JPH0746863B2 - Video signal decoding device - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an interframe decoding device for a moving image signal such as a television signal.

(Prior art and its problems) When conventional line coding / decoding is performed and a line error occurs, an error remains on the TV screen, and the screen is rewritten periodically to eliminate this error. I was running a so-called refresh.

Recently, inter-frame coding using motion compensation has come to be performed. However, in inter-frame coding using motion compensation, an error generated in a transmission path spatially moves due to motion compensation, and As a result, the error spreads, and even if the refresh is run, the error cannot be easily removed, and in the worst case, it may not be permanently removed.

This example will be described using three television images at frame times t ₁ to t ₃ shown in FIG. Below, simply times t ₁ , t ₂ , t ₃
Is abbreviated.

If encoding is performed in blocks of N lines in the vertical direction, refreshing is performed while moving N lines from the upper left to the lower right for each frame (screen).
In this description, the motion compensation range in the vertical direction does not exceed N lines in order to simplify the description. The shaded area is the N line for which refresh is to be performed. Refresh the N lines containing block B at time t ₁ and assume that an error 1 occurred for some block A. At time t ₂ , the optimum vector U _t2 having the size and direction shown in FIG. 1 detected for the block B in the vicinity of the block A detected by the motion compensation circuit
When the motion compensation inter-frame coding / decoding of the block B is performed by, the coding using the vector U _t2 on the transmitting side is correctly executed, but the decoding of the block B using the vector U _t2 on the receiving side is performed. In the block A, since the error is included in the block A, the error of the block A is moved to the block B which has just been refreshed at the time t ₁ , and the error becomes 2. At time t ₃ , error 2 included in block B moves due to the optimum vector U _t3 having the size and direction shown in the figure detected for block C near block B, and error 2 included in block B moves as at time t _2. It becomes 3. In this way, as time goes by, the error is moved or magnified, and it is difficult to remove the error even if refreshing is performed, or it is impossible to remove the error as in this example.

(Object of the Invention) An object of the present invention is to eliminate the above-mentioned conventional drawbacks, and to provide a moving picture signal decoding device used in a method capable of surely refreshing regardless of the presence / absence and direction of motion even in motion compensation. To provide.

(Structure of the Invention) In order to achieve the above object, the present invention provides a coding for predictively coding an input moving image signal by using inter-screen correlation in which motion is compensated, and a moving image signal for a screen. The encoding is performed by using the internal correlation and the encoding is selected in a predetermined cycle, and the refresh is completed by encoding the moving image signal for refreshing the screen by the encoding using the intra-correlation. A prediction error signal obtained by an encoder that performs the predictive coding by prohibiting the motion compensation for a predetermined time for the stored portion, a refresh execution signal indicating the position of the refreshed portion, and a motion compensation prohibited area. A decoding device for a moving image signal, which decodes a compressed moving image signal including a signal for specifying A variable length decoding means for expanding each compensation signal,
First decoding means for obtaining a decoded signal from the motion-compensated prediction signal and the decompressed prediction error signal, and second decoding means for decoding the decompressed prediction error signal using intra-frame correlation,
A selection means for selecting one of the first decoding means and the second decoding means in accordance with the expanded refresh execution signal, and a frame memory for delaying the output of the selection means by about one frame time. A motion vector detecting means for detecting a motion vector from the frame memory output and replacing the motion vector with a value indicating inter-frame prediction in response to the motion compensation prohibition signal; and moving the frame memory output spatially according to the motion vector. However, a means for generating a motion-compensated prediction signal is provided.

(Principle of the Invention) The principle of the present invention will be described below with reference to FIG.

The disadvantage of the conventional method is that the motion compensation is executed for the N line immediately after the refresh is completed as in the other places. Therefore, the above drawbacks can be overcome if motion compensation is prohibited for at least N lines that have just been refreshed. The principle is shown below.

Similar to the above, it is assumed that an error occurs in a certain block A at time t ₁ . N line including block B (hatched part)
Refreshing is performed from now on, and motion compensation is prohibited for at least N lines (black spots) just after refreshing. At time t ₂ (referred to as motion compensation prohibition line), at least N lines that have just been refreshed have motion compensation prohibited, so that the spatial movement of block A due to motion compensation to block B is because not occur, error 1 block a generated by this pixel destruction of the motion compensation prohibition line is not, and the time t ₁ is
It is rewritten and removed by refreshing. At time t _3, since the error was removed by refreshed at time t _2, the error move or be expanded is impossible.

In this way, if the motion compensation is prohibited for the N line that has just been refreshed, the error will not be spatially moved or expanded, that is, destruction due to the movement of the error to the region just refreshed will occur. Since it does not exist, the error is promptly removed by one refresh.

When the vertical motion compensation range is N _V (N _V > N), motion compensation is prohibited in at least the N _V line.

There may be various sizes of the block of N lines in the vertical direction in the present invention. For example, one pixel may be regarded as one block, and a plurality of pixels may be regarded as one block. In any case, the motion is detected in block units. Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

In addition, A.N.Netravari
Other paper "Motion Compensated Television Coatings: Part I (Motion Compensat
ed Television coding: part1) ”, Bell System Technical Journal (Bell Syst.Tech.J.Vol.5)
8. No3, March 1979, p. 63 /), the motion vector in the screen can be detected using only the locally decoded signal, so that the vector need not be transmitted from the transmitting side to the receiving side.
This is an example in which one block is regarded as one pixel. This example will be described in detail below.

(Embodiment) FIG. 3 is a block diagram showing an embodiment of an interframe coding / decoding circuit using motion compensation. From the encoder input signal line 1, the digitized television signal is supplied to the interframe encoder 5 with motion compensation. The refresh circuit 2 generates a refresh execution signal and a motion compensation prohibition signal, and supplies the refresh execution signal and the motion compensation inhibition signal to the interframe encoder 5 with motion compensation via the signal lines 3 and 4 to control execution / stop of refresh and motion compensation. . In a line for which refresh is designated, encoding is performed using only intraframe correlation. For lines for which motion compensation is prohibited, interframe predictive coding is performed. For other lines, interframe predictive coding with motion compensation is performed.

The prediction error, which is the output of the interframe encoder with motion compensation 5, is supplied to the variable length encoder 9 via the signal line 6.

The refresh execution signal and the motion compensation inhibition signal, which are in phase with the output signal of the interframe encoder with motion compensation 5, are
Variable length encoder 9 via signal line 7 and signal line 8 respectively
And are converted into codes respectively indicating which lines are refreshed and motion-compensated. The variable length coded prediction error signal is output and transmitted. The prediction error signal sent through the transmission line 10
The code including the refresh execution signal / motion compensation prohibition signal is decoded as described below.

In the variable length decoder 11, the variable length decoded prediction error signal is transmitted via the signal line 12 and the decoded refresh execution signal / motion compensation inhibition signal is transmitted via the signal line 13 / signal line 14, respectively. It is supplied to the interframe decoder with compensation 15. In the inter-frame decoder with motion compensation 15, in decoding the line refreshed according to the refresh execution signal, the decoding for the coding method used on the transmission side is performed, and for the line for which motion compensation is prohibited, the frame is Decoding by inter-prediction is performed, and decoding is performed by inter-frame prediction with motion compensation for other lines.

The signal decoded by the inter-frame decoder with motion compensation 15 becomes the original digitized television signal and is output to the decoder output signal line 16. Next, the refresh circuit 2 will be described with reference to FIG.

The refresh clock generated in the control circuit 17 is supplied to the refresh counter 19 via the signal line 18, and the refresh execution signal is generated by counting the line number, for example. The refresh execution signal generated by the refresh counter 19 moves by N lines every frame or every several frames according to the refresh speed, for example. The refresh execution signal is supplied to the inter-frame encoder 5 with motion compensation shown in FIG. 3 via the signal line 3 and the register shown in FIG.
Supplied to 21. The register 21 delays the refresh execution signal by N line time by the set pulse supplied from the control circuit through the signal line 20 and outputs it as the motion compensation inhibition signal to the signal line 4. As a result, motion compensation is prohibited for the N line that has just been refreshed. Next, an interframe encoder with motion compensation and a decoder will be described with reference to FIGS. 5 (a) and 5 (b).

In FIG. 5 (a), the subtractor 22 is supplied with the digitized television signal via the input signal line 1. The vector detector 30 detects an optimum vector, that is, a motion vector from the locally decoded signal supplied from the frame memory 28 by using the method shown in the above-mentioned Netrabari article, and also prohibits motion compensation via the signal line 4. When a signal is supplied and motion compensation is prohibited, a vector indicating inter-frame prediction is output. The optimum vector detected by the vector detector is supplied to the variable delay circuit 29.

The variable delay circuit 29 controls the delay time of the locally decoded signal supplied from the frame memory 28 by the supplied optimum vector, and supplies it to the subtractor 22 and the adder 24. The subtractor 22 generates an inter-frame motion compensation prediction error between the current signal supplied via the signal line 1 and the variable delayed signal supplied from the variable delay circuit about one frame time ago. The calculation result of the subtractor 22 and the prediction error signal are quantized by the quantizer 23 and supplied to the switch 31 and the adder 24.

The adder 24 reproduces the locally decoded signal from the quantized prediction error signal and the signal from the variable delay circuit which is about one frame time before. The locally decoded signal is the DPCM encoder 25 and the switch.
Supplied to 27. The DPCM encoder 25 encodes the locally decoded signal using intraframe encoding and supplies it as a refresh signal to the switch 31 and the DPCM decoder 26.
At 26, local decoding within the frame is performed and the result is supplied to the switch 27.

The switch 27 uses the DPCM when refresh is performed by the refresh execution signal supplied through the signal line 3.
The output signal of the decoder 26 is supplied to the frame memory 28, and the output signal of the adder 24 is supplied to the frame memory 28 when refresh is not performed. Switch 31 is switch 27
Similarly to, the refresh execution signal switches between the refresh signal and the prediction error signal, and the signal is supplied to the variable-length encoder via the signal line 6.

FIG. 5 (b) is a diagram showing a motion compensation decoder. The prediction error signal is added to the adder from the variable length decoder via the signal line 12.
Supplied to 34. The vector detector 32 detects a motion vector from the decoded signal supplied from the frame memory 37 by using the method shown in the above-mentioned Netrabari paper,
Further, the motion compensation is executed / stopped by the motion compensation prohibition signal supplied through the signal line 14. When motion compensation is prohibited, a vector representing the frame is supplied to the variable delay circuit 33, and in the normal case, the calculated and detected motion vector is supplied to the variable delay circuit 33. The variable delay circuit 33 is about 1 from the frame memory 37.
Decoded signal before frame time is supplied, vector detector
The decoded signal about one frame time before the delay time is controlled by the motion vector supplied from 32 is supplied to the adder 34. The adder 34 performs motion compensation decoding on the prediction error signal supplied via the signal line 12 and the decoded signal supplied from the variable delay circuit 33 about one frame time before the delay time control, Supply to the switch 36. The DPCM decoder 35 intraframe-decodes the prediction error signal supplied via the signal line 12, and uses the switch 36 as a refresh signal.
Supply to. The switch 36 performs switching by a refresh execution signal supplied via the signal line 13. When refreshing, the output of the DPCM decoder 35 is selected, and in the normal case, the output of the adder 34 is selected. The output of the switch 36 is supplied to the frame memory 37, and the output of the inter-frame decoder 15 with motion compensation becomes the original digital television signal, which is output from the signal line 16.

For refreshing, not only intraframe coding such as DPCM of the locally decoded signal but also a method of using DPCM of the input signal supplied from the signal line 1 to the input of the DPCM encoder 25, or the input PCM signal as it is There is a method of using. In the latter case, DPCM encoder 25, DPCM decoder 26, switch 27 and
The DPCM decoder 35 is unnecessary. Orthogonal transform coding or the like can be used instead of DPCM intraframe coding. In this case, 25 is an orthogonal transform encoder, and 26 and 35 are orthogonal exchange decoders.

(Effects of the Invention) As described in detail above, by using the present invention, it is possible to reliably and promptly remove an error that occurs during motion compensation interframe coding / decoding without moving or expanding. It is possible to provide a moving picture signal decoding apparatus that can be used in a motion compensation inter-frame coding / decoding method. When the present invention is put to practical use, the effect thereof is extremely large.

[Brief description of drawings]

FIG. 1 is a diagram for explaining movement / expansion of an error by motion compensation, FIG. 2 is a diagram for explaining a situation in which an error is removed when the present invention is used, and FIG. 3 is an embodiment of the present invention. 4 is a block diagram illustrating a refresh circuit, FIG. 5A is a diagram illustrating an interframe encoder with motion compensation, and FIG. 5B is an interframe frame with motion compensation. It is a figure explaining a decoder. Reference numerals in the figures indicate the following. 2 ... Refresh circuit 5 ... Interframe encoder with motion compensation 9 ... Variable length encoder, 10 ... Transmission line 11 ... Variable length decoder 15 ... Interframe decoder with motion compensation 17 ... Control circuit, 19 ... Refresh counter 21 ... register, 22 ... subtractor 23 ... quantizer, 24 ... adder 25 ... DPCM encoder, 26 ... DPCM decoder 27 ... switch, 28 ... frame memory 29 ... variable delay circuit, 30 ... vector detector 31 ... switch , 32 ... Vector gate circuit 33 ... Variable delay circuit, 34 ... Adder 35 ... DPCM decoder, 36 ... Switch 37 ... Frame memory

Claims (1)

[Claims] 1. An encoding method for predictively encoding an input moving image signal using inter-picture correlation in which motion is compensated,
Coding for coding the moving picture signal using intra-frame correlation is selected at a predetermined cycle, and coding of the moving picture signal is performed for refreshing the screen by coding using the intra-frame correlation. , A prediction error signal obtained by an encoder that performs the predictive coding by inhibiting the motion compensation for a predetermined time for the refreshed portion, and a refresh execution indicating the position of the refreshed portion. A decoding device of a moving image signal for decoding a compressed moving image signal including a signal and a signal designating a motion compensation prohibited area, wherein a prediction error signal transmitted in compression,
A variable length decoding means for expanding the refresh execution signal and the motion compensation inhibition signal, a first decoding means for obtaining a decoded signal from the motion compensation prediction signal and the expanded prediction error signal, and the expanded prediction error signal. Selection for selecting either the first decoding means or the second decoding means according to the second decoding means for decoding using the intra-screen correlation and the expanded refresh execution signal Means and
A frame memory that delays the output of the selecting means by about one frame time, and a motion vector detecting means that detects a motion vector from the output of the frame memory and replaces the motion vector with a value indicating inter-frame prediction in response to a motion compensation inhibition signal. And a unit for spatially moving the frame memory output according to the motion vector to generate a motion compensation prediction signal.