JP6469501B2 - Video distribution system, video distribution method, and video distribution program - Google Patents

Description

  The present invention relates to a video distribution system, a video distribution method, and a video distribution program for outputting video having the same original data to a plurality of displays.

  Conventionally, various systems for displaying a distribution video on a display device have been devised. For example, in Patent Document 1, a video receiving device is connected to a display. At this time, for example, the video receiving device and the display are connected by an HDMI (registered trademark) cable. The video receiving apparatus establishes wireless communication with a wireless router or a portable communication terminal, and receives video data through the wireless communication. The video receiving device converts the received video data into the HDMI format and outputs it to the display.

  In such a configuration, when video data is displayed on a plurality of displays, it is necessary to provide a video receiver for each display. Each video receiving apparatus individually establishes wireless communication with a wireless router or a portable communication terminal, and receives video data by individual wireless communication.

  FIG. 6 is a block diagram of a video distribution system employing a conventional configuration. As shown in FIG. 6, a video distribution system employing a conventional configuration includes communication control units 41P and 42P. The communication control unit 41P is connected to the display device 901 with an HDMI cable 991. The communication control unit 42P is connected to the display device 902 with an HDMI cable 992.

  The communication control units 41P and 42P individually perform wireless communication with the tablet terminals 911 and 912, and receive video data. The communication control unit 41P converts the video data into the HDMI format and outputs it to the display 901. The communication control unit 42P converts the video data into the HDMI format and outputs it to the display device 902. The communication control units 41P and 42P correspond to the above-described video receiving device.

JP 2014-78771 A

  However, in the case of displaying a plurality of displays with the configuration of the above-described Patent Document 1, each video receiving apparatus individually performs communication control and display video generation, so that the load on the video receiving apparatus increases, and the display is performed. There may be a delay in video display. In addition, since a plurality of video receiving apparatuses communicate with each other, the communication band for each video receiving apparatus occupying the wireless communication band is narrowed, and transmission of video data may be delayed.

  As described above, when the configuration of Patent Document 1 described above is used, it may not be possible to display an image at a desired timing with a plurality of displays.

  As another conventional video distribution method, there is also a method of establishing communication and transmitting video data by sequentially switching a plurality of video receiving apparatuses. In this case, video data cannot be simultaneously transmitted to a plurality of video receiving apparatuses.

  An object of the present invention is to provide a video distribution system and a video distribution method capable of reliably displaying a video on a plurality of displays at a desired timing.

  The video distribution system according to the present invention includes a relay unit and first and second display control units. The relay unit outputs the original video data received by wireless communication to the first display control unit and the second display control unit. The first display control unit converts the original video data into video specifications corresponding to the first display, and outputs the original video data to the first display as first video data. The second display control unit converts the original video data into video specifications corresponding to the second display and outputs the converted video data to the second display as second video data.

  In this configuration, it is not necessary to provide a wireless communication unit for receiving original video data for each display, and video with different video specifications is output for each display for one original video data.

  In the video distribution system of the present invention, the relay unit multicasts the original video data to the first and second display control units.

  In this configuration, the amount of communication data between the relay unit and the first and second display control units is reduced.

  In the video distribution system according to the present invention, the relay unit unicasts the original video data to the first and second display control units at individual times.

  In this configuration, the original video data is provided at different times for each display control unit. Thereby, the original video data is transmitted to a display control unit (and display device) that requires video data at a certain time, and the original video data is not transmitted to a display control unit (and display device) that is not necessary. It becomes feasible.

  According to the present invention, an image can be reliably displayed on a plurality of displays at a desired timing.

The block diagram of the video delivery system which concerns on embodiment of this invention, and its peripheral device The figure which shows the data and the display state of each part of the video delivery system which concern on embodiment of this invention Time chart showing from operation start to video display in the video distribution system according to the present embodiment and the conventional video distribution system In the video distribution system according to the present embodiment, a time chart of a mode in which display timing is changed for each display The flowchart which shows the process of the video delivery method which concerns on embodiment of this invention. Block diagram of a video distribution system employing a conventional configuration

  A video distribution system according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram of a video distribution system and its peripheral devices according to an embodiment of the present invention. FIG. 2 is a diagram showing data and display states of each part of the video distribution system according to the embodiment of the present invention.

  The video distribution system 10 includes a relay unit 21 and display control units 41, 42, and 43. One of the display control units 41, 42, 43 corresponds to the “first display control unit” of the present invention, and the other one corresponds to the “second display control unit” of the present invention. The relay unit 21 is connected to the display control units 41, 42, and 43 by, for example, Ethernet (registered trademark) 31. The connection between the relay unit 21 and the display control units 41, 42, and 43 may be wired or wireless, but is preferably wired. Ethernet 31 is preferably used for this connection, and the relay unit 21 and the display control units 41, 42, 43 are connected via a LAN cable. The relay unit 21 and the display control units 41, 42, and 43 are not limited to the Ethernet 31, and may be connected by a cable capable of data communication, and preferably have a connection mode capable of multicasting. In addition to the Ethernet 31, a so-called bus-type connection network may be used.

  The relay unit 21 and the external tablet terminals 911 and 912 can be connected by wireless communication. For example, the relay unit 21 and the tablet terminals 911 and 912 can be connected by WiFi (registered trademark).

  The relay unit 21 receives the original video data VD0 from the tablet terminal 911 or the tablet terminal 912 using the established wireless communication. The relay unit 21 transmits the original video data VD0 to the display control units 41, 42, and 43 via the Ethernet 31. This transmission is realized by, for example, multicast transmission for the display control units 41, 42, and 43.

  The display control unit 41 is connected to the display device 901 via the HDMI cable 991. The display control unit 42 is connected to the display device 902 via the HDMI cable 992. The display control unit 43 is connected to the display device 903 via the HDMI cable 993. In the display devices 901, 902, and 903, the display device connected to the “first display control unit” of the present invention corresponds to the “first display device” of the present invention, and is connected to the “second display control unit”. The display corresponds to the “second display” of the present invention. The connection mode between the display control unit and the display using these HDMI cables is the “connection mode between the first display control unit and the first display unit, the connection mode between the second display control unit and the second display unit” of the present invention. Is equivalent to.

  The display control unit 41 includes a data reception unit 411 and a video data generation unit 412. The data receiving unit 411 and the video data generating unit 412 are connected. The data receiving unit 411 is connected to the relay unit 21 via the Ethernet 31. The video data generation unit 412 is connected to the display device 901 via the HDMI cable 991.

  The data receiving unit 411 establishes communication with the relay unit 21 via the Ethernet 31. The data receiving unit 411 receives the original video data VD0 from the relay unit 21. The data receiving unit 411 outputs the original video data VD0 to the video data generating unit 412.

  The video data generation unit 412 converts the original video data VD0 into the HDMI format. At this time, the video data generation unit 412 converts the video data into the video data DD1 according to the display specifications of the display 901. The video data generation unit 412 outputs the converted video data DD1 to the display device 901 via the HDMI cable 991.

  The display control unit 42 includes a data reception unit 421 and a video data generation unit 422. The data receiving unit 421 and the video data generating unit 422 are connected. The data reception unit 421 is connected to the relay unit 21, and the video data generation unit 422 is connected to the display 902.

  The data receiving unit 421 establishes communication with the relay unit 21 via the Ethernet 31. The data receiving unit 421 receives the original video data VD0 from the relay unit 21 via the Ethernet 31. The data receiving unit 421 outputs the original video data VD0 to the video data generating unit 422.

  The video data generation unit 422 converts the original video data VD0 into the HDMI format. At this time, the video data generation unit 422 converts the video data into the video data DD2 corresponding to the display specifications of the display 902. The video data generation unit 422 outputs the converted video data DD2 to the display device 902 via the HDMI cable 992.

  The display control unit 43 includes a data reception unit 431 and a video data generation unit 432. The data receiving unit 431 and the video data generating unit 432 are connected. The data receiving unit 431 is connected to the relay unit 21, and the video data generating unit 432 is connected to the display 903.

  The data receiving unit 431 establishes communication with the relay unit 21 via the Ethernet 31. The data receiving unit 431 receives the original video data VD0 from the relay unit 21 via the Ethernet 31. The data receiving unit 431 outputs the original video data VD0 to the video data generating unit 432.

  The video data generation unit 432 converts the original video data VD0 into the HDMI format. At this time, the video data generation unit 432 converts the video data into the video data DD3 corresponding to the display specifications of the display 902. The video data generation unit 432 outputs the converted video data DD3 to the display 903 via the HDMI cable 993.

  In the converted video data DD1, DD2, DD3, the converted video data generated by the “first display control unit” corresponds to the “first video data” of the present invention, and the “second display control unit” The converted video data generated by "" corresponds to the "second video data" of the present invention.

  With this configuration, as shown in FIG. 2, the video distribution system 10 uses the video data DD1 corresponding to the display specifications of the display 901 and the display specifications of the display 902 from the original video data VD0. Video data DD2 and video data DD3 corresponding to the display specifications of the display 903 can be generated.

  The video distribution system 10 outputs the video data DD1 to the display 901, the video data DD2 to the display 902, and the video data DD1, DD2, DD3 to the display 903. That is, the video distribution system 10 can individually output the video data set for each display device for each display device to be set. For example, in the embodiment shown in FIG. 2, the display units 901, 902, and 903 have different display resolutions and display screen sizes. The display units 901 and 903 are designated for subtitle display, and the display unit 902 is not designated for subtitle display. As described above, the display specifications of the displays 901, 902, and 903 are different. Even in such a case, the video distribution system 10 uses one original video data according to the display specifications determined by the display resolution, display screen size, subtitles, and the like of the displays 901, 902, and 903. Appropriate video data can be output for each of the displays 901, 902, and 903.

  In addition, the video distribution system 10 is individually connected according to the connection between the display control unit 41 and the display device 901, the connection between the display control unit 42 and the display device 902, and the connection between the display control unit 43 and the display device 903. The video data DD1, DD2 and DD3 are determined. That is, the video data DD1, DD2, and DD3 are determined according to the connection mode between the display control unit and the display.

  Thereby, the video distribution system 10 is based on the display specification of each display unit described above and the connection mode between the display control unit and the display unit, that is, the video specification for each display unit 901, 902, 903 (" Based on the “first video specification, second video specification”, it is possible to output appropriate video data for each of the displays 901, 902, and 903.

  Furthermore, in the video distribution system 10 of the present embodiment, the original video data VD0 from the tablet terminals 911 and 912 is received by the common relay unit 21 for the plurality of displays 901, 902, and 903. As a result, a simpler configuration can be realized than the conventional configuration in which the display units 901, 902, and 903 each include an original video data receiving unit.

  In the video distribution system 10 of the present embodiment, one relay unit 21 performs wireless communication with the tablet terminals 911 and 912. Therefore, the configuration (conventional configuration) in which the plurality of receiving units that receive the original video data and the tablet terminals 911 and 912 perform wireless communication is not required, the communication band of each communication is narrowed, and the data communication speed is reduced. This can be suppressed. Thereby, the delay of the display of the video data on the plurality of displays 901, 902, and 903 can be suppressed, and the video can be surely displayed at a desired timing on each display.

  In the video distribution system 10 according to the present embodiment, original video data is transmitted from one relay unit 21 to the plurality of display control units 41, 42, and 43 via the Ethernet 31. Therefore, a configuration for distributing the original video data to the plurality of display control units 41, 42, and 43 can be realized by an inexpensive and highly versatile cable (LAN cable). Thereby, the configuration of the video distribution system 10 can be realized by a member that is easier to route than the HDMI cables 991, 992, 993, and the displays 901, 902, 903 can be easily arranged at desired positions.

  Further, when the number of display devices is changed by using the Ethernet 31, the number of display control units is changed in accordance with the change, and a plurality of display control units are connected to one relay unit 21 with a LAN cable. That's fine. Therefore, it is possible to easily configure an appropriate video distribution system according to the situation on the display side. At this time, by using multicast, it is possible to display an image on each display device at a desired timing without being affected by the number of display control units.

  In the video distribution system 10 of the present embodiment, the original video data before being converted into the HDMI format is distributed to a plurality of pieces. As a result, as described above, even when the display modes of the displays 901, 902, and 903 are different, the video data DD1, DD2, and DD3 corresponding to the displays 901, 902, and 903 can be output. On the other hand, when an HDMI distributor is used, only the same video data can be output to a plurality of displays connected to the distributed HDMI cable. Thus, by using the video distribution system 10 of the present embodiment, it is possible to more flexibly cope with various display modes by a plurality of display devices.

  Further, in the video distribution system 10 of the present embodiment, the video data can be provided from the tablet terminals 911, 912 to the displays 901, 902, 903 as they are without being compressed. Therefore, the video output from the tablet terminals 911 and 912 can be displayed on the displays 901, 902, and 903 as they are.

  In the video distribution system 10 of the present embodiment, the display control units 41, 42, and 43 establish connections with the displays 901, 902, and 903 before performing the original video data reception process in the relay unit 21. Can do. Thereby, the following effects can be obtained.

  FIG. 3 is a time chart showing the operation from the start of operation to the display of video in the video distribution system according to the present embodiment and the conventional video distribution system. As shown in FIG. 3, in the conventional configuration, starting from the operation start, the communication control unit starts, searches for the tablet terminal that is the connection destination, the connection between the tablet terminal and the communication control unit, and the communication control unit and display. Establish a connection with the instrument. In the conventional configuration, after the connection is established, the original video data is acquired from the tablet terminal, and the display preparation for converting the video data into video data corresponding to the display is executed. In the conventional configuration, video display (playback) is performed after the display preparation is completed.

  On the other hand, in the video distribution system 10 according to the present embodiment, since each unit is connected by a communication network of a bus type connection such as Ethernet, if the relay unit 21 and the display control units 41, 42, 43 are activated, The connection between the relay unit 21 and the display control units 41, 42, and 43 and the connection between the relay unit 21 and the tablet terminal are established. For this reason, the video distribution system 10 according to the present embodiment starts the operation start and immediately acquires the original video data without performing the connection destination search or the connection establishment process, and converts it into the video data corresponding to the display. Perform display preparation for conversion. The video distribution system 10 according to the present embodiment displays (reproduces) video after the display preparation is completed.

  As described above, in the video distribution system 10 according to the present embodiment, it is not necessary to search for connection to the display device or the tablet terminal and establish connection after the operation is started. Can be shortened. Note that in the video distribution system 10 according to the present embodiment, it is not necessary to establish connection after the start of operation without adding connection processing to the tablet. Therefore, the time from the start of operation to the display on the display unit is conventionally determined. It can be made shorter than the configuration.

  FIG. 4 is a time chart of an aspect in which the display timing is changed for each display in the video distribution system according to the present embodiment. FIG. 4A shows a mode in which the display start timing is different among a plurality of displays. FIG. 4B shows a mode in which a plurality of indicators alternately display in time series.

  As shown in FIG. 4A, in the video distribution system 10 according to the present embodiment, the same original video data is transmitted to the display control unit 41 and the display control unit 42 at the same timing (time). The display control unit 41 executes display preparation for converting the original video data into video data DD1 corresponding to the display 901. The display control unit 42 executes display preparation for converting the original video data into video data DD2 corresponding to the display 901. These display preparations are individually performed in parallel by the display control units 41 and 42.

  The display control unit 41 outputs the video data DD1 to the display device 901 when the own device outputs the video data DD1 (time). The display control unit 42 stands by until the timing (time) when the device itself outputs the video data DD2, and outputs the video data DD2 to the display device 902 when the output timing comes.

  As described above, by using the video distribution system 10 according to the present embodiment, it is possible to display a video at a different timing (time) for each display device without being delayed at each timing.

  As shown in FIG. 4B, in the video distribution system 10 according to the present embodiment, the same original video data is transmitted to the display control unit 41 and the display control unit 42 at the same timing (time). The display control unit 41 executes display preparation for converting the original video data into video data DD1 corresponding to the display 901. The display control unit 42 executes display preparation for converting the original video data into video data DD2 corresponding to the display 901. These display preparations are individually performed in parallel by the display control units 41 and 42.

  The display control unit 41 outputs the video data DD1 to the display device 901 when the own device outputs the video data DD1 (time).

  The display control unit 42 stands by until the timing (time) when the display device 901 is switched to the display device 902, and outputs the video data DD2 to the display device 902 at this timing. At this time, the display control unit 41 stops outputting the video data DD1.

  Next, the display control unit 41 waits until the timing (time) when the display device 902 switches to the display device 901, and outputs the video data DD1 to the display device 901 when the timing comes. At this time, the display control unit 42 stops outputting the video data DD2.

  Thus, by using the video distribution system 10 according to the present embodiment, it is possible to display video while switching between a plurality of displays. The video can be switched and displayed without delay in switching timing.

  The processing executed by the relay unit 21 and the display control units 41, 42, and 43 shown in the above description may be programmed, and the computer may execute the program. FIG. 5 is a flowchart showing processing of the video distribution method according to the embodiment of the present invention.

  The relay unit 21 receives the original video data VD0 from the tablet terminals 911 and 912 by wireless communication (S201). The relay unit 21 transmits the original video data VD0 by multicast transmission for the plurality of display control units 41, 42, and 43 (S202).

  The display control unit 41 receives the original video data VD0 from the relay unit 21 (S411). The display control unit 41 converts the original video data VD0 into HDMI format video data DD1. The display control unit 41 acquires the display mode of the display unit 901 from the display unit 901 in advance via the HDMI cable 991. The display control unit 41 generates video data DD1 corresponding to the display mode of the display 901 (S412). The display control unit 41 outputs the video data DD1 to the display 901 (S413).

  The display control unit 42 receives the original video data VD0 from the relay unit 21 (S421). The display control unit 42 converts the original video data VD0 into video data DD2 in the HDMI format. The display control unit 42 acquires the display mode of the display unit 902 from the display unit 902 via the HDMI cable 992 in advance. The display control unit 42 generates video data DD2 corresponding to the display mode of the display 902 (S422). The display control unit 42 outputs the video data DD2 to the display device 902 (S423).

  The display control unit 43 receives the original video data VD0 from the relay unit 21 (S431). The display control unit 43 converts the original video data VD0 into HDMI format video data DD3. The display control unit 43 acquires the display mode of the display unit 903 from the display unit 903 via the HDMI cable 993 in advance. The display controller 43 generates video data DD3 corresponding to the display mode of the display 903 (S432). The display control unit 43 outputs the video data DD3 to the display 903 (S433).

  In the above description, the case where there are two tablet terminals is shown, but there may be one or more than three. Moreover, although the case where the number of displays was three was shown, two or four or more may be sufficient. That is, it is sufficient if there are a plurality of displays, and it is only necessary that a display control unit is provided for each display.

  In the above description, the mode in which the transmission of the original video data VD0 between the relay unit 21 and the display control units 41, 42, and 43 is set to multicast transmission has been described. However, broadcast transmission or unicast transmission is used. Also good. In the case of unicast transmission, the relay unit 21 can transmit to the display control units 41, 42, and 43 individually at different times. Therefore, it is possible to transmit the original video data VD0 to the display control unit that requires the original video data VD0 only at the time that the display control units 41, 42, and 43 require.

10: Video distribution system 21: Relay unit 31: Ethernet
41: Display control units 41, 42, 43: Display control units 411, 421, 431: Data reception units 412, 422, 432: Video data generation units 901, 902, 903: Display units 911, 912: Tablet terminals 991, 992 993: HDMI cable DD1, DD2, DD3: video data VD0: original video data

Claims (13)

A relay connected to the first display control unit and the second display control unit via a bus-type connection communication network and outputting original video data received by wireless communication to the first display control unit and the second display control unit And
The first display control unit for converting the original video data into a video specification corresponding to the first display and outputting the original video data to the first display as first video data;
The second display control unit which converts the original video data into video specifications corresponding to a second display and outputs the converted video data to the second display as second video data;
Equipped with a,
The relay unit multicast-transmits the original video data to the first display control unit and the second display control unit,
The output period of the first video data by the first display control unit and the output period of the second video data by the second display control unit are between the first display control unit and the second display control unit. Individually switched by individual control,
Film image distribution system. The video distribution system according to claim 1,
The video specification according to the first display is determined by the display specification of the first display and the connection mode between the first display control unit and the first display,
The video specifications according to the second display are determined by the display specifications of the second display and the connection mode between the second display control unit and the second display.
Video distribution system. The video distribution system according to claim 1 or 2, wherein
The relay unit is connected via Ethernet to the first display control unit and the second display control unit.
Video distribution system. The video distribution system according to any one of claims 1 to 3 ,
At the timing of switching from the output period of the first video data to the output period of the second video data, the first display control unit stops outputting the first video data, and the second display control unit , Start outputting the second video data,
At the timing of switching from the output period of the second video data to the output period of the first video data, the second display control unit stops outputting the second video data, and the first display control unit Starting to output the first video data;
Video distribution system. The video distribution system according to claim 4 ,
The original video data transmitted to the first display control unit and the original video data transmitted to the second display control unit are the same.
Video distribution system. The video distribution system according to any one of claims 1 to 5 ,
The first display control unit establishes a connection with the first display before receiving the original video data,
The second display control unit is connected to the second display before receiving the original video data.
Video distribution system. The video distribution system according to any one of claims 1 to 6 ,
A connection to the relay unit is established in advance, and further includes a transmission source device that transmits the original video data,
Video distribution system. Establishing a connection of a distribution path of the original video data that is the source of the video data before starting the operation of displaying the video data;
Receiving the original video data by wireless communication; and receiving the original video data;
A process of distributing original video data for transmitting the original video data to a first address and a second address;
Wherein converting the original image data to the first video specifications and second video specification, the said image data of the first video specification to output to the first display, the image data of the second image Specifications second display Output process of the converted video data to be output to the device,
I have a,
In the distribution process of the original video data, the original video data is multicast transmitted,
In the output step of the video data after the conversion, an output period of the video data of the first video specification to the first display and an output of the video data of the second video specification to the second display The period is switched individually,
Video distribution method. The video distribution method according to claim 8 ,
The first video specification is determined by a display specification of the first display and a connection mode to the first display,
The second video specification is determined by a display specification of the second display and a connection mode to the second display.
Video distribution method. The video distribution method according to claim 8 or 9 , wherein
The original video data distribution step is performed using Ethernet.
Video distribution method. A video distribution method according to any one of claims 8 to 10 ,
The output period of the video data of the first video specification and the output period of the video data of the second video specification are alternately switched.
Video distribution method. A video distribution method according to any one of claims 8 to 11 ,
Establishing a connection to the first display before receiving the original video data;
Establishing a connection to the second display before receiving the original video data,
Video distribution method. A video distribution program for causing a computer to execute a process of distributing video data to a plurality of displays,
The computer
Before starting the operation of displaying the video data, establishing a connection of the distribution path of the original video data that is the source of the video data;
A process of distributing original video data for transmitting the original video data received by wireless communication to the first address and the second address;
Converting said to convert the original image data to the first video specifications and second video specification, and outputs the image data of the second video specifications and video data of the first video specification, the separate display Later video data output processing,
The execution,
In the distribution process of the original video data, the original video data is multicast transmitted,
In the output processing of the video data after the conversion, an output period of the video data of the first video specification to the first display and output of the video data of the second video specification to the second display Switch between periods individually,
Video distribution program.

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