JP2002152744A - Method for expanding conversion coded image - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain an expanded image with high image quality and high reliability with a simple configuration without applying magnification variation processing to the image after expansion processing or to generate an image size suitable for applications by applying the magnification processing to the image. SOLUTION: A user uses an image size designation means 1 to designate an expanded image size 2 to an image (wavelet transform coefficient) having already been wavelet-transformed image. A hierarchical wavelet transform coefficient 3 is referenced from the designated image size 2 and a hierarchical number (i) is obtained to satisfy a directly upper layer (i+1) closest or equal to a designated expanded image size in terms of an inner size and a directly lower layer (i) closest to the designated expanded image size greater than the expanded image size or equal thereto. The hierarchical inverse wavelet transform is applied to the image from the highest layer to the layer (i+1) or to the layer (i) to obtain an expanded image 6. Furthermore, the magnification variation processing to magnify the expanded image 6 to the image size designated by the user is conducted to obtain a bit map image 11.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for decompressing a transform code, and more particularly, to determining a reduced image size for obtaining a high-quality decompressed image from a wavelet transform code or a sub-band transform code of an image signal. The present invention relates to an image expansion method to be performed.

[0002]

2. Description of the Related Art In decompression of an encoded natural image,
The JPEG method, which is a conventional encoding method, has been used for decompressing a decompressed image having the same size as the original image (ISO
/ IEC 10918-1 Information Technology Digital compre
ssion and coding of continuous-tone still image
s). Therefore, in order to output one encoded image to various output devices having different resolutions, it is necessary to perform expansion / reduction processing of the expanded image after expansion. Conventionally, in the wavelet transform coding method, the decompressed image size is the same size as the original image. Therefore, in order to obtain the decompressed image at the size specified by the user, the decompressed image is transformed after performing the inverse wavelet transform. It was necessary to perform double processing and adjust the image size.

[0003]

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned circumstances, and has a simple configuration of performing high-reliability and high-quality decompressed image processing by not performing scaling processing after decompression processing. Or by applying a scaling process to generate an image size suitable for the intended use.

[0004]

According to the first aspect of the present invention, there is provided an image decompression method for obtaining a decompressed image from an encoded image, comprising: an image size specifying means, a hierarchical number specifying means,
It has a memory for storing the hierarchical wavelet transform coefficients, a buffer memory, and an image decompression means for decompressing the image from the hierarchical wavelet-transformed code, and the size of the decompressed image when the hierarchical wavelet-transformed code is decompressed. It is characterized in that it is determined by the vertical (horizontal) size of the wavelet transform coefficient of the layer closest to the vertical (horizontal) size of the specified image (vertical x horizontal).

According to a second aspect of the present invention, there is provided an image decompression method for obtaining a decompressed image from an encoded image, comprising: an image size specifying means, a hierarchical number specifying means, and a memory for storing a hierarchical wavelet transform coefficient. And a buffer memory,
Image expansion means for expanding the image from the hierarchical wavelet-transformed code, and the size of the decompressed image (vertical x horizontal) when the hierarchical wavelet-transformed code is image-expanded
Is determined by the size of the wavelet transform coefficient of the immediately upper layer (i + 1) (the lowest subband level that realizes the image quality among the subband levels smaller than the image size specified by the user). It is.

According to a third aspect of the present invention, there is provided an image expanding method for obtaining an expanded image from an encoded image, wherein an image size specifying means, a hierarchical number specifying means, and a memory for storing hierarchical wavelet transform coefficients. And a buffer memory,
Image expansion means for expanding the image from the hierarchical wavelet-transformed code, and the size of the decompressed image (vertical x horizontal) when the hierarchical wavelet-transformed code is image-expanded
To the immediately lower hierarchy (i) (for subband levels larger than the image size specified by the user,
This is characterized by being determined by the size of the wavelet transform coefficient at the highest subband level).

According to a fourth aspect of the present invention, in the second or third aspect of the present invention, there is further provided an interpolation presence / absence designating means, wherein the expanded image is directly converted into an expanded image without scaling. It is.

The invention according to claim 5 is the invention according to claim 2 or 3, further comprising scaling means for designating the presence or absence of scaling and scaling means for scaling to an image size designated by the user. The feature is to convert to size.

According to a sixth aspect of the present invention, in the fourth aspect, the image compression / decompression is performed by a JPEG2000 Image Coding System.
(ISO / IEC FCD 15444-1). It is applied to a code stream encoded by a method specified in (ISO / IEC FCD 15444-1).

[0010] The invention of claim 7 is the invention of claim 5, further comprising an interpolation presence / absence designation means.
Pixels that are not in the expanded image are not assigned to the bitmap image (no interpolation is performed).

According to an eighth aspect of the present invention, in the seventh aspect of the present invention, the image compression / decompression is performed by a JPEG2000 Image Coding System.
(ISO / IEC FCD 15444-1). It is applied to a code stream encoded by a method specified in (ISO / IEC FCD 15444-1).

According to a ninth aspect of the present invention, the image processing apparatus according to the fifth aspect further comprises an interpolation means and an interpolation presence / absence designation means. Is generated.

According to a tenth aspect of the present invention, in addition to the fifth aspect of the present invention, the image processing apparatus further comprises an interpolation means and an interpolation presence / absence designation means. It is characterized in that a bitmap image is generated with the value of a pixel having the shortest distance as a representative value.

According to an eleventh aspect of the present invention, in accordance with the ninth or tenth aspect, the image compression / decompression is performed by JPEG2000 Image Cod.
It is applied to a code stream encoded according to a method specified by the ing System (ISO / IEC FCD 15444-1).

According to a twelfth aspect of the present invention, there is provided an image decompression method for obtaining a decompressed image from an encoded image, comprising: an image size specifying means, a hierarchical number specifying means, and a memory for storing subband transform coefficients. , A buffer memory, and an image decompression means for decompressing an image from the subband-converted code, and specifying the size (length × width) of the decompressed image when decompressing the subband-converted code. ) It is characterized in that it is determined by the vertical (horizontal) size of the subband transform coefficient of the hierarchy closest to the size.

According to a thirteenth aspect of the present invention, there is provided an image decompression method for obtaining a decompressed image from an encoded image, comprising: an image size specifying means, a hierarchical number specifying means, and a memory for storing a subband transform coefficient. , A buffer memory, and image decompression means for decompressing an image from the subband-converted code, and expanding the size (length × width) of the decompressed image when the subband-converted code is image-decompressed to the immediately upper layer (i + 1) ( Among the sub-band levels smaller than the image size designated by the user, the sub-band level is determined by the size of the sub-band coefficient of the lowest sub-band level that realizes the image quality.

According to a fourteenth aspect of the present invention, there is provided an image decompression method for obtaining a decompressed image from an encoded image, comprising: an image size specifying means, a hierarchical number specifying means, and a memory for storing subband transform coefficients. , A buffer memory, and an image decompression means for decompressing an image from the sub-band-converted code. Of the sub-band levels larger than the image size specified by the user, the highest sub-band level that realizes the image quality)
Is determined based on the size of the subband coefficient.

The invention of claim 15 is the invention of claim 13 or 14
The invention according to the third aspect of the present invention is characterized in that the image processing apparatus further comprises a scaling presence / absence specifying means, and the expanded image is directly used as an expanded image without scaling.

The invention of claim 16 is the invention of claim 13 or 14
The present invention further comprises means for scaling the image to an image size designated by the user and means for designating the presence or absence of scaling, and converts the image size to the image size designated by the user.

A seventeenth aspect of the present invention is the image processing apparatus according to the sixteenth aspect, further comprising a scaling presence / absence designating means, and when scaling is performed, pixels not in the expanded image are not assigned to the bitmap image (no interpolation is performed) ).

According to an eighteenth aspect of the present invention, in the sixteenth aspect of the present invention, the image processing apparatus further comprises an interpolation presence / absence designating means, and linearly interpolates a pixel not included in the expanded image to generate a bitmap image when scaling. It is characterized by the following.

According to a nineteenth aspect of the present invention, in the invention of the sixteenth aspect, at the time of scaling (reduction), a value of a pixel having the shortest pixel distance among a plurality of pixels in the expanded image is set as a representative value. It is characterized by generating an image.

[0023]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS First, the configuration and operation principle when the present invention is applied to a wavelet transform system (claims 1 to 11) will be described. Because Hierarchical wavelet transform coding scheme structure constituting each sub-band by separating the low and high frequency components of the image at the time of coding, the low-frequency component of the size of 1/2 ⁿ of vertically and horizontally original image Is constituted by the LL component (low-frequency component in both the vertical and horizontal directions of the original image). By using this, the subsequent scaling (enlargement / reduction) process may not be necessary.

Also, unlike the method of subsampling the adjacent pixels of the decompressed bitmap image as in JPEG, the hierarchical wavelet transform coding method uses low-frequency components of the closest hierarchy corresponding to the designated reduced image. By configuring as an expanded image, a high-quality expanded image can be configured without losing information of adjacent pixels in the original image.

FIG. 1 shows the most complicated structure of the invention according to the first to eleventh aspects of the present invention. The natural image (wavelet transform coefficient) encoded by the wavelet transform allows the user to select the image size. 1 shows a configuration of an apparatus that obtains a bitmap image from a portion that specifies an image size when decompression is performed.

In FIG. 1, reference numeral 1 denotes an image size designating means;
2 is a designated image size, 3 is a wavelet transform coefficient, 4 is a wavelet transform coefficient of the immediately upper layer (i + 1), 5 is a wavelet transform coefficient of the immediately lower layer (i), 6
Is a decompressed image, 7 is a magnification change designation means, 8 is a magnification change means, 9
Is an interpolation designation means, 10 is an interpolation means, 11 is a bitmap image. First, the user designates an expanded image size 2 by the image size designation means 1 with respect to the already wavelet-transformed image (wavelet transform coefficient). (At this time, in order to reproduce the original image more faithfully, it is assumed that the aspect ratio is not changed. Therefore, hereinafter, it is simply referred to as the size without saying the aspect size.)

Next, referring to the hierarchical wavelet transform coefficient 3 in the memory from the image size 2 designated by the image size designating means 1, the immediately upper layer (the innermost closest or equal to the designated expanded image size at the inner end) i + 1), and a layer number (integer value) that exceeds the specified decompressed image size and satisfies the nearest lower layer (i) that is the closest or equal
Find i. That is, a hierarchy number (integer value) i that can be uniquely determined is calculated by satisfying the following conditions. Original image size / 2 ^{(i + 1)} ≤ specified image size <original image size / 2 ^I

Next, the hierarchical number (i) is expanded by performing a hierarchical inverse wavelet transform from the highest hierarchical level to i + 1 (claim 2) or from the highest hierarchical level to i (claim 3). An image 6 is obtained (claim 4).

Further, if necessary, a scaling process for scaling the expanded image 6 to an image size designated by the user is performed.
A bitmap image 11 is obtained. Hereinafter, the bitmap image 11 will be described. If no scaling is specified according to the state specified by the scaling presence / absence specifying means 7, this expanded image is directly used as a bitmap image,
The process ends. On the other hand, when scaling is designated (claim 5), the scaling unit 8 then scales the expanded image to the image size designated by the user. This scaling method may use a method known in the prior art as it is.

Further, since the size of the image changes with the scaling, one pixel before the scaling process does not correspond to one pixel after the scaling process. Therefore, when the interpolation is not specified by the interpolation presence / absence specifying means 9, the interpolation is not performed.
Only the scaling of the size is performed to obtain a bitmap image 11 (claim 7). On the other hand, when it is specified to perform the interpolation, the interpolation is performed by the interpolation means 10 to obtain the bitmap image 11 (claims 9 and 10). Here, the interpolation means 10 assumes a method widely known in the related art, such as linear interpolation or bi-cubic.

The method of using the decompressed image created by the above processing as a bitmap image is a means for decompressing a hierarchical wavelet-transformed code used in claim 4 into a natural image. In this part, JPE2000 Image Codi
ng System (ISO / IEC FCD 15444-1), a decompression method characterized by being applied to a code stream coded according to a method specified by the method defined in ISO / IEC FCD 15444-1. In the case of 7, the invention of claim 8 is applied, and in the case of claims 9 and 10, the invention of claim 11 is applied.

Further, the bitmap image 11 can be obtained by a method similar to the above-described hierarchical wavelet transform method by using a means for expanding a subband transformed code into a natural image. FIG. 2 is a configuration diagram for explaining an embodiment of the hierarchical sub-band transform method. This hierarchical sub-band transform method is different from the hierarchical wavelet transform method in the hierarchical wavelet transform method shown in FIG. And the fact that a hierarchical subband conversion scheme is used
In the E2000 Image Coding System (ISO / IEC FCD 15444-1), since it is a decompression method based on wavelet transform, it differs in that there is no corresponding claim, but the basic operation is the same as that described above, so Description is omitted.

[0033]

According to the first, second, third and fourth aspects of the present invention, a decompressed image having the highest image quality and closest to the image size designated by the user can be obtained. According to the first aspect of the present invention, it is possible to obtain a high-speed, memory-saving bitmap image having higher image quality than a method of performing subsampling after decompression over all layers. According to the second aspect of the present invention, not only a required memory is reduced, but also high-speed decompression is possible. According to the third aspect of the present invention, an image larger than the size specified by the user can be obtained. According to the fourth aspect of the present invention, a high-quality bitmap image without deterioration in image quality due to zooming can be obtained.

In addition to the above, according to the invention of claim 5, it is possible to completely match the image size specified by the user. Further, with regard to the image quality and the expansion speed, the invention of claim 7 can perform expansion at a higher speed and with less memory than the inventions of claims 9 and 10. According to the ninth and tenth aspects of the present invention, higher-quality decompression can be performed than the seventh aspect of the present invention.

Further, with respect to claims 6, 8, and 11,
In addition to the effects described above, compatibility is maintained because the decompression method standardized internationally is used. Therefore, it has a feature that the same bitmap image can be generated for the same input file and parameter even for codes created by products of various manufacturers.

Compared with the wavelet transform coding method, the subband transform coding method sequentially decomposes not only low frequency components but also high frequency components in each layer.
The point of the present invention that a "high-quality decompressed image that is closest to the image size designated by the user and can be obtained at high speed and with a small memory capacity" can be applied as it is. Therefore, claim 1
According to the inventions 2, 13, 14, and 15, an expanded image having the highest image quality which is closest to the image size designated by the user can be obtained. According to the twelfth aspect, a bitmap image having higher image quality, high speed, and memory saving can be obtained as compared with a method of performing subsampling after decompression over all layers.
According to the thirteenth aspect, not only a required memory is reduced, but also high-speed decompression is possible. According to the fourteenth aspect, an image larger than the size specified by the user is obtained. According to the fifteenth aspect, a high-quality bitmap image without deterioration in image quality due to zooming can be obtained.

In addition to these, in the invention of claim 16,
It is possible to completely match the image size specified by the user. Further, the image quality and the expansion speed are described in claim 17.
According to the invention, expansion can be performed at higher speed and with less memory than the inventions of claims 18 and 19. The inventions of claims 18 and 19 can achieve higher image quality expansion than the invention of claim 17. It has an excellent feature.

According to the above description of the operation, a reduced bitmap image of high image quality and memory saving close to the size specified by the user or a size close to that specified by the user is rapidly expanded from the wavelet transform or subband transform code.

[Brief description of the drawings]

FIG. 1 is a diagram showing a configuration when the present invention is applied to a hierarchical wavelet transform coding scheme.

FIG. 2 is a diagram showing a configuration of a hierarchical subband transform coding system according to the present invention.

[Explanation of symbols]

1 ... image size designation means, 2 ... designated image size,
3: Wavelet transform coefficient, 4: Upper hierarchy (i + 1)
5: Wavelet transform coefficient of the immediately lower layer (i), 6: Expanded image, 7: Magnification specifying unit, 8: Magnification unit, 9: Interpolation specifying unit, 10: Interpolation unit, 11 ... Bitmap image, 12: Subband conversion coefficient, 13: Subband conversion coefficient of the immediately upper layer (i + 1), 14: Subband conversion coefficient of the immediately lower layer (i).

Claims (19)

[Claims] 1. An image decompression method for obtaining a decompressed image from an encoded image, comprising: an image size specifying means, a hierarchical number specifying means, a memory for storing a hierarchical wavelet transform coefficient, and a buffer memory. Image decompression means for decompressing an image from the hierarchical wavelet-transformed code, and specifying the size (length × width) of the decompressed image when the hierarchical wavelet-transformed code is irreversibly expanded. An image decompression method characterized in that it is determined by the size of the wavelet transform coefficient of the hierarchy closest to the size. 2. An image decompression method for obtaining a decompressed image from an encoded image, comprising: an image size specifying means, a hierarchical number specifying means, a memory for storing a hierarchical wavelet transform coefficient, and a buffer memory. Image decompression means for decompressing an image from the hierarchical wavelet-transformed code, and decompressing the size (vertical × horizontal) of the decompressed image when the hierarchical wavelet-transformed code is image-expanded,
+1) An image decompression method characterized by determining the size of the wavelet transform coefficient. 3. An image decompression method for obtaining a decompressed image from an encoded image, comprising: an image size specifying means, a hierarchical number specifying means, a memory for storing a hierarchical wavelet transform coefficient, and a buffer memory. Image decompression means for decompressing an image from the hierarchical wavelet-transformed code, and decompressing the size (length × width) of the decompressed image when the image subjected to the hierarchical wavelet-transformed code is decompressed. An image decompression method characterized by determining the size of a wavelet transform coefficient. 4. The image decompression method according to claim 2, wherein the decompressed image is directly used as a decompressed image without scaling. 5. The image processing apparatus according to claim 2, further comprising scaling means for specifying the presence or absence of scaling, and scaling means for scaling the image to a user-specified image size. Image expansion method. 6. The method according to claim 4, wherein the compression / decompression of the image is performed.
JPEG2000 Image Coding System (ISO / IEC FCD 15444-1)
An image decompression method characterized in that the image decompression method is performed by applying a code stream encoded according to the method defined in (1). 7. The image decompression method according to claim 5, further comprising an interpolation presence / absence designation means, wherein when scaling is performed, pixels not in the decompressed image are not assigned to the bitmap image. 8. The method according to claim 7, wherein the compression / decompression of the image is performed.
JPEG2000 Image Coding System (ISO / IEC FCD 15444-1)
An image decompression method characterized in that the image decompression method is performed by applying the method to a code stream encoded according to the method defined in (1). 9. The image processing apparatus according to claim 5, further comprising an interpolation unit and an interpolation presence / absence designating unit, wherein a pixel not present in the expanded image is linearly interpolated at the time of scaling to generate a bitmap image. Image extension method. 10. An image processing apparatus according to claim 5, further comprising an interpolation unit and an interpolation designation unit, wherein, when scaling (reducing), a pixel having a shortest pixel distance among a plurality of pixels in the expanded image. An image decompression method characterized by generating a bitmap image using a value as a representative value. 11. The method according to claim 9, wherein the image compression / decompression is performed using a JPEG2000 Image Coding System (ISO / IEC FCD).
15444-1) An image decompression method characterized by being applied to a code stream encoded according to the method specified in 15444-1). 12. An image decompression method for obtaining an expanded image from an encoded image, comprising: an image size specifying unit;
A layer number specifying unit, a memory for storing a subband conversion coefficient, a buffer memory, and an image decompression unit for decompressing the image from the subband-converted code, and An image decompression method characterized in that the size (length × width) of the decompressed image is determined by the size of the subband conversion coefficient of the layer closest to the designated image size. 13. An image decompression method for obtaining an expanded image from an encoded image, comprising: an image size specifying unit;
A layer number specifying unit, a memory for storing a subband conversion coefficient, a buffer memory, and an image decompression unit for decompressing the image from the subband-converted code, and An image expansion method characterized in that the size (length × width) of an expanded image is determined by the size of the subband coefficient of the immediately upper layer (i + 1). 14. An image decompression method for obtaining an expanded image from an encoded image, comprising: an image size specifying unit;
A layer number specifying unit, a memory for storing a subband conversion coefficient, a buffer memory, and an image decompression unit for decompressing the image from the subband-converted code, and An image decompression method characterized in that the size (length × width) of the decompressed image is determined by the size of the subband coefficient of the immediately lower layer (i). 15. The method according to claim 13, further comprising:
An image decompression method, comprising: means for specifying the presence or absence of scaling, wherein the decompressed image is directly used as a decompressed image without scaling. 16. The method according to claim 13, further comprising:
An image decompression method comprising: means for scaling to an image size designated by a user; and means for designating whether or not to scale, and converting the image size to an image size designated by the user. 17. An image decompression method according to claim 16, further comprising a scaling presence / absence designation means, wherein pixels which are not included in the decompressed image at the time of resizing are not assigned to a bitmap image. 18. An image decompression method according to claim 16, further comprising means for designating interpolation presence / absence, wherein a bitmap image is generated by linearly interpolating pixels not present in the decompressed image when scaling. . 19. A bitmap image according to claim 16, wherein a value of a pixel having the shortest pixel distance among a plurality of pixels in the expanded image is generated as a representative value when scaling (reducing). Image extension method.