JPS62290290A - Picture communication terminal equipment - Google Patents

Abstract

PURPOSE:To simultaneously and plurally transmit and display plural moving images, or still images on a single display device, by providing plural picture data transmission/reception circuits which transfer picture data to a communication control means within the frame period of a picture memory, and transfer received picture data to the rectangular area of the picture memory set in advance. CONSTITUTION:By inputting the position(X1, Y1) and the size(DELTAX1, DELTAY1) of the rectangular area within a picture plane having resolution (XXY) by a coordinate input means 6, at a transmission side, picture data to be transmitted within rectangular areas (X1, Y1)-(X1+DELTAX1, Y1+DELTAY1) is segmented at every frame period, from the picture data from a picture input device 8a, and is written on a picture memory 1, and an image on a display device 2 is updated, and also, it is sent to a communication control means 3. At a reception side, by repeating the read of transmitted picture data in a corresponding rectangular area in the picture memory 1 at every frame period, by a picture data reception circuit 5a, the picture data is displayed on the display device 2, then the picture transmission of the rectangular area can be realized.

Description

Detailed Description of the Invention 3. Detailed Description of the Invention [Field of Industrial Application] The present invention relates to an image communication terminal device that simultaneously transmits moving images and/or still images to a plurality of areas on a display device. It is.

[Conventional technology]

2. Description of the Related Art Video conferencing is conventionally known as a conversational communication service using moving images and still images. Video conferences use high-efficiency encoding technology to transmit video or still image data to each other over regular audio lines or high-speed dedicated lines, and it is possible to display the other party's image on a display device. It is said that Additionally, in video conferencing connecting multiple points, it is common practice to display images from multiple points using multiple display devices or by switching screens on a single display device. .

Furthermore, in order to simultaneously display images of a plurality of points on a single display device, images a, b, c, and d of the terminal device 50 of each point are displayed as shown in FIG. 5(a).

e on the exchange 51, reduced in the image processing device 52, and synthesized into a plurality of divided screens as shown in FIG. A method of displaying the progress has been proposed. In addition, Figure 5 (
In b), the image shows the screen of the terminal device in a.

[Problem that the invention seeks to solve]

However, because conventional image communication terminal devices transmit one entire screen as image data, only a single image can be viewed on a single display device, and multiple images are used to simultaneously view the material and the other party. The disadvantage of conventional conversations was that they required complex equipment as described above.

In addition, if multiple display devices are required for video conferences connecting multiple points, or if a single display device is used,
There was a problem in that it was not possible to view images from all locations at the same time. In order to solve this problem, even if a screen splitting method as described in FIG. 5 is used, the image must be displayed in a reduced size, resulting in a reduction in resolution.

An object of the present invention is to provide an image communication terminal device that can simultaneously transmit and display a plurality of moving images and/or still images on a single display device.

[Means for solving problems]

The present invention provides an image communication terminal device that transmits and receives image data of a plurality of moving images and/or still images, including an image memory that stores image data, a display device that displays the image data of the image memory, and a display device that displays the image data of the image memory. coordinate input means for inputting the position of a rectangular area; communication control means for controlling a communication line; and image data of the rectangular area set by the coordinate input means from the image memory to the communication control means. a plurality of image data transmitting circuits that transfer the received image data within a frame period of the image communication control means, and a plurality of images that transfer the received image data from the image communication control means to a preset rectangular area of the image memory within the frame period of the image memory. A data receiving circuit is provided.

[Effect]

FIG. 1 shows the basic configuration of an image communication terminal device equipped with two image data transmitting circuits and two image data receiving circuits.

The image memory 1 that stores images includes an image input device 8a,
The video signal from 8b is sampled at the sampling frequency and stored as image data. The image data is always read out at the timing of the sampling frequency, reproduced as a video signal, and sent to the display device 2. In the case of a moving image, the image data of the next frame is written, the screen is updated, and the screen is stopped. In the case of images, the image data is retained by being written back to the image memory 1 again.

In the communication terminal device of the present invention, for example, as shown in FIG. 4, the size of a rectangular area W (X
+, Y+) and the magnitude ΔX1. When ΔY1) is inputted by the coordinate input means 6, on the transmitting side, under the control of the terminal control means 7, the image data transmitting circuit 4a selects (X+) within the rectangular area to be transmitted.

Y+) (X+ +ΔX,,y, +ΔY+
) is written in the cut-out image memory 1 from the image data from the image input device 8a every frame period, and the image on the display device 2 is updated and sent to the communication control means 3. The communication control means 3 transmits through the communication line 9.

On the receiving side, the communication control means 3 receives the image data through the communication line 9, and the image data receiving circuit 5a reads out the transmitted image data into the corresponding rectangular area of the image memory 1 every frame period. By repeating this, the image is displayed on the display device 2, and image transmission of a rectangular area is realized. At this time, since the image data transmitting circuit and the image data receiving circuit can process in parallel, it is possible to implement a plurality of image data transmitting circuits and a plurality of image data receiving circuits, respectively, as shown in Figure 1, and execute the above transmission procedure in parallel. This enables mutual transmission and reception in a plurality of rectangular areas, and it is possible to transmit and display a plurality of images on a single display device as shown in FIG.

Further, since the size 1 position of the rectangular area is variable, it can be dynamically increased or decreased.

〔Example〕

FIG. 2 shows an embodiment of the image communication terminal device of the present invention.

A microprocessor 10 controls the entire terminal device. 11 is a mouse; 12 is a mouse interface which is a coordinate input means for inputting a rectangular area; 13 is a communication control interface which interfaces with communication control means 14; 14 is a communication control means that performs communication through a communication line 25. 15 is an image data transmission/reception circuit;
Sends and receives image data in a rectangular area. 16 is a display device that displays images. 17 is an external storage control interface that interfaces with the external storage device 18; 1
Reference numeral 9 denotes a ROM in which a program executed by the microprocessor 10 is stored. 20 is a RAM which is a work area. 21 and 22 input image data using an image input device such as a camera or a video disk. All interfaces are connected by a CPU bus 23. Further, the communication control interface 13 and the image data transmitting/receiving circuit 15 are connected by a dedicated local bus 24 for high-speed transfer.

FIG. 3 shows a more specific configuration example of the image data transmitting/receiving circuit 15 shown in FIG. 2. In FIG. This image data transmitting/receiving circuit is an example in which two image data receiving circuits and two image data transmitting circuits are implemented.

Position detecting means 30a, 30b, 30c, and 30d detect the timing of reading a rectangular area in the image data.

31a, 31b, 31c, 31d, and 31e are selectors for switching image data and turning it on and off;
2a and 32b are writers for writing image data into the transmission buffer. 33a and 33b are transmitting buffers, and 34a and 34b are receiving buffers, both of which are buffer memories between the communication line and the communication line. 35a and 35b are readers for reading out data as image data from the receiving sofa 348.degree. 34b, and 36 is a NAND circuit.

Reference numeral 37 denotes an image memory for holding image data, which is refreshed every frame period based on the sampling signal of the image input device and the horizontal synchronization signal.

In the image communication terminal device having the above configuration, the first image data receiving circuit includes the receiving buffer 34a, the reader 35a1 and the position detecting means 30c, and the receiving buffer 34b,
The reader 35b1 and the position detecting means 30d constitute a second image data receiving circuit. In addition, the position detection means 30
a, selector 31a1 selector 31c.

The writer 32a and the transmission buffer 33a constitute a first image data transmission circuit, and the position detection means 30b.

A second image data transmission circuit is composed of the selector 31b1 selector 31d, the writer 32b, and the transmission buffer 33b.

Next, the operation of this embodiment will be explained. The image memory 37 that stores image data stores image data obtained by sampling the video signals from the image input devices 21 and 22 at a sampling frequency. Image data is always read out at the timing of the sampling frequency, reproduced into a video signal, and sent to the display device 16. In the case of a moving image, the image data of the next frame is written and the screen is updated, and the image data of the next frame is updated. In some cases, the image data is retained by being written back to the image memory.

To transmit an image, first, when a rectangular area is designated by the mouse 11, the end points X1 and Yl and the sizes ΔX1 and ΔY1 of the rectangular area are input to the microprocessor 10 through the mouse interface 12. The microprocessor 10 controls the communication control interface 13 to establish a connection with the other party's terminal device, and upon negotiation, issues an image transmission command and its display area X, Y.
,, ΔX1. ΔY, is sent to the other party's terminal device, and the negotiation is completed. Next, the display area XI is displayed on the position detection means 30a.

Yl, ΔX1. Set ΔY1. Then, every time the image memory 37 is refreshed, the position detection means 30a detects the basic clock CL indicating the image data readout timing.
When the reading position of the image data from the image memory 37 reaches the display area based on K and the horizontal synchronizing signal H, the output is turned on. Then, the selector 31a cuts out the image signal from the camera 21, sends it to the image memory 37, and displays it on the display device 16. The selector 31c sends the written image data to the writer 32a. The writer 32a writes the image data to the transmitting sofa 33a when the output of the position detecting means 30a is turned on. The contents of the transmission buffer 33a are sent to the communication control interface 13 via the local bus 24, and are sequentially transmitted via the communication line 25 by the communication control means 14 under the control of the communication control interface.

On the other hand, upon reception, the communication control means 14
The communication control interface 13 detects the communication request of 5.
to the microprocessor-10. The microprocessor 10 controls the communication control interface 13 to establish a connection, perform negotiation, and display the received image display areas X, , Y, , ΔX1 .
Obtain ΔY1. Next, microprocessor-1
0 indicates the display area x, , Y, , on the position detector a30c.
ΔX1. Set ΔY1.

Then, the position detecting means 30c detects the image data reading position (X+, Y+) (Xl
The output signal is turned on only during +ΔX, , Y, +ΔY+). The image data is received through the communication line 25, sent through the communication control interface of the communication control means 141, and sent to the image data transmission/reception circuit 15 via the local bus 24, and stored in the reception buffer 34a. Then, when the output of the position detection means 30c is turned on,
The reader 35a writes the received data from the reception buffer 34a into the image memory 37 as image data.

All position detection means 30a, 30b, 30c, 3
When 0d is off, the selector 31e controlled through the NAND circuit 36 writes and holds the read contents of the image memory 37 as they are in the image memory 37.
On the screen, only the transmission area and reception area are updated.

If the above-described operations on the transmitting side and receiving side are executed within the frame period, images can be continuously transmitted.

Furthermore, in this embodiment, the transmission is terminated by adding a frame end command to the transmission signal by the communication control interface 13 on the transmitting side at the end of the frame, and upon receiving it, the receiving side sends an acknowledgment command to each other. ing. Termination is input using the mouse 11 of both terminal devices, the microprocessor 10 stops the image data transmitting/receiving circuit 15, then controls the communication control interface 13,
The transmitting side sends a communication end command instead of the frame end command, and the receiving end sends a communication end command instead of the acknowledge command. The communication control interface 13 of the other party's terminal device detects the communication termination command, notifies the microprocessor 10, and stops transmission and reception. Next, after the microprocessor 10 stops the image data transmitting and receiving circuit 15, the communication is terminated by releasing the connection using the communication control interface 13.

The image data transmitting/receiving circuit shown in FIG. 3 has a plurality of transmitting circuits and receiving circuits mounted in parallel, and this configuration has two image data transmitting circuits and two image data receiving circuits.

If the communication line has a broadcast function for at least three parties, the image data transmitting circuit sends the image of the own terminal device, and the image data receiving circuit receives the images of the two points, so that the images of the three points can be sent to each of the three points. It is now possible to display simultaneously in a rectangular area,
A multi-point television conference xm can be realized on a single screen.

In addition, although the explanation so far has not mentioned image band compression, image band compression is performed by adding an encoder to the image data transmission circuit and a decoder to the image data reception circuit. Of course, it is also possible to transmit in a low band.

In this embodiment, the mouse 11 is used to input the rectangular position, but it is of course also possible to use a tablet, etc., and the rectangular area can also be specified as the range surrounded by two points instead of the end points and size. You can also do it.

This embodiment corresponds to the case of moving images, but it can also be used for still images by transmitting and receiving frame by frame using a pair of image data transmitting and receiving circuits, and by sequentially transmitting and receiving data for multiple areas. I can handle it. In addition, by using a high-resolution display device for displaying a general television signal as an image input signal or a video signal from a video device such as a video disk on multiple screens, it is possible to display a television on a high-resolution display device.

It also becomes possible to simultaneously display and transmit multiple low-resolution images from video discs and the like.

〔Effect of the invention〕

By using the image communication terminal device of the present invention, it is possible to display multiple images simultaneously on a single display device, allowing services that use multiple videos, services that mix still images and moving images, and services that use multiple images to be displayed simultaneously. Point-to-point conference services will become possible.

[Brief explanation of the drawing]

FIG. 1 is a basic configuration diagram of an image communication terminal device of the present invention; FIG. 2 is a diagram showing an embodiment of the image communication terminal device of the present invention; FIG. 3 is a diagram showing an example of an image data transmission/reception circuit; Figure 4 is a diagram showing a rectangular area on the screen, Figure 5 is an explanatory diagram of the conventional method, where (a) is an overall configuration diagram, and (b) is a diagram showing an image displayed on a terminal device. . 1...Image memory 2...Display device 3...Communication control means 4a, 4b...Image data transmission circuits 5a, 5b...
...Image data receiving circuit 6...Coordinate input means 7...Terminal control means 8a, 8b...Image input device

Claims (1)

[Claims] (1) In an image communication terminal device that transmits and receives image data of a plurality of moving images and/or still images, an image memory that stores image data, a display device that displays the image data of the image memory, and a rectangular shape on the display device. A coordinate input means for inputting the position of the area, a communication control means for controlling the communication line, and image data of the rectangular area set by the coordinate input means is transferred from the image memory to the communication control means of the image memory. a plurality of image data transmission circuits that transfer the received image data within a frame period; and a plurality of image data that transfers the received image data from the image communication control means to a preset rectangular area of the image memory within the frame period of the image memory. An image communication terminal device comprising: a receiving circuit.