KR100311399B1 - Image data transmission method for image communication apparatus - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of transmitting image data of a video communication device. In the related art, it is only after a considerable time is required to receive the first image data after connection to a communication network. If the normal speed does not come out due to the disturbance, etc., the transmission amount of image data to be continuously transmitted every predetermined time (e.g. 30msec) is reduced (e.g., the maximum data that can be transmitted when the transmission speed is 33.6Kbps). If the size of the file is 128 bytes, the audio data is fixed at 24 bytes (when G723 voice compression / 6.3 Kbps is used) regardless of the speed for real time call, and the remaining 104 bytes of image data increases or decreases according to the transmission speed. As long as it takes longer to receive video data on one screen, the user may feel frustrated with the call. Deflect and there is a problem in that tteurige dropped calls satisfaction. Therefore, when the transmission speed of the line is not normal, such as when the line is poor due to disturbance during communication during communication initial communication or during communication, the present invention adjusts the size or compression rate of the image to reduce the transmission rate. By compensating and transmitting, there is an effect of improving the call satisfaction by preventing the user from feeling a transmission delay.

Description

IMAGE DATA TRANSMISSION METHOD FOR IMAGE COMMUNICATION APPARATUS}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a video data transmission method of a video communication device, and more particularly, to a video communication device that makes a video call by simultaneously transmitting an image and a voice using a general telephone network (PSTN). The present invention relates to a method of transmitting image data of an image communication apparatus in which a user does not feel a transmission delay by compensating by adjusting an image size or a compression rate in accordance with the state of the line when the line state becomes poor due to poor line condition.

FIG. 1 is a block diagram showing a schematic configuration of a general video telephone system. As shown therein, a CD 1 converts and charges light incident through a lens (not shown) into an electrical signal; Input the digital sample output suitable for color / luminance processing by reading the signal charged to the CD (CDS: Correlated Double Sampling) to remove noise and adjusting it to an appropriate level on the display (AGC: Auto Gain Control) A signal processor 2; A digital signal processing (DSP) unit 3 for correcting and outputting a color / luminance signal inputted through the input signal processor 2; A display unit 4 for displaying image data on an LCD or a monitor; A memory unit 5 for storing video and audio; A compression / restoring unit 6 for compressing the image and audio to be transmitted or reconstructing the received image and audio; A modem control unit 7 for monitoring and transmitting data transmitted through the telephone line; A modem 8 for converting analog data to be transmitted over the telephone line 9 into digital or vice versa; It is composed of a voice codec unit 10 for converting and outputting the voice data transmitted through the modem (8) to analog, or receiving a voice signal and converting it to digital. Same as

Unlike PC-based video conferencing systems and Internet phones (IP phones), which are recognized exclusively for some computer users, video phones can easily make video calls without a high-speed leased line and a computer with a TV set and a regular phone line. In order to perform a video call using the video phone as described above, it is necessary to first connect to the communication network through the modem 8 built in the video phone. Only after the connection is completed to the communication network and a waiting time of several seconds has elapsed even after the connection has been completed, the setting is completed with the receiving end, and the image data transmitted from the transmitting side is displayed on the receiving side monitor.

Of course, the actual time at which the first image data is displayed on the receiving side monitor may be further delayed by an internal decoding process according to the size of the image data transmitted after the waiting time of several seconds.

Depending on whether the screen mode of the data transmitted from the transmitting side is set to 'high quality' or 'low quality', the image compression ratio is applied relatively small or large. The size of the image is increased so that the receiving side takes a long time to receive the image data of one screen, and when the compression ratio is large, the size of the image data is small, so that the receiving side takes less time to receive the image data of the screen. On the other hand, the modem control unit 7 continuously monitors the state of the line, and if the state of the line is continuously bad, retraining is performed to adjust the speed of the modem. Not only will this be impossible, but if retraining is performed during transmission, It is to lose all the data is to be retransmitted from the beginning.

In addition, when only a part of the transmission data is lost due to intermittent disturbance or the like, the modem controller 7 may fail to detect it. In this case, the error check (CRC) may be performed by the compression / restore unit 6 of the receiving system. If the retransmitted data continues to be defective, the receiving side continues to request retransmission until a predetermined time, but after the predetermined time has elapsed, the image data of one screen received so far is received. The video data of the next screen is discarded and sent again. Accordingly, when the above-mentioned phenomenon continues, the still image is continuously output and the call is inconvenient.

As described above, in the conventional technology, it is only after a considerable time is required to receive the first image data after connecting to the communication network that the image on the transmission side can be seen, resulting in a long waiting time and a normal speed under the influence of disturbance. If does not occur, the amount of image data to be continuously transmitted is reduced every predetermined time (e.g. 30 msec) (e.g., when the transmission speed is 33.6 Kbps, the maximum data size that can be transmitted is 128 bytes. Is fixed at 24 bytes (when using G723 audio compression / 6.3 Kbps) for real-time call, and the remaining 104 bytes of video data are increased or decreased depending on the transmission speed. Takes time, and users become frustrated with calls and degrade call satisfaction There was.

Accordingly, the present invention has been made to solve the above-mentioned problems, and when the initial state of a communication with a relatively high delay time or a disturbance during communication causes a poor line condition and a drop in the transmission speed, Accordingly, an object of the present invention is to provide an image data transmission method of a video communication device that improves call satisfaction by compensating for a dropped transmission speed by adjusting an image size or compression rate.

1 is a block diagram showing a schematic configuration of a typical video telephone system.

2 is a flowchart showing one embodiment of a method of transmitting image data of a video communication apparatus according to the present invention;

In order to achieve the above object, the present invention provides a video communication apparatus capable of varying the compression rate and the size of an image, by minimizing the size of the image and increasing the compression rate if it is the first transmission state after being connected to a communication network. Transmitting at a low resolution; A second step of determining a transmission speed of the line and whether the data is normally received after the initial transmission of the image data; As a result of the determination, when the normal data is received at a predetermined transmission speed or more, it is achieved by the third step of the user returning to the original resolution set by the user and transmitting the same. When described in detail with reference to the drawings as follows.

In general, the resolution of a monitor depends a lot on the size of the image (QCIF (160 × 120), CIF (320 × 240), VGA (640 × 480)), which can display up to 640 × 480, for example. If the image in QCIF mode is displayed on the whole screen on the monitor, the resolution will be reduced.

On the other hand, since the resolution is not so high, the size of the data is reduced to 1/16 as compared with the data transmitted in the VGA mode, so that the transmission speed is increased accordingly. Accordingly, in the present invention, as described above, the transmission speed of the line is increased. If it is low, the image size is minimized (QCIF) and the compression rate is transmitted so that the transmission speed does not differ even though the resolution is lowered. If the transmission speed of the line is increased to the normal speed, the image size is changed to the original mode. By switching to (VGA) and lowering the compression rate, it is possible to transmit high resolution images without any difference in transmission speed.

Fig. 2 is a flow chart showing an embodiment of the image data transmission method of a video communication device according to the present invention. First, as shown in Fig. 2A, after a video communication device is connected to a communication network via a modem, it is first transmitted from a transmitting side. The image data to be transmitted is transmitted with a minimum size of the image (QCIF), so that the image quality is reduced but transmitted quickly so that the user does not feel bored, and the size of the original image set by the user at predetermined time intervals thereafter. By returning to CIF or VGA, the quality of the image displayed on the screen is improved.

At this time, if a normal transmission speed does not come out due to a disturbance or the like, the retraining is performed by the modem controller 7 to adjust to a more stable transmission speed. Even after resuming communication at the newly set rate after the transmission, the image is transmitted with the minimum size (QCIF), so that there is no difference in the transmission rate so that the user does not feel that a transmission delay has occurred. After this is completed, the speed of the track is slowed down, so it is transmitted at a resolution that is not felt by the user in proportion to the speed (for example, when the original setting mode is set to VGA, it is converted to CIF, which is one step lower resolution). Do it.

In addition, as shown in FIG. 2B, when an error occurs in the received data under the influence of intermittent disturbance, a retransmission is usually requested to the transmitting side. In general, when an error occurs in the retransmitted data again, All of the received image data of one screen is given up, and the receiving side sends a control signal (remote control request) to the transmitting side to request that the image data of the new screen be transmitted.

That is, when an error occurs in the received data due to an intermittent disturbance rather than an error in the track, the image data of the current screen is to be given up to recover and the image data of the new screen needs to be received. As in the case of the initial transmission and the retraining to transmit at a new transmission speed), by reducing the size of the image and increasing the compression rate, the resolution is reduced and the size of the data is minimized to be transmitted.

In other words, the size of the image data is an important factor in the transmission time. In general, the image telephone sets the image size based on when the line outputs a normal transmission speed. Therefore, in the present invention, until the transmission speed of the line becomes normal, the present invention compensates for the lower transmission speed of the line by increasing the compression ratio by smaller than the size of the originally set image, so that the user is able to reduce the transmission speed even though the resolution is reduced. Do not feel the transmission delay.

As described above, in the image data transmission method of the image communication apparatus of the present invention, when the transmission speed of the line is not normal, such as at the time of initial connection of the communication or when the line state is poor due to disturbance during communication, the transmission speed is decreased. By adjusting the size or compression rate of the compensator to compensate for the dropped transmission speed, the user can feel the transmission delay, thereby improving the call satisfaction.

Claims (3)

An image communication apparatus capable of varying a compression ratio of an image and a size of an image, the image communication apparatus comprising: a first step of minimizing the size of an image if the first transmission state is connected after being connected to a communication network, and transmitting the image at a low resolution by increasing the compression ratio; A second step of determining a transmission speed of the line and whether the data is normally received after the initial transmission of the image data; And if the normal data is received at a predetermined transmission speed or more as a result of the determination, a third step of the user returning to the original resolution set by the user and transmitting the data. The image data transmitted after the retraining is minimized in size and the compression rate is increased when the retraining is performed because the transmission speed of the line in the second step is less than the normal speed. Image data transmission method of a video communication device, characterized in that the transmission is minimized in size. 2. The method of claim 1, wherein the second step comprises: a retransmission request step of checking an error of the received data and requesting retransmission to the transmitting side when an error occurs; When the error occurs again by checking the error of the retransmitted data, the image data of the received current screen is discarded, and the image data of the new screen is requested to be transmitted to repeat the process of claim 1. Image data transmission method of a video communication device.