JPH07274165A - Image information compression device - Google Patents

Abstract

PURPOSE:To reduce blurring and to improve the image quality of a decoding image by attenuating a high band component in a vertical direction in a field with respect to input image information and executing highly efficient encoding based on the output information. CONSTITUTION:Input image information aa is supplied to intra-field vertical direction LPF-A. First image information (a) where the high band component of the vertical direction is attenuated and second image information (b) where the high band component is not attenuated are outputted. Information (a) and (b) are inputted to coefficient units 1 and 2 controlled by a first control signal (c), the outputs of the coefficient units 1 and 2 are mixed in an adder 3 and they are outputted as image information (d). The information (d) is written into a frame memory 4 and information on a prescribed line is read at the time of reading. Thus, a system is set to be the state of a frame image. Then, an encoding DCT means 5 fetches the picture elements by vertically 8 elements Xhorizontally 8 elements from pixel array in the state of the frame image, executes two-dimensional 8X8DCT and generates output image information bb.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image information compression apparatus, and more particularly to an image information compression apparatus for compressing image information into a smaller code amount in a recording, transmitting and displaying apparatus for processing digital signals.

[0002]

2. Description of the Related Art In recent years, JPEG and MPEG-1 standards have been established as high-efficiency coding methods for image signals (Reference 1,
Saito, Yasuda, "Introduction to Image Information Compression (9th), Still Image Coding System", Journal of the Television Society, Vol. Four
4, No. 2, pp. 153-161 (1990). Reference 2, Yoneman, “MPEG Standard Video Part (ISO1
1172 VIDEO) ", The Institute of Image Electronics Engineers of Japan, 20, 4,
pp. 306-316 (Aug. 1991)). JPE
Both G and MPEG-1 use DCT as an encoding method.
(Discrete Cosine Transformation), requantization and variable length coding are used. Furthermore, in MPEG, interframe predictive coding is used in combination. Of these, quantization noise occurs in the decoded image due to the requantization process, but requantization is necessary to reduce the amount of information after encoding.

In JPEG and MPEG-1, DCT is used in order to reduce redundancy by utilizing spatial correlation of image signals.
Is used instead of DCT, or DCT
As a coding method used together with the above, there is a method called subband coding or wavelet coding (Reference 3, Nyozawa, Watanabe, “Frequency domain of motion-compensated interframe prediction in non-equal subband / wavelet transform coding”). Realization ”, IEICE Technical Report IE91-8
3). In addition, predictive coding, vector quantization, and the like are known (Reference 4, Hatori, "Introduction to Image Information Compression (Part 4), Image Coding Algorithm (I) -Predictive Coding-", TV. John Society Journal Vol. 43, No.
9, pp. 949-956 (1989)). In either method, requantization is necessary to reduce the amount of information after encoding, and quantization noise occurs in the decoded image due to the requantization process.

The quantization noise in such a decoded image is
There is an artificial feeling in the appearance of noise, which causes a large visual deterioration. Therefore, conventionally, a high-efficiency coding is performed by applying a pre-filter to the input image before the high-efficiency coding of the image to reduce the image information to some extent, resulting in a small requantization step size. A method for reducing the quantization noise has been proposed (Reference 5, Takishima, Wada, "Adaptive Coding Control by Variable Prefilter", IEICE Autumn National Conference D-228, 1990). And
In the prior art, FIG. 5 shows the filter coefficient of the pre-filter shown in the above-mentioned document 5, which is obtained by multiplying the target pixel by K ² and the pixels on the upper, lower, left and right sides thereof by K or 1 to obtain the sum. ^The filter output was the value divided by ² + 4 · (K + 1).

[0005]

When the pre-filter used in the above-mentioned prior art is applied, there is a drawback in that the image is blurred, and the motion is blurred especially in the image having the interlaced structure.

The present invention has been made in view of the above points, and requantization is performed when the amount of image information is reduced and the amount of image information is controlled to a constant code amount while the image blur is relatively reduced. The objective is to raise the visual subjective image quality by reducing the quantization step size to reduce the interference due to the quantization noise in the decoded image.

[0007]

The present invention provides the following configurations in order to solve the above problems.

According to a first aspect of the present invention, input image information in which one frame is composed of two fields having an interlaced structure is encoded by using spatial correlation between pixels in the frame, whereby a high efficiency code is obtained. In the image information compression apparatus for converting the input image information, a high efficiency encoding is performed based on an in-field vertical LPF that attenuates a high frequency component in the vertical direction in the field and output information of the in-field vertical LPF. An image information compression apparatus is provided, which comprises:

A second aspect of the invention is a high-efficiency code by coding input image information in which one frame is composed of two fields forming an interlaced structure by utilizing spatial correlation between pixels in the frame. In the image information compression apparatus for converting the input image information, an in-field vertical LPF that attenuates a high frequency component in the vertical direction in the field, output information of the in-field vertical LPF, and the input image information are input. Provided is an image information compression apparatus characterized by having a mixing means for mixing at an adaptive ratio according to a code amount, and a coding means for performing high efficiency coding based on output information of the mixing means. Is.

According to a third aspect of the present invention, high efficiency coding is performed by coding input image information in which one frame is composed of two fields forming an interlaced structure by utilizing spatial correlation between pixels in the frame. In an image information compression apparatus for converting the input image information, a vertical LPF in the field for attenuating the high frequency component in the vertical direction in the field, and a high frequency component in the vertical direction in the frame for the input image information. LPF in the frame that attenuates
And a mixing means for mixing the output information of the in-field vertical direction LPF and the output information of the in-frame vertical direction LPF at an adaptive ratio according to the motion amount, and a high efficiency based on the output information of the mixing means. The present invention provides an image information compression device, characterized in that it has an encoding means for performing encoding.

According to a fourth aspect of the present invention, input image information in which one frame is composed of two fields forming an interlaced structure is encoded by using spatial correlation between pixels within the frame, thereby achieving high efficiency coding. In the image information compression device for converting the horizontal direction HPF for extracting the high frequency component in the horizontal direction of the input image information, and the high frequency component in the vertical direction in the field or the frame with respect to the output information of the horizontal direction HPF. It is an object of the present invention to provide an image information compression apparatus characterized by having a vertical LPF to be attenuated and a coding means for performing high efficiency coding based on output information of the vertical LPF.

According to a fifth aspect of the present invention, input image information in which one frame is composed of two fields forming an interlaced structure is encoded by utilizing spatial correlation between pixels in the frame, whereby a high efficiency code is obtained. In the image information compression device for converting the input image information into subbands, the input image information is subband-divided into horizontal high band information and horizontal low band information, and a field only for the high band information. A vertical LPF for attenuating a high frequency component in the vertical direction within a frame or a frame, and mixing means for mixing the high frequency band information and the output information of the vertical direction LPF at an adaptive ratio according to the code amount, An image information compression apparatus is provided, which has an encoding unit that performs high-efficiency encoding based on output information of the mixing unit.

[0013]

FIG. 1 is a block diagram for explaining a main part of an image information compression apparatus according to a first embodiment which is an embodiment of the present invention, and FIG. 2 is a second embodiment which is an embodiment of the present invention. FIG. 3 is a block diagram for explaining main parts of an image information compression apparatus according to an example, and FIG. 3 is a block diagram for explaining main parts of an image information compression apparatus according to a third embodiment which is an embodiment of the present invention.
FIG. 4 is a block diagram for explaining the main part of an image information compression apparatus according to the fourth embodiment which is an embodiment of the present invention. The first embodiment will be described below with reference to the drawings.

(First Embodiment) In the present embodiment, when image information in which one frame is composed of two fields having an interlaced structure is encoded by DCT or the like in the frame, it is used as a pre-filter in the field. A feature is that a low-pass filter (hereinafter referred to as "in-field vertical direction LPF") is applied in the vertical direction.

In FIG. 1, the interlaced-scanned input image information aa is the in-field vertical direction LPF A.
Is supplied to. This in-field vertical direction LPF A is composed of a so-called comb filter, and 1H delay memories A1 and A2 for delaying one line and a coefficient unit A3.
It is composed of A5 and an adder A6, and outputs the first image information a in which the high frequency component in the vertical direction is attenuated and the second image information b in which no high frequency component is attenuated. .
The coefficients used for the coefficient units A3 to A5 may be, for example, A3 = 1/4, A4 = 1/2, and A5 = 1/4.

Then, the first and second image information a and b are supplied to the first mixing means composed of the coefficient unit 1, the coefficient unit 2 and the adder 3. Here, the coefficients used in the coefficient unit 1 and the coefficient unit 2 are M and M−1 (where 0 <M <1), and the mixing ratio of the first and second image information a and b is M: (1- M)
Has become. Further, the coefficients used in the coefficient unit 1 and the coefficient unit 2 are controlled by the first control signal c, and the control signal c is generated by the code amount detecting means (not shown) for detecting the code amount of the input image information aa. ing. That is, the coefficient is varied based on the first control signal c so that M is increased when the code amount is large and M is decreased when the code amount is small. The outputs of the coefficient units 1 and 2 are mixed by the adder 3 to form the image information d. It should be noted that the code amount may be detected by feedback based on the code amount of previously encoded frames, or may be determined in advance by checking the frame to be encoded and determined by feedforward. May be.

This image information d is written in the frame memory, and by reading out the information relating to a predetermined line at the time of reading, the state of the frame image (the state where the even field lines are placed between the odd field lines) is set. There is. Then, the DCT means 5 takes out vertical 8 pixels × horizontal 8 pixels from the pixel array in the state of the frame image and performs two-dimensional 8 × 8 DCT to generate output image information bb.

With the above configuration, it is possible to reduce the blur even in the case of a moving image. Note that it is not always necessary to control the mixing ratio by the image code amount,
It may be fixed as M = 1. Further, in this embodiment, DC
Although T is used as a coding method for reducing redundancy by utilizing spatial correlation of image signals, subband coding, wavelet coding, prediction are used as a coding method instead of DCT or used with DCT. Encoding, vector quantization, etc. may be used. In addition, after the interframe predictive coding is performed after the frame image is set, the DCT
Etc. may be performed.

(Second Embodiment) In the second embodiment, when an image signal in which one frame is composed of two fields forming an interlaced structure is encoded by DCT or the like in the frame, the output of the pre-filter is used. It is characterized in that a signal obtained by mixing the output applied with the LPF in the vertical direction in the field and the output applied with the LPF in the vertical direction in the frame while adaptively changing the ratio is used. This mixing ratio is controlled according to the motion detection signal detected between frames. That is, when it is detected that there is motion, the ratio of the output applied with the LPF in the vertical direction in the field is increased.

In explaining the second embodiment with reference to FIG. 2, the same components as those in FIG. 1 are designated by the same reference numerals and the description thereof will be omitted. The interlaced scanned input image information aa is supplied to the in-field vertical direction LPF A, and then the second image information b is supplied to the in-frame vertical direction LPF B for extracting the vertical low-frequency component in the frame. It The in-frame vertical direction LPF B is composed of a field memory B1 for delaying one field, a 1H delay memory B2 for delaying one line, coefficient units B3 to B5, and an adder B6. The third image information e in which the high frequency component in the vertical direction is attenuated is output. The coefficient unit B
The coefficients used for 3 to B5 are, for example, B3 ¼ and B4
Should be 1/2 and B5 should be 1/4.

Then, the first and third image information a and e are supplied to the second mixing means composed of the coefficient unit 6, the coefficient unit 7 and the adder 8. Here, the coefficients used in the coefficient unit 6 and the coefficient unit 7 are L and L-1 (where 0 <L <1), and the mixing ratio of the first and third image information a and e is L: (1- L)
Has become. Further, the coefficients used in the coefficient unit 6 and the coefficient unit 7 are controlled by the second control signal f, and the second control signal f is generated by the motion detection means 9 which detects the motion amount of the input image information aa. ing. That is, the coefficient is varied based on the second control signal f so that L is increased when the motion amount is large, and L is decreased when the code amount is small. The outputs of the coefficient units 6 and 7 are the adder 8
Are mixed to obtain the fourth image information g.

Further, the fourth image information g is mixed by the first mixing means with the second image information b in which any high frequency component is not attenuated to generate the image information d. Then, it is the first to write this image information d into the frame memory and read the information related to a predetermined line at the time of reading to make it into the state of the frame image (the state where the even field lines are placed between the odd field lines). This is the same as in the first embodiment.

The control of the mixing ratio based on the image code amount is not always necessary, and may be fixed as M = 0 in the figure. Further, in this embodiment, DCT is used as a coding method for reducing redundancy by utilizing spatial correlation of image signals, but subband coding is used as a coding method instead of DCT or used together with DCT. Alternatively, wavelet coding, predictive coding, vector quantization, or the like may be used. Alternatively, the DCT or the like may be performed after performing the inter-frame predictive coding after setting the state of the frame image.

In the present embodiment, motion detection is performed, and when the amount of motion is small, the ratio of the output of the intra-frame vertical direction LPF is increased. Therefore, the blur of the still portion of the image is smaller than that in the first embodiment. There is an effect that. (Third Embodiment) The third embodiment is characterized in that the processing of applying the LPF in the vertical direction of the first and second embodiments is performed only on the high frequency component in the horizontal direction.

In the description of the third embodiment with reference to FIG. 3, the same components as those in FIGS. 1 and 2 are designated by the same reference numerals and the description thereof will be omitted. Input image information aa interlaced scanned
Is supplied to the horizontal HPFC (high pass filter), where the horizontal high frequency components are extracted to obtain the image information h.
To get Then, the processing of the first or second embodiment is performed on this image information h. That is, the vertical direction L in FIG.
PF D corresponds to the configuration BB in FIG. 2, and when the operation of the first embodiment is performed, the coefficient of the coefficient unit 6 is set to “1” and the coefficient unit 7 is set.
Is set to “0”.

The image information d obtained by mixing the second image information b and the fourth image information g by the first mixing means having the configurations 1 to 3 is input to one input of the adder 11. We are supplying. Further, the other input of the adder 11 is supplied with image information p having a horizontal low-frequency component obtained by subtracting the image information h from the input image information aa by the subtractor 10, At 11, the image information d and the image information p are mixed to obtain the image information q.

Using the frame memory 4, the image information q is converted into a state of a frame image (a state in which lines of even fields are placed between lines of odd fields), and further, from the pixel array in the state of frame images. Two-dimensional 8 × 8D is taken out by the DCT means 5 by taking out vertical 8 pixels × horizontal 8 pixels each.
The CT is performed as in the first and second embodiments.

In this embodiment, DCT is used as a coding method for reducing redundancy by utilizing the spatial correlation of image signals. However, as a coding method that replaces DCT or is used together with DCT, Band coding, wavelet coding, predictive coding, vector quantization, etc. may be used. Alternatively, the DCT or the like may be performed after performing the inter-frame predictive coding after setting the state of the frame image.

In the present embodiment, the frequency component cut by the low-pass filter is in the high frequency region in the horizontal direction and the high frequency region in the vertical direction in the diagonal direction as compared with the first and second embodiments, so that blurring is further reduced. There is an effect that.

(Fourth Embodiment) In the fourth embodiment, the high-frequency band obtained by horizontally dividing the input image information aa into subbands is subjected to the vertical LPF processing of the first and second embodiments. Is characterized by.

In describing the fourth embodiment with reference to FIG. 4, the same components as those in FIGS. 1 to 3 are designated by the same reference numerals and the description thereof will be omitted. Input image information aa interlaced scanned
Is supplied to a low-frequency sub-band division filter 12 for extracting low-frequency components and a high-frequency sub-band division filter 13 for extracting high-frequency components, and the input image information aa is band-divided in the horizontal direction by the decimator. 14: 1 performs 2: 1 subsampling. this house,
The image information d is obtained by performing the processes of the first and second embodiments only on the horizontal high band information r. Then, the image information d related to the horizontal high band information r and the horizontal low band information s are used in the frame memories 4 and 16, respectively, to determine the state of the frame image (the line of the even field between the lines of the odd field). State). Further, the vertical 8 pixels × horizontal 8 pixels are taken out from the pixel array in the state of the frame image, and two-dimensional 8 × 8 DCT is performed by the DCT means 5 and 17, respectively.

In this embodiment, the DCT is used as a coding method for reducing redundancy by utilizing the spatial correlation of image information. However, as a coding method that replaces the DCT or is used together with the DCT, Band coding, wavelet coding, predictive coding, vector quantization, etc. may be used. Alternatively, the DCT or the like may be performed after performing the inter-frame predictive coding after setting the state of the frame image.

In this embodiment, as in the third embodiment,
As compared with the second embodiment, the frequency component cut by the low-pass filter is the high frequency portion in the horizontal direction and the high frequency portion in the diagonal direction, so that the blur is further reduced. Also, during the sub-band encoding process, the vertical LP
Since the F processing is added and a dedicated circuit for extracting the high frequency component in the horizontal direction is not provided as in the third embodiment, the hardware can be efficiently used.

Although the image information compression apparatus has been described in the above embodiment, it goes without saying that the image information compression apparatus may be used as a part of the image information compression / decompression apparatus.

[0035]

As described above, according to the structure of the image information compressing apparatus of the present invention as set forth in claim 1, in the field vertical for attenuating the high frequency component in the vertical direction in the field with respect to the input image information. Since the direction LPF is provided, by reducing the information amount of the input image information, it is possible to reduce the requantization step size when performing high-efficiency encoding to a constant code amount, and to reduce the prefilter of the conventional example. In comparison, since the image blurring is relatively small, there is an effect that the visually subjective image quality of the decoded image can be improved.

As described above, according to the image information compressing apparatus according to the present invention as defined in claim 2, in addition to the effect of the image information compressing apparatus according to the present invention as defined in claim 1, especially in the vertical direction in the field. Since there is a mixing unit that mixes the output information of the LPF and the input image information at an adaptive ratio according to the code amount, it is possible to further reduce the information amount while preventing blurring of the image.

As described above, according to the image information compressing apparatus of the present invention described in claim 3, in addition to the effect of the image information compressing apparatus of the present invention described in claim 2, especially in the input image information. On the other hand, since it has the intra-frame vertical direction LPF that attenuates the high-frequency component in the vertical direction within the frame, the amount of information is further reduced as compared with the image information compression apparatus according to claim 2 while preventing image blurring. The effect is that you can.

As described above, according to the image information compressing apparatus of the present invention as defined in claim 4, in particular, the horizontal direction HPF for extracting the high frequency component in the horizontal direction of the input image information is provided. , 3, there is an effect that it is possible to further reduce the amount of information while preventing blurring of the image as compared with the image information compression apparatus described in 3 above.

As described above, according to the image information compression apparatus of the present invention as defined in claim 5, in particular, the input image information is subbanded into horizontal high band information and horizontal low band information. Since there is a sub-band dividing means for dividing and a vertical LPF for attenuating the vertical high frequency component within the field or frame only for the high frequency band information, the horizontal high frequency and the vertical high frequency diagonal direction. Since the high frequency part is deleted, there is an effect that the amount of information can be further reduced while preventing blurring of the image. In addition, since the vertical LPF process is added in the middle of the subband encoding process and a dedicated circuit for extracting the horizontal high frequency component is not provided, it is possible to efficiently use the hardware. effective.

[Brief description of drawings]

FIG. 1 is a block diagram for explaining main parts of an image information compression apparatus according to a first embodiment which is an embodiment of the present invention.

FIG. 2 is a block diagram for explaining a main part of an image information compression apparatus according to a second embodiment which is an embodiment of the present invention.

FIG. 3 is a block diagram for explaining a main part of an image information compression apparatus according to a third embodiment which is an embodiment of the present invention.

FIG. 4 is a block diagram illustrating a main part of an image information compression apparatus according to a fourth embodiment, which is an embodiment of the present invention.

FIG. 5 is a diagram for explaining coefficients of a conventional prefilter.

[Explanation of symbols]

1, 2 coefficient unit (mixing means) 3 adder (mixing means) 5 DCT means (encoding means) 12 low-frequency subband division filter (subband division means) 13 high-frequency subband division filter (subband division means) 14 and 15 decimator (sub-band dividing means) aa Input image information A In-field vertical direction LPF B In-frame vertical direction LPF C Horizontal direction HPF D Vertical direction LPF

Claims (5)

[Claims] 1. Image information for high-efficiency encoding by encoding input image information in which one frame is composed of two fields having an interlaced structure by utilizing spatial correlation between pixels in the frame. In the compression device, a vertical LPF in the field for attenuating a high frequency component in the vertical direction in the field for the input image information, and coding for performing high-efficiency coding based on output information of the vertical LPF in the field An image information compression apparatus having means. 2. Image information for high-efficiency encoding by encoding the input image information in which one frame is composed of two fields having an interlaced structure by utilizing spatial correlation between pixels in the frame. In the compression device, a vertical LPF in the field that attenuates a high frequency component in the vertical direction in the field with respect to the input image information, output information of the vertical LPF in the field, and the input image information are input according to a code amount. An image information compression apparatus comprising: a mixing unit that mixes at an adaptive ratio and an encoding unit that performs high-efficiency coding based on output information of the mixing unit. 3. Image information for high-efficiency encoding by encoding the input image information in which one frame is composed of two fields forming an interlaced structure by utilizing spatial correlation between pixels in the frame. In the compression device, an in-field vertical direction LPF for attenuating a high frequency component in the vertical direction within the field with respect to the input image information, and a frame for attenuating a high frequency component in the vertical direction within the frame for the input image information An inner vertical direction LPF, mixing means for mixing the output information of the in-field vertical direction LPF and the output information of the in-frame vertical direction LPF at an adaptive ratio according to the amount of motion, and output information of the mixing means. And a coding means for performing high-efficiency coding based on the image information compression apparatus. 4. Image information for high-efficiency encoding by encoding input image information in which one frame is composed of two fields having an interlaced structure by utilizing spatial correlation between pixels in the frame. In the compression device, a horizontal direction H for extracting a high frequency component in the horizontal direction of the input image information.
PF and a vertical LP for attenuating a high frequency component in the vertical direction within a field or a frame with respect to the output information of the horizontal HPF.
An image information compression device, comprising: F, and an encoding means for performing high efficiency encoding based on output information of the vertical direction LPF. 5. Image information for high-efficiency encoding by encoding the input image information in which one frame is composed of two fields forming an interlaced structure by utilizing spatial correlation between pixels in the frame. In the compression device, sub-band dividing means for dividing the input image information into horizontal high band information and horizontal low band information, and a sub-band dividing unit for only the high band information in a field or in a frame. Vertical LPF that attenuates high frequency components in the vertical direction
Mixing means for mixing the high band information and the output information of the vertical LPF at an adaptive ratio according to the code amount, and coding for performing high efficiency coding based on the output information of the mixing means. An image information compression apparatus having means.