JPH1141585A - Video communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a video communication system in which a partial video image sent from different video servers is integrated as one video content at a receiver side and the image is continuously displayed. SOLUTION: Video data at the head of a partial video image to be received next at a video reception terminal are transferred from a video server 103 for storing the above data to a video server 102 for storing one preceding partial video image, so as to allow the video server 102 to send a head of a succeeding partial video image immediately after the transmission of the partial video image without interruption. Thus, the effect of fluctuation in a delay time is reduced and a buffer underflow at the reception side is suppressed. Furthermore, the video reception terminal 105 is provided with two buffer sections 124, 126, and the video data are shared depending on senders to allow the two video servers 102, 103 to easily detect the part received in duplicate and either of them is deleted. Thus, mixture of the video data at the border of the partial video image is avoided.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a video communication system for transmitting stored video stored in a video storage terminal to a video receiving terminal via a communication network.

[0002]

2. Description of the Related Art In a video-on-demand (VOD) service, video contents are stored in a video storage terminal (commonly called a video server), and the video contents are transmitted from the video server in response to a user request from a video receiving terminal. This is a video communication service to be taken out. As one extended form of such a VOD service, there is a form in which a plurality of component videos are stored in a video server, and a video obtained by connecting the component videos is presented to a user as one video content.

FIG. 6 shows an example of a conventional video communication system for realizing such a VOD service.

In FIG. 6, reference numeral 601 denotes a management server;
03 is a video server, 604 is a communication network, and 605 is a video receiving terminal. The service provider side of the video communication system in FIG. 6 includes a management server 601, a video server 602,
The video server 603 includes three devices, and the service consumer side includes a video receiving terminal 605. In FIG. 6, there is only one video receiving terminal for simplicity, but when actually providing service, a plurality of video receiving terminals are usually connected to a communication network. Also, the number of video servers does not need to be two.

In FIG. 6, reference numerals 606 to 609 denote components of a management server 601, 606 denotes a content management unit, 607 denotes a video server control unit, 608 denotes a user command receiving unit, and 609 denotes a network interface unit. 610 to 613 are components of the video server 602, and 614 to 617 are components of the video server 603. The components of the video server 602 and the video server 603 are the same, 610 and 614 are video data storage units, 611 and 615 are transmission control units, and 612 and 616.
Denotes a buffer unit, and 613 and 617 denote network interface units. 618 to 623 are video receiving terminals 605
618 is a network interface unit, 619 is a buffer unit, 620 is a user command transmission unit, 621 is a decoding unit, 622 is a video display unit, and 623 is a user interface unit.

[0006] The content management unit 60 of the management server 601
No. 6 manages how the component images stored in the respective video servers 602 and 603 are transmitted to the video receiving terminal with respect to time by providing a management table (hereinafter referred to as assembly data) for each video content. doing.

FIG. 7 shows an example of the assembly data of the content management unit 606. In this case, the content management unit 606
In FIG. 7A, there are shown 3001 shown in FIG.
02 are registered. As can be seen from the assembly data in FIG. 7A, the video content 3001 is a video in which six component videos are connected. According to the assembly data, the component images 602 -B,
602 -A, 602 -D are stored in the video server 602, and the component images 603 -D, 603 -P, 603-
F is stored in the video server 603. Time S ₁ is the time at which the reproduction of the component video is started, and time E ₁ is the time at which the reproduction of the component video is stopped, which is a relative time measured from the beginning of the video content. Time S ₂ indicates whether to start playback from which frame parts video, a relative time measured from the beginning of the part image. Time E
Reference numeral ₂ indicates at which frame the reproduction is stopped, which is also a relative time measured from the beginning of the component video.

FIG. 8 is a view for explaining the temporal relationship between the video content 3001 and the component videos constituting it.

First, the video content 3001 uses 5 seconds from the top of the component video 602-B. Parts video 60
2-B has a length of 10 seconds, but since S ₂ = 0 and E ₂ = 5, only the first 5 seconds are used. Subsequent to the component image 602-B, a component image 603-D is used. The component video 603-D is a video of 8 seconds, but S ₂ = 2, E ₂
= 4, the video of 2 seconds from the position of 2 seconds from the head is used. Subsequent to the component video 603-D, the component video 603-P is used. The component video 603 -P is originally a video for 4 seconds, and since S ₂ = 0 and E ₂ = 4, all of the video from the beginning to the end is used for the video content 3001. With the same mechanism as above, the component video 603
After -P, the component video 602-A and the component video 603-
F, the component video 602-D is used.

The video server control unit 607 sends one of the transmission control units 611 and 615 to one of the transmission control units 611 and 615 via the communication network 604 so that the six component images are delivered to the video reception terminal 605 in such a time relationship. Send control signal. The specification of the video content to be transmitted is performed by a user operation via the user interface unit 623. The user interface unit 623 includes an input device such as a mouse, a keyboard, and a touch panel. The user operates this input device to specify video content to be extracted. When two video contents 3001 and 3002 are registered in the content management unit 606 as shown in FIG.
Can be selected by the user. The user command transmitting unit 620 includes the user interface unit 6
23, the user command receiving unit 608 via the network interface unit 618, the communication network 604, and the network interface unit 609,
Send a command. The video server control unit 607 stores the requested video content assembling data in the content management unit 6.
06, and sends a control signal to the transmission control units 611 and 615 while referring to the assembly data. This control signal includes the following information.

1) Information for specifying a component video to be transmitted (for example, component video ID) 2) Information for specifying from which video frame of the component video to start reproduction (for example, S ₂ ) 3) Which Information (eg, E ₂ ) for designating whether to stop reproduction at a video frame 4) Information (eg, address of video receiving terminal 605) for designating a destination video receiving terminal (eg, address of video receiving terminal 605) Which one to send can be determined from the video server ID of the assembly data.

In the video data storage units 610 and 614 of the video servers 602 and 603, magnetic disks and CD-Rs are stored.
An encoded component video is stored in a recording device such as an OM. The management server 6 determines which component video is to be transmitted.
01, the transmission control units 611 and 615 sequentially read the data of the specified component video from the video frame at the specified reproduction start position to the video frame at the specified stop position to the buffer units 612 and 616. The data read to the buffer units 612 and 616 is
The data is transmitted to the video receiving terminal 605 via the network interface units 613 and 617 at t-In First-Out. The buffers 612 and 616 are used because the transmission speed to the communication network 604 and the video data storage 61
This is to absorb the mismatch of the reading speed from 0,614. There may be various designs for starting transmission after reading all data to be transmitted into the buffer unit, or reading data into the buffer unit while transmitting. The destination of the video data is specified by the management server 601.

On the other hand, the video receiving terminal 605 transmits video data transmitted from any of the video servers to the communication network 6.
04, and temporarily stores them sequentially in the buffer unit 619. Then, the decoding unit 621 sequentially reads and decodes the video data from the buffer unit 621, and decodes the video data.
To be displayed. The buffer unit 619 is a mechanism for balancing the decoding speed of the decoding unit 621 and the reception speed from the communication network 604.

[0014]

The video server, management server, and video receiving terminal are connected via a communication network. Therefore, the time from when the management server instructs the video server to transmit the component video data to when the video data actually reaches the video receiving terminal (hereinafter referred to as delay time D) is different for each video server. Can be different. This is due to the difference in the reaction time of the video server, the difference in the number of exchanges (or the number of routers) between the video server / video receiving terminal, the difference in the number of exchanges (or the number of routers) between the management server / video server, and the transmission path itself. This is due to a difference in transmission distance (particularly in the case of a satellite network).

When the delay time D is different for each video server and the management server controls the video server ignoring the difference, the buffer unit of the video receiving terminal at the boundary between the two component videos. 619 may underflow, or data may be sent from two servers at the same time and mixed in the buffer unit 619.

FIG. 9 is a diagram for explaining the above problem.
First component video 60 of video content 3001 in FIG.
Taking the boundary between 2-B and the second component video 603-D as an example, video data observed at the entrance of the buffer unit 619 is depicted. In FIG. 9A, since an interval is left between two component images, the buffer unit 619 may cause an underflow. On the other hand, FIG.
In, the data of the two component images are mixed,
The decoding unit 621 cannot correctly decode this data.

In order to solve these problems and to continuously display component videos transmitted from different video servers on the video receiving terminal side without inconsistency, a delay time D for each video server is predicted in advance and managed. A method is conceivable in which the server controls the video server based on the predicted value.

However, the delay time D differs not only between video servers, but is not always constant even for the same video server, and may vary statistically. In particular, when a best-effort network such as the Internet is used, the fluctuation becomes extremely large, and it is impossible to predict the delay time D and control the video server.

As described above, the conventional configuration has a problem that it is difficult to continuously display two component videos transmitted from different video servers on the video receiving terminal side without any inconsistency. .

It is an object of the present invention to provide a video communication system capable of continuously displaying component videos transmitted from different video servers on a video receiving terminal side without any inconsistency.

[0021]

In order to solve the above problems, the present invention comprises two or more video storage terminals, one or more video reception terminals, and a communication network, and is stored in the two or more video storage terminals. In the video communication system, the video data of a certain component video A is transmitted to the video receiving terminal in the video communication system, wherein the component video A is provided by the video receiving terminal. Transfer means for transferring the video data of the head portion of the component video B to be received next from the video storage terminal storing the component video B, and temporarily storing the video data of the component video B transferred by the transfer means. A temporary storage unit for storing the video data of the component video A, and a transmission control unit for starting transmission of the video data of the component video B stored in the temporary storage immediately after transmitting the video data of the component video A. Characterized by comprising the product terminal.

Also, two temporary storage means for temporarily storing the video data transmitted from the video storage terminal, and the transmission of the video data to one of the two temporary storage means depending on the source of the video data. Distribution means for distributing and temporarily storing the selected video data, and buffer control means for deleting the video data from one temporary storage means when the same video data is stored in both of the two temporary storage means. It is provided in a video receiving terminal.

Further, the video storage terminal includes a component video A
Means for notifying the video receiving terminal of the switching of the component video when the transmission of the video data of the component video B stored in the temporary storage means is started immediately after the transmission of the video data is completed. The terminal buffer control means operates based on the notification.

In the present invention, the video data at the head of the component video to be received next by the video receiving terminal is transferred to the video server which stores the immediately preceding component video and transmits the video to the video receiving terminal. As a result, two consecutive video data are made to exist on the same video server, and immediately after the video server finishes transmitting one component video, the data at the beginning of the next component video is transmitted without interruption. It can be so. This makes it less susceptible to fluctuations in the delay time D, and suppresses buffer underflow on the receiving side (see FIG. 9A), which has occurred at the boundary between component images in the conventional configuration.

Further, in the present invention, the video receiving terminal is provided with two temporary storage means (buffers), and the transmitted video data is distributed to any one of the temporary storage means according to the source of the video data. In the case where the leading data of the component video is sent successively to the previous component video, the video receiving terminal can easily detect the duplicated portion that will receive that portion redundantly from the two video servers. And
And one can be deleted. In addition, by performing the sorting, it has been a problem in the conventional configuration,
Eliminating the intermingling of video data (see FIG. 9B) at the boundary of the component video is eliminated.

[0026]

Embodiments of the present invention will be described below in detail with reference to the drawings.

FIG. 1 is a diagram for explaining an embodiment of the tree invention. In the figure, 101 is a management server, 102 and 103 are video servers, 104 is a communication network, and 105 is a video receiving terminal. On the service provider side, the management server 101,
It is composed of a video server 102 and a video server 103,
The service consumer side is configured by the video receiving terminal 105. Although two video servers are used in FIG. 1, the same can be applied to a case where there are three or more video servers. Further, a configuration is also possible in which the management server 101 and any of the video servers are physically located in the same device (in this case, the management server 101 and the video server are connected without passing through a communication network). Will be.) Although only one video receiving terminal is illustrated in FIG. 1, it is needless to say that a plurality of video receiving terminals can be connected to a communication network.

In this embodiment, in order to simplify the explanation,
The time from when the management server 101 sends a control signal instructing the video server to start transmitting the component video to when the video server actually starts to transmit the component video is 0.
The description will be made using an ideal system that is (zero). That is, in the present embodiment, the factor that causes the delay time D is only the communication network between the video server and the video receiving terminal. However, the present invention can be similarly implemented when the response time of the video server is not zero, or when the transmission time of the control signal from the management server to the video server is not zero. In this embodiment, the communication network 104
Although the description has been made with the case of a packet network such as a TM network or the Internet in mind, the same can be implemented in an analog network such as a CATV or a circuit-switched network by simply changing around the network interface. .

In FIG. 1, reference numerals 106 to 109 are constituent elements of the management server 101, 106 is a content management unit, 107 is a video server control unit, 108 is a user command receiving unit, and 109 is a network interface unit. 110 to 115 are components of the video server 102, and 116 to 121 are components of the video server 103. The configurations of the video server 102 and the video server 103 are the same. 110 and 116 are video data storage units, 111 and 117 are transmission / reception control units, 112 and 118 are head data buffer units, 113 and 119 are buffer units,
Reference numerals 114 and 120 denote head data extraction units, and reference numerals 115 and 121 denote network interface units. 122-130
Is a component of the video receiving terminal 105, 122 is a network interface unit, 123 is a data distribution unit, 124 and 126 are buffer units, 125 is a buffer control unit, 127 is a user command transmitting unit, 128 is a decoding unit, and 129 is a decoding unit. An image display unit 130 is a user interface unit.

The user interface unit 130 is composed of input devices such as a keyboard, a mouse, and a touch panel, and the user specifies which video content to retrieve using the user interface unit 130. Here, it is assumed that the user has requested the video content 2001. The user command transmitting unit 127 transmits a command indicating that the user has requested the video content 2001 to the user command receiving unit 108 of the management server 101 via the network interface unit 122, the communication network 104, and the network interface unit 109.

FIG. 2 shows an example of component video information (referred to as “assembly data”) of the content management unit 106. The content management unit 106 stores the component video information constituting the video content in the same manner as in the prior art. Information (assembly data) is managed for each video content. In the case of FIG. 2, the content management unit 106 stores the video contents 2001 and 2
002 are managed.

FIG. 3 is a diagram for explaining the time relationship between the video content 2001 and the component video, which is described in the same manner as in the prior art.

When the video content 2001 is requested by the user, the video server control unit 107 stores the assembly data of the video content 2001 in the content management unit 106.
Remove from The video server control unit 107 interprets the assembly data and controls the video server as described below.

The first component video of the video content 2001 is 102-B. Component Video 102-B, since stored in the video data storage unit 110 of the video server 102, video server control unit 107, first, as to deliver the component video 102-B from the position at time S ₂ in order,
The video server 102 is controlled. In the following description, it referred to the time of this time and t _0. The transmission / reception control unit 111 of the video server 102 uses the buffer unit 113 to balance the read speed from the video data storage unit 110 and the transmission speed to the communication network 104,
-B is transmitted to the video receiving terminal 105.

On the other hand, the video server control unit 107 controls the transmission of the component video 102 -B from the video server 102, and at the same time, starts the second component video 103 -D constituting the video content 2001. The video server 102 and the video server 102 transfer data from the video server 103 to the video server 102 so as to transfer the data (not the head of the component video stored in the video data storage unit, but the head of the component video to be delivered to the video receiving terminal). 1
03 is controlled. Video server 1 that has received the control signal
03, the transmission / reception control unit 117
To the S ₂ time of the component video 103 -D (in this case, S ₂
= 2 seconds) to ΔT seconds (referred to as head data) is read from the video data storage unit 116 and transferred to the head data buffer unit 112 of the video server 102 via the communication network 104. The transfer of the leading data of the component video 103-D is performed in parallel with the transmission of the component video 102-B.
Here, the following description will be made assuming that ΔT = 1 second. However, the value of ΔT can be set in various ways. There is also a problem that the size becomes large or the size of data that is redundantly sent to the video receiving terminal becomes large). ΔT at the beginning of the component video 103-D
First data buffer unit 112 that has received data for seconds
Temporarily stores this.

When the video server 102 finishes transmitting the component video 102-B by the time E ₂ (in this case, E ₂ = 5 seconds), it transmits a video switching identifier. , Video data of the component video 103-D temporarily stored in the head data buffer unit 112 (transferred from the video server 103 as described above)
Send Since this data is sent from the same video server 102 as the component video 102-B, the video receiving terminal should receive the data following the component video 102-B.

On the other hand, the video server control unit 107 transmits the second component video 103-D at time t ₀ +5.
(Seconds), it instructs the video server 103 to transmit the component video 103-D. The transmission of the component video 103-D from the video server 103 is performed in the same manner as the transmission of the component video 102-B from the video server 102. That is, the portion of the leading data subjected to transfer included, transmitted from the position of the S ₂ times. However, the third part image 10
Since 3-P is stored in the same video server 103 as the second component video 103-D, the above-described transfer operation, that is, the transfer of the leading data of the next component video is not performed. When the component video 103-D is transmitted to the position at time E ₂ (E ₂ = 4 seconds in this case) (that is, time t ₀ +7 (second)), the head data buffer unit 118 is not used, and the video switching identifier is used. Is not sent. After the component video 103-D, the component video 103-P is read from the video data storage unit 116 and transmitted via the buffer unit 119.

The video server control unit 107 repeats the operation described above up to the last component video of the video content 2001.

FIG. 4 is a diagram for explaining the time relationship of video data transmitted from the video servers 102 and 103 to the video receiving terminal 105. The time in the figure is the time at the exit of the video server. As can be seen from FIG. 4, for example, from S ₂ (= 2 seconds) of the component image 103-D, 1
Second video data, that is, head data, is transmitted redundantly from the two video servers 102 and 103. Among them, the one transmitted from the video server 102 is 1
Since the video is transmitted from the same video server immediately after the previous component video 102-B, it is considered that the video arrives immediately after the component video 102-B even at the entrance of the video receiving terminal. on the other hand,
Since the path transmitted from the video server 103 differs from the path of the video server 102 in the communication network, even if the path is started from the video server 102 at time t ₀ +5 (seconds) at the same time as the former, the former does not There is a possibility that it will arrive later or earlier than it reaches the entrance of the receiving terminal.

Next, the operation of the video receiving terminal 105 will be described.

Video data received from the communication network 104 via the network interface unit 122 is distributed to one of the buffer units 124 and 126 by the data distribution unit 123. Here, it is assumed that the data distribution unit 123 has selected 124 as the initial buffer at the start of the operation. When the first component video 102-B of the video content 2001 is sent from the video server 102, the data distribution unit 123 sequentially flows the video data of the component video 102-B to the buffer unit 124 and temporarily stores the video data. The first data for one second of the second component video 103-D is transmitted from the video server 102 following the component video 102-B by the above-described mechanism. Therefore, this is also temporarily stored in the buffer unit 124. On the other hand, the second component video 103-D is
3, the data distribution unit 123
The video data sent from the video server 103 is sent to the buffer unit 126 and temporarily stored.

[0042] Figure 5 is a diagram for explaining a state of the video data coming into the data distribution section 123 between the certain time t _a time t _b. As can be seen from FIG. 5, there is a possibility that video data from a plurality of video servers may enter the data distribution unit 123 in a mixed manner, so the data distribution unit 123 looks at the source address of each data. Distribute appropriately.

Now, the decoding unit 128
Alternatively, video data is sequentially read from 126 and decoded. In the case of the video content 2001, as described above, the video data of the component video 102-B is temporarily stored in the buffer unit 124, so that the video data is sequentially read and decoded, and the video is displayed on the video display unit 129. As described above, the video switching identifier is embedded at the boundary between the 5-second video data of the component video 102-B sent from the video server 102 and the video data of the first second of the component video 103-D. Have been. Buffer control unit 125
Detects this video switching identifier at the exit of the buffer unit, checks whether video data of the component video 103-D from the video server 103 has begun to arrive at the other buffer unit 126. If the video data of the component video 103-D has already started to arrive from the video server 103, the buffer unit 1 of the decoding unit 128
Reading from the buffer unit 126 is stopped, and reading from the buffer unit 126 is started. At this time, the data remaining in the buffer unit 124, that is, the leading data of the component video 103-D is cleared. Component video 10 in buffer section 124
If the head data of 3-D has not yet been received to the end, the buffer unit 124 waits until receiving the last data of the head data of the component video 103-D, and then clears the data of the buffer unit 124. .

On the other hand, when the video switching identifier is detected, if the video data from the video server 103 has not arrived in the buffer unit 126, the decoding unit 128 continues reading from the buffer unit 124,
-Decode sequentially from the beginning of D. At this time, the buffer control unit 125 sends the component video 1
The data amount (for example, the number of bytes) of the head of 03-D is measured. It is assumed that the measured value at time t is represented by b (t) bytes. Then, at a certain time t ', the buffer unit 12
When the video data amount of the component video 103-D from the video server 103 accumulates at least b (t ') bytes in 6, the buffer control unit 125 first stops reading from the buffer unit 124 by the decoding unit 128. Then, the video data of the amount of the head data already sent to the decoding unit 128, that is, b (t ') bytes, is deleted from the head of the buffer unit 126. This is a process for preventing the same video data from being redundantly decoded (data of the first second of the component video 103-D is stored in the video server 1).
02 and 103). Then, the reading of the video data from the buffer unit 126 by the decoding unit 128 is started. At the same time, the data remaining in the other buffer section 124 is cleared. Buffer unit 1
When the head data of the component video 103-D has not been received to the end yet, the buffer unit 124 stores
After waiting until the last data of the head data of 03-D is received, the data in the buffer unit 124 is cleared.

The video receiving terminal 105 processes the subsequent component video in the same manner.

Although the present embodiment does not refer to the presence or absence of voice, the present invention can be implemented regardless of the presence or absence of voice. Further, in the present embodiment, the timing of the transmission instruction to the video receiving terminal to the video server and the timing of the transfer instruction of the next component video are set at the same time. However, the timing of these two instructions does not necessarily have to be the same. Various timing designs are possible. Further, in the present embodiment, the start of data from the first data buffer unit is notified to the receiving side by inserting the video switching identifier on the video server side, but the time stamp and frame number attached to the video data are notified. May be notified by a discontinuous change of the video reception terminal, and the video receiving terminal may automatically determine.

In the embodiment, the video on demand service for selecting video content from the video receiving terminal has been described as an example. However, instead of the video receiving terminal selecting the video content, such as selecting the video content on the service provider side, even in a broadcast type service, when providing video content by combining the component video, The present invention is applicable.

[0048]

As described above, according to the present invention, the video data of the leading part of the component video to be received next by the video receiving terminal is transferred to the video server storing the component video immediately before. You. After the transfer, the two video data are present on the same video server. Therefore, immediately after the video server finishes transmitting a certain component video, the video server transmits the data at the beginning of the next component video without interruption. It becomes possible. Therefore, it is less susceptible to the fluctuation of the delay time D, and the buffer underflow on the receiving side (see FIG.
(See (a)) can be suppressed.

Further, when the video receiving terminal is provided with two buffers and the video data is allocated to one of the buffers according to the transmission source, the video data is redundantly received from the two video servers. It is possible to easily detect the overlapping portion and delete one of them. Also,
By allocating the video data to any of the buffers according to the transmission source, the mixing of the video data at the boundary of the component video (see FIG. 9B), which is a problem in the conventional configuration, is also eliminated.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating the configuration of an embodiment of the present invention.

FIGS. 2A and 2B are diagrams illustrating an example of video data assembly data managed by a content management unit according to the embodiment. FIG.

FIG. 3 is a diagram illustrating an example of a time relationship between component videos constituting the video content.

FIG. 4 is a diagram illustrating an example of a state of video data transmitted from two video servers to a video receiving terminal in the embodiment.

FIG. 5 is a diagram illustrating an example of a state of video data at an entrance of a data distribution unit in the embodiment.

FIG. 6 is a diagram illustrating a configuration of a conventional example.

FIGS. 7A and 7B are diagrams for explaining assembly data of video content managed by the content management unit of the conventional example.

FIG. 8 is a diagram for explaining a time relationship between component videos constituting the video content.

FIGS. 9A and 9B are diagrams illustrating a problem that may occur in the related art.

[Explanation of symbols]

 101 management server 102, 103 video server 104 communication network 105 video receiving terminal 106 content management unit 107 video server control unit 108 user command receiving unit 109 network interface unit 110, 116 video data storage unit 111 , 117 ... transmission / reception control units 112, 118 ... head data buffer units 113, 119 ... buffer units 114, 120 ... head data extraction units 115, 121 ... network interface units 122 ... network interface units 123 ... data distribution units 124, 126 ... buffers Unit 125: Buffer control unit 127: User command transmission unit 128: Decoding unit 129 ... Video display unit 130: User interface unit

Claims (3)

[Claims] 1. A system comprising two or more video storage terminals, one or more video reception terminals, and a communication network, wherein component videos stored in the two or more video storage terminals are transmitted to the video reception terminals in a preset order. In the video communication system provided, when video data of a certain component video A is transmitted to a video receiving terminal, video data of a leading part of a component video B to be received next to the component video A by the video receiving terminal. Transfer means for transferring the video data of the component video B transferred from the video storage terminal storing the component video B, temporary storage means for temporarily storing the video data of the component video B transferred by the transfer means, Transmission control means for starting transmission of the video data of the component video B stored in the temporary storage means immediately after the transmission has been completed, in the video storage terminal. Temu. 2. Temporary storage means for temporarily storing video data transmitted from a video storage terminal, and said video data transmitted to one of said two temporary storage means according to a source of the video data. Receiving means for distributing and temporarily storing video data; and buffer control means for deleting the video data from one of the temporary storage means when the same video data is stored in both of the two temporary storage means. The video communication system according to claim 1, wherein the video communication system is provided in a terminal. 3. The image storage terminal, when starting transmission of the video data of the component video B stored in the temporary storage means immediately after the transmission of the video data of the component video A is completed, switches the video of the component video. The video communication system according to claim 2, further comprising means for notifying the receiving terminal, wherein the buffer control means of the video receiving terminal operates based on the notification.