JP2007259133A - Video transmission system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a video transmission system capable of easily configuring a synthesized video synthesized with a plurality of the videos. <P>SOLUTION: Places of displays in the synthesized video and first and second display-size changers 5 and 7 correspond to each other at a ratio of 1:1. Consequently, the places of the displays in the synthesized video are determined unidivertionally in response to a video reconfiguring section 4<SB>i</SB>reconfiguring a received video signal. As a result, the arbitrary synthesized video (four-division video and master-slave video in this embodiment) can be configured easily only by changing over the video reconfiguring section 4<SB>i</SB>taking charge of the reconfiguration of each video signal by a transmission-origin discriminating section 3 controlled by a first control unit 12. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a video transmission system for time-division multiplexing transmission of a plurality of videos.

Conventionally, a plurality of transmission devices that store video signals in different time slots via transmission lines and perform time division multiplex transmission, and receive video signals stored and transmitted in each time slot, and replay the original video. There has been provided a video transmission system including one or more receiving apparatuses configured and displayed. In such a conventional system, for example, the receiving device performs a process of combining images transmitted separately from four transmitting devices and displaying them on one screen. As described above, when a plurality of videos are combined, it is necessary to change the display size of each video. Conventionally, a plurality of videos are time-divided and processed by one processing circuit (for example, Patent Document 1). reference).
JP 2000-83193 A

  However, when a plurality of videos are processed in a time-sharing manner as in the conventional example, there is a problem that complicated control is required for the order of reading each video and the arrangement on the screen.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a video transmission system in which a composite video obtained by combining a plurality of videos can be easily configured.

  In order to achieve the above object, the first aspect of the present invention provides a plurality of transmission apparatuses that store video signals in different time slots and perform time division multiplex transmission via transmission lines, and transmit the signals stored in each time slot. Transmission system comprising one or more receiving devices that receive a received video signal and reconstruct and display the original video, wherein the receiving device reconstructs the received video signal for each time slot A plurality of video reconstruction means for processing, a display size changing means for changing the display size of the video reconstructed by at least one of the video reconstruction means, and a video whose display size has been changed by the display size changing means Are provided at a display position corresponding to each video reconstruction means on a one-to-one basis, and a video composing means for displaying the composite video synthesized by the video compositing means on a screen. The features.

  According to a second aspect of the invention, in the first aspect of the invention, the display size changing means changes the display size of the video reconstructed by all the video reconstruction means.

  According to a third aspect of the present invention, in the first aspect of the present invention, the video synthesizing means sets the standard size for displaying one video in full screen, and superimposes the video reduced by the display size changing means on the standard size video. It is characterized by creating a composite video.

  According to a fourth aspect of the present invention, in any one of the first to third aspects, the video composition unit waits for reconstruction until one or more videos to be composed are reconstructed by the video reconstruction unit. A composite video in which a dummy video painted with a single color is arranged at the display position is created.

  The invention of claim 5 comprises, in the receiving apparatus according to any one of claims 1 to 4, a first control means for switching whether to display the composite video synthesized by the video synthesis means on the display means, The first control means is characterized in that the display on the display means is switched in response to a reconstruction completion notification for notifying completion of the reconstruction of the video arranged at each display position.

  According to a sixth aspect of the present invention, in any of the first to fourth aspects of the present invention, an occurrence status of a video signal reception error is acquired from at least one of the video reconstruction means and the video synthesis means, and a reception error occurs. The receiving apparatus is provided with second control means for switching whether to display the displayed video on the display means.

  The invention of claim 7 is the invention of claim 4 or 5, wherein the receiving device includes switching means for switching whether or not the display size is changed by the display size changing means, and when the switching means switches whether or not the display size is changed, or When the video displayed on the display means is changed, the video reconstruction means and the video composition means initialize the video reconstruction processing and composition processing.

  The invention according to claim 8 is the video transmitted in the invention according to any one of claims 1 to 7, wherein an identification code for identifying the transmitter is added to the video signal transmitted from the transmitter, and the video is stored in the time slot and transmitted. The receiving apparatus is provided with reconstruction control means for controlling in accordance with an identification code which video reconstruction means to reconstruct the signal.

  The invention according to claim 9 is the invention according to claim 8, wherein the reconstruction control means discards the video signal when the identification code added to the video signal cannot be determined.

  According to the first aspect of the present invention, since the display position in the composite video and the display size changing means correspond one-to-one, the display position in the composite video according to the video reconstruction means for reconstructing the received video signal. Is uniquely determined, and an arbitrary composite video can be easily configured simply by switching the video reconstruction means responsible for the reconstruction of each video signal.

  According to the invention of claim 2, since the display size changing means changes the display size of the video reconstructed by all the video reconstruction means, it is possible to easily compose a composite video in which all the videos are synthesized. .

  According to the invention of claim 3, since the video composition means sets the standard size to display one video full on the screen, and creates the composite video in which the video reduced by the display size changing means is superimposed on the standard size video. Therefore, it is possible to easily compose a composite video in which a video reduced to a standard size video is combined.

  According to the invention of claim 4, a dummy in which the video composition means fills the display position of the video awaiting reconstruction with a single color until one or more videos to be composed are reconstructed by the video reconstruction means. Since the composite video with the video is created, the reconstructed video is displayed sequentially, so the waiting time until the video is displayed on the display means is shortened, and at the display position of the video waiting for reconstruction. By arranging the dummy video, the composite video can be displayed easily.

  According to the invention of claim 5, the first control means switches the display on the display means in response to the reconstruction completion notification that the video composition means notifies the completion of the reconstruction of the video arranged at each display position. Therefore, when at least one of the videos is reconstructed and can be displayed, the synthesized video can be displayed on the display means, and the display can be easily switched and the convenience is improved.

  According to the sixth aspect of the present invention, whether or not the video signal reception error occurrence status is acquired from at least one of the video reconstruction means and the video synthesis means, and the video in which the reception error has occurred is displayed on the display means. Since the receiving device is provided with the second control means for switching between them, the display quality of the video is improved by switching so that the video in which the reception error has occurred is not displayed on the display means.

  According to the seventh aspect of the present invention, the receiving device is provided with switching means for switching whether or not the display size is changed by the display size changing means, and the video displayed on the display means when the switching means switches whether or not the display size is changed. When changed, the video reconstruction means and the video composition means initialize the video reconstruction processing and composition processing, so when the video (synthesized video) displayed on the display means is changed, the video is distorted or interrupted. Can be prevented.

  According to the invention of claim 8, since the combination of the video signal stored in the time slot and the video reconstruction means for reconstructing the video signal can be arbitrarily selected by the identification code, it is transmitted from the same transmitter. Received video signals are stored in different time slots, the number of videos composing the composite video does not match the number of videos stored and transmitted in the time slots, or there is a reception error due to noise, etc. Even if it occurs, individual images can be displayed normally.

  According to the ninth aspect of the invention, since the reconstruction control means discards the video signal when the identification code added to the video signal cannot be determined, an erroneous video is reconstructed by a video signal of a different video. Can be prevented.

(Embodiment 1)
As shown in FIG. 2, the communication system according to the present embodiment is connected to a plurality of transmission apparatuses T that transmit digitally modulated video signals (packets) and the transmission apparatuses T via signal lines Ls. A main apparatus M that receives a video signal that is time-division-multiplexed and a plurality of receiving apparatuses R that receive and display the video signal that is time-division-multiplexed from the transmission apparatus T via the signal line Ls via the main apparatus M. It consists of and. Note that although a balanced line such as a pair line is used as the signal line Ls, an unbalanced line such as a coaxial line may be used. Further, a pair of enhanced category 5 or category 6 LAN cables or a pair of CPEV cables may be used for the signal line Ls.

  A plurality of time slots are defined by the synchronization signal SY sent from the main apparatus M to the signal line Ls, and each transmission apparatus T requests the main apparatus M to assign a time slot before starting transmission of the video signal. The video signal (packet) is stored and transmitted in the time slot TS allocated by the main apparatus M (see FIG. 3). The main apparatus M and the receiving apparatus R can receive the packet (video signal) stored in the time slot and reconstruct the original video. Moreover, according to the time division multiplex transmission method, video signals transmitted from different transmission devices T in different time slots are received, and data transmitted from different transmission devices T to each other by a plurality of reception devices R are separated. It can be acquired independently. However, which transmission device T uses which time slot is appropriately assigned to each transmission device T by the control signal transmitted from the main device M in the synchronization signal SY. The synchronization signal SY is composed of a header part and a data part as shown in FIG. The header part includes a preamble, a packet type, a modulation method, a time slot transmission availability code Ax, Bx, Cx, Dx, a data length, and an error check code. Here, the transmission permission / inhibition codes Ax, Bx, Cx, and Dx notify the transmission apparatus T from the main apparatus M whether or not the video signals can be transmitted to the four time slots A, B, C, and D defined in this system. It is. On the other hand, the data part is composed of allocation information Ay, By, Cy, Dy of the transmission apparatus T for each time slot A, B, C, D and an error check code. In the allocation information Ay, By, Cy, Dy, the identification code of the transmitting device T (for example, serial numbers 1, 2, 3,...) Is stored by the main device M, and the allocation information Ay, By, Cy, Dy is stored in the allocation information Ay, By, Cy, Dy. Transmitter T for each stored identification code transmits a video signal using each time slot A, B, C, D. However, even if identification codes are stored in the allocation information Ay, By, Cy, Dy, only the time slots A, B, C, D permitted by the transmission permission / inhibition codes Ax, Bx, Cx, Dx can be used. Needless to say.

  As shown in FIG. 4B, the video signal is also composed of a header part and a data part. The header part includes a preamble, an identification code indicating the transmission apparatus T as a transmission source, a packet type, a modulation method, a video data line number, a data length, and an error check code. On the other hand, the data part is composed of video data and an error check code. Here, the video data is video data for each line as shown in FIG. 5, and one frame of video is reconstructed by connecting the video data for each line in the vertical direction in the order of video data line numbers. (A so-called progressive method is adopted).

  In the main apparatus M, the transmitting apparatus T, and the receiving apparatus R, as shown in FIG. 3, the time when a predetermined waiting time T has elapsed from the falling edge of the synchronization signal SY is set as the start time of the first time slot A, and the next synchronization is performed. Four time slots A, B, C, and D are arranged within a period until the signal SY rises (signal transmission period). Here, in this embodiment, since four time slots A, B, C, and D are arranged within the signal transmission period, a maximum of four transmission devices T can individually transmit video signals.

As shown in FIG. 1, the receiving apparatus R of the present embodiment includes an amplifier that amplifies an analog received signal transmitted via a signal line Ls and an AD converter that converts the received signal amplified by the amplifier into a digital signal. A receiving circuit 1, a demodulating circuit 2 for demodulating original video data (video data for one line shown in FIG. 5) from a digital signal output from the receiving circuit 1, and a video signal demodulated by the demodulating circuit 2 The transmission source identification unit 3 that identifies the transmission device T that is the transmission source of the video data from the identification code, and the video data for each line that is demodulated and connected to the demodulation circuit 2 via the transmission source identification unit 3 The first to fourth video reconstruction units 4 _i (i = 1, 2, 3, 4) for reconstructing one frame of video by connecting the line numbers in the vertical direction, and the second video reconstruction Display of the video reconstructed in part 4 ₂ A first display size changing unit 5 for changing the size (reduction), the path a first display of the image reconstructed by the second image reconstructing section 4 ₂ input to the first display size changing section 5 The display size of the image reconstructed by the first route switching unit 6 and the first to fourth image reconstructing units 4 _i that selectively switch the route that bypasses the size changing unit 5 is changed (reduced). The path for inputting the video reconstructed by the second display size changing unit 7 and the first to fourth video reconfiguring units 4 _i to the second display size changing unit 7 and the second display size changing unit 7 A second route switching unit 8 that selectively switches a route that bypasses the first and second display size changing units 5 and 7, and the first to fourth video reconstruction a video synthesizing unit 9 that creates the synthesized image is arranged at a display position corresponding to the one-to-one with the section 4 _i, is synthesized by the image synthesizing unit 9 A video output circuit 10 that converts the data for each frame of the recorded video into a display signal and outputs the signal, and a display device having a display device such as a liquid crystal display, and the display device is driven by the signal output from the video output circuit 10 A display unit 11 for displaying video, a transmission source identification unit 3, first to fourth video reconstruction units 4 _i , first and second path switching units 6 and 8, a video composition unit 9, and a display unit 11 And a first control unit 12 to be controlled.

The transmission source identification unit 3 identifies the transmission device T that is the transmission source of the video data from the identification code of the video data demodulated by the demodulation circuit 2, and then, for each identification code, according to the instruction given from the first control unit 12. The video reconstruction unit 4 _i at the output destination is switched to Here, the route output to the _first video reconstruction unit 4 ₁ is the first channel cH1, the route output to the second video reconstruction unit 4 ₂ is the second channel cH2, and the third video reconstruction unit 4 _3. third channel cH3 a path for outputting, when it is assumed that a path for outputting the fourth to the video reconstruction unit 4 ₄ referred to as a fourth channel ch4, for example, in accordance with an instruction given from the first control unit 12, identification code = 3 is output to the first channel cH1, and the transmission device T with the identification code = 1 (hereinafter referred to as “T1”). Is output to the fourth channel cH4, and the video data transmitted by the transmitting device T with identification code = 2 (hereinafter referred to as “T2”) is output to the third channel cH3, and the identification code = 4 transmission device T (hereinafter, Denoted as T4. ") Is to output the video data transmitted to the second channel cH2.

The first to fourth video reconstruction units 4 _i all have the same function. As described above, by connecting the video data for each line in the vertical direction in the order of the video data line numbers, one frame can be obtained. In addition to the function of reconstructing the video, it also has a function of adjusting the image quality of the reconstructed video according to the instruction given from the first control unit 12. However, in the following, for simplification of description, the videos reconstructed by the first to fourth video reconstruction units 4 _i are referred to as the first to fourth channel videos, respectively. Here, the first to fourth video reconstruction units 4 _i output a reconstruction completion notification to the first control unit 12 when the reconstruction of the video for one frame is completed. The first control unit 12 determines that the video of the first to fourth channels cH1 to cH4 can be displayed by the reconfiguration completion notification.

First display size changing unit 5, when the second image reconstructed by the image reconstruction unit 4 ₂ by the first control unit 12 is switched a first path switching unit 6 is inputted A process of reducing the display size of the video (the video of the second channel cH2) is executed. The second display size changing unit 7 inputs the video reconstructed by the first to fourth video reconstruction units 4 _i after the second path switching unit 8 is switched by the first control unit 12. In this case, a process of reducing the display size of the video (videos of the first to fourth channels cH1 to cH4) is executed. However, the process of reducing the display size is well known in the art and will not be described.

The video synthesizing unit 9 writes and reads video to and from the frame memory 9a in accordance with instructions given from the first control unit 12 and a frame memory 9a that stores videos of the first to fourth channels cH1 to cH4. Video processing unit 9b that creates a composite video in which the videos of the first to fourth channels cH1 to cH4 read from the frame memory 9a are arranged at display positions corresponding to the first to fourth video reconstruction units 4 _i on a one-to-one basis. For example, as shown in FIG. 6B, the second display size changing unit 7 displays the standard size (the image of one channel cH1 as shown in FIG. 6A) on the full screen. The images of the first to fourth channels cH1 to cH4 reduced to a size of one-fourth of the size of the image) are arranged at the display positions of the upper left, upper right, lower left, and lower right, respectively. And a video (child video) obtained by reducing the video of the second channel cH2 by the first display size changing unit 5 as shown in FIG. 6C. ) Is superimposed on the standard size first channel cH1 or third channel cH3 or fourth channel cH4 video (parent video) (hereinafter referred to as “parent-child video”).

  Next, the operation of the receiving device R in this embodiment will be described.

For example, when the video transmitted from the transmission device T3 with the identification code = 3 is displayed in the standard size, the video signal (packet) in which the identification code of the header part is set to 3 is the first channel cH1, that is, the first along with giving an instruction to the transmission source identification unit 3 from the first control unit 12 to output the image reconstruction unit 4 _1, the first and second path switching unit 6, 8 at the first control unit 12 By controlling, both the first and second display size changing units 5 and 7 are bypassed, and further, an instruction is given from the first control unit 12 to the video synthesizing unit 9 without performing video synthesizing processing. The video of the first channel cH1 is output to the video output circuit 10 as it is. That is, an arbitrary transmission device Tm (m) is obtained by instructing the transmission source identification unit 3 from the first control unit 12 to the identification code of the video output to the first channel cH1 (first video reconstruction unit 4 ₁ ). = 1, 2,...) Can be displayed on the screen of the display unit 11 in a standard size.

The video signal (packet) in which the identification code of the header part is set to 1 to 4 is output to the first to fourth channels cH1 to cH4, that is, the first to fourth video reconstruction units 4 _i. The first control unit 12 gives an instruction to the transmission source identification unit 3, and the first control unit 12 controls the first and second path switching units 6 and 8 to control the first display size changing unit 5. And the video of the first to fourth channels cH1 to cH4 is input to the second display size changing unit 7 to reduce the display size, and further, the first control unit 12 applies to the video synthesizing unit 9 If an instruction to create a quadrant image is given, a quadrant image in which the images transmitted from the transmission devices T1 to T4 with identification codes = 1 to 4 are respectively arranged at the upper left, upper right, lower left, and lower right display positions is displayed. can do. However, the display positions of the images transmitted from the transmission devices T1 to T4 can be easily determined by instructing the combination of each image and the channels cH1 to cH4 output from the transmission source identification unit 3 from the first control unit 12. It can be changed.

  Alternatively, the video signal having the header identification code set to 1 is output to the first channel cH1, and the video signal having the header identification code set to 3 is simultaneously output to the second channel cH2. The first control unit 12 gives an instruction to the transmission source identification unit 3, and the first control unit 12 controls the first and second path switching units 6 and 8 so that the first display size changing unit 5 The video of 2 channel cH2 is input, the display size is reduced, the second display size changing unit 7 is bypassed, and the first control unit 12 instructs the video composition unit 9 to create a parent-child video. If given, it is possible to display a parent-child video in which the video transmitted from the transmission device T1 is a parent video and the video transmitted from the transmission device T3 is a child video. However, the selection of the video as the parent video (transmission device T) and the video as the child video (transmission device T) is performed by assigning the identification code of the video output to the first and second channels cH1 and cH2 to the first controller 12. It can be easily changed by instructing from

As described above, according to the present embodiment, since the display position in the composite video and the first and second display size changing units 5 and 7 correspond one-to-one, video reconfiguration for reconstructing the received video signal is performed. uniquely determined display position in the composite image according to the configuration section 4 _i, an image reconstruction unit 4 _i responsible for reconstruction of the video signal, the transmission source identification unit 3 controlled by the first control unit 12 Arbitrary composite video (in this embodiment, four-segment video and parent-child video) can be easily configured simply by switching.

By the way, in the video transmission system for time-division multiplex transmission of video signals as in the present embodiment, the timings at which the transmission devices T usually start transmitting video signals are not uniform. The timing at which the reconstruction of the video is completed in the unit 4 _i also varies. For example, after an instruction is given from the first control unit 12 until the quadrant video is actually displayed on the screen of the display unit 11. In some cases, considerable waiting time may occur.

Therefore, in the receiving device R according to the present embodiment, when the reconstruction completion notification is transmitted from at least one of the video reconstruction units 4 _i , the first control unit 12 gives an instruction to the video composition unit 9, and other video Until the reconstruction completion notification is sent from the reconstruction unit 4 _i, a composite image is created in which a dummy image painted in a single color (for example, black or blue) is arranged at the display position of the image waiting for reconstruction. Since the reconstructed video is sequentially displayed, the waiting time until the video is displayed on the display unit 11 is shortened, and the dummy video is arranged at the display position of the video waiting for reconstruction. This has the advantage that the composite video can be displayed easily. In addition, an incomplete video during reconstruction is not displayed on the screen of the display unit 11, and an easy-to-view composite video can be displayed. Accordingly, there is an advantage that display quality is improved. Alternatively, when the video signal of the specific channel cH cannot be received due to a failure of the specific transmission device T, disconnection of the signal line Ls, attenuation of the video signal, periodic external noise, or the like, the normally received channel cH Can be displayed (early) upon completion of reconstruction, and the display position where the video of the channel cH that cannot be received can be displayed as a dummy video, so that a transmission failure can be detected without impairing the display quality. There is an advantage that convenience is improved.

When the first or second path switching unit 6 or 8 is switched under the control of the first control unit 12, that is, the video displayed on the display unit 11 is changed (for example, from four-segment video to parent-child video). In the case of (changed), the first to fourth video reconstruction units 4 _{i and the} video composition unit 9 perform initialization to interrupt the processing and discard the processing result at that time, and display on the display unit 11. This prevents the video from being disturbed or interrupted when the video (synthesized video) is changed.

(Embodiment 2)
FIG. 7 shows a block diagram of the receiving device R in the present embodiment. However, since the basic configuration of the receiving device R in this embodiment is the same as that in the first embodiment, the same components are denoted by the same reference numerals and description thereof is omitted.

In the present embodiment, whether or not a video signal reception error has occurred is acquired from at least one of the video reconstruction unit 4 _{i and the} video synthesis unit 9, and the video in which the reception error has occurred is displayed on the display unit 11. This is characterized in that the receiving device R includes a second control unit 13 for switching between the two. Here, the first to fourth video reconstructing units 4 _i discard the video signal when there is a reception error in the identification code or line number of the video signal, so that an erroneous video is generated due to the video signal of a different video. The video is reconstructed only by the video signal that is prevented from being reconstructed and can be normally received. Therefore, the first to fourth video reconstruction units 4 _i can detect the occurrence status of the video signal reception error from the number of missing line numbers and notify the second control unit 13 of the detection. Further, in the present embodiment, since different error check codes are used for the header portion and the data portion of the video signal (see FIG. 4B), the occurrence of reception errors in the header portion and the data portion individually. Can be detected.

The second control unit 13 switches whether to display the video in which the reception error has occurred on the display unit 11 according to the reception error occurrence status notified from the video reconstruction unit 4 _i or the video synthesis unit 9. . Therefore, the second control unit 13 can display the channel cH in which reception errors frequently occur, and display a dummy image at a display position where the image of the channel cH is displayed.

  Here, as shown in FIG. 8, by simply connecting the connector of the functional module 108 to the connection port of the gate device 103, the power path and the information path of the functional module 108 can be secured at the same time. There is a wiring system that can be connected also to the gate device 103 and is excellent in workability. In this wiring system, one or a plurality of switch boxes 102 embedded and disposed at appropriate positions in a building are provided, and a power line 110 and an information line 111 that are wired in advance in a wall surface between the switch boxes 102 are sent and wired. At the same time, with respect to the switch box 102 at the starting end, a field line 110 drawn indoors through the main breaker MB and the branch breaker BB drawn into the wiring board 101, and a gateway 120 ( Information line 111 connected via a router and a hub is connected. It is also possible to incorporate the video transmission system according to the present invention in such a wiring system.

2 is a block diagram of a receiving device in Embodiment 1. FIG. It is a system block diagram same as the above. It is explanatory drawing of the time slot in the same as the above. (A) is an explanatory view of the synchronization signal in the above, and (b) is an explanatory view of the video signal in the above. It is explanatory drawing of the video data in the same as the above. It is explanatory drawing of the synthetic | combination image | video in the same as the above. 6 is a block diagram of a receiving device according to Embodiment 2. FIG. It is a system configuration diagram of a wiring system incorporating the same.

Explanation of symbols

M main apparatus T transmitting apparatus R receiving apparatus 1 receiving circuit 2 demodulating circuit 3 transmission source identification section 4 ₁ to ₄ 4 _first to _fourth video reconstruction sections 5 first display size changing section 6 first path switching section 7 Second display size change unit 8 Second path switching unit 9 Video composition unit 10 Video output circuit 11 Display unit 12 First control unit

Claims (9)

A plurality of transmission devices that store video signals in different time slots via transmission lines and perform time division multiplex transmission, and receive video signals stored and transmitted in each time slot and reconstruct the original video A video transmission system comprising one or more receiving devices for displaying,
The receiving device includes a plurality of video reconstruction means for performing reconstruction processing of the received video signal for each time slot, and a display size for changing a display size of the video reconstructed by at least one of the video reconstruction means A video synthesizing unit that creates a synthesized video in which the video whose display size has been changed by the display size changing unit is arranged at a display position corresponding to each video reconstruction unit on a one-to-one basis; A video transmission system comprising display means for displaying a composite video on a screen.   2. The video transmission system according to claim 1, wherein the display size changing means changes a display size of the video reconstructed by all of the video reconstruction means.   2. The video composition unit according to claim 1, wherein the video synthesizing unit has a standard size for displaying one video on a full screen, and creates a synthesized video by superimposing the video reduced by the display size changing unit on the standard size video. Video transmission system.   The video composition means creates a composite video in which a dummy video painted with a single color is arranged at the display position of the video waiting for reconstruction until one or more videos to be composed are reconstructed by the video reconstruction means. The video transmission system according to any one of claims 1 to 3.   The receiving apparatus includes first control means for switching whether to display the synthesized video synthesized by the video synthesizing means on the display means. The first control means is an image in which the video synthesizing means is arranged at each display position. 5. The video transmission system according to claim 1, wherein display switching is performed on the display means in response to a reconfiguration completion notification for notifying completion of reconfiguration.   Second control means for acquiring whether or not a video signal reception error has occurred from at least one of the video reconstruction means and the video composition means and switching whether or not to display the video in which the reception error has occurred on the display means; The video transmission system according to claim 1, wherein the video transmission system is provided in a receiving device.   The receiving device is provided with switching means for switching presence / absence of display size change by the display size changing means, and when the switching means switches presence / absence of display size change, or when a video displayed on the display means is changed, video reconstruction means 6. The video transmission system according to claim 4, wherein the video synthesizing means initializes the video reconstruction processing and synthesis processing. An identification code for identifying the transmission device is added to the video signal transmitted from the transmission device,
The reception apparatus includes a reconstruction control unit that controls, according to an identification code, which video reconstruction unit reconstructs a video signal stored and transmitted in a time slot. 8. The video transmission system according to any one of 7 above.   9. The video transmission system according to claim 8, wherein the reconstruction control means discards the video signal when the identification code added to the video signal cannot be determined.

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