KR20000020801A - Method for controlling transmitting speed of image - Google Patents

Abstract

PURPOSE: A method for controlling a transmitting speed of an image capable of improving a transmitting speed of an image and easily transmitting many image frames per hour by confirming display information by mutual communication protocol while continuously communicating with other person in an image communication is provided. CONSTITUTION: In a method for controlling a transmitting speed of an image, a screen display state of a receiver is read from a transmitter through a protocol which is promised with the receiver. According to the read screen display state of the receiver, an image omitting an image area which a user cannot see or a part of a sampled image in a receiver is compressed in a transmitted. The compressed image is transmitted to the receiver. When a screen state of the receiver read from the transmitter is larger than a screen state of the transmitter, a screen of the transmitter is sampled and compressed at the rate of a larger screen to a smaller screen. The sampled and compressed screen is transmitted to the receiver.

Description

Image transmission speed control method

According to the present invention, when video communication through a video communication device (eg, a video phone) is omitted, an image area to be transmitted / received is reduced by eliminating the compression code size to be transmitted per frame by omitting the video area that is not visible at the receiving end. It relates to a transmission rate control method of.

In general video communication devices, the compression rate is adjusted and transmitted to make the required number of video frames per second.

This is usually defined as a standard. In general, the image compression method is a still image compression standard (JPEG), a moving image compression standard (MPEG), etc., which uses a quantization table.

In this case, as the image is compressed using the quantization table as described above, in the case of a complex image, the file size of the data increases, which causes a delay in transmission time.

Therefore, in order to fill the required number of images per second, the block size (edge) is not properly represented by reducing the file size by increasing the compression ratio using the quantization table or restoring the file transmitted from the receiving side. The image quality considerably deteriorated by the effect) or loss of the reconstructed data is displayed.

1 is a block diagram showing the configuration of a conventional conventional video communication apparatus as described above.

A charge coupled device (CCD) 1 for converting external light input through the lens 1a into an electric image signal;

A CCD driver 2 for driving the CCD 1 and transferring an image signal input through the CCD 1 to a digital signal processor (DSP) 3;

A digital signal processing unit (3) for digitally processing the image signal input from the CCD driver (2) and displaying and outputting the image signal through a monitor (4), and outputting the image signal in the format of a luminance signal and a color signal for image compression;

An image compression / restoration unit 5 which is responsible for compressing and restoring an input image signal;

A communication control and interface unit 6 for transmitting the compressed video signal and receiving the transmitted video signal, and a control unit 7 for controlling each part of the system for processing, compressing, restoring the video signal, and the like. It is composed.

The operation of the video communication apparatus having such a configuration will be described below.

The external light input through the lens 1a is converted into an electric image signal through the CCD 1 and input to the CCD driver 2.

The CCD driving unit 2 performs analog signal correction on the input image signal as described above, makes it to a predetermined level, and outputs the same to the DSP 3.

The DSP 3 executes clamping, RGB color control, brightness control, and the like on the input image signal, and then displays the image input through the monitor 4.

At this time, the DSP 3 converts the input image into a constant format of a luminance signal and a color signal for image compression for transmission to the outside and outputs the image to the image compression / recovery unit 5.

The image compression / recovery unit 5 performs image compression in JPEG and MPEG according to the type of the input image signal, and the compressed image signal is transmitted to the communication line through the communication control and interface unit 6. .

The signal flow as described above is controlled by the controller 7.

At this time, the transmission speed in the communication line is lowered according to the communication load and environment of the surroundings, and as the complexity of the image to be transmitted increases, the amount of data compressed in the video signal increases.

Here, as described above, the communication control and interface unit 6 adjusts the compression rate so as to uniformly adjust the number of transmission frames per second, and compresses and transmits at a high compression rate in the case of a complex image.

However, in the case of such a complex image, the higher the compression ratio is, the more it is displayed as a degraded screen such as block event, contour collapse, etc., when the receiving side is restored.

In particular, since it aims to transmit 30 frames at a few frames per second, a complex image may have a higher compression ratio, resulting in a totally different result from the original image.

As such, in the related art, the compression ratio is adjusted according to the complexity of the image to be transmitted, so that the required number of transmissions per second is adjusted. When the image is complex, the amount of compression increases as the image is complex. There was a problem of being transformed completely differently.

That is, in the conventional video communication device, the video output from the camera is captured at a specific moment and transmitted in units of frames. In this case, the entire frame of the constant screen is continuously compressed and transmitted.

In fact, by compressing and transmitting even the invisible part of the receiver, it did not help the number of frames per unit time, which is a key factor of the video communication device.

In other words, as shown in FIG. 2, in the conventional video communication apparatus, the viewer may not only view the screen coming from the other party through the monitor 4 but also view the screen with his own screen, thereby increasing the code size to be transmitted per frame. There is a problem in that the image frame to be transmitted in time can not be properly transmitted and received.

In the present invention, in order to solve the above-mentioned conventional problems, while continuously performing communication with the other party during video communication, the communication protocol is determined between each other, and after confirming the information on the display status by continuous transmission and reception, the image area that is not visible at the receiving end is omitted. By reducing the compression code size to be transmitted per frame by compression, and to improve the transmission speed of the image as well as to smoothly transmit and receive a large number of video frames per unit time.

1 is a block diagram showing the configuration of a general video communication device.

2A is a screen state diagram when the screen of the transmitter is small and the screen of the receiver is large.

2B is a screen state diagram when the screen of the transmitting end is large and the screen of the receiving end is displayed small;

2C is a screen state diagram when only the screen of the transmitting end is displayed.

2D is a screen state diagram when only the screen of the receiving end is displayed.

3 is a flowchart showing a method of controlling a transmission speed of an image applied to the present invention.

3 is a flowchart illustrating a method of controlling a transmission rate of an image applied to the present invention, which is implemented by the image communication apparatus of FIG. 1.

As shown in Figure 3, the image transmission rate control method of the present invention,

Reading, by the transmitting end, a screen display state of the receiving end through the promised communication protocol with the receiving end;

Compressing and transmitting only a part of an image or a sampled image, which is omitted from an image region, which is not visible at the receiving end, according to the screen display state of the receiving end read by the step; Proceeds.

At this time, if the screen state of the receiver read from the transmitter is larger than the screen state of the transmitter, the image of the transmitter is sampled at a large screen to small screen ratio, compressed, and then transmitted to the receiver.

When the screen state of the receiving end read from the transmitting end is smaller than the screen state of the transmitting end, the small screen displayed at the receiving end is skipped in the image area to be compressed at the transmitting end, the compression is performed, and then transmitted to the receiving end.

If all the screen state of the receiving end read from the transmitting end is the screen of the receiving end, the transmitting end immediately reads the screen state of the receiving end, and performing compression in the case of changing the screen state of the receiving end, and then transmitting to the receiving end. It is.

Referring to Figures 1 to 3 attached to the operation of the transmission rate control method of the present invention configured as described above is as follows.

First, the communication protocol of the transmitting end and the receiving end is determined so that the screen display state of the receiving end can be read by the transmitting end during video communication through the image communication device.

That is, as an example, when the screen display state of the receiver is small as shown in FIG. 2A, the screen of the receiver is small and the screen of the receiver is large.

When the screen of the transmitting end is larger and the screen of the receiving end is smaller as shown in FIG. 2B.

When only the screen of the transmitter is displayed as in FIG. 2C.

When only the screen of the receiving end is displayed as in Figure 2d.

As described above, if a code that can recognize each other is promised, the transmitting end or the receiving end can easily check the information on the screen display state during transmission and reception while continuously communicating with the other party.

Here, the communication protocol between the transmitting end and the receiving end is made possible by inserting a promised code value into the header of the transmitted image data.

Accordingly, the transmitting end may compress only a part of an image or a sampled video that omits an unviewable video area according to the screen state read from the receiving end through a promised communication protocol with the receiving end during a video call, and then transmit it to the receiving end. Will be

By reducing the average compression code size per frame during a video call through a video communication device, the receiver can receive a large number of frames per unit time.

This will be described in more detail as follows.

First, in the case of a video call, when the screen of the receiver read from the transmitter is larger than the screen of the transmitter as shown in FIG. 2A,

In the DSP (3) of the video communication apparatus, under the control of the control unit (7), the image of the transmitting end is sampled at a large screen to small screen ratio, and displayed on the monitor (4) and output to the image / compression restore unit (5). Done.

In this case, the image / compression restoring unit 5 compresses the sampled and inputted image into MPEG and transmits it to the receiving end through the communication control and interface unit 6, so that the receiving end transmits the image transmitted from the transmitting end. It is regarded as a small screen and displayed as it is.

In addition, in the case of a video call, as shown in FIG. 2B, when the screen of the receiver read from the transmitter is smaller than the screen of the transmitter,

The DSP 3 of the video communication apparatus omits the small screen portion of the receiver from the image area to be compressed at the transmitter under the control of the controller 7, and then displays it on the monitor 4 and the image / compression restore unit 5 Will output

In this case, the video / compression restorer 5 compresses the video of the transmitter, in which the small screen portion of the receiver is omitted, to MPEG, and then transmits the video to the receiver through the communication control and interface unit 6. As described above, the small screen portion is omitted, so that the entire screen of the monitor can be displayed without damaging the screen using only the compressed image.

On the other hand, in the case of video call, as shown in Fig. 2d when the screen of the receiver read from the transmitter is displayed only the screen of the receiver,

In the DSP 3 of the video communication apparatus, under the control of the control unit 7, the compression is performed after the compression is performed according to the case where the screen state of the receiver is changed while immediately reloading the screen state of the receiver. The transmitted image is transmitted to the receiving end.

On the other hand, as shown in FIG. 2C, when all the screen states of the receiver read from the transmitter are the screens of the transmitter, the DSP 3 of the video communication apparatus compresses all the images of the transmitter under the control of the control unit 7. After this, it can be transmitted to the receiving end through the communication control and interface (6).

As described above, the present invention is to determine the screen display state of the receiving end through the communication protocol promised to each other in the video communication, and then to the receiving end through sampling or region elimination compression for the video region that is not visible at the receiving end Since the compression code size is transmitted in the smallest frame unit without affecting the display state of the image, it is possible to improve the transmission speed of the image and to smoothly transmit and receive many image frames per unit time.

Claims (5)

Reading, by the transmitting end, a screen display state of the receiving end through the promised communication protocol with the receiving end; Compressing and transmitting only a part of an image or a sampled image, which is omitted from an image region, which is not visible at the receiving end, according to the screen display state of the receiving end read by the step; The transmission rate control method of the image, characterized in that proceeds to. 2. The method of claim 1, wherein if the screen state of the receiver read from the transmitter is larger than the screen state of the transmitter, sampling the image of the transmitter at a large screen to small screen ratio, performing compression, and transmitting the image to the receiver; The transmission rate control method of the image, characterized in that it comprises a. The method of claim 1, wherein if the screen state of the receiving end read from the transmitting end is smaller than the screen state of the transmitting end, the step of omitting the small screen displayed at the receiving end in the image area to be compressed at the transmitting end and performing the compression is transmitted to the receiving end. The transmission rate control method of the image, characterized in that it comprises a. The receiver as claimed in claim 1, wherein when the screen state of the receiver read from the transmitter is all the screens of the receiver, compression is performed according to the case where the screen state of the receiver changes while the screen state of the receiver is immediately read again by the transmitter. The transmission rate control method of the image comprising the step of transmitting. 2. The method of claim 1, wherein the communication protocol between the transmitting end and the receiving end is made by a promised code value embedded in a header of the transmitted image data.