JP2003023624A - Image decoder - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image decoder that can always obtain an improved result on the image quality of various bit rate. SOLUTION: Image information from an input terminal 1 is feed to a contour feature extract section 2 to extract a feature of the contour of a compressed block so as to calculate the activity of the block order and a contour step difference or the like. The calculation result is fed to a block distortion decision section 3, which decides whether or not the calculation result is to be corrected by a threshold 1 or the like optionally set and supplied from an external controller section 100. The decision result is fed to a block distortion correction strength calculation section 4, which calculates a block distortion correction quantity according to thresholds 2, 3 or the like optionally set and supplied from the controller section 100. Then the calculated block distortion correction quantity is fed to a block distortion correction section 5, where correction processing for adding/subtracting the correction quantity of block distortion is applied to a pixel around the block border.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention relates to, for example, MPEG.
(Moving Picture coding Exp
The present invention relates to an image decoding apparatus suitable for use when decompressing and decoding image information that has been compression-encoded using the erts group) method. Specifically, for example, in a compression / expansion system for image information such as the MPEG system, a reduction characteristic for distortion generated according to a bit rate is made variable so that good image information can always be decoded. is there.

[0002]

2. Description of the Related Art For example, in a compression / decompression system for image information of the MPEG system, when the bit rate at the time of compression is insufficient, high frequency components of the image information are reduced during the compression process. In such a case, in the decompressed and decoded image information, block distortion occurs at the boundary of the compressed block. As a countermeasure, for example, a method of increasing the bit rate to reduce the reduction amount of high frequency components,
A method of performing block distortion reduction processing for reducing block distortion on the decompressed and decoded image information can be considered.

However, in these measures, the method of increasing the bit rate is difficult to implement because it involves system changes and the like. Therefore, conventionally, a method of performing block distortion reduction processing for reducing block distortion on the decompressed and decoded image information is generally adopted. However, in the conventional block distortion reduction process, the criteria used for the block distortion reduction process used are always constant, and MPEG block
The effect of improving the image quality was small for low bit rate image information such as search images of the system.

[0004]

This application has been made in view of such a point, and a problem to be solved is to determine the block distortion reduction process used in the conventional device. The criteria and the like are always constant, and it is impossible to obtain a good image quality improving effect for low bit rate image information, for example.

[0005]

Therefore, in the present invention, the characteristic of the block distortion reducing means is changed according to the bit rate of the input image information.
According to this, it is possible to obtain a good image quality improvement effect for the low bit rate image information, and it is possible to prevent excessive correction for the high bit rate image information. It is possible to always obtain the optimum image quality improvement effect for the image information of the bit rate of.

[0006]

BEST MODE FOR CARRYING OUT THE INVENTION That is, according to the present invention, there is provided an image decoding apparatus for decompressing and decoding input image information coded and compressed for each arbitrary block. Block distortion reducing means for reducing the block distortion occurring at the block boundary, and the characteristic of the block distortion reducing means is changed according to the bit rate of the input image information.

The present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing a configuration of an embodiment of a block distortion reducing means which is a main part of an image decoding apparatus to which the present invention is applied. .

In FIG. 1, for example, expanded image information (8 bits) is input to the input terminal 1. The image information from the input terminal 1 is supplied to the block boundary feature extraction unit 2 that extracts the feature of the boundary between the adjacent compressed blocks of 8 × 8 pixels, for example. The block boundary feature extraction unit 2 calculates the activity of the block boundary, the boundary step, etc., and supplies the calculation result to the block distortion determination unit 3 for determining whether or not the calculation result is the block distortion in the subsequent stage.

Further, the block distortion determination unit 3 uses the activity and the boundary level difference supplied from the block boundary feature extraction unit 2 and the arbitrarily set threshold value 1 (8 bits) supplied from the external controller unit 100. , It is determined whether the image information should be corrected as block distortion. The determination result of the block distortion determination unit 3 is supplied to the block distortion correction strength calculation unit 4 for calculating the block distortion correction level in the subsequent stage.

Further, the block distortion correction strength calculation unit 4
Then, the pixels around the block boundary, the step of the block boundary,
Further, the block distortion correction amount is calculated by the threshold value 2 and the threshold value 3 (each 8 bits) which are arbitrarily set and supplied from the controller unit 100. Then, the block distortion correction amount calculated by the block distortion correction strength calculation unit 4 is supplied to the block distortion correction unit 5 in the subsequent stage for actually correcting the block distortion.

Further, in the block distortion correction unit 5, the block distortion is reduced by adding or subtracting the above-mentioned correction amount of the block distortion to the pixels around the block boundary of the image information supplied from the input terminal 1. To do so. Further, the image information with the block distortion reduced by the block distortion correction unit 5 is selected by the switch 6 as the image information from the input terminal 1 and is taken out to the output terminal 7. In this way, the image information with reduced block distortion is taken out to the output terminal 7.

In this apparatus, the concrete block feature extraction operation in the block boundary feature extraction section 2 is as follows. That is, FIG. 2 shows a block boundary and a correction range for, for example, adjacent compressed blocks of 8 × 8 pixels. For these pixels, information on the unevenness of the pixels (activity: hereinafter, abbreviated as act) is checked for the five pixels before and after the block boundary by the following equation. act = (| b−a | + | c−b | + | dc− + | e
-D | + | g-f | + | h-g | + | i-h | + | j-
i |) / 8

Further, the absolute value of the step (hereinafter abbreviated as atmp0) at the compression block boundary of 8 × 8 pixels is obtained by the following equation. atmp0 = | fe |

Further, these pieces of information are supplied to the block distortion judging section 3 in the subsequent stage. The specific block distortion determination operation in the block distortion determination unit 3 is performed as follows. That is, FIG. 3 shows a block distortion determination algorithm. In FIG. 3, when the operation is started, it is determined in step [1] whether or not the absolute value [atmp0] is less than or equal to a threshold value 1 which is arbitrarily set. Where [atm
If p0 ≦ threshold value 1] is not satisfied (N), it is determined in step [2] that the block distortion is not satisfied, and the processing is terminated.

When [atmp0≤threshold value 1] is satisfied in step [1] (Y), the absolute value [a] is calculated in step [3].
It is determined whether tmp0] is greater than or equal to the activity [act]. If [atmp0 ≧ act] is not satisfied (N), it is determined in step [2] that the block distortion is not generated, and the process is terminated.

Further, in step [3], [atmp0 ≧ a
ct] (Y), it is determined in step [4] whether the absolute value [atmp0] is larger than the value [| ef |]. If [atmp0> | e−f |] is not satisfied (N), it is determined in step [2] that the block distortion is not present, and the process ends.

In step [4], [atmp0> | e
If -f |] (Y), it is determined in step [5] whether the absolute value [atmp0] is larger than the value [| g-f |]. If [atmp0> | e−f |] is not satisfied (N), it is determined in step [2] that the block distortion is not present, and the process ends. Then, when all of the above steps [1] and [3] to [5] are set to (Y), it is determined that there is block distortion in step [6], and the process ends.

That is, in the above judgment, the step [1] utilizes the feature that when the boundary step is large, it is often the original image step, not the step created by block compression. . Note that here, by setting the threshold value 1, the judgment value can be arbitrarily changed.

Further, the step [3] utilizes the feature that in the case of block distortion, the boundary step is larger than the degree of unevenness of the peripheral pixels. Further step [4]
In the case of block distortion, [5] utilizes the feature that the boundary step is larger than the steps at both ends of the boundary.

With respect to the block distortion thus determined, the block distortion correction strength calculation unit 4 calculates a basic correction amount of block distortion (hereinafter abbreviated as sigma0) by the following equation. sigma0 = | atmp0- {| (ed) + (g-
f) | / 2} | / 2

Then, with respect to the basic correction amount [sigma0] of the block distortion calculated in this way, the correction amount is corrected as shown in FIG. 4 by the threshold values 2 and 3 which are set arbitrarily. Be seen. In this operation, the relationship between the threshold 1, the threshold 2, and the threshold 3 is 0 ≦ threshold 2 ≦ threshold 3 ≦
The threshold value is 1.

That is, in FIG. 4, when the operation is started, it is judged in step [11] whether or not there is block distortion. Here, the determination as to whether or not there is block distortion is based on the above step [2] or [6] in FIG. If it is not block distortion (N), the correction amount is set to 0 in step [12] and the operation is ended.

If block distortion is found in step [11] (Y), the absolute value [atmp] is calculated in step [13].
0] is less than or equal to the arbitrarily set threshold value 2 or less. When [atmp0 ≦ threshold value 2] here (Y)
In step [14], the correction amount = [sigma0] is set, and the operation is ended.

Further, in step [13], [atmp0≤
When it is not the threshold value 2] (N), it is determined in step [15] whether or not the absolute value [atmp0] is less than or equal to the threshold value 3 which is arbitrarily set. If [atmp0 ≦ threshold value 3] (Y), the correction amount = [sigm] in step [16].
a0 / 2] to end the operation. When it is not [atmp0 ≦ threshold value 3] in step [15] (N)
Is the correction amount in step [17] = [sigma0 / 4]
And the operation is terminated.

In this way, the correction amount is determined. In this case, the thresholds 2 and 3 can be set from the outside, so that optimum parameters can be obtained according to various bit rates.

That is, in the case of a high bit rate, if the step difference at the block boundary is large even if it is judged as block distortion, it is often the original step difference of the image, not the step difference caused by the block compression. Therefore, at the time of a high bit rate, erroneous correction can be reduced by making the threshold values 2 and 3 small by external control.

In most cases, the block boundary level difference at the low bit rate is the level difference caused by block compression. Therefore, when the bit rate is low, the threshold value 2 and the threshold value 3 are externally controlled to be large so that the range of the normal correction amount can be widened and the image quality can be expected to be improved.

Further, the correction amount thus determined is supplied to the block distortion correction section 5. Then, the block distortion correction unit 5 corrects the block distortion of the input image information using the supplied correction amount.
That is, the correction amount itself supplied to the pixel on the block boundary, 1/2 of the correction amount supplied to the pixel separated by 1 pixel, and the correction amount supplied to the pixel separated by 2 pixels 1/4 of the correction amount is used, and 1/8 of the supplied correction amount is used for the pixels 3 pixels away from each other so that the boundary step is reduced.

In this way, for example, image information having a step at the block boundary as indicated by a circle in FIG.
No correction for j, 1/8 of the basic correction amount for pixels b and i, and 1/1 of the basic correction amount for pixels c and h
4, the basic correction amount is 1/2 for the pixels d and g, and the basic correction amount is for the pixels e and f.
For example, as indicated by Δ in FIG. 5, correction for reducing block distortion is performed.

As described above, the threshold value 1, the threshold value 2, and the threshold value 3 which determine the correction amounts are set by the external controller section 100 to be image information of a low bit rate such as an MPEG search image. By determining and adaptively controlling: -It is possible to enhance the effect of reducing block distortion for low bit rate image information such as a search image. -Failure due to overcorrection can be reduced for high bit rate image information such as a normal image. The effect such as can be obtained.

Therefore, in this embodiment, the characteristic of the block distortion reducing means is changed according to the bit rate of the input image information, so that a good image quality improving effect can be obtained with respect to the low bit rate image information. In addition, the image information of high bit rate is not excessively corrected, and the optimum image quality improvement effect can be always obtained for image information of various bit rates.

As a result, in the conventional apparatus, the criterion used for the block distortion reduction process and the like used are always constant, and a good image quality improving effect can be obtained for low bit rate image information, for example. According to the present invention, the problems that could not be solved can be easily solved.

Thus, according to the above image decoding apparatus,
An image decoding apparatus that expands and decodes input image information that has been encoded and compressed for each arbitrary block, and that reduces block distortion occurring at a block boundary with respect to the decoded image information. By including the distortion reducing means and changing the characteristics of the block distortion reducing means according to the bit rate of the input image information, it is possible to obtain a good image quality improving effect for the low bit rate image information. Excessive correction is not performed on high bit rate image information, and the optimum image quality improvement effect can always be obtained for various bit rate image information.

The present invention is not limited to the embodiment described above, and various modifications can be made without departing from the spirit of the present invention.

[0035]

Therefore, according to the first aspect of the present invention, the characteristic of the block distortion reducing means is changed according to the bit rate of the input image information, so that the image information having a low bit rate is excellent. It is possible to obtain the image quality improvement effect, and there is no excessive correction for high bit rate image information, and the image quality improvement effect is always optimal for various bit rate image information. Is what you can get.

According to the second aspect of the present invention, the block distortion reducing means changes the level for reducing the block distortion in accordance with the bit rate of the input image information, so that the image information of various bit rates can be obtained. In contrast to this, the optimum image quality improving effect can always be obtained.

Further, according to the third aspect of the invention, the block distortion reducing means varies the correction amount for reducing the block distortion according to the bit rate of the input image information, so that the image of various bit rates can be obtained. It is possible to always obtain the optimum image quality improvement effect for information.

Further, according to the invention of claim 4, the block distortion reducing means discriminates the image information after decoding at the boundary portion of the block to detect the level of block distortion, and sets the level to an arbitrary threshold value. By controlling the block distortion by comparison and making the threshold variable according to the bit rate of the input image information, it is possible to always obtain the optimum image quality improvement effect for image information of various bit rates. Is something that can be done.

Further, according to the invention of claim 5, the block distortion reducing means discriminates the image information after decoding at the block boundary portion to detect the level of the block distortion, and detects the block distortion corresponding to the level. By forming a correction amount, comparing the level with an arbitrary threshold value, and controlling the weighting of the correction amount, and by making the threshold variable according to the bit rate of the input image information, image information of various bit rates can be obtained. On the other hand, it is possible to always obtain the optimum effect of improving the image quality.

As a result, in the conventional apparatus, the criterion used for the block distortion reduction processing and the like used at all times are constant, and a good image quality improvement effect can be obtained for low bit rate image information, for example. According to the present invention, the problems that could not be solved can be easily solved.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of an embodiment of a block distortion reducing unit which is a main part of an image decoding apparatus to which the present invention has been applied.

FIG. 2 is a diagram for explaining the explanation.

FIG. 3 is a flowchart for explaining the operation.

FIG. 4 is a flow chart for explaining the operation.

FIG. 5 is a diagram for explaining the effect.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Input terminal, 2 ... Block boundary feature extraction part, 3 ... Block distortion determination part, 4 ... Block distortion correction strength calculation part, 5
... Block distortion correction unit, 6 ... Switch, 7 ... Output terminal,
100 ... External controller section

Claims (5)

[Claims] 1. An image decoding apparatus for decompressing and decoding input image information encoded and compressed for each arbitrary block, wherein the image information after the decoding occurs at a boundary of the block. An image decoding apparatus comprising: a block distortion reducing unit configured to reduce block distortion, wherein a characteristic of the block distortion reducing unit is changed according to a bit rate of the input image information. 2. The image decoding apparatus according to claim 1, wherein the block distortion reducing unit makes a level for reducing the block distortion variable according to a bit rate of the input image information. 3. The image decoding apparatus according to claim 1, wherein the block distortion reducing unit makes a correction amount for reducing the block distortion variable according to a bit rate of the input image information. . 4. The block distortion reducing means discriminates the image information after the decoding at the boundary portion of the block to detect the level of the block distortion, and compares the level with an arbitrary threshold value. The image decoding apparatus according to claim 1, wherein the threshold value is controlled according to a bit rate of the input image information while controlling block distortion reduction. 5. The block distortion reducing means determines the block distortion level by discriminating the image information after the decoding at a boundary portion of the block, and correcting the block distortion according to the level. 2. The level is compared with an arbitrary threshold value to control weighting of the correction amount, and the threshold value is variable according to the bit rate of the input image information. Image decoding device.