JPH04170184A - Picture transmitter - Google Patents

Abstract

PURPOSE:To refresh only a destroyed part when a picture is destroyed at a receiver side by dividing a pattern so as to apply an error check record. CONSTITUTION:A sender side multiplexes an error check code and check position information onto a video signal and sends the result to a receiver side, while the receiver side demultiplexes the video signal from the multiplexed signal and stores the video signal into a frame memory 19 and an error check section 21 checks an error between video signals resulting from demultiplexing the stored video signal based on an error check code. When an error is detected, check position information multiplexed on the video signal is sent to a sender side refresh control section 12 and the video signal corresponding to the video signal generated in error at a receiver side is sent again to a frame memory 10 of a sender side. Thus, when an error is generated in the video signal in the frame memory 19 at the receiver side, the error is immediately refreshed.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Field of Application] The present invention relates to an image transmission device that digitizes video, compresses the amount of information, and transmits the compressed information.

[Conventional technology]

FIG. 3 shows a conventional image transmission device disclosed in, for example, Japanese Patent Laid-Open No. 114675/1983.

In the figure, (1) is an input terminal, (2) is an analog-to-digital converter, (3) is a subtracter, (4) is a quantizer, (
5) is a multiplexing unit, (6) and (14) are inverse quantizers,
(7), 1ls) is an adder, f8), (17)
is a switch, (91, 1181 is a pixel memory, (10)
, (19) is the frame memory, (121, (2(1)
is a refresh control section, (13) is a separation section, (16) is a digital-to-analog conversion section, and (22) is an output terminal.

Next, the operation will be explained. On the transmitting side, the input terminal (11
The video signal input from the converter is converted into a digital signal by the analog-to-digital converter (2).

At the same time, as shown in FIG. 2, pulses are generated for every m scanning lines of the input video signal, and the refresh control unit (12)
is input to. A subtracter (3) subtracts the output value of the switch (8) from the digital video signal, and the difference value is quantized by a quantizer (4). One of the outputs of the quantizer (4) is dequantized by the dequantizer (6) and sent to the adder (
In step 7), the output values of the switch (8) are added to form a locally decoded signal, which is stored in the pixel memory (9) and frame memory (lO), respectively. The pixel memory (9) has a storage capacity for one pixel, and the frame memory (10) has a storage capacity for one frame.
It is used as a prediction signal in subsequent encoding. The refresh control section (12) is a digital-to-analog conversion section (
Based on the output pulse of 2), an m-line section switching signal is output in one frame, and the switching position is further shifted every frame. The switch (8) receives the switching signal from the refresh control unit (12) and selects the output of the pixel memory (9) for the section to be refreshed, and selects the output of the frame memory (10) for the other sections. , sends the selected data to a subtracter (3) and an adder (7). The multiplexing unit (5) multiplexes the information on the period to be refreshed from the refresh control unit (12) and the output signal of the quantizer (4), and sends the multiplexed information to the transmission line (23). As a result, intraframe coding is performed in the refresh period, interframe coding is performed in the other periods, and refresh is performed periodically.

On the receiving side, a separation unit (13) separates the video signal and refresh period information. The video signal is processed by an inverse quantizer (1
4), and is dequantized by the adder (15) and the switch (17).
The output values of
) and frame memory (19), respectively. Based on the refresh period information separated by the separation unit (13), a switch (17) selects the output of the pixel memory (18) and frame memory (19) in synchronization with the switch (8) on the transmitting side. The decoded signal is sent to a digital-to-analog converter (16
), it becomes an analog video signal and is output from the output terminal (22).

[Problem to be Solved by the Invention 1] The conventional image transmission device is configured as described above, so that if a problem occurs in the video signal stored in the frame memory on the receiving side and the picture is destroyed, the transmitting side There was a drawback that the picture had to be fixed until it was refreshed.

This invention has been made to solve the above-mentioned problems, and aims to provide an image transmission device in which when a picture is damaged on the receiving side, the picture can be repaired immediately without waiting for periodic refresh.

[Means for Solving the Problems] An image transmission device according to the present invention includes a frame memory for storing a digitized video signal on the transmitting side, and an error check code and an error check at which screen position for the video signal. an error information adding section that adds error information consisting of check position information indicating whether the video signal is a code; a multiplexing section that multiplexes error information on the video signal and transmits the same; and a video that refreshes according to error detection information from the video signal receiving side. A refresh control unit reads the signal from the frame memory and retransmits it to the receiving side, and the receiving side includes a separating unit that separates the video signal and error information from the received signal, and a frame that stores the separated video signal. Error detection information that performs error checking between the memory, the video signal stored in the frame memory, and the separated video signal, and indicates from which screen position the error was detected based on check position information multiplexed at the time of error detection. and an error check unit that transmits the information to the transmitting side.

[Operation 1] According to the present invention, the transmitting side multiplexes the error check code and check position information together with the video signal and transmits it to the receiving side, while the receiving side separates the video signal from the multiplexed signal and stores it in the frame memory. After storing, an error check between the video signals separated from the stored video signal is performed in an error check section based on the error check code, and when an error is detected, the check position information multiplexed with the video signal is checked. The video signal corresponding to the video signal in which the error occurred on the receiving side is sent to the refresh control unit on the transmitting side, and the video signal corresponding to the video signal in which the error occurred on the receiving side is retransmitted from the frame memory on the transmitting side to the receiving side. If this occurs, it can be refreshed immediately.

[Example 1 An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram of the image transmission device in this embodiment. In the figure, +1) is an input terminal, and (2) is an analog -
Digital conversion unit, (3) is a subtracter, (4) is a quantizer,
(5) is a multiplexing unit, (6), +141 is an inverse quantizer, +7), (151 is an adder, +81, (17)
) is a switch, (91, (18) is a pixel memory, (101
, +191 is a frame memory, (11) is a parity addition unit, (12), +201 is a refresh control unit, (
13) is a separation section, (16) is a digital-to-analog conversion section, (21) is a parity check section, (22) is an output terminal, +231, and (24) is a transmission line.

Next, the operation will be explained. On the transmitting side, the input terminal (1
) is converted into a digital signal by the analog-to-digital converter (2), the output value of the switch (8) is subtracted by the subtracter (3), and the difference value is sent to the quantizer (
4) is quantized. One of the outputs of the quantizer (4) is
The dequantized signal is dequantized by the dequantizer (6), and the output value of the switch (8) is added by the adder (7) to become a locally decoded signal, which is stored in the pixel memory (9) and frame memory (lO), respectively. . The pixel memory (9) is for one pixel, and the frame memory (
lO) has a storage capacity for one frame and is used as a prediction signal in subsequent encoding. Frame memory (
As shown in Fig. 2, the output of the lO) is assigned parity by the parity addition unit (11) for each unit of screen division, for example, every 41m scanning line, and the parity value and the screen position of the parity are determined. The position information indicating the
). The refresh control unit (12) receives the error information signal from the game sent from the transmission path (24), determines the refresh period, and controls the switch (8). The switch (8) is a refresh control unit (12)
In the section to be refreshed, the output of the pixel memory (9) is selected and intra-frame coding is performed, and for the other sections, the output of the frame memory (lO) is selected and inter-frame coding is performed. The selected data is sent to a subtracter (3) and an adder (7). The multiplexing unit (5) multiplexes the information on the period to be refreshed from the refresh control unit (12), the output signal of the quantizer (4), and the output of the parity addition unit (11), and sends the multiplexed information to the transmission path (23). Send to.

On the receiving side, a separation unit (13) separates the video signal, refresh period information, and parity. The video signal is dequantized by the dequantizer (14), and the output value of the switch (17) is added by the adder (15) to become a decoded signal, which is sent to the pixel memory (18) and frame memory (19). are respectively memorized. Based on the refresh interval information separated by the separation unit (13), the switch (17) synchronizes with the switch (8) on the transmitting side and switches the video signal to the pixel memory (18) if the video signal is intra-frame encoded. , and if interframe encoding has been performed, select the output of the frame memory (19). The data in the frame memory (19) is checked by a parity check section (21) against the parity sent from the transmitting side separated by the separation section (13). If an error is detected here, the parity check unit (21
) from which part of the screen is in error is sent to the transmitting side through the transmission line (24), and on the transmitting side, as soon as the refresh control section (12) receives the error information, it immediately switches on the switch ( 8) Switches to intra-frame encoding and refreshes only the incorrect part. The decoded signal, which is the output of the adder (15), is turned into an analog video signal by a digital-to-analog converter and is output from the output terminal (22).

In addition, although the above embodiment shows a case where parity is used for error detection, error check codes such as CRC and BCH may also be used.

[Effects of the Invention] As described above, according to the present invention, since the screen is divided and an error check code is attached, if the picture is broken on the receiving side, the broken part can be separated, so only the broken part can be displayed. The amount of information in the video signal transmitted during the refresh operation can be kept to the minimum necessary.Also, if the picture is corrupted, the broken part can be immediately refreshed on the transmitting side, so the refresh speed can be reduced. It has the effect of improving.

[Brief explanation of drawings]

FIG. 1 is a block diagram of an image transmission apparatus according to an embodiment of the present invention, FIG. 2 is a diagram showing an example of screen division, and FIG. 3 is a block diagram of a conventional image transmission apparatus. In the figure, (2) is an analog-digital converter, (5
) is the multiplexing unit, f91, (18) is the pixel memory, (
10), (19+ is a frame memory, (11) is a parity addition unit, (12), (20) is a refresh control unit, (13) is a separation unit, (21) is a parity check unit, (23), (241) is a transmission line. In each figure, the same reference numerals indicate the same or equivalent parts. Written amendment (spontaneous) December 21, 1990 Patent Application No. 2-274768 2 Title of the invention Image transmission device 3. Relationship with the case of the person making the amendment Patent applicant address: 2-2-3 Marunouchi, Chiyoda-ku, Tokyo
(IiOl) Mitsubishi Electric Co., Ltd. Representative: Moriya Shiki 4, Agent address: 4th floor, Nakayama Building, 1-9-13 Nihonbashi-honmachi, Chuo-ku, Tokyo The detailed description of the invention column and drawings in the specification. 6. Contents of the amendment (1) The description "conventional image transmission device" in the first line of page 5 of the specification is amended to read "conventional image transmission device." (2) The statement "The picture cannot be repaired" on page 5, line 4 of the specification is amended to "The picture cannot be repaired." (3) The statement ``There was a defect.'' on page 5, line 5 of the specification is amended to ``There was a defect.'' (4) Amend Middle East Figures 1 and 3 as shown in the attached sheet. 7.Drawings after correction of catalog of attached documents 1. On tools

Claims (1)

[Claims] The transmitting side includes a frame memory for storing a digitized video signal, and error information including an error check code and check position information indicating which screen position the error check code is located in the video signal. an error information adding section that adds error information to the video signal, a multiplexing section that multiplexes error information to the video signal and transmits it, and a video signal to be refreshed according to error detection information from the video signal receiving side, which reads the video signal from the frame memory and retransmits it to the receiving side. and a refresh control section, on the receiving side, a separation section that separates a video signal and error information from a received received signal, a frame memory that stores the separated video signal, and a frame memory that stores the video signal stored in the frame memory. an error check unit that performs an error check between the signal and the separated video signal, and transmits error detection information indicating from which screen position the error was detected from multiplexed check position information when an error is detected to the transmitting side; An image transmission device comprising: