JPH02274084A - Inter-multispot video conference system - Google Patents

Abstract

PURPOSE:To eliminate the need of providing an encoding part and a decoder part of every terminal on a communication controller by switching directly video encoding data. CONSTITUTION:When switching of an image is requested from an arbitrary one of video conference terminals 2a-2c, in-frame encoding data sending-out request means 12a-12c of a communication controller 1 request to the requested video conference terminal so as to send out in-frame encoding data, and from the requested video conference terminal, the in-frame encoding data is sent out. Also, freeze request means 12a-12c request to other video conference terminals containing the requested video conference terminal so as to freeze the present image. Therefore, the communication controller 1 switches directly the in-frame encoding data so as to output the in-frame encoding data to each video conference terminal which is freezing the present image, and when each video conference terminal 2a-2c receives the in-frame encoding data, the present image is switched to the image of the in-frame encoding data. In such a way, it is possible to make a decoder and an encoder unnecessary.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a multi-point video conference system in which a plurality of video conference terminals arranged between multiple points are connected via a communication control device.

[Prior art] Figure 5 shows, for example, Research and Practical Application Report Vol. 33, No. 11 (19
84) is a block diagram showing the conventional multipoint video conference communication control device (hereinafter abbreviated as MCU) shown in 84), in which (1) is the MCU.

(2a) to (2c) are video conference terminals that transmit and receive encoded video/audio data and control data, and subscripts a to C are attached to stations A to C, respectively (subscripts a to C are attached in the same manner below). (3a) to (3c) are digital lines that bidirectionally transmit digital signals; (4a) to (4c) are interfaces with the digital lines (3a) to (3c), and are used to transmit encoded video/audio data and A line interface unit that multiplexes/demultiplexes control data, (5a) to (5c) are video input lines that input encoded video data to the video switching unit (10), and (6) is selected by the video switching unit (10). The encoded video data is sent to line interface units (4a) to (4C).
), the video output line (7) is connected to each terminal (2a) to (
The video switching request signal line inputs the video switching request signal sent from 2C) to the video control (8), and the video switching request signal line (8) sends it to each terminal (2a) to (2C) based on the video switching request signal. The video is determined and the video switching instruction signal (9) is sent to the video switching unit (
10), and also sends an intra-frame encoded data transmission request/screen freeze request signal to the line interface section (3).
a) to (3C), a video control unit (9) is a video switching instruction signal, and (10) is a video switching instruction signal that is inputted from video human power lines (5a) to (5c) based on the video switching instruction signal (9). This is a video switching unit that selects the encoded video data and outputs it to the video output line (6).

FIG. 6 is a block diagram showing the video switching unit (1o) in FIG. A video decoding section converts data into an analog video signal and outputs it to analog video input lines (14a) to (14c), (14a) to (14c) are analog video input lines, (1
1) selects one analog video signal input from the three analog video input lines (14a) to (14c) based on the video switching instruction signal (9), and selects one of the analog video signals input from the three analog video input lines (14a) to (14c),
5), (15) is the analog video output line, and (16) is the video output line (6) after converting the analog video signal input from the analog video output line (15) into video encoded data. This is a video encoder that outputs to

Next, the operation will be explained.

When a terminal (2a) makes a connection request to other terminals (2b) to (2c) to the MCU (1), the MCU (1) connects each terminal via the line interface unit (4a) to (4C). Connect with (2a) to (2c). When the connection is completed, a multipoint video conference can be held between the terminals (2a) to (2c).

Video encoded data multiplexed with audio encoded data and control data at each terminal (2a) to (2c) is sent to the MCU (1) via each digital line (3a) to (3c).
transmitted to. In MCIJ (1), each terminal (2a) ~ (
Each video encoded data received from 2c) is separated by line interface sections (4a) to (4c) and sent to video input line (5
The signals are input to the video switching unit (10) via a) to (5C).

The video encoded data input to the video switching section (10) is converted into an analog video signal in the video encoding sections (13a) to (13c), and then sent to the analog video input lines (14a) to
(14c) is input to the changeover switch (11). Each analog video signal input manually to the changeover switch (11) is converted into one analog video signal based on the instruction of the video switching instruction signal (9). Output. Now, for example, suppose that the video of station A is selected. That is, assume that the changeover switch (11) is connected to point a.

The analog video signal of the selected station A is input to the video encoder (16) via the analog video output line (15). The video encoder (16) converts the input analog video signal of station A into video encoded data and outputs it to the video output line (6).

The video encoded data of station A is sent via the video output line (6).
It is input to each line interface section (4a) to (4c). The MCU (1) multiplexes the video encoded data of station A with the audio encoded data and control data at each line interface section (4a) to (4C) and transmits it to each digital line (3a).
- (3c) to each terminal (2a) - (2C). As a result, the video of station A is displayed on each terminal (2a) to (2c).

Next, assume that the terminal (2c) of station 0 makes a screen switching request for the video of station B to the MCU (1). The video switching request signal from station 0 is input to the line interface section (4C) of the MCU (1) via the digital line (3c). The video switching request signal separated by the line interface section (4C) is input to the video control section (8) via the video switching request signal line (7). The video control section outputs a video switching instruction signal (9) based on the video switching request.

The changeover switch (11) of the video switching unit (10) connects point a to point b based on the instruction of the video switching instruction signal (9), and the video encoded data of station B is transmitted via the video output line (6). It is output to line interface sections (4a) to (4C) and transmitted to each terminal (2a) to (2c). As a result, the video of station B is displayed on each terminal (2a) to (2C).

Thereafter, each time a screen request is generated from any of the terminals (2a) to (2C), the desired video can be displayed through similar operations.

[Problem to be solved by the invention] Since the conventional multipoint video conference system is configured as described above, the multipoint video conference communication control device has the following features:
After converting the video encoded data transmitted from each terminal into an analog video signal, the screen-selected analog video signal is converted into a video signal again. ] The signal must be returned to the transmitter and then transmitted to each terminal. Therefore, a decoder and an encoder are required in the multipoint video conference communication control device, resulting in a complicated configuration.

Purpose of the Invention The present invention was made with the aim of solving such problems, and is a multiplex system that enables video switching without converting video encoded data sent from each terminal into an analog video signal. The purpose is to provide a point-to-point video conference system.

[Means for Solving the Problems] In order to achieve the above object, the present invention provides that when a communication control device receives a request for video switching from an arbitrary video conference terminal, intraframe encoded data transmission requesting means for requesting the terminal to transmit intraframe encoded data that can be transmitted; a freeze request means for requesting each video conference terminal to freeze the current video being displayed until the intra-frame encoded data is received, and the communication control device transmits the intra-frame encoded data to each video conference terminal. It is designed so that the output is switched to the corresponding one.

[Operation] In the above means, when video switching is requested from any one video conference terminal, the intra-frame encoded data transmission request means of the communication control device transmits the intra-frame encoded data transmission to the requested video conference terminal. A request is made to send encoded data, and intraframe encoded data is sent from the requested video conference terminal. Further, the freeze request means requests other video conference terminals including the requested video conference terminal to freeze the current video.

Therefore, the communication control device directly switches the intra-frame encoded data to be output to each video conference terminal that is freezing the current video, and when each video conference terminal receives the intra-frame encoded data, it outputs the intra-frame encoded data directly. The video is switched to the video of the intra-frame encoded data.

[Example] An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a functional block diagram showing a multipoint video conference communication control device (hereinafter abbreviated as MCU) of the present invention.

In the figure, (8) determines the video to be sent to each video conference terminal (2a) to (2c) based on the video switching request signal, outputs the video switching instruction signal (9) to the video switching unit (10), and outputs the video switching unit (10). The inner encoded data transmission request or screen freeze request signal is sent to the line interface units (4a) to (4).
(12a) to (12c) are intraframe encoded data transmission request/screen freeze request signal lines for transmitting an intraframe encoded data transmission request signal and a screen phrase request signal to each terminal. It is.

FIG. 2 is a block diagram of the video switching unit (10) in the MCU of the present invention.

In the figure, (11) is the video input line (5a) to (5C)
This is a changeover switch that directly switches the video encoded data output from the video encoded data, and the switching is controlled by a video switching instruction signal (9).

Next, the operation of the above embodiment will be explained with reference to FIGS. 3 and 4.

FIG. 3 is a diagram showing the sequence when video encoded data sent to each video conference terminal (2a) to (2C) is switched, and FIG. FIG. 2 is a diagram showing a transfer format of video encoded data.

When the terminal (2a) makes a connection request to the other terminals (2b) to (2c) to the MCU (1), the MCU (1) connects each terminal via the line interface section (4a) to (4C). Connect with (2a) to (2C). When the connection is completed, a multipoint video conference can be held between each terminal (2a) to (2C).

Video encoded data multiplexed with audio encoded data and control data at each terminal (2a) to (2C) is sent to MCU (1) via each digital line (3a) to (3C).
transmitted to. In MCU (1), each terminal (2a) to (
Each video encoded data received from the video input line (5C) is separated by the line interface section (4a) to (4C) and sent to the video input line (5C).
The signals are input to the video switching unit (10) via a) to (5C).

The video encoded data input to the video switching section (10) is input to the changeover switch (11). Changeover switch (11
), one type of video encoded data is outputted to the video output line (6) based on the instruction of the video switching instruction signal (9).

For example, suppose that the video of station A is selected as shown in FIG. 3 (30). That is, assume that the changeover switch (11) is connected to point a. The video encoded data of the selected station A is sent to the line interface section (4a) via the video output line (6).
) to (4C). Therefore, the MCU (1) transmits the video encoded data of the selected station A as shown in FIG. 3 (31) to (33) to each line interface unit (4a) to (4C).
) is multiplexed with audio encoded data and control data and sent to each terminal (2) via each digital line (3a) to (3C).
a) to (2C). This allows each terminal (2a
) to (2C), the video of station A is displayed.

Next, suppose that the terminal (2C) of station 0 makes a screen switching request for the video of station B to the MCU (1) as shown in FIG. 3 (34). The video switching request signal from station 0 is input to the line interface section (4C) of the MCU (1) via the digital line (3C).

The video switching request signal separated by the line interface section (4C) is input to the video control section (8) via the video switching request signal line (7). The video control unit (8) outputs the video switching instruction signal (9) based on the video switching request, and also outputs the intra-frame encoded data transmission request/screen freeze request signal line (12b) as shown in FIG. 3 (35). An intraframe encoded data transmission request signal is transmitted to the terminal (2b) of station B via the terminal 2b. In addition, as shown in FIG. 3 (36) to (38), each terminal (2a)
A screen freeze request signal is sent to (2C).

The terminal (2b) of station B, which received the intra-frame encoded data transmission request, sends the intra-frame encoded data (full-screen information for one frame) as shown in Fig. 3 (39), and on the other hand sends a screen freeze request signal. Each terminal (2a) to (2C) that received
The current screen displayed on the local station is frozen until intraframe encoded data is received from the station. Here MCU
The changeover switch (11) in (1) is a video switching instruction signal (9
) is connected from point a to point b based on the instructions in Figure 3 (
As shown in 40) to (42), the video encoded data of station B is sent to the line interface section (4a) through the video output line (6).
(4C) and transmitted to each terminal (2a) to (2C). As a result, each terminal (2a) to (2C) has B
The station image is displayed.

Thereafter, as shown in Figure 3 (43) to (50), any terminal (2
Every time a screen request occurs from a) to (2b), the desired screen can be displayed through a similar sequence.

The transfer format of video encoded data on the video output line (6) at this time is shown in FIG. (60) is the intra-frame encoded data (full screen information) frame of station A, (61
) to (64) are interframe encoded data frames (difference information from the full screen) of station A, (65) are intraframe encoded data frames of station B, and (66) to (69) are frames of station B. It is an inter-coded data frame, and each frame (6
1) to (69) have front and rear portions (71) to (79) containing identification information of intra-frame/inter-frame encoded data, etc. Each terminal (2a) to (2c) reads this header section (
Intraframe/interframe encoded data is identified from 71) to (79).

In the above embodiment, video from one terminal is transmitted to all terminals, but the same applies when conducting a multipoint video conference in which video from any terminal is transmitted to any terminal. Video switching is possible without converting to an analog video signal.

[Effects of the Invention] As described above, according to the present invention, since video encoded data is directly switched, there is no need to provide the communication control device with an encoding unit and a decoder unit for each terminal, and the configuration is simplified. becomes easy.

[Brief explanation of drawings]

FIG. 1 is a functional block diagram showing a multipoint video conference communication control device according to an embodiment of the present invention, FIG. 2 is a functional block diagram of a video switching section, and FIG. 3 is a functional block diagram of a video switching section, and FIG. 4 is a transfer format of encoded video data, FIG. 5 is a functional block diagram showing a conventional multipoint video conference communication control device, and FIG. 6 is a functional block diagram of a conventional video switching unit. It is. As shown in the figure, (1) is the MCU, (2a) to (2C) are video conference terminals, (3a) to (3C) are digital lines,
(4a) to (4C) are line interface sections, (5a)
~(5C) is the video input line, (6) is the video output line, (7)
is a video switching request signal line, (8) is a video control unit, (9) is a video switching instruction signal, (10) is a video switching unit, (11) is a changeover switch, and (12a) to (12c) are intraframe codes. This is a data transmission request/screen freeze request signal line. In addition, in the figures, the same reference numerals indicate the same or equivalent parts.

Claims (1)

[Scope of Claims] A plurality of teleconference terminals capable of transmitting and receiving and a communication control device arranged between multiple points are provided, and video encoded data and audio encoded data can be transmitted from any one of the teleconference terminals. In a multipoint video conference system, the video encoded data and the audio encoded data are output to and received by any other video conference terminal via the communication control device, comprising: communication control; When an arbitrary video conference terminal requests video switching, the device generates an intra-frame code that requests the requested video conference terminal to send intra-frame encoded data that can be transmitted by that terminal. freezing the current video displayed by each video conference terminal until the intra-frame encoded data is received by other video conference terminals including the requested one video conference terminal; 1. A multipoint video conference system, comprising: freeze request means for requesting a freeze request, and is configured to switch to output the intraframe encoded data to each of the video conference terminals.