JP2003283807A - Image processing method, apparatus and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To perform frequency processing to obtain a constant visual effect regardless of the output resolution of an image. <P>SOLUTION: Luminance image data Y1 are obtained from image data S0 and the luminance image data are converted to have an intermediate resolution higher than an assumed reference resolution by a sharpness processing means 5. Luminance image data Y1 of the intermediate resolution are subjected to wavelet transform so that a resolution in a bottom frequency band becomes the reference resolution. Sharpness processing assumed with the reference resolution is applied to bottom frequency band image data YsN, inverse wavelet transform is performed by using bottom frequency band image data YsN' after processing, the resolution of luminance image data Y2 after inverse wavelet transform is converted to an output resolution and further, color conversion is performed into RGB color space to obtain processed image data S1. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image processing method and apparatus for performing frequency processing on image data to obtain processed image data, and a program for causing a computer to execute the image processing method.

[0002]

2. Description of the Related Art The applicant of the present invention has proposed various frequency processing methods for improving sharpness of an image by performing sharpness processing using non-sharp mask image data (hereinafter referred to as blurred image data). Kaisho 55-163472, 55-
87953, JP-A-3-222577, 10-75395, 10-7536
No. 4, 10-171983, etc.). In this frequency processing method, for example, a predetermined spatial frequency component of image data is emphasized by adding to the image data Sorg a product of the original image data Sorg minus the blurred image data Sus multiplied by the emphasis degree β. This is a method of performing the processing. This can be expressed by the following formula (1). Sproc = Sorg + β × (Sorg−Sus) (1) However, Sproc: processed image data Sorg: original image data Sus: blurred image data β: enhancement degree ● The blurred image data Sus is a blurred mask for the image data Sorg. It is obtained by applying the filtering process used. Here, the blur mask is 3 × 3 or 5 × 5.
As described above, a filter that performs a two-dimensional filtering process on the image data Sorg is used. Since the frequency characteristics of the image differ depending on the resolution at which the processed image data is reproduced, the size of the blur mask is set according to the resolution of the image at which the processed image data is reproduced.

Here, the visual effect that a reproduced image gives to a viewer can be considered as a product of the frequency characteristic and the visual characteristic of the reproduced image. The frequency processing method described above is a method of controlling the frequency characteristic that affects the visual effect of the reproduced image on the viewer. The frequency characteristic can be expressed by setting the frequency on a predetermined scale on the horizontal axis and plotting the response at each frequency on the vertical axis.

By the way, since the size of one pixel on an image differs when the resolution when reproducing the image is different, the scale of the frequency characteristic of the reproduced image on the horizontal axis is different, and as a result, The visual effect obtained by multiplying the visual characteristics is also different.

For example, a printer with a resolution of 600 dpi (hereinafter referred to as a 600 dpi printer) and a printer with a resolution of 300 dpi (hereinafter referred to as a 300 dpi printer)
And, the size of one pixel is twice as large in a 300 dpi printer as in a 600 dpi printer. Therefore, the horizontal axis scale of the frequency characteristic is 6 for the 300 dpi printer.
1/2 of that of a 00 dpi printer, resulting in 300d
The visual effect given to the viewer by the image obtained by the pi printer is different from the visual effect given by the image obtained by the 600 dpi printer.

FIG. 7 is a diagram showing the visual characteristics with respect to the luminance and the color difference when the observation distance is 30 cm. The horizontal axis is the frequency and the vertical axis is the degree of contrast perception, that is, the visual sensitivity. The solid line indicates the luminance characteristic and the broken line indicates the color difference characteristic. As shown by the solid line in FIG. 7, when the observation distance is 30 cm, there is a peak of visual sensitivity in the vicinity of 1 cycle / mm, and the visual sensitivity decreases at frequencies higher than that. Therefore, when reproducing an image, it is preferable to emphasize the frequency band corresponding to the vicinity of 1 cycle / mm.

However, the pixel size of the 300 dpi printer is twice as large as that of the 600 dpi printer.
The information equivalent to 1 cycle / mm in the dpi printer is
This corresponds to 2 cycle / mm in a 600 dpi printer. Therefore, the image data that has been subjected to frequency processing suitable for reproducing an image on a 300 dpi printer is
When printed out by a 00 dpi printer, in the obtained image, the emphasized frequency band and the peak of visual sensitivity are deviated from each other, and an appropriate visual effect can be given to a viewer of the reproduced image. It's gone.

Therefore, in order to reproduce an image that produces the optimum visual effect in consideration of the visual characteristics, reproduction is performed when the frequency processing parameters (specifically, the size of the blur mask, the degree of emphasis, etc.) are set. You need to know the resolution of time.

[0009]

If the resolution at the time of reproducing the image is known, the frequency processing parameter is set by taking this and visual characteristics into consideration, and frequency processing is performed on the image data. It is possible to obtain processed image data capable of reproducing an image having an optimum visual effect. In other words, the frequency processing parameter is a specific resolution (reference resolution) where the image data to be frequency processed has a certain resolution.
It can be said that it is set on the premise that it will be reproduced in. Therefore, if the processed image data is reproduced at a different resolution (referred to as the output resolution) from the reference resolution, the reproduced image can give the optimum visual effect to the viewer. It's gone.

Therefore, the image data is scaled up and down to the reference resolution, the resolution is converted, frequency processing is performed, and resolution conversion by scaling is performed to the output resolution after the frequency processing to process the processed image data. It is possible to get it. However, especially when the reference resolution is smaller than the output resolution, there is a problem that the high frequency information included in the original image is lost by the reduction process.

The present invention has been made in view of the above circumstances, and obtains a processed image that can provide the same visual effect as that when frequency processing is performed on an image of the reference resolution regardless of the output resolution. As described above, it is intended to perform frequency processing.

[0012]

A first image processing method according to the present invention is an image processing method for obtaining processed image data by subjecting image data to a reference frequency process adapted to a reference resolution. When obtaining the processed image data from the high resolution image data having a higher output resolution, the resolution of the high resolution image data is converted to obtain enlarged image data having an intermediate resolution higher than the output resolution, and the enlarged image is obtained. The lowest resolution image data that has been processed by performing the reference frequency process on the lowest resolution multiresolution image data by subjecting the data to the multiresolution conversion so that the lowest resolution becomes the reference resolution. The processed lowest resolution image data and the other multiresolution image data other than this are subjected to demultiplexing resolution conversion and demultiplexing. Give Zodo converted image data, the inverse multi-resolution transform image data to resolution conversion such that the output resolution, and is characterized in that to obtain the processed image data of the output resolution.

In the first image processing method according to the present invention, it is preferable that the intermediate resolution is 2 ⁿ times the reference resolution (n: an integer of 0 or more).

"Resolution" refers to the resolution when the image data is reproduced. When "resolution of image data" is mentioned, it means the image data on the premise that reproduction is performed at that resolution. For example, in the case of image data of 300 dpi, it means image data that is premised on reproduction at a resolution of 300 dpi.

Converting the resolution of image data means converting image data that is supposed to be reproduced at a certain resolution into image data that is supposed to be reproduced at another resolution. For example, converting the resolution of image data from 300 dpi to 600 dpi means that when the size of the image data is 300 × 600 dots,
It means enlarging the size of image data to 600 × 1200 dots so that the resolution when reproduced with the same reproduction size is doubled.

“Reference frequency processing adapted to reference resolution”
The term “frequency processing” refers to frequency processing that can give an optimum visual effect to a viewer of a processed image when the processed image is reproduced at the reference resolution.

Known methods for multiresolution conversion include wavelet transform, Laplacian pyramid, Fourier transform and the like. In particular, the wavelet transform is one of the frequency analysis methods for signals, but it is superior to the Fourier transform, which is also widely used as a frequency analysis method, in that it is easy to detect local change information of signals. Therefore, it has been spotlighted in the field of all signal processing in recent years (OLIVIER RIOUL and MARTIN VETTERL
I; Wavelets and Signal Processing, IEEE SP MAGAZINE,
P.14-38, OCTOBER 1991, Stephane Mallat; Zero-Crossin
gs of a Wavelet Transform, IEEE TRANSACTIONS ON I
NFORMATION THEORY, VOL.37, NO.4, P.1019-1033, JULY 199
1, JP-A-6-274614, 6-350989, 6-350990,
7-23228, 7-23229, 7-79350, etc.).

A second image processing method according to the present invention is an image processing method for obtaining processed image data by subjecting image data to a reference frequency process adapted to a reference resolution, wherein the output resolution is higher than the reference resolution. When obtaining the processed image data from the high-resolution image data, the high-resolution image data is subjected to multi-resolution conversion so that the lowest resolution becomes the reference resolution to obtain multi-resolution image data, and the lowest-resolution multi-resolution image data. Against
The processed minimum resolution image data is obtained by performing the reference frequency processing, and the processed minimum resolution image data and the other multiresolution image data are inversely multiresolution converted to obtain the processed image data of the output resolution. It is characterized by that.

A first image processing apparatus according to the present invention is an image processing apparatus which obtains processed image data by subjecting image data to a reference frequency process adapted to the reference resolution, and having an output resolution higher than the reference resolution. When obtaining the processed image data from the high resolution image data, the resolution of the high resolution image data is converted so as to obtain the enlarged image data having an intermediate resolution higher than the output resolution, and the enlarged image data. A multi-resolution conversion means for performing multi-resolution conversion to obtain multi-resolution image data so that the lowest resolution becomes the reference resolution, and the reference frequency processing has been performed on the lowest resolution multi-resolution image data. Frequency processing means for obtaining the lowest resolution image data, the processed lowest resolution image data and the other Demultiplexing resolution conversion means for demultiplexing the resolution image data to obtain demultiplexing resolution converted image data; and converting the demultiplexing resolution converted image data to have the output resolution, And output resolution conversion means for obtaining processed image data.

The first image processing apparatus according to the present invention preferably further comprises intermediate resolution setting means for setting the intermediate resolution to 2 ⁿ times the reference resolution (n: an integer of 0 or more). .

A second image processing apparatus according to the present invention is an image processing apparatus which obtains processed image data by subjecting image data to a reference frequency process adapted to the reference resolution, and having an output resolution higher than the reference resolution. When obtaining the processed image data from the high resolution image data, multiresolution conversion means for performing multiresolution conversion of the high resolution image data so that the minimum resolution becomes the reference resolution to obtain multiresolution image data, and the minimum resolution. Frequency processing means for performing the reference frequency processing on the multi-resolution image data to obtain processed lowest resolution image data, and the processed multi-resolution image data and the other multi-resolution image data are subjected to inverse multi-resolution conversion. And inverse multi-resolution conversion means for obtaining the processed image data having the output resolution. It is an feature.

The first and second image processing methods according to the present invention may be provided as a program for causing a computer to execute.

[0023]

According to the first image processing method and apparatus of the present invention, when image data is output, the reference frequency processing adapted to the reference resolution is applied to the image data to obtain processed image data. It is assumed that. And
When obtaining processed image data from high-resolution image data having an output resolution higher than the reference resolution, first, the resolution of the high-resolution image data is converted to an intermediate resolution higher than the output resolution, and enlarged image data is obtained. And
The enlarged image data is subjected to multi-resolution conversion by wavelet transformation or the like to obtain multi-resolution image data. In addition,
Multi-resolution conversion is performed so that the lowest resolution becomes the reference resolution. Next, reference frequency processing is performed on the lowest resolution multi-resolution image data to obtain processed lowest resolution image data. After that, the processed lowest resolution image data and the other multiresolution image data are subjected to inverse multiresolution conversion to obtain inverse multiresolution image data,
The resolution is converted so as to become the output resolution, and processed image data having the output resolution is obtained.

As described above, in the first image processing method and apparatus according to the present invention, the lowest resolution image data of the reference resolution is obtained by the multi-resolution conversion, and the lowest frequency image data is subjected to the reference frequency processing. Therefore, regardless of the output resolution of the image data to be processed, the processed lowest resolution image data is subjected to frequency processing so as to obtain an optimum visual effect. Therefore, even if the resolution of the image data for obtaining the processed image data is different from the reference resolution, it is possible to obtain the processed image data capable of giving the viewer the visual effect expected by the reference frequency processing.

Further, since the resolution of the image data is converted to an intermediate resolution higher than the output resolution before the multi-resolution conversion, the high frequency information contained in the high resolution image data is not lost. . Therefore, it is possible to obtain processed image data capable of reproducing an image without loss of high-frequency information.

In particular, by setting the intermediate resolution to 2 ⁿ times the reference resolution (n: an integer of 0 or more), it is possible to facilitate the multi-resolution conversion with the lowest resolution as the reference resolution.

According to the second image processing method and apparatus of the present invention, similarly to the first image processing method and apparatus of the present invention, when outputting image data, the image data conforms to the reference resolution. It is premised that the processed image data is obtained by performing the reference frequency processing. Then, when obtaining the processed image data from the high resolution image data having an output resolution higher than the reference resolution, first, the high resolution image data is subjected to multi-resolution conversion by wavelet transformation or the like,
Multi-resolution image data is obtained. Note that the multi-resolution conversion is performed so that the lowest resolution becomes the reference resolution. Next, reference frequency processing is performed on the lowest resolution multi-resolution image data to obtain processed lowest resolution image data. Then, the processed lowest resolution image data and the other multiresolution image data are subjected to inverse multiresolution conversion to obtain processed image data of output resolution.

As described above, in the second image processing method and apparatus according to the present invention, the lowest resolution image data of the reference resolution is obtained by the multi-resolution conversion, and the lowest frequency image data is subjected to the reference frequency processing. Therefore, regardless of the output resolution of the image data to be processed, the processed lowest resolution image data is subjected to frequency processing so as to obtain an optimum visual effect. Therefore, even if the resolution of the image data for obtaining the processed image data is different from the reference resolution, it is possible to obtain the processed image data capable of giving the viewer the visual effect expected by the reference frequency processing.

[0029]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic block diagram showing the configuration of an image processing apparatus according to an embodiment of the present invention. Figure 1
As shown in FIG. 3, the image processing apparatus according to the present embodiment performs sharpness processing on image data S0 composed of color data R0, G0, B0 of RGB three colors on the assumption that the image data is output at a predetermined output resolution. Yes, image data S
A brightness conversion unit 1 for converting 0 into brightness image data Y, an intermediate resolution conversion unit 2 for converting the brightness image data Y into brightness image data Y1 of intermediate resolution, and an intermediate resolution setting for setting the intermediate resolution based on the output resolution. Means 3, wavelet transform means 4 for wavelet transforming the luminance image data Y1 to obtain band image data Ysn (n = 0 to N, N: lowest frequency band) consisting of a plurality of frequency bands, and a band image of the lowest frequency band. The lowest frequency band image data Y that has been processed by performing sharpness processing on the data YsN
sharpness processing means 5 for obtaining sN ′, processed lowest frequency band image data YsN ′ and band image data Y
inverse wavelet transform of sn (n = 0 to N-1),
Inverse wavelet transform means 6 for obtaining the intermediate luminance image data Y2 that has undergone inverse wavelet transformation, and output luminance image data Y3 by converting the intermediate luminance image data Y2 into output resolution.
Output resolution conversion means 7 for obtaining the output brightness image data Y
3 and RGB conversion means 8 for obtaining the processed image data S1 based on the color data R0, G0, B0.

In the present embodiment, the image data S
The output resolution of 0 is 450 dpi, and its size is 6
It is assumed that the size is 00 × 1200 dots. As will be described later, the reference resolution of the sharpness processing performed by the sharpness processing means 5 is 300 dpi.

The brightness conversion means 1 converts the color data R0, G0, B0 forming the image data 0 into the brightness image data Y by the following equation (2). Y = 0.3 × R0 + 0.59 × G0 + 0.11 × B0 (2) The intermediate resolution conversion means 2 converts the resolution of the luminance image data Y into the luminance image data Y1 of the intermediate resolution.

The intermediate resolution setting means 3 sets the intermediate resolution based on the output resolution and the reference resolution. Here, the output resolution is input to the intermediate resolution setting means 3 when the image data S0 is input. Then, the intermediate resolution setting means 3 finds the minimum nmin that satisfies the relationship of output resolution ≦ reference resolution × 2 ⁿ (n: integer of 0 or more), and sets the intermediate resolution as follows: intermediate resolution = reference resolution × 2 ^nmin . In this embodiment,
Output resolution is 450 dpi, standard resolution is 300 dpi
Therefore, n = 1, and as a result, the intermediate resolution is 600.
is set to dpi.

Therefore, in the intermediate resolution conversion means 2, the resolution of the luminance image data Y1 is converted so as to have an intermediate resolution of 600 dpi. As a result, the size of the luminance image data Y1 is from 600 × 1200 dots to 8
This is 00 × 1600 dots.

The wavelet transforming means 4 performs wavelet transform on the luminance image data Y1 as follows. First, as shown in FIG. 2A, the luminance image data Y1 is wavelet transformed to obtain the luminance image data Y1.
Data LL1, HL having a resolution of 1/2
It is decomposed into 0, LHO and HHO. Here, the data LL1 is obtained by reducing the vertical and horizontal sizes of the image represented by the luminance image data Y1 to 1/2, that is, the resolution is 1/2.
Data, and the data HL0, LH0, and HH0 represent images of vertical edge, horizontal edge, and diagonal edge components, respectively. Then, as shown in FIG. 2B, the data LL1 is further wavelet transformed to obtain four data LL2, HL1, LH1 and HH1. Here, the data LL2 represents an image in which the vertical and horizontal sizes of the data LL1 are further reduced to 1/2, that is, an image whose resolution is 1/4 of the luminance image data Y1.
1, LH1 and HH1 represent images of vertical edge, horizontal edge and diagonal edge components of the data LL1, respectively. Then, the wavelet transform is repeated the desired number of times for the data LL obtained each time the wavelet transform is performed to obtain data for each of a plurality of resolutions. In the present embodiment, the individual
That is, the data of each frequency band is converted to the band image data Ysn.
(N = 1 to N).

Here, in the present embodiment, the wavelet transform is performed so that the resolution of the band image data YsN in the lowest frequency band matches the reference resolution. Therefore, the wavelet transform is performed once on the luminance image data Y1, and the size of the lowest frequency band image data YsN is 400 × 800 dots.

The sharpness processing means 5 performs sharpness processing on the lowest frequency band image data YsN.
Here, in the sharpness processing means 5, the image is
Sharpness processing is performed so that the visual effect of the processed image is optimized, assuming that the image is output at a resolution of 00 dpi. The resolution of the sharpness processing assumed by the sharpness processing means 5 becomes the reference resolution. In the sharpness processing means 5, specifically, the sharpness processing is performed as shown in the following formula (3). YsN ′ = YsN + β × (YsN−YsNus) (3) However, YsN ′: processed lowest frequency band image data YsNus: blurred image data β: emphasis degree. It is obtained by performing a filtering process using a blur mask. Here, as the blur mask, a filter that two-dimensionally performs filtering processing on the lowest frequency band image data YsN, such as 3 × 3 or 5 × 5, is used. It should be noted that the size and the degree of enhancement of the blur mask are set so as to match the reference resolution.

The inverse wavelet transforming means 6 inversely wavelet transforms the processed lowest frequency band image data YsN 'and the band image data Ysn (n = 0 to N-1) to obtain the inverse wavelet transformed intermediate luminance image data Y.
Get 2. Here, the resolution of the intermediate luminance image data Y2 is the same as the resolution of the luminance image data Y1, and the image size thereof is 800 × 1600 like the luminance image data Y1.
It becomes a dot.

The output resolution converting means 7 converts the resolution of the intermediate luminance image data Y2 into the output resolution. Here, since the output resolution is 450 dpi, 450 dpi
The resolution of the intermediate-luminance image data Y2 is converted so that the resolution becomes. As a result, the size of the output luminance image data Y3 is 600 × 1200 dots.

The RGB conversion means 8 outputs the output luminance image data Y3 and the color data R0, G according to the following equation (4).
Based on 0, B0, RGB color data R1, G1,
The processed image data S1 including B1 is acquired. R1 = R0 + (Y3-Y) G1 = G0 + (Y3-Y) B1 = B0 + (Y3-Y) (4) Next, the operation of the present embodiment will be described. FIG. 3 is a flowchart showing the operation of this embodiment. First, the input of the image data S0 and the output resolution is accepted (step S1), and the brightness conversion means 1 converts the image data S0 into the brightness image data Y (step S1).
2). Then, the intermediate resolution setting means 3 sets the intermediate resolution based on the output resolution and the reference resolution (step S3), and the intermediate resolution converting means 2 converts the resolution of the luminance image data Y to the intermediate resolution to obtain the luminance of the intermediate resolution. Image data Y1 is obtained (step S
4).

The luminance image data Y1 is wavelet-transformed by the wavelet transformation means 4 so that the resolution of the image data YsN in the lowest frequency band becomes the reference resolution, and band image data Ysn is obtained (step S).
5). The sharpness processing means 5 performs sharpness processing on the lowest frequency band image data YsN assuming a reference resolution to obtain processed lowest frequency band image data YsN '(step S6). The processed lowest frequency band image data YsN ′ is inverse wavelet-transformed by the inverse wavelet transforming unit 6 together with the band image data Ysn of the other frequency band to obtain the intermediate luminance image data Y2 which has been inverse wavelet transformed (step S7). .

The intermediate luminance image data Y2 is converted into the output resolution by the output resolution converting means 7, and the output luminance image data Y3 is obtained (step S8). The output brightness image data Y3 and the color data R0, G0, B0 are color data R1, G1, B of RGB three colors in the RGB conversion means 8.
The processed image data S1 consisting of 1 is converted (step S9), and the process ends. The processed image data S1 is printed out at a resolution of 450 dpi.

The transition of the data size in this embodiment is shown in FIG.

As described above, in the present embodiment, the lowest frequency band image data YsN of the reference resolution is obtained by the wavelet transform, and the sharpness processing assuming the reference resolution is performed on the lowest resolution image data YsN. Regardless of the output resolution of the image data S0, the processed lowest resolution image data YsN 'is subjected to sharpness processing so as to obtain an optimum visual effect. Therefore, even if the output resolution of the image data S0 is different from the reference resolution assumed by the sharpness processing, it is possible to obtain the processed image data S1 capable of giving the viewer the visual effect assumed by the reference sharpness processing. it can.

Further, before the wavelet transform, the resolution of the luminance image data Y is converted so as to have an intermediate resolution higher than the output resolution, so that the high frequency information contained in the luminance image data Y may be lost. Disappear. Therefore, the processed image data S1 without loss of high-frequency information
Can be obtained.

In particular, by setting the intermediate resolution to 2 ⁿ times the reference resolution (n: an integer of 0 or more), it is possible to facilitate the wavelet transform conversion with the lowest resolution as the reference resolution.

Although the output resolution is 450 dpi and the reference resolution is 300 dpi in the above embodiment, the output resolution is 600 dpi and the reference resolution is 300 dpi.
In the case of dpi, the data size changes as shown in FIG. In this case, since the output resolution and the intermediate resolution are the same, conversion to the intermediate resolution and conversion to the output resolution are unnecessary. That is, the brightness image data Y is used as it is as the brightness image data Y1, and the intermediate brightness image data Y2 is used as it is as the output brightness image data Y3. Therefore, the processed image data S1 can be obtained without performing the processing in the intermediate resolution conversion means 2 and the output resolution conversion means 7.

When the output resolution is 600 dpi and the reference resolution is 300 dpi, as shown in FIG. 6, the image processing apparatus shown in FIG. 1 has an intermediate resolution converting means 2 and an intermediate resolution setting means 3 in the image processing apparatus. The output resolution converting means 7 may be omitted.

In the above embodiment, the luminance image data Y1 is converted into the band image data Ysn by the wavelet transform. However, the luminance image data Y1 is converted by a method such as Laplacian pyramid or Fourier transform.
May be converted into band image data Ysn.

[Brief description of drawings]

FIG. 1 is a schematic block diagram showing the configuration of an image processing apparatus according to an embodiment of the present invention.

FIG. 2 is a diagram for explaining a wavelet transform.

FIG. 3 is a flowchart showing the operation of this embodiment.

FIG. 4 is a diagram (1) showing changes in image data size.

FIG. 5 is a diagram showing changes in image data size (No. 1)

FIG. 6 is a schematic block diagram showing the configuration of an image processing apparatus according to another embodiment of the present invention.

FIG. 7 is a diagram for explaining frequency characteristics.

[Explanation of symbols]

1 Luminance conversion means 2 Intermediate resolution conversion means 3 Intermediate resolution setting means 4 Wavelet transforming means 5 Sharpness processing means 6 Inverse wavelet transform means 7 Output resolution conversion means 8 RGB conversion means

   ─────────────────────────────────────────────────── ─── Continued front page    F-term (reference) 5B057 CA01 CA08 CA12 CA16 CB01                       CB08 CB12 CB16 CD06 CD10                       CE03 CE06 CE18                 5C076 AA21 AA22 AA31 BA06 CB04                       CB05                 5C077 LL04 LL19 MP01 PP03 PP49                       PQ08 PQ12 TT02

Claims (9)

[Claims] 1. An image processing method for obtaining processed image data by subjecting image data to a reference frequency process adapted to a reference resolution, wherein the processed image is processed from high resolution image data having an output resolution higher than the reference resolution. When obtaining the data, the resolution of the high resolution image data is converted to obtain enlarged image data having an intermediate resolution higher than the output resolution, and the enlarged image data is multi-resolution so that the minimum resolution becomes the reference resolution. The converted multi-resolution image data is obtained, the reference frequency processing is performed on the multi-resolution image data of the minimum resolution to obtain processed minimum resolution image data, and the processed minimum resolution image data and the other Inverse multiresolution image data is obtained by performing inverse multiresolution conversion on the multiresolution image data. Data resolution conversion so that the output resolution, the image processing method characterized by obtaining the processed image data of the output resolution. 2. The intermediate resolution is 2 of the reference resolution.
The image processing method according to claim 1, wherein the number is ⁿ times (n: an integer of 0 or more). 3. An image processing method for obtaining processed image data by subjecting image data to a reference frequency process adapted to a reference resolution, wherein the processed image is processed from high resolution image data having an output resolution higher than the reference resolution. When obtaining data, the high-resolution image data is subjected to multi-resolution conversion so that the lowest resolution becomes the reference resolution to obtain multi-resolution image data, and the reference frequency processing is performed on the lowest-resolution multi-resolution image data. And the processed minimum resolution image data is obtained, and the processed minimum resolution image data and the other multiresolution image data are subjected to inverse multiresolution conversion to obtain the processed image data of the output resolution. Image processing method. 4. An image processing apparatus for obtaining processed image data by subjecting image data to a reference frequency process adapted to a reference resolution, wherein the processed image is processed from high resolution image data having an output resolution higher than the reference resolution. When obtaining the data, an intermediate resolution conversion means for converting the resolution of the high resolution image data to obtain enlarged image data having an intermediate resolution higher than the output resolution, and the enlarged image data having a minimum resolution as the reference resolution. Multi-resolution conversion means for performing multi-resolution conversion to obtain multi-resolution image data, and frequency processing means for performing the reference frequency processing on the lowest-resolution multi-resolution image data to obtain processed lowest-resolution image data And demultiplexing the processed lowest resolution image data and the other multiresolution image data. Demultiplexing resolution converting means for converting to obtain demultiplexing resolution converted image data, and output for performing resolution conversion of the demultiplexing resolution converted image data to have the output resolution to obtain the processed image data having the output resolution An image processing apparatus comprising: a resolution conversion unit. 5. The intermediate resolution is 2 times the reference resolution.
The image processing apparatus according to claim 4, further comprising an intermediate resolution setting unit for setting ⁿ times (n: an integer of 0 or more). 6. An image processing apparatus for obtaining processed image data by subjecting image data to a reference frequency process adapted to a reference resolution, wherein the processed image is processed from high resolution image data having an output resolution higher than the reference resolution. When obtaining the data, a multi-resolution conversion unit that obtains multi-resolution image data by performing multi-resolution conversion on the high-resolution image data so that the lowest resolution becomes the reference resolution, and the multi-resolution image data of the lowest resolution, Frequency processing means for performing the reference frequency processing to obtain processed lowest resolution image data; and the processed minimum resolution image data and the other multiresolution image data subjected to inverse multiresolution conversion to obtain the processed output resolution. An image processing apparatus comprising: an inverse multi-resolution conversion means for obtaining image data. 7. A program for causing a computer to execute an image processing method of subjecting image data to a reference frequency process adapted to a reference resolution to obtain processed image data, the output resolution being higher than the reference resolution. When obtaining the processed image data from the resolution image data, the resolution of the high resolution image data is converted to obtain enlarged image data having an intermediate resolution higher than the output resolution, and the enlarged image data has the minimum resolution. To obtain the multi-resolution image data by performing multi-resolution conversion so as to be the reference resolution, and a step of performing the reference frequency processing on the multi-resolution image data of the lowest resolution to obtain processed lowest resolution image data. Demultiplexing the processed lowest resolution image data and the other multiresolution image data The procedure of obtaining the inverse multi-resolution converted image data by image resolution conversion, and the procedure of performing the resolution conversion of the inverse multi-resolution converted image data to the output resolution to obtain the processed image data of the output resolution. Program to have. 8. The intermediate resolution is 2 times the reference resolution.
The program according to claim 7, further comprising a step of setting ⁿ times (n: an integer of 0 or more). 9. A program for causing a computer to execute an image processing method for subjecting image data to a reference frequency process adapted to a reference resolution to obtain processed image data, the output resolution being higher than the reference resolution. When obtaining the processed image data from the resolution image data, a procedure for obtaining multiresolution image data by performing multiresolution conversion of the high resolution image data so that the minimum resolution becomes the reference resolution, and the multiresolution image of the minimum resolution. The procedure of performing the reference frequency processing on the data to obtain the processed lowest resolution image data, and the processed lowest resolution image data and the other multiresolution image data are subjected to inverse multiresolution conversion to obtain the output resolution. And a procedure for obtaining the processed image data.