JP2009218819A - Video system and video receiving terminal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve a problem wherein, when a user of a home electric appliance such as a TV and a DVD recorder equipped with an IP broadcast receiving function suddenly turns off power to the home electric appliance, the processing to end reception of the IP broadcast cannot be executed and video streaming is left in progress and wherein this dissipates a general household network band and keeps on occupying a resource of the distribution server. <P>SOLUTION: The first and second video receiving terminals are respectively equipped with a communication means capable of transmitting control information to each other. When reception or reproduction of a video content starts, the first video receiving terminal sends reception parameters to the second video receiving terminal. When the second video receiving terminal detects that the first video receiving terminal is powered off when reception or reproduction of a video content is in progress by means of a communication means, the second video receiving terminal executes processing to end reception and reproduction of the video content by deputy by using the reception parameters that were notified in advance. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a video system and a video receiving terminal in a communication field using an IP (Internet Protocol) network such as the Internet, and more particularly to prevention of bandwidth breakdown in a network to which a plurality of video receiving terminals are connected.

  Broadcast services (hereinafter referred to as IP broadcast) that provide video content on an IP network are generally implemented using IP multicast technology. In IP multicast technology, IGMP (Internet Group Management Protocol) or MLD (Multicast Listener Discovery) is used as a protocol for a receiving terminal to control a video stream. In these standard protocols, when a receiving terminal wants to start receiving a video stream, it sends a Join message to a relay router on the network, and conversely, when it wants to stop receiving a video stream, it sends a Leave message. By transmitting, the receiving terminal can receive only a desired video stream (Non-Patent Document 1 and Non-Patent Document 2).

  Here, when IP broadcasting is provided to a general home via a broadband access line such as FTTH (Fiber To The Home), there is a problem of securing a communication band. Since IP broadcasting occupies a certain network bandwidth for each channel viewing, if the number of channels exceeding the upper limit of the network bandwidth of each home is viewed, of course, the video quality of the IP broadcasting is degraded. appear. On the other hand, as described above, IGMP and MLD only perform simple Join and Leave control, and cannot perform video stream control considering the network bandwidth.

As a prior art for this problem, there is a method disclosed in Patent Document 1 “Multicast video distribution system and request reception processing program in the same system”. In this method, a filtering gateway device is installed between the subscriber line and the backbone network. When the filtering gateway apparatus receives the viewing request from the receiving terminal, it checks whether 1) there is a receiving terminal that has already watched the same channel, or 2) whether there is room in the network bandwidth. Dynamically change the process relay operation. Through these operations, the amount of information transmitted to the subscriber line is dynamically controlled to solve the problem of overflowing network bandwidth.
Japanese Patent No. 36552670 RFC2326 IGMP Version2 RFC3810 MLD Version2

  However, when an IP broadcast receiving function is installed in a home appliance such as a TV (television) or a DVD (Digital Versatile Disk) recorder, a new problem occurs. In home appliances such as TVs and DVD recorders, when the user suddenly turns off the power of the device, the Leave message transmission process cannot be executed, so the video stream remains flowing, and the network bandwidth of a general household However, there is a problem that the resources of the distribution server remain occupied.

  Therefore, the present invention has been made in view of such problems, and an object of the present invention is to provide a video system and a video receiving terminal that prevent waste of network bandwidth and efficiently use resources.

  To achieve the above object, a video system according to the present invention is a video system having first and second video receiving terminals capable of receiving and playing back video content via an IP network. Information transmission means capable of transmitting control information between the first video receiving terminal and the second video receiving terminal, and the first video receiving terminal receives the video content when starting to receive and play the video content. The reception parameters used for reception and reproduction are notified to the second video reception terminal via the information transmission means, and the second video reception terminal uses the reception parameters to end the reception and reproduction processing of the video content. Is executed on behalf of the first video receiving terminal.

  The second video receiving terminal detects that the first video receiving terminal is powered off while receiving and playing the video content through the information transmission means, and uses the reception parameter to determine the video content. The reception and playback end processing is executed on behalf of the first video receiving terminal.

  In addition, when the first video receiving terminal starts receiving and playing the video content distributed by IP multicast, the first video receiving terminal sends the distribution multicast address of the video content to the second video receiving terminal via the information transmission unit. And the second video receiving terminal transmits a multicast group leaving message on behalf of the first video receiving terminal using the multicast address.

  The second video receiving terminal detects that the first video receiving terminal is powered off during execution of reception and playback of video content distributed by IP multicast via the information transmission means, and the multicast group The leaving message is transmitted on behalf of the first video receiving terminal.

  The present invention can be realized not only as such a video system, but also as a video receiving terminal, a video receiving method, a program, a storage medium storing the program, and an integrated circuit included in the video system. Can also be realized.

  In the present invention, in response to a sudden power-off of a device that is unavoidable with home appliances, another device performs the IP broadcast termination process on behalf of the device, thereby preventing the video stream from remaining flowing, It is possible to solve the problem that the network bandwidth of a general household is wasted and the resources of the distribution server remain occupied.

  Embodiments for carrying out the present invention will be described below with reference to the drawings.

(Basic operation of IP broadcasting system)
First, the basic operation of the IP broadcast system which is the premise of the present invention will be described.

  FIG. 1 is a diagram showing a configuration of an IP broadcast system using an IP multicast technology. The video server 106 has a function of sending video content to the network by IP multicast communication. The TV 101 and the DVD recorder 102 have a function of receiving and playing back video content transmitted by IP multicast. The edge router 105 has a function of controlling IP multicast communication between the video server 106 and the TV 101 and DVD recorder 102. The TV 101 and the DVD recorder 102 are connected to the edge router 105 via the IP network 104. A plurality of TVs 101 and DVD recorders 102 may be connected on the IP network. In this embodiment, one TV 101 and one DVD recorder 102 are connected. In this embodiment, the TV 101 and the DVD recorder 102 constitute a video system.

  Next, the operation of each component of the IP broadcast system will be described with reference to FIG. 2 and FIG. In this description, since there is no difference between the TV 101 and the DVD recorder 102, the TV 101 will be described as an example. A channel correspondence table 201 in FIG. 2 is a correspondence list of channel names and multicast addresses in the IP broadcast system. Channel correspondence table 201 stipulates that channel A is distributed using a multicast address of 225.1.1.1, and channels B, C, and D are the same. The channel correspondence table 201 is uniquely determined for the entire IP broadcast system, and the TV 101 acquires the channel correspondence table 201 by means of, for example, acquiring from a server on the network.

  FIG. 3 is a diagram showing a communication sequence when each operation of viewing start, channel switching, and viewing end is executed in the IP broadcast system. When the user 301 performs channel A viewing start operation on the TV 101 by selecting the channel A with a remote controller (not shown), the TV 101 uses the channel correspondence table 201 to indicate that the multicast address 225. Obtain 1.1.1. Next, the TV 101 transmits an IGMP Join message addressed to 225.1.1.1 to the edge router 105. The edge router 105 that has received IGMP Join starts relaying the video stream addressed to 225.1.1.1, and the video stream addressed to 225.1.1.1 is distributed to the TV 101. The TV 101 starts receiving / reproducing the video stream addressed to 225.1.1.1, and the user 301 can view channel A.

  Next, an operation when the user 301 switches to channel B will be described. When the user 301 selects channel B, the TV 101 first transmits an IGMP Leave message addressed to 225.1.1.1 to the edge router 105. The edge router 105 that has received the IGMP Leave addressed to 225.1.1.1 stops relaying the video stream addressed to 225.1.1.1. Next, the TV 101 acquires the multicast address 225.1.1.2 corresponding to the channel B from the channel correspondence table 201, and transmits the IGMP Join addressed to 225.1.1.2 to the edge router 105. . Similar to the channel A viewing start operation, the video stream addressed to 225.1.1.2 is distributed to the TV 101, so that the user 301 can view channel B.

  Next, an operation when the user 301 finishes viewing channel B will be described. The TV 101 transmits the IGMP Leave addressed to 225.1.1.2 to the edge router 105, and the edge router 105 stops relaying the video stream addressed to 225.1.1.2, thereby receiving the channel B.・ End playback.

  In FIG. 3, the video stream of all channels is distributed from the video server 106 to the edge router 105, but there may be a form in which only the video streams of some necessary channels are distributed. The multicast path control between the video server 106 and the edge router 105 will not be described because it is not directly related to the present invention. In this embodiment, IGMP is used for explanation, but in the case of IPv6, similar control is possible by MLD.

(System configuration)
FIG. 4 is a block diagram showing the configuration of the TV 101 according to an embodiment of the present invention. In the TV 101, when the remote control receiving unit 402 receives the viewing command for channel A, the microcomputer 403 obtains the multicast address 225.1.1.1 corresponding to channel A from the channel correspondence table 409 held in the memory 408. Read and instruct the IP communication unit 405 to start receiving. The IP communication unit 405 transmits an IGMP Join message addressed to 225.1.1.1 to the IP network 104, and distribution of the video stream of channel A is started. The IP communication unit 405 receives the video stream of channel A, performs IP packet processing, and then inputs the video stream to the decoder 406. The decoder 406 performs video / audio decoding processing, and the video is displayed on the display / speaker 407, so that the user 301 can start viewing channel A.

  FIG. 5 is a block diagram showing the configuration of the DVD recorder 102 according to an embodiment of the present invention. Description of the configuration and operation common to the TV 101 is omitted. The HDMI / CEC communication unit 404 of the TV 101 and the HDMI / CEC communication unit 504 of the DVD recorder 102 are connected by a high-definition multimedia interface (HDMI) cable 103 to transmit video / audio and to each other with Consumer Electronics Control (CEC). ), The CEC command can be transmitted and received.

(System operation)
FIG. 6 is a communication sequence diagram showing the linking operation of the TV 101 and the DVD recorder 102 according to an embodiment of the present invention. When the user 301 performs a viewing operation on channel A to the TV 101, the TV 101 transmits an IGMP Join message addressed to 225.1.1.1 to the edge router 105, and receives and plays back channel A. To start. At this time, the microcomputer 403 of the TV 101 notifies the DVD recorder 102 of the multicast address 225.1.1.1 of channel A via the HDMI / CEC communication unit 404. The microcomputer 503 of the DVD recorder 102 stores the multicast address 225.1.1.1 in the memory 508 when notified from the HDMI / CEC communication unit 504 of the multicast address 225.1.1.1.

  When the user 301 performs a channel A viewing end operation on the TV 101, the TV 101 transmits an IGMP Leave message addressed to 225.1.1.1 to the edge router 105, and receives / receives the channel A. End playback. This is a normal viewing end sequence.

  On the other hand, the user 301 may turn off the power of the TV 101 without performing the channel A viewing end operation. In this case, since the IGMP Leave message addressed to 225.1.1.1 is not transmitted, the video stream of channel A remains flowing. In IGMP, when the edge router 105 transmits a query at an interval of N seconds and there is no response for M times, the edge router 105 stops the distribution of the video stream (the values of N and M are set for each IP broadcast system). In general, since a wideband video stream remains flowing for several minutes, the network bandwidth is occupied.

  When the TV 101 receives a power-off instruction, the TV 101 communicates with the DVD recorder 102 that the power of the TV is turned off. After that, the TV 101 is turned off.

  The DVD recorder 102 detects that the power of the TV 101 has been turned off, and the microcomputer 503 reads the multicast address 509 held from the memory 508 and sends to the IP communication unit 505 an IGMP Leave addressed to the multicast address 509. Instruct to send a message.

  As means for detecting whether or not the TV 101 is turned off by the DVD recorder 102, an instruction to turn off the power of the TV 101 received from the TV 101, or transmission / reception of a signal through an HDMI cable connected to the TV 101 It can be used to detect whether or not there is a power supply signal or not. In addition, the DVD 102 may periodically inquire of the TV 101 whether or not the power remains on.

  As described above, the DVD recorder 102 immediately transmits the IGMP Leave message after the TV 101 is turned off, so that the distribution of the video stream of channel A is immediately stopped and the network bandwidth is not occupied unnecessarily. It becomes possible.

  In this embodiment, the TV 101 and the DVD recorder 102 are connected by using HDMI / CEC, but may be connected by other means.

  The video system and the video receiving terminal of the present invention have the effects of preventing waste of network bandwidth and efficient use of resources, and can be applied to, for example, DVD recorders and televisions.

It is the figure which showed the structure of the IP broadcast system using the IP multicast technique which concerns on this invention. It is the figure which showed the correspondence table of the IP broadcast channel name and multicast address which concern on this invention. It is the communication sequence diagram which showed the basic operation | movement of the IP broadcast system which concerns on this invention. It is the block diagram which showed the structure of TV101 which concerns on this invention. It is the block diagram which showed the structure of the DVD recorder 102 which concerns on this invention. It is a communication sequence diagram which shows the cooperation operation | movement of TV101 and the DVD recorder 102 based on this invention.

Explanation of symbols

101 TV
102 DVD recorder 103 HDMI cable 104 IP network 105 edge router 106 video server 201 channel correspondence table 301 user 402 remote control receiving unit 403 microcomputer 404 HDMI / CEC communication unit 405 IP communication unit 406 decoder 407 display / speaker 408 memory 409 channel correspondence table 502 Remote control receiving unit 503 Microcomputer 504 HDMI / CEC communication unit 505 IP communication unit 506 Decoder 507 Video / audio output unit 508 Memory 509 Multicast address

Claims (8)

A video system having first and second video receiving terminals capable of receiving and playing back video content via an IP (Internet Protocol) network,
Comprising information transmitting means capable of transmitting control information between the first video receiving terminal and the second video receiving terminal;
When the first video receiving terminal starts receiving and playing back the video content, the second video receiving terminal receives the reception parameters used for receiving and playing the video content via the information transmitting unit. Notify
The video system, wherein the second video receiving terminal uses the reception parameter to execute the video content reception and playback end processing on behalf of the first video receiving terminal. The second video receiving terminal detects that the first video receiving terminal is powered off during the reception and playback of the video content through information transmission means, and uses the reception parameter to The video system according to claim 1, wherein content reception and playback end processing is executed on behalf of the first video receiving terminal. When the first video receiving terminal starts receiving and playing back video content distributed by IP multicast, the first video receiving terminal sends a distribution multicast address of the video content to the second video receiving terminal via an information transmission unit. Notify
The video system according to claim 1, wherein the second video receiving terminal transmits a multicast group leaving message on behalf of the first video receiving terminal using the multicast address. The second video receiving terminal detects that the first video receiving terminal is powered off during execution of reception and playback of video content distributed by IP multicast via an information transmission means, and a multicast group The video system according to claim 3, wherein a leave message is transmitted on behalf of the first video receiving terminal. A video receiving terminal capable of receiving and playing back video content via an IP (Internet Protocol) network,
Information transmission means capable of transmitting control information to other video receiving terminals;
Parameter notification means for notifying the other video receiving terminal of reception parameters used for reception and playback of the video content via the information transmission means when reception and playback of the video content is started. A video receiving terminal comprising: A video receiving terminal capable of receiving and playing back video content via an IP (Internet Protocol) network,
Information transmission means capable of transmitting control information to other video receiving terminals;
A reception parameter is obtained from the other video receiving terminal via the information transmission means, and the reception processing of the video content by the other video receiving terminal and the end processing of the reproduction are performed using the reception parameter. A video receiving terminal comprising: proxy execution means for executing on behalf of the video. A video receiving method in a video receiving terminal capable of receiving and playing back video content via an IP (Internet Protocol) network,
A parameter notification step of notifying other video reception terminals of reception parameters used for reception and reproduction of the video content when reception and reproduction of the video content by the video reception terminal is started, To receive video. A video receiving method in a video receiving terminal capable of receiving and playing back video content via an IP (Internet Protocol) network,
A parameter acquisition step of acquiring reception parameters from other video receiving terminals;
And a proxy execution step of executing, on behalf of the other video receiving terminal, reception processing and playback end processing of the video content by the other video receiving terminal using the reception parameter.

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