terminal management DB 5003 (see FIG. 13). ) And the operation state is read for each terminal ID extracted by the terminal extraction unit 54. Thereby, the terminal state acquisition unit 55 can acquire the operating state of the candidate destination terminal that can make a call with the request source terminal that has requested the login. Further, the terminal state acquisition unit 55 searches the terminal management DB 5003 using the terminal ID extracted by the terminal extraction unit 54 as a search key, and also acquires the operating state of the request source terminal that has requested login.

  The primary narrowing unit 56 is realized by a command from the CPU 102 shown in FIG. 6, and this final narrowing process is performed in order to support a final narrowing process that finally narrows down from a plurality of relay apparatuses 30 to one relay apparatus 30. Perform the previous primary narrowing process. For this purpose, the primary narrowing-down unit 56, as shown in FIG. 9, in response to an instruction from the CPU 201 shown in FIG. 5, the selection session ID generation unit 56a, the terminal IP address extraction unit 56b, the primary selection The unit 56c and the priority determination unit 56d are realized.

  Among these, the selection session ID generation unit 56 a generates a selection session ID used for executing a session for selecting the relay device 30. The terminal IP address extraction unit 56b obtains the terminal management DB 5003 (see FIG. 13) based on the terminal ID of the request source terminal and the terminal ID of the destination terminal included in the start request information sent from the request source terminal. By searching, the IP address of each corresponding terminal 10 is extracted. The primary selection unit 56c selects the relay device ID of the relay device 30 whose operation state is “online” from among the relay devices 30 managed by the relay device management DB 5001 (see FIG. 11). The device 30 is selected.

  Further, the primary selection unit 56c searches the relay device management DB 5001 (see FIG. 11) based on the IP address of the request source terminal and the IP address of the destination terminal extracted by the terminal IP address extraction unit 56b. Thus, for each dot address of the IP address of the selected relay device 30, it is investigated whether it is the same as or different from each dot address in each IP address of the request source terminal and the destination terminal. Further, for each relay device, the primary selection unit 56c includes the higher two relay devices having the higher points of the integrated points obtained by integrating the higher points with respect to the terminal 10 at the address priority points and the transmission speed priority points. By selecting 30, the relay device 30 is further selected. In the present embodiment, the top two relay devices 30 with high points are selected. However, the present invention is not limited to this. If one relay device 30 can be narrowed down as many as possible, the top points with high points are selected. Three or more relay devices 30 may be selected.

  The priority determination unit 56d refers to the priority management DB 5006 (see FIG. 16), and determines an address priority point for each relay device 30 investigated by the primary selection unit 56c. Further, the priority determination unit 56d searches the priority management DB 5006 (see FIG. 17) based on the maximum data transmission rate of each relay device 30 managed by the relay device management DB 5001 (see FIG. 11). The point of the transmission rate priority is determined for each relay device 30 narrowed down by the first narrowing-down process by the primary selection unit 56c.

  Subsequently, the session management unit 57 is realized by an instruction from the CPU 102 shown in FIG. 6, and the selection generated by the selection session ID generation unit 56a in the session management DB 5005 (see FIG. 15) of the storage unit 5000. The session ID, the terminal ID of the request source terminal, and the terminal ID of the destination terminal are stored and managed in association with each other. In addition, the session management unit 57, for the session management DB 5005 (see FIG. 15), for each selection session ID, the relay device of the relay device 30 that is finally selected by the final selection unit 16c of the terminal 10 Store and manage IDs.

  The quality determination unit 58 searches the quality management DB 5007 (see FIG. 18) using the delay time as a search key and extracts the image quality of the corresponding image data, thereby determining the image quality of the image data to be relayed to the relay device 30. To do.

  The storage / read processing unit 59 is executed by the instruction from the CPU 102 shown in FIG. 6 and the HDD 205 shown in FIG. 6, and stores various data in the storage unit 5000 or stored in the storage unit 5000. To read various data.

The delay time management unit 60 is realized by an instruction from the CPU 102 shown in FIG. 6, and searches the terminal management DB 5003 (see FIG. 13) using the IP address of the destination terminal as a search key, thereby corresponding terminals. The ID is extracted, and further, in the session management table of the session management DB 5005 (see FIG. 15), the delay time indicated by the delay information is stored in the field of the delay time in the record including the extracted terminal ID. And manage.
<< Process and Operation of Embodiment >>
Next, a processing method in the transmission system 1 according to the present embodiment will be described with reference to FIGS. FIG. 19 is a sequence diagram illustrating processing for managing state information indicating the state of each relay device 30 transmitted from each relay device 30 to the management system 50. FIG. 20 is a sequence diagram illustrating processing in a preparation stage for starting a call between a plurality of terminals 10. FIG. 21 is a sequence diagram illustrating a process of narrowing down the relay devices 30. FIG. 22 is a process flow diagram illustrating a process of narrowing down the relay devices 30. FIG. 23 is a diagram illustrating a point calculation state when the relay device 30 performs the narrowing-down process. 24 and 25 are sequence diagrams illustrating processing in which the terminal 10 selects the relay device 30. FIG. FIG. 26 is a process flow diagram illustrating a process of selecting the relay device 30 at the terminal. FIG. 27 is a sequence diagram illustrating processing for transmitting and receiving image data and audio data between terminals.

  First, a process for managing state information indicating the state of each relay device 30 transmitted from each relay device 30 to the management system 50 will be described with reference to FIG. First, in each relay device 30, the state detection unit 32 shown in FIG. 7 periodically detects the operating state of the relay device 30 that is its own device (steps S1-1 to S6). Then, the transmission / reception unit 31 of each relay device 30 periodically transmits each state information to the management system 50 via the communication network 2 so that the operation state of each relay device 30 is managed in real time on the management system 50 side. (Steps S2-1 to 6). Each state information includes the relay device ID for each relay device 30 and the operating state detected by the state detection unit 32 of the relay device 30 related to each relay device ID. In the present embodiment, the relay devices (30A, 30B, 30a, 30b, 30d) operate normally and are “online”, while the relay device 30c is in operation, but the relay device 30c. In this example, the program for executing the relay operation is “offline” due to some trouble.

  Next, in the management system 50, the transmission / reception unit 51 receives each status information sent from each relay device 30, and the relay device management DB 5001 in the storage unit 5000 via the storage / read processing unit 59 (see FIG. 11). ) Stores and manages status information for each relay device ID (steps S3-1 to S6). As a result, the operating status of “online”, “offline”, or “failing” is stored and managed for each relay device ID in the relay device management table as shown in FIG. At this time, the reception date and time when the status information is received by the management system 50 is also stored and managed for each relay device ID. If the status information is not sent from the relay device 30, the field portion of the operation state and the field portion of the reception date and time in each record of the relay device management table shown in FIG. The operation status and the reception date and time at the previous reception are shown.

  Next, a transmission / reception process of each management information in a preparation stage before starting a call between the terminal 10aa and the terminal 10db will be described with reference to FIG. In FIG. 20, various types of management information are transmitted and received through the management information session sei shown in FIG.

  First, when the user turns on the power switch 109 shown in FIG. 5, the operation input accepting unit 12 shown in FIG. 7 accepts power on and turns on the power (step S21). The login request unit 13 automatically transmits login request information indicating a login request from the transmission / reception unit 11 to the management system 50 via the communication network 2 when the power-on is received (step S22). The login request information includes a terminal ID and a password for identifying the terminal 10aa that is the own terminal as a request source. These terminal ID and password are data read from the storage unit 1000 via the storage / read processing unit 19 and sent to the transmission / reception unit 11. When the login request information is transmitted from the terminal 10aa to the management system 50, the management system 50 that is the receiving side can grasp the IP address of the terminal 10ab that is the transmitting side.

  Next, the terminal authentication unit 52 of the management system 50 uses the terminal ID and password included in the login request information received via the transmission / reception unit 51 as search keys, and the terminal authentication management DB 5002 of the storage unit 5000 (see FIG. 12). ) And terminal authentication is performed by determining whether the same terminal ID and password are managed in the terminal authentication management DB 5002 (step S23). Since the same terminal ID and password are managed by the terminal authentication unit 52, if it is determined that the login request is from the terminal 10 having a valid usage right, the state management unit 53 The DB 5003 (see FIG. 13) stores the terminal ID of the terminal 10aa, the operating state, the reception date and time when the login request information is received, and the IP address of the terminal 10aa in association with each other (step S24). Accordingly, in the terminal management table shown in FIG. 13, the terminal ID “01aa”, the operation state “online”, the reception date and time “2009.11.10.13:40”, and the IP address “1” of the terminal 10aa are displayed. .2.1.3 "is managed in association with each other.

  Then, the transmission / reception unit 51 of the management system 50 sends the authentication result information indicating the authentication result obtained by the terminal authentication unit 52 via the communication network 2 to the request source terminal (terminal 10aa) that made the login request. (Step S25). In the present embodiment, the case where the terminal authentication unit 52 determines that the terminal has a valid usage right will be described below.

  The terminal extraction unit 54 of the management system 50 searches the destination list management DB 5004 (see FIG. 14) using the terminal ID “01aa” of the request source terminal (terminal 10aa) that requested the login as a search key, and requests the request source terminal (terminal 10aa). The terminal IDs of candidate destination terminals that can communicate with the destination terminal are read out (step S26). Here, the terminal IDs (“01ab”, “01ba”, “01db”) of the destination terminals (terminals 10ab, 10ba, 10db) corresponding to the terminal ID “01aa” of the request source terminal (terminal 10aa) are extracted. Will be.

  Next, the terminal state acquisition unit 55 uses the terminal IDs (“01ab”, “01ba”, “01db”) of the destination terminal candidates extracted by the terminal extraction unit 54 as search keys, and the terminal management DB 5003 (FIG. 13). Each of the terminals (10ab, 10ba, 10db) by reading the operating state ("offline", "online", "online") for each terminal ID extracted by the terminal extracting unit 54. A state is acquired (step 27).

  Next, the transmission / reception unit 51 uses the terminal IDs (“01ab”, “01ba”, “01db”) as the search keys used in step 27 and the corresponding destination terminals (terminals 10ab, 10ba, 10db). Are transmitted to the requesting terminal (terminal 10aa) via the communication network 2 (step S28). The destination state information including the respective operating states (“offline”, “online”, “online”). As a result, the request source terminal (terminal 10aa) has the respective current operating states (“offline” of the terminals (10ab, 10ba, 10db) that are candidates for destination terminals that can communicate with the request source terminal (terminal 10aa). ”,“ Online ”,“ online ”).

  Further, the terminal extraction unit 54 of the management system 50 searches the destination list management DB 5004 (see FIG. 14) using the terminal ID “01aa” of the request source terminal (terminal 10aa) that requested the login as a search key, and the request source The terminal IDs of other requesting terminals that have registered the terminal ID “01aa” of the terminal (terminal 10aa) as candidates for the destination terminal are extracted (step S29). In the destination list management table shown in FIG. 14, the terminal IDs of the other request source terminals to be extracted are “01ab”, “01ba”, and “01db”.

  Next, the terminal status acquisition unit 55 of the management system 50 searches the terminal management DB 5003 (see FIG. 13) using the terminal ID “01aa” of the request source terminal (terminal 10aa) that requested the login as a search key. Then, the operating state of the request source terminal (terminal 10aa) that has made the login request is acquired (step S30).

  Then, the transmission / reception unit 51 includes the terminal management DB 5003 (FIG. 13) among the terminals (10ab, 10ba, 10db) related to the terminal IDs (“01ab”, “01ba”, “01db”) extracted in step S29. The terminal (10ba, 10db) whose operation state is “online” in the reference) includes the terminal ID “01aa” and the operation state “online” of the request source terminal (terminal 10aa) acquired in step S30. The destination state information is transmitted (steps S31-1, 2). When the transmission / reception unit 51 transmits the destination status information to the terminals (10ba, 10db), it is managed by the terminal management table shown in FIG. 13 based on the terminal IDs (“01ba”, “01db”). Refers to the IP address of the terminal being used. Accordingly, the request source terminal (terminal 10aa) that requested the login is sent to each of the other destination terminals (terminals 10db and 10ba) that can communicate with the request source terminal (terminal 10aa) that requested the login. The terminal ID “01aa” and the operation state “online” can be transmitted.

  On the other hand, in the other terminals 10 as well, when the user turns on the power switch 109 shown in FIG. 6, the operation input receiving unit 12 shown in FIG. Since the same processing as the processing of steps S22 to S31-1, 2 is performed, the description thereof is omitted.

  Next, processing for narrowing down the relay devices 30 will be described with reference to FIG. Note that FIG. 21 illustrates a process in which various types of management information are transmitted and received through the management information session sei illustrated in FIG. In the present embodiment, the request source terminal (terminal 10aa) is the terminal (10ba, 10db) whose operation state is online based on the terminal state information received in step S32 among the terminals 10 as destination candidates. ) And at least one of them. Therefore, hereinafter, a case where the user of the request source terminal (terminal 10aa) has selected to start a call with the destination terminal (terminal 10db) will be described.

  First, when the user presses the operation button 108 shown in FIG. 5 to select the terminal 10db, the operation input reception unit 12 shown in FIG. 7 issues a request to start a call with the destination terminal 10db. Accept (step S41). Then, the transmission / reception unit 11 of the request source terminal (terminal 10aa) includes the terminal ID “01aa” of the terminal 10aa and the terminal ID “01db” of the destination terminal (terminal 10db), and indicates a start request indicating that a call is to be started. Information is transmitted to the management system 50 (step S42). Accordingly, the transmission / reception unit 51 of the management system 50 can receive the start request information and grasp the IP address “1.2.1.3” of the request source terminal (terminal 10aa) that is the transmission source. .

  Then, based on the terminal ID “01aa” of the request source terminal (terminal 10aa) and the terminal ID “01db” of the destination terminal (terminal 10db) included in the start request information, the state management unit 53 determines the terminal management DB 5003 (see FIG. 13). ) In the terminal management table, both of the field portions of the operation state of the records each including the terminal ID “01aa” and the terminal ID “01db” are changed to “busy” (step S43). In this state, the request source terminal (terminal 10aa) and the destination terminal (terminal 10db) have not started a call, but are in a call state and the other terminal 10 is a request source terminal (terminal 10aa) or a destination terminal. When a call is made to (terminal 10db), a notification sound or a display indicating a so-called busy state is output.

  Next, a process for executing a session for selecting the relay device 30 will be described. First, the selection session ID generation unit 56a shown in FIG. 9 generates a selection session ID used for executing a session for selecting the relay device 30 (step S44). Then, the session management unit 57 stores the selection session ID “se1” generated in step S44 and the terminal ID “01aa” of the request source terminal (terminal 10aa) in the session management DB 5005 (see FIG. 15) of the storage unit 5000. And the terminal ID “01db” of the destination terminal (terminal 10db) are stored and managed in association with each other (step S45).

  Next, the primary screening unit 56 of the management system 50 shown in FIG. 7 includes a request source terminal (terminal 10aa) and a destination terminal based on the relay device management DB 5001, the terminal management DB 5003, and the priority management DB 5006. The primary narrowing down of the relay device 30 for relaying a call with the (terminal 10db) is performed (step S46).

  Here, the process in step S46 will be described in more detail with reference to FIG. First, the terminal IP address extraction unit 56b shown in FIG. 9 has the terminal ID “01aa” of the request source terminal (terminal 10aa) included in the start communication information sent from the request source terminal (terminal 10aa). By searching the terminal management DB 5003 (see FIG. 13) based on the terminal ID “01db” of the destination terminal (terminal 10db), the IP addresses (“1.2” of the corresponding terminals (10aa, 10db) are searched. 1.3 ”and“ 1.3.2.4 ”) are extracted (step S46-1).

  Next, the primary selection unit 56c selects each of the relay devices (30a, 30b, 30d) that are “online” among the operating states of the relay device 30 managed by the relay device management DB 5001 (see FIG. 11). The relay device ID (111a, 111b, 111d) is selected (step S46-2). Further, the primary selection unit 56c extracts the IP address “1.2.1.3” of the request source terminal (terminal 10aa) and the IP address “1” of the destination terminal (terminal 10db) extracted in step S46-1. .3.2.4 "is used to search the relay device management DB 5001 (see FIG. 11), and thereby each IP address (" "of the relay device (30a, 30b, 30d) selected in step S46-2 is selected. "1.2.1.2.", "1.2.2.2", "1.3.2.2") for each dot address of the request source terminal (terminal 10aa) and destination terminal (terminal 10db). ) Is checked whether it is the same as or different from each dot address in each IP address (“1.2.1.3”, “1.3.2.4”) (step S46-3).

  Next, the priority determination unit 57c refers to the priority management DB 5006 (see FIG. 16), and determines the point of the address priority for each relay device (30a, 30b, 30d) investigated in step 46-3. Is determined (step S46-4). When the result of this determination process is shown in a table, the state shown in FIG. 23 is obtained. FIG. 23 is a diagram illustrating a calculation state of priority points when the relay device 30 performs the narrowing-down process. In FIG. 23, an address priority point, a transmission speed priority point, and an integration point are shown for each relay device ID. The address priority points further indicate points for the request source terminal (terminal 10aa) and points for the destination terminal (terminal 10db) of each relay device 30. The integration point is the sum of the higher one of the two address priority points and the transmission speed priority point.

  In the present embodiment, the IP address “1.2.1.2” of the relay device 30a is different from the IP address “1.2.1.3” of the request source terminal (terminal 10aa). .. ”, the address priority point is“ 5 ”as shown in FIG. Further, as shown in FIG. 1, the IP address “1.2.1.2” of the relay device 30a is different from the IP address “1.3.2.4” of the destination terminal (terminal 10db). As shown in FIG. 16, since “same. Different. Different. Different”, the point of the address priority is “1” as shown in FIG. Further, the IP address “1.2.2.2” of the relay device 30b is “same. Same. Different. Different” with respect to the IP address “1.2.1.3” of the request source terminal (terminal 10aa). Therefore, the address priority point is “3”. Further, the IP address “1.2.2.2” of the relay device 30b is “same. Different. Same. Different” with respect to the IP address “1.3.2.4” of the destination terminal (terminal 10db). Therefore, the point of address priority is “1”. Further, the IP address “1.3.2.2” of the relay device 30d is “same. Different. Different. Different” with respect to the IP address “1.2.1.3” of the request source terminal (terminal 10aa). Therefore, the address priority point is “1”. Further, the IP address “1.3.2.2” of the relay device 30d is “same. Same. Same. Different” with respect to the IP address “1.3.2.4” of the destination terminal (terminal 10db). Therefore, the address priority point is “5”.

  Next, returning to FIG. 22, the priority determination unit 57d determines the priority management DB 5006 (FIG. 17) based on the maximum data transmission rate of each relay device 30 managed by the relay device management DB 5001 (see FIG. 11). By searching for (reference), the point of the transmission speed priority is determined for each relay device (30a, 30b, 30d) narrowed down by the first narrowing-down process in step S46-2 (step S46-5). In the present embodiment, as shown in FIG. 11, the maximum data transmission rate of the relay device 30a is 100 (Mbps). Therefore, referring to the transmission rate priority shown in FIG. The degree is 3 points. Similarly, if the maximum data transmission rate of the relay device 30b is calculated to be 1000 (Mbps), the transmission rate priority is 5 points. Similarly, if the maximum data transmission rate of the relay device 30d is calculated to be 10 (Mbps), the transmission rate priority is 1 point.

  Next, for each relay device (30a, 30b, 30d), the primary selection unit 56c integrates the higher point of the terminals (10aa, 10db) and the transmission speed priority point at the address priority point. Among the integrated points, the top two relay devices 30 with the highest points are selected (step 46-6). In the present embodiment, as shown in FIG. 23, since the relay device IDs (111a, 111b, 111d) have integration points “8”, “8”, and “6”, respectively, the relay device ID “ The relay device 30a related to “111a” and the relay device 30b related to the relay device ID “111b” are selected.

  When the narrowing-down process in step S46 is completed, the transmission / reception unit 51 illustrated in FIG. 7 transmits the number of narrowed relay apparatuses 30 to the destination terminal (terminal 10db) via the communication network 2. Relay device narrowing information is transmitted (step S47). The relay device narrowing information includes the number “2” of the relay devices 30 narrowed down in the step 46, the terminal ID “01aa” of the request source terminal (terminal 10aa), and the selection session ID “se1”. It is. Thereby, the terminal 10db can grasp how many relay devices 30 are in the execution of the session with the selection session ID “se1” and which terminal 10 has requested to start a call. At the same time, the IP address “1.1.1.2” of the management system 50 that is the transmission source of the relay device narrowing information can be grasped.

  Then, the terminal 10db transmits reception completion information indicating that reception of the relay device narrowing information is completed from the transmission / reception unit 11 to the management system 50 via the communication network 2 (step S48). This reception completion information includes the session ID “se1”. As a result, the management system 50 completes the transmission of the number of relay apparatuses being executed with the session ID “se1”, and the IP address “1.3.2.4” of the destination terminal (terminal 10db) that is the transmission source. Can be grasped.

  Next, a process in which the destination terminal (terminal 10db) selects the relay device 30 will be described with reference to FIGS. In FIG. 24 and FIG. 25, various types of management information are transmitted and received through the management information session sei shown in FIG.

  First, before starting a video conference call, the management system 50 applies to each of the high-reliability relay devices (30A, 30B) and the relay devices (30a, 30b) narrowed down in step S46. Prior relay request information for requesting relay in advance is transmitted (steps S61-1 to S6-4). The pre-relay request information includes the session ID “se1”, the IP address “1.2.1.3” of the request source terminal (terminal 10aa), and the IP address “1.3.2” of the destination terminal (terminal 10db). .4 "is included. As a result, each relay device (30A, 30B, 30a, 30b) can grasp which selection session it belongs to, what the request source terminal is, and what the destination terminal is, The IP address “1.1.1.2” of the management system 50 that is the transmission source of the advance relay request information can be grasped.

  In FIG. 24, the highly reliable relay device (30a, 30b) is represented as the first relay device group, and the relay device (30a, 30b) narrowed down in step S46 is defined as the second relay device group. It is represented.

  Next, each relay device (30A, 30B, 30a, 30b) starts a call from the transmission / reception unit 31 to the request source terminal (terminal 10aa) grasped in steps S61-1 to S4-4 via the communication network 2. Prior transmission request information indicating that prior transmission information including ping (Packet Internet Groper) to be described later is transmitted to each relay device (30A, 30B, 30a, 30b) as its own device (step) S62-1 to 4). This pre-transmission information includes the session ID “se1”. Thereby, the request source terminal (terminal 10aa) transmits the pre-transmission information to each relay device (30A, 30B, 30a, 30b) in the selection process of the relay device 30 executed with the session ID “se1”. And the IP addresses of the relay devices (30A, 30B, 30a, 30b) that are the transmission sources of the advance transmission request information.

  The management system 50 directly notifies the IP address of the destination terminal to the relay device 30a as in step 61-1, without notifying the request source terminal of the IP address of the destination terminal. As in step 61-2, the relay device 30a requests the request source terminal to transmit the pre-transmission request information to the own device (relay device 30a). This is to ensure security by not informing the IP address of 10.

  Next, the request source terminal (terminal 10aa) transmits the first pre-transmission information from the transmission / reception unit 11 to the first relay device group (30A, 30B) via the communication network 2, and the second relay. The second pre-transmission information is transmitted to the device group (30a, 30b) (steps S63-1 to S63-4). Prior to the transmission of the image data and audio data, the first and second pre-transmission information is sent to the destination terminal (30A, 30B, 30a, 30b) via each relay device (30A, 30B, 30a, 30b). It is information used for measuring the time required from transmission of the request source terminal (terminal 10aa) to reception of the destination terminal (terminal 10db) by being transmitted to the terminal 10db). The prior transmission information is used to confirm that the request source terminal (terminal 10aa), the relay device (30A, 30B, 30a, 30b), and the destination terminal (terminal 10db) are communicably connected. ping, the transmission date and time when each pre-transmission information is transmitted from the request source terminal (terminal 10aa), and the session ID “se1” are included. Thereby, each relay device (30A, 30B, 30a, 30b) can grasp that the first or second pre-transmission information has been sent in the execution of the session with the selection session ID “se1”. The IP address “1.2.1.3” of the request source terminal (terminal 10aa) that is the transmission source of the first and second pre-transmission information can be grasped.

  Next, each highly reliable relay device (30A, 30B) receives the IP address “1.3 of the destination terminal (terminal 10db) included in the pre-relay request information received in steps S61-1, 2 above. .2.4 ", the first pre-transmission information is relayed (steps S64-1, 2). Thereby, the destination terminal (terminal 10db) can grasp that the first pre-transmission information has been sent in the execution of the session with the session ID “se1”, and the transmission source of the first pre-transmission information The IP address (“1.1.3.2”, “1.1.4.2”) of the relay device (30A, 30B) that is the (relay source) can be grasped. Similarly, each low-reliability relay device (30a, 30b) receives the IP address “1.3.2” of the destination terminal (terminal 10db) included in the pre-relay request information received in steps S61-3 and S4. .4 ", the first or second pre-transmission information is relayed (steps S64-1, 2). As a result, the destination terminal (terminal 10db) can grasp that the large amount of prior transmission information has been sent in the execution of the session with the session ID “se1”, and the transmission source of the second prior transmission information The IP address (“1.2.1.2”, “1.2.2.2”) of the relay device (30a, 30b) that is the (relay source) can be grasped.

  Next, as shown in FIG. 25, the final narrowing unit 16 of the destination terminal (terminal 10db) finally stores the image in the video conference call based on the first and second pre-transmission information. The basic data is narrowed down to one relay device 30 and the image extension data and audio data are narrowed down to one relay device 30 (step S65).

  Here, the process in step S65 will be described in more detail with reference to FIGS. First, the measurement unit 16a of the final narrowing unit 16 illustrated in FIG. 8 transmits and receives the transmission / reception unit 11 of the terminal 10db for each first pre-transmission information relayed by the first relay device group (30A, 30B). The reception date and time when it is received is measured (step S65-1). Similarly, the measurement unit 16a measures the reception date and time when it is received by the transmission / reception unit 11 of the terminal 10db for each second pre-transmission information relayed by the second relay device group (30a, 30b) (step) S65-1).

  Next, the calculation unit 16b includes the measured reception time, the first preliminary transmission information, and the second preliminary transmission information for each of the first and second preliminary transmission information for which the reception time is measured. Based on the difference from the transmission time, the required time from transmission to reception of the first and second pre-transmission information is calculated (step S65-2). Next, in the execution of the session with the session ID “se1”, the final selection unit 16c has received all the first and second pieces of pre-transmission information corresponding to the number “2” of relay devices 30 scheduled to be relayed. Is determined (step S65-3). And when not having received all (NO), the last selection part 16c is predetermined time after receiving the last prior transmission information at the time among the 1st and 2nd prior transmission information with the terminal 10db. It is determined whether (here 1 minute) has passed (step S65-4). Further, if the predetermined time has not elapsed (NO), the process returns to step S65-1. On the other hand, when all of the information is received in step 65-3 (YES) or when a predetermined time has elapsed in step S65-4 (YES), the final selection unit 16c includes the first pre-transmission information. The difference between the required time of the predetermined first pre-transmission information and the required time of the predetermined second pre-transmission information among the second pre-transmission information, the required time of the predetermined first pre-transmission information, And the predetermined first and second relay apparatuses respectively relaying the first and second pre-transmission information in a combination that minimizes the time required for adding the required time of the predetermined second pre-transmission information. Is selected (step S65-5).

In other words, the final selection unit 16c selects a combination of the first and second relay devices so that the following evaluation function f has a minimum value.
f (i, j) = a * d_h (i) + b * d_l (i) + c * | d_h (i) −d_l (i) |
d_h (k) is a required time from transmission to reception of the first pre-transmission information (network delay time) when the highly reliable relay device k is used.
d_l (k) is the time required from transmission to reception of the second pre-transmission information when using the low-reliability relay device k (network delay time)
a, b, c are constants
Note that the “c * | d_h (i) −d_l (i) |” portion reduces the difference in required time from transmission to reception of the basic data and the extended data so that the highly reliable relay apparatus is low. A combination of reliable relay devices is determined. In addition, the “a * d_h (i) + b * d_l (i)” portion allows reception from the transmission of each of the basic data and the extension data even if the difference in the time required from the transmission of the basic data to the extension data is small. It can be stopped so that the time required until is not too long.

Next, a specific example when the above evaluation function f is used will be shown. For example, the time required for each first pre-transmission information when using the highly reliable first relay device (30A, 30B) is 0.01 seconds and 01 seconds, respectively. It is assumed that the time required for each second pre-transmission information when using the relay devices (30a, 30b) is 0.1 seconds and 0.5 seconds, respectively. When the constants a, b, and c are all 1, the value of the evaluation function f is as follows.
(1) In the case of a combination of the first relay device 30A and the second relay device 30a: f (30A, 30a) = 00.1 + 0.1 + | 0.01−0.1 | = 1.01
(2) In the case of a combination of the first relay device 30B and the second relay device 30a: f (30B, 30a) = 0.1 + 0.1 + | 0.1−0.1 | = 0.2
(3) In the case of a combination of the first relay device 30A and the second relay device 30b f (30A, 30b) = 0.01 + 0.5 + | 0.01−0.5 | = 1.0
(4) In the case of a combination of the first relay device 30B and the second relay device 30b: f (30B, 30b) = 0.1 + 0.5 + | 0.1−0.5 | = 1.0
From the above, the value of the evaluation function f becomes the minimum value in the case of the combination of the first relay device 30B and the second relay device 30b. Therefore, in this case, the final selection unit 16c selects the first relay device 30B from the first relay device group (30A, 30B) and also from the second relay device group (30a, 30b). The second relay device 30b is selected.

  In addition, without using the evaluation function f as described above, the final selection unit 16c determines the time required for the predetermined first pre-transmission information and the second pre-transmission information among the first pre-transmission information. The predetermined first and second relay devices that respectively relay the first and second pre-transmission information in a combination that minimizes the difference from the required time of the predetermined second pre-transmission information are selected. May be.

  That is, a combination of the first and second relay devices is selected such that the following evaluation function F is the minimum value.

F (i, j) = | d_h (i) −d_l (i) |
d_h (k) and d_l (k) are the same as in the case of the evaluation function f. In the above embodiment, the relay device 30b is narrowed down on the destination terminal side, but this is not restrictive. By transmitting all the required time information indicating the required time from transmission to reception of the pre-transmission information to the original terminal or the management system 50, one request is finally made on the request source terminal side or the management system 50 side. 30b may be narrowed down.

  Next, the destination terminal (terminal 10db) transmits selection information indicating that the relay device (30A, 30b) has been selected from the transmission / reception unit 11 to the management system 50 via the communication network 2 (step S66). This selection information includes the session ID “se1” and the relay device ID (“111A”, “111b”) of the selected relay device (30A, 30b). As a result, the management system 50 can grasp that the relay device (30A, 30b) has been selected in the execution of the session with the session ID “se1”, and the destination terminal (terminal 10db) that is the transmission source of the selection information. The IP address “1.3.2.4” can be grasped.

  Next, the session management unit 57 of the management system 50 finally adds 1 to the field part of the relay device ID of the record including the session ID “se1” in the session management table of the session management DB 5005 (see FIG. 15). The relay device ID “111a” of the selected relay device 30a is stored and managed (step S67). Then, the transmission / reception unit 51 of the management system 50 transmits relay start request information indicating a request to start relay to the relay devices (30A, 30b) via the communication network 2 (step S68-1). , 2). In this relay start request information, each IP address (“1.2.1.3”, “1.3.2.4”) of the request source terminal (terminal 10aa) and destination terminal (terminal 10db) to be relayed is included. It is included. As a result, the relay device 30A can grasp that the relay device 30A that is its own device has been selected, and therefore establishes a session for calling the low-resolution image data between the terminals (10aa, 10db) ( Step S69-1). In addition, since the relay device 30b can grasp that the relay device 30b as its own device has been selected, two image data of medium resolution and high resolution, and audio data between the terminals (10aa, 10db). A session for making a call is established (step S69-2). Accordingly, the terminals (10aa, 10db) can start a video conference call.

  In step S47, the management system 50 transmits relay device narrowing information to the destination terminal (terminal 10db), and relays on the destination terminal (terminal 10db) side through steps S48 to S64-1,2. Although the device selection process (step S65) has been performed, the present invention is not limited to this. In step S47, the management system 50 transmits the relay device narrowing information to the request source terminal (terminal 10aa). From S64-1 and S64-1, the transmission source and reception source of each information may be switched between the request source terminal (terminal 10aa) and the destination terminal (terminal 10db). Thereby, the request source terminal (terminal 10aa) can perform the relay device selection process instead of step S65, and can also transmit the selection information instead of step S66.

  Next, a process of transmitting and receiving image data and audio data to perform a video conference call between the request source terminal and the destination terminal will be described with reference to FIGS. First, the display control unit 17 of the request source terminal (terminal 10aa) uses basic data (low resolution image data) and extended data (medium resolution image data, high resolution) from the image data of the subject imaged by the imaging unit 14a. The transmission / reception unit 11 transmits the extended data including the audio data to the relay device 30b through the image / audio data session sedL shown in FIG. 2 (step S81). Accordingly, in the relay device 30a, the transmission / reception unit 31 receives medium resolution image data, high resolution image data, and audio data as extension data. Then, the data quality confirmation unit 33 searches the change quality management DB 3001 (see FIG. 10) based on the IP address “1.3.2.4” of the destination terminal (terminal 10db), and corresponding image data to be relayed. By extracting the image quality (image quality level), the image quality of the image data to be relayed is confirmed (step S82). In the present embodiment, the image quality of the confirmed image data is “high image quality”, which is the same as the image data quality of the image data received by the transmission / reception unit 31, and therefore the relay device 30a uses the image / audio data session sedL. The extended image quality and audio data is transmitted to the destination terminal (terminal 10db) (step S83).

  On the other hand, the basic data is transmitted from the transmission / reception unit 11 of the request source terminal (terminal 10aa) to the destination terminal (terminal 10db) via the highly reliable relay device 30A by the image / audio data session sedH. Since the quality of the image data is not changed as in step S93 described later, detailed description thereof is omitted.

As described above, the destination terminal (terminal 10db) receives the high-quality image data and the audio data including the low resolution, the medium resolution, and the high resolution at the transmission / reception unit 11. Then, the display control unit 17 can decode and combine the three image quality image data, display an image on the display 120, and the sound output unit 15b can output sound based on the sound data.

  Next, the delay detection unit 18 of the terminal 10db detects the delay time of reception of the extension data received by the transmission / reception unit 11 at regular intervals (for example, every second) (step S84). In the present embodiment, the following description is continued for a case where the delay time is 200 (ms).

  The transmission / reception unit 11 of the destination terminal (terminal 10db) sends delay information indicating the delay time “200 (ms)” to the management system 50 via the communication network 2 by the management information session sei shown in FIG. Transmit (step S85). As a result, the management system 50 can grasp the delay time and the IP address “1.3.2.4” of the terminal 10db that is the transmission source of the delay information.

  Next, the delay time management unit 60 of the management system 50 searches the terminal management DB 5003 (see FIG. 13) based on the IP address “1.3.2.4” of the destination terminal (terminal 10db). The corresponding terminal ID “01db” is extracted, and further, in the session management table of the session management DB 5005 (see FIG. 15), the delay information field part of the record of the terminal ID “01db” is indicated by the delay information. The stored delay time “200 (ms)” is stored and managed (step S86).

  Next, the quality determination unit 58 searches the quality management DB 5007 (see FIG. 18) based on the delay time “200 (ms)”, and extracts the image quality “medium image quality” of the image data portion of the corresponding extended data. Thus, the image quality is determined as “medium image quality” (step S87).

  Next, the transmission / reception unit 51 uses the relay device management DB 5001 (FIG. 11) based on the relay device ID “111b” associated with the terminal ID “01db” in the session management table of the session management DB (see FIG. 15). Search) and the IP address “1.2.2.2” of the corresponding relay device 30b is extracted (step S88). Then, the transmission / reception unit 51 transmits the quality “medium image quality” of the image data determined in step 87 to the relay apparatus 30b via the communication network 2 by the management information session sei shown in FIG. Information is transmitted (step S89). This quality information includes the IP address “1.3.2.4” of the destination terminal (terminal 10db) used as the search key in step S86. Accordingly, in the relay device 30b, the change quality management unit 34 stores the IP address “1.3.2.4” of the destination terminal 10 (here, the terminal 10db) in the change quality management DB 3001 (see FIG. 10). , And the image quality “medium image quality” of the relayed image data is stored and managed in association with each other (step S90).

  Next, the terminal 10aa continues to the basic data (low-resolution image data and extension data (medium-resolution image data, high-resolution image data) to the relay device 30b through the image / sound data session sed as in step S81. (Step S91) As a result, in the relay device 30b, as in step S82, the data quality confirmation unit 33 sends the IP address “1.3 of the destination terminal (terminal 10db). .2.4 ”is searched for the quality management database 3001 (see FIG. 10), and the image quality“ medium image quality ”of the corresponding image data to be relayed is extracted to thereby determine the image quality of the image data to be relayed. In this embodiment, the image quality of the confirmed image data is “medium image quality” and the image received by the transmission / reception unit 31 is confirmed. Since the image quality of the data is lower than the “high image quality”, the data quality changing unit 35 changes the image quality of the image data by suppressing the image quality of the image data from “high image quality” to “medium image quality” ( Step S93).

Then, the transmission / reception unit 31 transmits, to the destination terminal (terminal 10db) by the image / sound data session sedL, the extended data including the image data whose image quality is changed to “medium image quality” and the sound data whose sound quality is not changed. Is transmitted (step S94). As a result, the destination terminal (terminal 10db) receives the basic data (low-resolution image data) and the extended data (medium-resolution image data and audio data) by the transmission / reception unit 11. Then, the display control unit 17 decodes and combines the low-resolution image data and the medium-quality image data to display the image on the display 120, and the audio output unit 15b outputs the audio based on the audio data. Can do.

As described above, when reception delay occurs at the destination terminal (terminal 10db) that receives the image data, the relay device 30b changes the quality of the image and gives a strange feeling to the person participating in the video conference. Can not be.
<< Main effects of this embodiment >>
As described above, according to the present embodiment, basic data and extended data are received via different relay apparatuses (30A, 30b), and the average failure interval has a high reliability with a predetermined time or more. To receive basic data essential for content data reproduction via the relay device 30A, and to improve the quality of content data reproduction via the relay device 30b having low reliability with an average failure interval less than a predetermined time. Therefore, it is possible to eliminate problems such as delay, interruption or cancellation of the reproduction of the content data at the destination terminal on the receiving side as much as possible.

  In addition, even if the environment of the LAN 2 such as the IP address of the relay device 30 in the communication network 2 can be grasped, it is difficult to grasp the entire environment of the Internet 2i. The information is narrowed down to two or more of the plurality of relay devices 30 that relay the extended data. Then, before actually transmitting / receiving the extension data among the plurality of terminals 10, it is possible to actually relay the advance transmission information earliest by transmitting / receiving the advance transmission information instead of the extension data. There is an effect that it can be narrowed down to one possible relay device 30.

  That is, by selecting the relay device 30 to which the upper two or more IP addresses close to any of the IP addresses of the terminal 10 are assigned, two or more candidates for the relay device 30 to be finally used are left. be able to. As a result, the transmission / reception information is transmitted / received between the request source terminal and the destination terminal via each relay device 30 that is actually a candidate, so that transmission / reception among the two or more candidate relay devices 30 is performed. Can be narrowed down to relay devices 30 that relayed the pre-transmission information with the shortest required time. Therefore, it is possible to realize the transmission and reception of the high-quality extension data to the maximum in the current communication network 2 environment.

  In the present embodiment, when narrowing down the relay devices 30, not only the relay device 30 having an IP address close to the IP address of the terminal 10 that conducts the video conference is preferentially selected, but the maximum data transmission in each relay device 30 is also performed. In consideration of speed, two or more relay devices 30 are selected. Thereby, the effect that the candidate of the relay apparatus 30 according to the environment of the actual communication network 2 can be narrowed down is produced.

  Furthermore, in this embodiment, when the relay devices 30 are narrowed down, the relay devices 30 whose operation state is online are narrowed down, and therefore, the candidates for the relay devices 30 that are more suitable for the actual network 2 environment can be narrowed down. .

  In addition, the final selection unit 16c selects a combination of the high reliability relay device 30 and the low reliability relay device 30 using the evaluation function f ′, so that the basic data and the extended data can be transmitted and received. A combination of a highly reliable relay device and a low reliability relay device can be determined so that the difference in required time is minimized.

Further, the final selection unit 16c selects a combination of the high reliability relay device 30 and the low reliability relay device 30 using the evaluation function f, so that the requirements from transmission to reception of basic data and extension data are required. It is possible to determine a combination of a highly reliable relay device and a low reliability relay device so that the time difference is shortened and the required time from transmission to reception of basic data and extension data itself is shortened. it can.
[Second Embodiment]
Hereinafter, a second embodiment of the present invention will be described with reference to FIG. FIG. 28 is a sequence diagram illustrating processing in which a terminal selects a relay device according to the second embodiment of the present invention. Note that since the present embodiment and the first embodiment are different only in the processing and operations in FIG. 28 and FIG. 24, only the differences in processing and operations will be described here, as shown below. To do.
<< Processing and Operation of Embodiment >>
In steps S61-1, S62-1; S61-2, S62-2; S61-3, S62-1; S61-4, S62-4 in FIG. 24 of the first embodiment, each relay is performed from the management system 50. In the present embodiment, the request source is directly requested from the management system 50 while the request request terminal (terminal 10aa) is requested to transmit the pre-request information via the devices (30A, 30B, 30a, 30b). Both differ in that the prior request information is transmitted to the terminal (terminal 10aa).

  That is, in the present embodiment, as shown in FIG. 28, first, the management system 50 transmits pre-transmission request information to the request terminal 10aa (step S161-1). The pre-transmission request information in this case includes the session ID “se1”, the first relay device group (30A, 30B), and the IP addresses of the second relay device group (30a, 30b) that have been primarily narrowed down. ("1.1.3.2", "1.1.4.2", "1.2.1.2", "1.2.2.2") and the destination terminal (terminal 10db) The IP address “1.3.2.4” is included. As a result, the request source terminal (terminal 10aa) becomes the final narrowing candidate by the primary narrowing down which selection session it belongs to and what the IP address of the highly reliable second relay device is. It is possible to know what the second relay device 30 is and what the IP address of the destination terminal (terminal 10db) is, and the IP address “1” of the management system 50 that is the transmission source of the advance transmission request information. .1.1.2 ”.

Next, the request source terminal (terminal 10aa) transmits the first pre-transmission information to the first relay device (30A, 30B) (steps S162-1, 2), and the second relay device (30a, 30a). The second pre-transmission information is transmitted to 30b) (steps S162-3, 4). These first and second pre-transmission information are transmitted from the requesting terminal (terminal 10aa) by the first and second pre-transmission information, respectively, as in Steps S63-1, 2 in the first embodiment. In addition to the transmission date and time and the session ID “se1”, the IP address “1.3.2.4” of the destination terminal (terminal 10db) is further included. Thereby, the first and second relay devices (30A, 30B, 30a, 30b) can grasp that each pre-transmission information has been sent in the execution of the session with the selection session ID “se1”. The IP address “1.2.1.3” of the request source terminal (terminal 10aa) that is the transmission source of each pre-transmission information can be grasped, and further, the destination terminal ( The IP address “1.3.2.4” of the terminal 10db) can be grasped. Then, each relay device (30A, 30B, 30a, 30b) transmits (or forwards) each pre-transmission information to the acquired IP address of the destination terminal (terminal 10db) (step S1633-1). 4) can be. In addition, about the process after step S1633-1 to 4, since it is the same as that of each process of FIG. 25, the description is abbreviate | omitted.
<< Main effects of this embodiment >>
As described above, according to the present embodiment, the same effects as the main effects of the first embodiment can be obtained.

However, in this embodiment, since the requesting terminal is notified of the IP address of the destination terminal, it is inferior in terms of security compared to the first embodiment. However, for example, in the first embodiment, when a firewall is installed in order to ensure the confidentiality of the LAN 2a shown in FIG. 1, from the relay device 30b to the request source terminal (terminal 10aa). ), It may be impossible to deliver the advance transmission request information in step S62-2. On the other hand, in this embodiment, since the advance transmission request information is not sent from the relay device 30 side to the terminal 10aa, the problem that the advance transmission request information cannot be delivered does not occur. In this case, the management system 50 is on the communication network outside the firewall. However, since the terminal 10aa and the management system 50 are already connected as shown in FIG. 50 can pass through the firewall and deliver the pre-transmission request information to the terminal 10aa.
[Supplement of Embodiment]
The relay device 30, the management system 50, the program providing system 90, and the maintenance system 100 in the above embodiment may be constructed by a single computer, or may be arbitrarily assigned by dividing each unit (function or means). It may be constructed by a plurality of computers. In addition, when the program providing system 90 is constructed by a single computer, the program transmitted by the program providing system 90 may be transmitted by dividing it into a plurality of modules. It may be transmitted. Further, when the program providing system 90 is constructed by a plurality of computers, a plurality of modules may be divided and transmitted from each computer.

  The terminal program, the relay device program, or the transmission management program of each of the above embodiments, the recording medium storing the program, the HD 204 storing the program, and the program providing system 90 including the HD 204 are: All of them are used when the terminal program, the relay device program, and the transmission management program are provided to users or the like as program products in Japan or abroad.

  Furthermore, in the above-described embodiment, as an example of the image quality of the image data relayed by the relay device 30 using the changed quality management table shown in FIG. 10 and the quality management table shown in FIG. Although it was managed by focusing on the resolution of the image of the data, the present invention is not limited to this. Other examples of the quality include the depth of image quality of the image data, the sampling frequency of the audio data, and the bit length of the audio data. You may manage it paying attention to. Further, the audio data may be transmitted and received by being divided into data of three types of resolution (high resolution, medium resolution, and low resolution).

  11, FIG. 13 and FIG. 15 manage the reception date and time, but the present invention is not limited to this, and at least the reception time of the reception date and time may be managed.

  Further, in the above embodiment, the IP address of the relay device is managed in FIG. 11 and the IP address of the terminal in FIG. 13, but the present invention is not limited to this, and the relay device 30 is specified on the communication network 2. Each relay device specifying information or terminal specifying information for specifying the terminal 10 on the communication network 2 may manage each FQDN (Fully Qualified Domain Name). In this case, an IP address corresponding to the FQDN is acquired by a known DNS (Domain Name System) server. In addition to “relay device specifying information for specifying the relay device 30 in the communication network 2”, “relay device connection destination information indicating a connection destination to the relay device 30 on the communication network 2” or “communication It may be expressed as “relay device destination information indicating a destination to the relay device 30 on the network 2”. Similarly, not only “terminal specifying information for specifying the terminal 10 in the communication network 2” but also “terminal connection destination information indicating a connection destination to the terminal 10 on the communication network 2” or “on the communication network 2 It may be expressed as “terminal destination information indicating a destination to the terminal 10”.

  In the above embodiment, a video conference system has been described as an example of the transmission system 1. However, the present invention is not limited to this, and a telephone system such as an IP (Internet Protocol) telephone or an Internet telephone may be used. . Further, the transmission system 1 may be a car navigation system. In this case, for example, one of the terminals 30 corresponds to a car navigation device mounted on a car, and the other of the terminals 30 is mounted on a management terminal or management server of a management center that manages car navigation, or another car. This corresponds to a car navigation device. The transmission system 1 may be a mobile phone communication system. In this case, for example, the terminal 10 corresponds to a mobile phone.

  In the above embodiment, image data and audio data have been described as an example of content data. However, the present invention is not limited to this, and touch data may be used. In this case, the feeling that the user touched on one terminal side is transmitted to the other terminal side. Further, the content data may be smell data. In this case, the odor (odor) on one terminal side is transmitted to the other terminal side. Further, the content data may be at least one of image data, audio data, tactile data, and olfactory data.

  Further, in the above embodiment, the case where a video conference is performed by the transmission system 1 has been described. However, the present invention is not limited to this, and a general conversation such as a meeting, a family or a friend, or information in one direction is performed. It may be used for presentation.

  Furthermore, although the case where audio data is included in extended data has been described in the above embodiment, the present invention is not limited to this, and audio data may be included in basic data. In addition to dividing image data into basic data and extended data, audio data can also be divided into basic data (low-quality sound data) and extended data (medium-quality sound data, high-quality sound data). Good.

  Moreover, in the said embodiment, primary narrowing-down of the relay apparatus 30 is performed by said step S46 (refer FIG. 21), and said step S61-1, 2, 3, 4-S64-1, 2, 3, 4 (FIG. 24, FIG. 24). 25) or the above-described steps S161 to 163-1, 2, 3, 4 (see FIG. 28), the relay device 30 is finally narrowed down. However, the present invention is not limited to this, and the above-described step S46 (see FIG. 21). ) May be omitted. In this case, there is no concept of “primary narrowing down” and “final narrowing down”, but only “narrowing down”. Accordingly, the concepts of “primary selection” by the primary selection unit 56c (see FIG. 9) and “final selection” by the final selection unit 16c (see FIG. 8) are eliminated, and mere “selection” by the final selection unit 16c. Become.

DESCRIPTION OF SYMBOLS 1 Transmission system 10 Transmission terminal 11 Transmission / reception part (An example of a content reception means, an example of a prior reception means)
16 Final narrowing part 16a Measuring part (an example of measuring means)
16b calculation unit (an example of calculation means)
16c Final selection unit (an example of selection means)
17 Display control unit (an example of playback means)
DESCRIPTION OF SYMBOLS 18 Delay detection part 30 Relay apparatus 31 Transmission / reception part 32 State detection part 33 Data quality confirmation part 34 Change quality management part 35 Data quality change part 50 Transmission management system 51 Transmission / reception part 52 Terminal authentication part 53 State management part 54 Terminal extraction part 55 Terminal Status acquisition unit 56 Primary selection unit 56a Selection session ID generation unit 56b Terminal IP address extraction unit 56c Primary selection unit 56d Priority determination unit 57 Session management unit 58 Quality determination unit 60 Delay time management unit 70 Router 90 Program providing system 100 Maintenance system 1000 storage unit (an example of storage means)
3000 storage unit 3001 change quality management DB
5000 storage unit 5001 relay device management DB
5002 Terminal authentication management DB
5003 Terminal management DB
5004 Destination list management DB
5005 Session management DB
5006 Priority management DB
5007 Quality Management DB

Special table 2009-518996

Claims (5)

A plurality of transmission terminals for reproducing the content data based on at least the basic data among basic data essential for reproducing the content data and extended data for improving the reproduction quality of the content data, and the plurality of transmissions A management system that manages a session for transmitting the content data between terminals, a first relay device group that includes a plurality of highly reliable relay devices having an average failure interval of a predetermined time or more, an average A second relay device group configured by a plurality of relay devices having low reliability whose failure interval is less than a predetermined time ,
Any one of the plurality of transmission terminals is
Before receiving the basic data and extension data from another transmission terminal as a communication partner, the other data is transmitted from the other transmission terminal via each first relay device of the first relay device group, and the other Receiving each first pre-transmission information indicating the transmission time at the time of transmission from the other transmission terminal and the other transmission terminal via each second relay device of the second relay device group Pre-reception means for receiving each second pre-transmission information transmitted from the other transmission terminal and indicating the transmission time when transmitted from the other transmission terminal;
For each received first pre-transmission information, the reception time when each of the first pre-transmission information is received by the pre-reception means is measured, and for each received second pre-transmission information Measuring means for measuring a reception time when each of the second prior transmission information is received by the prior reception means;
For each first pre-transmission information for which the reception time is measured, each first pre-transmission is based on the difference between the measured reception time and the transmission time included in each first pre-transmission information. The time required from transmission information transmission to reception is calculated and included in the measured reception time and each second pre-transmission information for each second pre-transmission information in which the reception time is measured. Calculating means for calculating a required time from transmission to reception of each second pre-transmission information based on a difference from the transmission time being
Based on the calculated time required for each of the first pre-transmission information, a specific first relay device is selected from the first relay device group, and the calculated second pre-transmission information. Selection means for selecting a specific second relay device from the second relay device group based on the required time of
First relay device identification information for identifying the first relay device selected by the selection means, and second relay device identification information for identifying the second relay device selected by the selection means And transmitting means for transmitting to the management system,
The management system determines whether the transmission terminal and the other transmission terminal are based on the first relay device identification information and the second relay device identification information transmitted by the transmission unit included in the transmission terminal. To establish a session for transmitting the basic data via the first relay device, and to transmit a session for transmitting the extension data between the transmission terminal and the other transmission terminal. A transmission system characterized by being established via a relay device . Any one of the plurality of transmission terminals is
The basic data transmitted from another transmission terminal and the low reliability with the average failure interval being less than the predetermined time for the specific first relay device having high reliability with the average failure interval being a predetermined time or more Content reception for receiving at least basic data transmitted from the other transmission terminal via the first relay device among the specific transmission device having a specific second relay device Means,
Playback means for playing back the content data based on the received at least basic data;
The transmission system according to claim 1, further comprising:
The selecting means is based on the time required for each first pre-transmission information and the time required for each second pre-transmission information calculated by the calculation means, among the plurality of first and second relay devices. The transmission system according to claim 2, wherein the specific first relay device and the specific second relay device are selected in a predetermined combination. The selection means is a request for the predetermined first pre-transmission information of the first pre-transmission information as the specific first relay device and the specific second relay device by the predetermined combination. First and second pre-transmission information relayed in a combination in which the difference between the time and the required time of the predetermined second pre-transmission information among the second pre-transmission information is the shortest. The transmission system according to claim 3, wherein the second relay device is selected. The selection means is a request for the predetermined first pre-transmission information of the first pre-transmission information as the specific first relay device and the specific second relay device by the predetermined combination. The difference between the time and the time required for the predetermined second pre-transmission information among the second pre-transmission information, the time required for the predetermined first pre-transmission information, and the predetermined second pre-transmission information 4. The first and second relay apparatuses that respectively relay the first and second pre-transmission information in a combination that makes the time required for the transmission information plus the shortest time are selected. The described transmission system .

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