JPH07170512A - Method for post filter processing in picture signal decoder and post filter processor - Google Patents

Abstract

PURPOSE:To effectively eliminate a coding noise such as block distortion by a DCT even when a quantization width is set wider in the post filter processing method and the post filter processor in the picture signal decoder. CONSTITUTION:When a coded noise is eliminated from a decoded reproduction picture through post filters 18,19, a quantization width 23 obtained at decoding is used and it is compared with any of K-sets (K is a natural number) of threshold values TK (TK is a natural number). Coefficients of the post filter circuits 18, 19 are selected at a changeover circuit 20 based on the comparison result 29. Or the quantization width obtained at decoding is stored for a predetermined period and the stored quantization width and the threshold value TK are compared. The coefficient of the post filters is selected for each block comprising NXN sets (N is a natural number) of picture elements, or each of M-lines (M is a natural number) or each frame based on the comparison result.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a post filter processing method and a post filter in an image signal decoding apparatus for effectively removing the coding noise generated when an image signal is coded on the decoding side. The present invention relates to a processing device.

[0002]

2. Description of the Related Art As a method often used for coding a moving image, there is a method in which DCT (discrete cosine transform) is combined with motion compensation interframe prediction. This divides the input image signal into N × N (N is a natural number) blocks,
In this method, a differential signal between frames is obtained by motion compensation for each block, DCT is performed, and quantization is performed to perform variable length coding.

In order to decode the bit stream coded by this method, variable length decoding is first performed and then inverse quantization is performed. Next, inverse DCT is performed and motion compensation is performed to obtain a reproduced image. Further, a method of applying a post filter to a reproduced image to remove coding noise is used.

FIG. 3 shows a block diagram of an apparatus for explaining an example of post-filter processing in a conventional image signal decoding apparatus. As shown in FIG. 3, first, an encoded bit stream 81 is input, and a variable length decoding circuit (V
LD) 71 performs variable length decoding. The variable length decoded signal 82 is inversely quantized by the inverse quantization circuit (Q ~ ¹ ) 72, and the inversely quantized signal 83 is inverse D by the inverse DCT circuit (IDCT) 73.
CT is given. Also, from the frame memory (FM) 76,
The reproduced image signals 86 of the preceding and succeeding frames are read out, and the motion compensation circuit (MC) 75 performs motion compensation. The signal 84 to which the inverse DCT has been applied is the signal to which the motion compensation has been performed in the adding circuit 74
85 is added to obtain a reproduced image signal 87. The reproduced image signal 87 becomes the output image signal 88 after the coding noise is removed by the post filter circuit 77.

[0005]

However, in the conventional post-filter processing method and post-filter processing apparatus in the image signal decoding apparatus as described above, although the coding noise is not conspicuous when the quantization width is small, When the coding width becomes large, coding noise such as block distortion due to DCT becomes conspicuous, and there is a problem that a sufficient coding noise removal effect cannot be obtained.

The present invention solves the above-mentioned problems and a post-filter processing method in an image signal decoding apparatus capable of effectively removing coding noise such as block distortion due to DCT even when the quantization width becomes large. Another object of the present invention is to provide a post filter processing device.

[0007]

In order to solve the above problems and to achieve the object, the present invention provides a post-filter processing method in an image signal decoding apparatus according to the present invention, in which a quantization width obtained at the time of decoding is The quantization width is compared with the _K thresholds (K is a natural number) T _K (T _K is a natural number), and the coefficient of the post filter is switched according to the comparison result.

Further, in the post-filter processing method in the image signal decoding apparatus of the present invention, the quantization width obtained at the time of decoding is stored for a certain period, and the stored quantization width and K are stored.
The threshold value is compared with each threshold value T _K, and the coefficient of the post filter is switched for each block of N × N (N is a natural number) pixels, for each M line (M is a natural number), or for each frame.

Further, the post-filter processing device in the image signal decoding device of the present invention uses a comparison circuit for comparing the quantization width obtained at the time of decoding with the K threshold values T _K, and an output signal of the comparison circuit. And a switching circuit for switching the coefficient of the post filter.

Further, the post-filter processing device in the image signal decoding device of the present invention is a storage circuit for storing a quantization width obtained at the time of decoding for a certain period, the stored quantization width and K threshold values T. A comparison circuit for comparing with _K and a switching circuit for switching the coefficient of the post filter for each block of N × N pixels, for each M line, or for each frame according to the output signal of the comparison circuit.

[0011]

According to the present invention, since the coefficient of the post filter is switched by using the quantization width obtained at the time of decoding by the above means, even if the quantization width becomes large, the block distortion due to DCT It is possible to effectively remove coding noise such as.

Further, by storing the quantization width obtained at the time of decoding for a certain period, the coefficient of the post filter is N × N.
Since switching is performed for each block including (N is a natural number) pixels, for each M line (M is a natural number), or for each frame, the coding noise can be removed more effectively.

[0013]

Embodiments of the present invention will be described below in detail with reference to the drawings.

FIG. 1 is a block diagram of an apparatus for explaining post-filter processing in an image signal decoding apparatus showing a first embodiment of the present invention. In FIG. 1, 11 is a variable length decoding circuit (VLD), 12 is a dequantization circuit (Q to ¹ ), 13 is a comparison circuit, 14 is an inverse DCT circuit (IDCT), 15 is an addition circuit, and 16 is motion compensation. Circuit (MC), 17 is a frame memory (F
M), 18 and 19 are post filter circuits, and 20 is a switching circuit. Here, the comparison circuit 13 that compares the threshold value _TK with the quantization width 23, and the switching circuit 20 that selects one of the output signals 30 and 31 of the post filter circuits 18 and 19 based on the comparison result 29. This is a structural feature of this embodiment.

Next, the operation of the post-filter processing in the image signal decoding apparatus having the above configuration will be described. First, the encoded bit stream 21 is input and variable-length decoded by the variable-length decoding circuit (VLD) 11. The variable-length decoded signal 22 is inversely quantized by the inverse quantization circuit (Q ~ ¹ ) 12. In addition, the variable length decoded quantization width 23 is
Threshold T _K of the K (K is a natural number) at 13 (T _K is a natural number) is compared with. Here, the number K of the threshold T _K is described for the case of one. Further, the inverse quantized signal 24 has an inverse DCT
Inverse DCT is performed in the circuit (IDTC) 14.

Further, the reproduced image signals 28 of the preceding and succeeding frames are read from the frame memory (FM) 17, and the motion compensation circuit (MC) 16 performs motion compensation. The signal 25 subjected to the inverse DCT is added to the signal 27 subjected to motion compensation by the adder circuit 15 to obtain the reproduced image signal 26.

The reproduced image signal 26 is subjected to the removal of coding noise in the post filter circuit 18 and the post filter circuit 19 having different filter coefficients, and then the switching circuit.
Entered in 20. The switching circuit 20 uses the comparison result 29 obtained by the comparison circuit 13 to select either the output signal 30 of the post filter circuit 18 or the output signal 31 of the post filter circuit 19. As a result, the signal selected by the switching circuit 20 becomes the output image signal 32.

FIG. 2 is a block diagram of an apparatus for performing post-filter processing in an image signal decoding apparatus showing a second embodiment of the present invention. In FIG. 2, 33 is a memory circuit, and other functional blocks that are the same as those in FIG.

First, the encoded bit stream 21 is input and variable-length decoded by the variable-length decoding circuit 11. The variable-length decoded signal 22 is dequantized by the dequantization circuit 12. In addition, the variable length decoded quantization width 23
Are stored in the storage circuit 33 for a certain period. The quantization width 34 stored for this fixed period is for each block composed of N × N (N is a natural number) pixels, or for each M line (M is a natural number),
Or sent per frame in the comparator circuit 13, the threshold T _K of the K (K is a natural number) (T _K is a natural number) is compared with. Here, the number K of the threshold T _K is described for the case of one. Further, the inverse quantized signal 24 is inverse D
CT is given.

Further, the reproduced image signals 28 of the preceding and succeeding frames are read from the frame memory 17, and the motion compensation circuit 16 performs motion compensation. The signal 25 subjected to the inverse DCT is added to the motion-compensated signal 27 in the adder circuit 15 to obtain a reproduced image signal 26.

The reproduced image signal 26 is subjected to removal of coding noise in the post filter circuit 18 and the post filter circuit 19 having different filter coefficients, and then the switching circuit.
Entered in 20. The switching circuit 20 uses the comparison result 29 obtained by the comparison circuit 13 to select either the output signal 30 of the post filter circuit 18 or the output signal 31 of the post filter circuit 19. As a result, the signal selected by the switching circuit 20 becomes the output image signal 32.

As described above, the quantization width obtained at the time of decoding is used to compare the quantization width with the K threshold values T _K, and the coefficient of the post filter is switched according to the comparison result. DCT even if the quantization width becomes large
It is possible to effectively remove coding noise such as block distortion due to.

Further, the quantization width obtained at the time of decoding is stored for a certain period of time, and the stored quantization width and K thresholds T are stored.
Compared with _K, and the coefficient of the post filter is switched for each block of N × N pixels, for each M line, or for each frame according to the comparison result, so that the coding noise can be removed more effectively. You can

[0024] The present invention, the number K of the threshold T _K 1
The number of individual and post filter coefficients is not limited to two, and various modifications are possible based on the spirit of the present invention, and these are not excluded from the scope of the present invention.

[0025]

As described above, according to the present invention,
In the image signal decoding device which decodes the image data encoded by the image signal encoding device and removes the coding noise from the decoded reproduced image through the post filter, the quantization width obtained at the time of decoding is set. The quantization width is compared with _K thresholds (K is a natural number) of _K ( _K is a natural number) and the coefficient of the post filter is switched according to the comparison result, so that the quantization width is increased. Even D
Coding noise such as block distortion due to CT can be effectively removed.

Further, the quantization width obtained at the time of decoding is stored for a fixed period, and the stored quantization width and K thresholds T are stored.
Compared with _K, and the coefficient of the post filter is switched for each block of N × N pixels, for each M line, or for each frame according to the comparison result, so that the coding noise can be removed more effectively. You can

[Brief description of drawings]

FIG. 1 is a block diagram of an apparatus for performing post-filter processing in an image signal decoding apparatus showing a first embodiment of the present invention.

FIG. 2 is a block diagram of an apparatus for performing post-filter processing in an image signal decoding apparatus showing a second embodiment of the present invention.

FIG. 3 is a block diagram of an apparatus for explaining an example of post-filter processing in a conventional image signal decoding apparatus.

[Explanation of symbols]

11 ... Variable length coding circuit (VLD), 12 ... Dequantization circuit
(Q ~ ¹ ), 13 ... Comparison circuit, 14 ... Inverse DCT circuit (IDC
T), 15 ... Adder circuit, 16 ... Motion compensation circuit (MC), 17
... Frame memory (FM), 18, 19 ... Post filter circuit, 20 ... Switching circuit, 21 ... Bit stream,
23 ... Quantization width, 29 ... Comparison result, 32 ... Output image signal,
33 ... Memory circuit, _TK ... Threshold value.

Claims (10)

[Claims] 1. An image signal decoding device for decoding image data encoded by an image signal encoding device and removing coding noise from a decoded reproduced image through a post filter, the image signal decoding device comprising: The quantization width and K thresholds (K is a natural number) T
A post-filter processing method in an image signal decoding apparatus, characterized in that _1K (T _1K is a natural number) is compared and the post-filter coefficient is switched according to the comparison result. 2. An image signal decoding device which decodes image data encoded by the image signal encoding device and removes encoding noise from a decoded reproduced image through a post filter, which is obtained at the time of decoding. The stored quantization width is stored for a certain period, the stored quantization width is compared with K (K is a natural number) threshold value T _2K (T _2K is a natural number), and the coefficient of the post filter is switched according to the comparison result. Post-filter processing method in an image signal decoding apparatus characterized by the above. 3. The stored quantization width is compared with K (K is a natural number) threshold value T _3K (T _3K is a natural number), and the post filter coefficient is N × N (N is a natural number) according to the comparison result. 3. The post-filter processing method in the image signal decoding device according to claim 2, wherein the switching is performed for each block including pixels. 4. The stored quantization width is compared with K (K is a natural number) threshold value T _4K (T _4K is a natural number), and the post-filter coefficient is M lines (M is a natural number) according to the comparison result.
The post-filter processing method in the image signal decoding apparatus according to claim 2, wherein the post-filter processing method is switched for each. 5. The stored quantization width is compared with K (K is a natural number) threshold values T _5K (T _5K is a natural number), and the coefficient of the post filter is switched for each frame according to the comparison result. The post-filter processing method in the image signal decoding device according to claim 2. 6. An image signal decoding device which decodes image data encoded by the image signal encoding device and removes encoding noise from a decoded reproduced image through a post filter, which is obtained at the time of decoding. And a switching circuit for switching the coefficient of the post-filter according to the output signal of the comparison circuit and a threshold value T _6K (K is a natural number) T _6K (T _6K is a natural number). And a post-filter processing device in an image signal decoding device. 7. An image signal decoding device for decoding image data coded by the image signal coding device and removing coding noise from a decoded reproduced image through a post filter A storage circuit that stores the quantization width that is stored for a certain period of time; a comparison circuit that compares the stored quantization width with K (K is a natural number) threshold values T _7K (T _7K is a natural number); A post filter processing device in an image signal decoding device, comprising: a switching circuit for switching a coefficient of a post filter according to an output signal. 8. A comparison circuit for comparing the stored quantization width with K threshold values T _8K ( _K is a natural number) (T _8K is a natural number), and a coefficient of a post filter according to an output signal of the comparison circuit. The post-filter processing device in the image signal decoding device according to claim 7, further comprising a switching circuit that switches each block made up of N × N (N is a natural number) pixels. 9. The threshold T _9K of the stored quantization width and K pieces (K is a natural number) (T _9K is a natural number) a comparator circuit for comparing the, the coefficients of the postfilter by the output signal of the comparator circuit The post-filter processing device in an image signal decoding device according to claim 7, further comprising a switching circuit for switching every M lines (M is a natural number). Threshold T _10K according to claim 10, wherein the stored quantization width and K pieces (K is a natural number) (T _10K is a natural number) a comparator circuit for comparing the, the coefficients of the postfilter by the output signal of the comparator circuit The post-filter processing device in the image signal decoding device according to claim 7, further comprising a switching circuit for switching for each frame.