JP2006078793A - Image processing method and apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image processing method and apparatus capable of reproducing appearance impression when the transparent image of a color reversal film is observed onto a photographic print, to provide an image forming apparatus using the image processing method and apparatus, and to provide a program and a recording medium for executing the image processing method. <P>SOLUTION: The image processing method includes: calculating a colorimetric value by acquiring the digital data of the transparent image of a color reversal film; acquiring the chromaticity information and illuminance information of a light source illuminating the transmission image being observed; subjecting the colorimetric value of the transparent image to at least contrast conversion or chroma conversion on the basis of a chromaticity value when an adaptation luminance higher than that obtained from the chromaticity information and illuminance information, thereby acquiring the converted colorimetric value; subjecting the converted colorimetric value to a color adaptation correction or a contrast correction on the basis of the chromaticity information and illuminance information; and correcting the converted colorimetric value subjected to the color adaptation correction and contrast correction, as a tristimulus value, from the amount of flare when the transparent image is outputted as a photographic print image. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an image processing method and an image processing apparatus for reproducing a transmission image of a color reversal film as a hard copy image (print image) on a photographic print (hereinafter also simply referred to as a print), an image forming apparatus using the same, and an image processing The present invention relates to an image processing program for executing the method and a recording medium recording the same, and more specifically, in addition to faithfully reproducing the appearance of the transmission image, particularly when outputting the transmission image of the color reversal film to a print. In addition, an image processing method and an image processing apparatus capable of performing conversion to values (brightness and saturation) that are preferable color reproduction common to various subjects and scenes, an image forming apparatus using the same, and an image processing The present invention relates to an image processing program for executing a method and a recording medium on which the program is recorded.

  In this specification, the term “subject” includes all subjects to be photographed that exist in the photographing scene photographed on the color reversal film (that is, not limited to only the main subject such as a person, including the background etc. The appearance of the image should also be referred to as an evaluation based on subjectivity of a large number of observers, and is a transmission image of a color reversal film under actual observation conditions, that is, as a transmission image. This is an evaluation index of many observers for the appearance of the subject image.

  In the field of photographic technology, the problem of how a subject (photographing scene) should be reproduced on a print has long been discussed. Regarding this problem, there is a situation that the way of thinking varies depending on the subject's content, shooting situation, region, culture, etc., so it is difficult to obtain a uniform answer, but the basic idea of photography is human (observer) It is preferable that the reproduction is close to the impression when the subject is viewed.

  For example, in Patent Document 1, from such a viewpoint, an image photographed with a color negative film is digitized, colorimetric information of a subject is obtained by digital signal processing, and the colorimetric values are reproduced on a print. Is disclosed. According to Patent Document 1, it is possible to faithfully reproduce the colorimetric value of the subject by reproducing the obtained colorimetric value as it is on the print.

On the other hand, the transmission image of the color reversal film can express vivid colors shined by high-luminance light from projectors and viewers, and can express subtle colors and abundant colors. It is observed in a viewer.
In addition, the transmission image of the color reversal film is also reproduced and observed as a photographic print (reflection image, hard copy image) in the same manner as the captured image of the color negative film.
As mentioned above, color reversal film can express abundant colors such as bright and subtle colors that are brighter than color negative film, so prints made from color reversal film can be used by professional photographers and photographers. Although it is used by experts (high amateurs), it is currently used less for general users than prints made from color negative films.

For this reason, in addition to color negative film, there are digital photo printers that can digitally process and output images shot on color reversal film. However, when printing from color reversal film, subtle colors and rich colors can be reproduced. The optical print (analog print) directly printed from the color reversal film is absolutely necessary, and the current situation is that the development of the print exceeding the optical print has not been performed. For this reason, in digital photo printers, it cannot be said that sufficient consideration has been given to the color reproduction unique to the transmission image of the color reversal film, and the print finish from the transmission image of the color reversal film is exclusively a print photosensitive material. The current situation depends on the performance of
In recent years, with high color saturation of color reversal films, color reproduction with high saturation has been demanded in optical printing.
JP-A-6-139323

By the way, after observing the transmission image of the color reversal film with a projector or a viewer, the user creates a photographic print that reproduces the transmission image. In other words, when a print is made from a color reversal film, the user is more likely to see the transmitted image of the color reversal film that is being observed by a projector, a viewer, or the like than the subject image when the subject is photographed on the color reversal film. Often, it is expected to be reproduced in the print.
However, photographic prints created based on the transmission images of color reversal films sold in the market faithfully reproduce the original gradation of the observed transmission images and the color reproduction characteristics of “shining beauty”. However, there is a problem that a user who expects reproduction of the original beauty of the transparent image on the print cannot be satisfied sufficiently. That is, it is difficult to say that a print produced based on a transmission image of a color reversal film is produced by an image processing method that reproduces an impression similar to that when a human (observer) sees the transmission image. There is a problem that it depends on the performance of the print photosensitive material.

  For this reason, at the photo print production site such as a lab shop, in order to match the appearance of the color reversal film transmission image and the print observed in the viewer, the operator uses digital reversal film images from digital reversal film images. The digital image data read by a scanner such as a printer is displayed on a display that matches the color of the printer output and its color, and the transmission image of the color reversal film displayed in the viewer is observed to output a hard copy printer for output. The digital image data is manually adjusted so that the display image on the color-adjusted display and the transparent image match, but adjustment is extremely difficult and extremely troublesome, especially for unskilled operators. The adjustment result is not always good There is a problem that does not become.

An object of the present invention is to solve the above-mentioned problems of the prior art and reproduce an impression of appearance when a human observes a transmission image of a color reversal film, that is, a transmission original image (transmission subject image) on a photographic print. In addition to this, the optimum values of brightness, contrast, and saturation enhancement common to various subjects and scenes are obtained from the reproduced image of the appearance of the transparent image, and the optimum center of the reproduced image of the appearance is obtained. An object of the present invention is to provide an image processing method and an image processing apparatus that can be set as performance, an image forming apparatus using the same, an image processing program for executing the image processing method, and a recording medium recording the same.
That is, the present invention obtains colorimetric information of an observed transmission image from a photographic print produced on the basis of the transmission image of a color reversal film, and uses the colorimetric values as they are or for contrast and color for further preferable reproduction. The object is to reproduce the original beauty of the transmission image on the print by producing the image with a degree of emphasis and reproducing it on the print.

  In order to achieve the above object, the present inventors have conducted intensive research, and as a result, in the case of a color negative film, a print created by the method described in Patent Document 1 is used as an original shooting scene (that is, Compared to (subject), in the case of color reversal film, the created print shows the appearance of the observed transmission image, as it may not actually reproduce the appearance of the shooting scene. It was found that was not reproduced. When we investigated under what circumstances such disparity in appearance occurred, it was found that the phenomenon of disagreement occurred in the following three cases.

That is,
1. If there is a difference between the absolute brightness of the observed transmission image and the absolute brightness when observing the print,
2. If the illumination color of the observed transmission image is different from the illumination color during print observation,
3. There are cases where there is an observation flare depending on the print observation environment.

  When the method for reproducing the colorimetric values in the conventional color negative film described in Patent Document 1 is applied to a color reversal film, the above-mentioned factors are not taken into account. Even if the color value can be accurately reproduced on the print, it has been found that the appearance of the observed transmission image has not been reproduced, and the present invention has been achieved.

  In other words, in order to achieve the above object, the first aspect of the present invention obtains digital data of a transmission image of a color reversal film, calculates a colorimetric value of the transmission image from the digital data, and is observed. Chromaticity when acquiring chromaticity information and illuminance information of a light source that illuminates a transmission image of the color reversal film, and setting the adaptive luminance higher than the adaptive luminance obtained from the acquired chromaticity information and illuminance information of the light source Based on the value, the colorimetric value of the transmission image is subjected to at least one of contrast conversion and saturation conversion to obtain the converted colorimetric value of the observed transmission image, and the chromaticity information and illuminance of the light source Chromatic adaptation correction is performed on the converted colorimetric value of the observed transmission image from the information, and the colorimetric correction value of the observed transmission image is converted from the illuminance information of the light source. Performing the trust correction, correcting the converted colorimetric value of the transmission image subjected to the color adaptation correction and the contrast correction from the flare amount when outputting the observed transmission image as a photographic print image, and outputting The present invention provides an image processing method characterized in that a colorimetric value to be obtained is obtained.

Here, in the contrast conversion, it is preferable to perform conversion corresponding to the observation illuminance of the transmission image of the color reversal film virtually in the range of 30,000 to 300,000 lux.
Further, in the saturation conversion, it is preferable that the increase ratio of saturation is 1.0 to 1.2 times, and the observation illuminance of the transmission image of the color reversal film is 30,000 to 300,000 lux. .
Further, in the saturation conversion, as an optimum value, the increase ratio of saturation is in the range of 1.0 to 1.05 times, and the observation illuminance of the transmission image of the color reversal film is 50,000 to 200,000. A range of looks is preferred.
It is preferable that the chromaticity value when it is set to an adaptation brightness higher than the adaptation brightness obtained from the chromaticity information and the illuminance information of the light source is a chromaticity value when it is assumed that the adaptation to the light source is completely or almost adapted. .

The enhancement parameter set in at least one of the contrast conversion and the saturation conversion is preferably at least one of a luminance ratio, a saturation, a contrast, and colorfulness.
The colorimetric value is preferably a tristimulus value.
In addition, at least one of the contrast conversion and the saturation conversion, the chromatic adaptation correction, the contrast correction, and the flare amount correction should output the colorimetric value of the transmissive image from the colorimetric value of the transmissive image. It is preferably created as a three-dimensional color conversion table for conversion to colorimetric values.
Further, it is preferable to add color conversion that changes a part of the three-dimensional color conversion table.
Further, the three-dimensional color conversion table is a color conversion three-dimensional lookup table, and is obtained by obtaining a distance from a color to be corrected for color to a lattice point of the three-dimensional lookup table in a color space. The three-dimensional color conversion table is obtained by obtaining a conversion amount of the lattice points necessary for converting the target color into a target desired color according to the distance, and correcting the three-dimensional lookup table. It is preferable to add color conversion that changes a part of.

Further, it is preferable that the chromaticity information and illuminance information of the light source are obtained by actually performing measurement with a measuring instrument.
Moreover, it is preferable that the illuminance information of the light source is acquired by performing estimation from a photometric value of an environment in which the transmission image is observed.
Moreover, it is preferable that the chromaticity information of the light source is acquired by performing estimation from a white point or average chromaticity in the observed transmission image.
Furthermore, it is preferable that a flare rate at the time of observing the hard copy image (print image) is acquired in advance, and the flare amount according to the observation environment is corrected using the acquired flare rate.

  In order to achieve the above object, according to the second aspect of the present invention, a transmission image of a color reversal film is photoelectrically read to obtain digital data of the transmission image, and the transmission data is obtained from the digital data. Imaging means for calculating a colorimetric value, acquisition means for acquiring chromaticity information and illuminance information of a light source that illuminates the observed transmission image of the color reversal film, and acquired chromaticity information and illuminance information of the light source And performing at least one of contrast conversion and saturation conversion on the colorimetric value of the observed transmission image based on the chromaticity value when the adaptation luminance is set higher than the adaptation luminance calculated from Conversion means for obtaining a converted colorimetric value, and chromatic adaptation correction for the converted colorimetric value of the observed transmission image from the acquired chromaticity information and illuminance information of the light source Chromatic adaptation correcting means to perform, contrast correcting means to perform contrast correction on the converted colorimetric value of the observed transmission image from the illuminance information of the light source, and an observation environment of the photographic print image of the observed transmission image A flare correction unit that corrects a flare amount corresponding to the converted colorimetric value of the observed transmission image subjected to the chromatic adaptation correction and the contrast correction. It is to provide.

Here, the conversion means preferably performs conversion corresponding to the fact that the observation illuminance of the transmission image of the color reversal film is virtually in the range of 30,000 to 300,000 lux as the contrast conversion. .
Further, the conversion means has a saturation increase ratio of 1.0 to 1.2 times as the saturation conversion, and an observation illuminance of the transmission image of the color reversal film is 30,000 to 300,000 lux. It is preferable to perform the conversion as follows.
Further, the conversion means has an increase ratio of saturation of 1.0 to 1.05 times as an optimum value of the saturation conversion, and an observation illuminance of the transmission image of the color reversal film is 50,000. It is preferred to perform the conversion in the range of ~ 200,000 looks.
In addition, the chromaticity value when the adaptation brightness is set higher than the adaptation brightness obtained from the chromaticity information and the illuminance information of the light source is a chromaticity value when it is assumed that the adaptation is completely or almost adapted to the light source. Is preferred.
The enhancement parameter set in at least one of the contrast conversion and the saturation conversion is preferably at least one of a luminance ratio, a saturation, a contrast, and colorfulness.
The colorimetric value is preferably a tristimulus value.

Moreover, it is preferable that the said acquisition means is a measuring device which actually measures the chromaticity and illumination intensity of the said light source.
Moreover, it is preferable that the said acquisition means acquires the illuminance information of the said light source by estimating from the photometric value of the observation environment of the said transmission image.
Moreover, it is preferable that the said acquisition means acquires the illuminance information of the said light source by estimating from the white point or average chromaticity in the said permeation | transmission image observed.
Furthermore, it has a flare rate acquisition means for acquiring in advance a flare rate when observing the hard copy image (print image), and the flare correction means uses the acquired flare rate to match the observation environment. It is preferable to correct the flare amount.

  In order to achieve the above object, according to a third aspect of the present invention, there is provided a photographic print image based on an image processing apparatus according to the second aspect of the present invention and image data corrected by the image processing apparatus. An image forming apparatus including an image output unit that outputs (hard copy image) is provided.

In order to achieve the above object, a fourth aspect of the present invention provides an image processing program for causing a computer control to execute the image processing method of the first aspect of the present invention.
In order to achieve the above object, a fifth aspect of the present invention provides a computer-readable recording medium on which an image processing program according to the fourth aspect of the present invention is recorded.

According to the present invention, the appearance of the transmitted image of the observed color reversal film, in particular, the gradation of the observed transmitted image and the color reproduction characteristic “shining beauty”, that is, the original beauty of the transmitted image. In addition to faithful reproduction, appropriate or natural contrast conversion, saturation conversion, and the like can be performed to achieve preferable color reproduction common to various subjects and scenes.
Therefore, according to the present invention, a photographic print that faithfully reproduces the beautiful high-quality image of the transparent original image of the color reversal film, and further, a photographic print that performs more preferable color reproduction in addition to such faithful reproduction. Can be provided to the user. As a result, according to the present invention, it is possible to satisfy a user who expects reproduction of an original beauty of an observed transmission image on a print.

  In addition, according to the present invention, by embedding and automating this image processing in the software, the image of the transparent original image of the color reversal film can be easily reproduced on the photographic print, and the printing work efficiency in the laboratory for producing the print Can be greatly improved.

  Hereinafter, an image processing method and an image processing apparatus according to the present invention, an image forming apparatus using the image processing apparatus, an image processing program for executing the image processing method, and a recording medium on which the image processing program is recorded will be described based on preferred embodiments shown in the accompanying drawings. Will be described in detail.

FIG. 1 is a block diagram of an embodiment of an image forming apparatus according to a third aspect of the present invention that includes the image processing apparatus according to the second aspect of the present invention that performs the image processing method according to the first aspect of the present invention. is there.
As shown in the figure, the image forming apparatus 10 photoelectrically reads a transmission image (transmission original image) F recorded on a reversal film in which a subject is imaged, acquires digital image data D0, and measures the transmission image. The image data acquired by the imaging unit 16 so as to not only faithfully reproduce the appearance of the transmitted image F of the reversal film being observed as it is, but also to achieve a more preferable color reproduction. An image processing unit 12 that performs image conversion processing on (colorimetric value D1 of the transparent image), and a hard copy image (photo print P) based on image data obtained by performing faithful reproduction conversion processing on the image processing unit 12 ) And the like, and an image output unit 14 that outputs a visual image.

The imaging unit 16 photoelectrically reads a transmission image (hereinafter, also referred to as a transmission subject image) recorded as a subject image on a reversal film that images the subject, acquires digital image data D0, and acquires the acquired digital image data. The colorimetric value D1 (here, the tristimulus value (XYZ) of the color of the transparent subject image) of each point of the transparent subject image is calculated from D0. The calculated colorimetric value D1 is the image processing unit 12. Is input. The imaging unit 16 may be any unit that can obtain the colorimetric values D1 of each point of the transparent subject image photographed on the color reversal film F. For example, the imaging unit 16 was obtained by photographing the subject. The transparent subject image of the color reversal film F is read using an imaging device such as a CCD or CMOS sensor, RGB data (digital image data D0) is obtained as digital data of the transparent subject image, and the RGB data D0 is converted into a colorimetric value D1, for example, transparent. It may be converted into tristimulus values XYZ of the color of the subject image. The colorimetric values used in the present invention are not limited to the color tristimulus values (XYZ).
In the present invention, the image pickup unit 16 performs photoelectric reading of a photographic film such as a reversal film and outputs digital image data D0 such as RGB data, and a transmission subject of the color reversal film F from the digital image data D0. The colorimetric value D1 of the image is calculated, and the colorimetric value D1 calculation unit may be built in the scanner, or may be externally attached to the scanner. And the colorimetric value D1 calculating means may be a separate unit or may be incorporated in the image processing unit 12.

  The image processing unit 12 is an embodiment of the image processing apparatus according to the second aspect of the present invention that implements the image processing method according to the first aspect of the present invention, and is a transmission image F of the reversal film being observed. The colorimetric values D1 (tristimulus values (XYZ) of the color of the transparent subject image) of each point of the transparent subject image acquired by the imaging unit 16 so that not only the appearance can be faithfully reproduced but also a more preferable color reproduction. A preferable color reproduction process for converting the colorimetric value D1 of the transparent subject image into the colorimetric value D6 of the transparent subject image (the converted tristimulus value (XaYaZa) of the transparent subject image). The colorimetric value D6 of the transmission subject image processed by the unit 34 and the preferred color reproduction processing unit 34 is input, and the colorimetric value D3 of the converted image (tristimulus value (X′Y′Z ′) of the output image) Converted to The flare amount corresponding to the observation environment of the reproduced image is corrected with respect to the faithful reproduction processing unit 32 and the colorimetric value D3 of the converted image, and is output as a reproduced image (hard copy image (print)). And a flare correction unit 24 for obtaining a colorimetric value D4 (tristimulus value (XYZ) of the reproduced image) of the subject image.

Here, the order of processing in the present invention is changed, but prior to the description of the preferred color reproduction processing unit 34 that is a feature of the present invention, the appearance faithful reproduction processing unit 32 that is the most characteristic of the present invention will be described.
FIG. 2 is a block diagram of an embodiment of the faithful reproduction processing unit. The faithful reproduction processing unit 32 shown in the figure is for performing image processing so as to faithfully reproduce the appearance of the transmitted subject image of the observed reversal film F, and is a preferred color reproduction processing unit 34 in the preceding stage. The colorimetric value D6 (transparent subject image conversion tristimulus value (XaYaZa)) of the transparent subject image sent from is converted into the colorimetric value D3 (tristimulus value (X′Y′Z ′) of the output image) of the converted image. To convert.
As shown in the figure, the faithful reproduction processing unit 32 includes a transmission image observation condition acquisition unit 18 that acquires observation illumination conditions of a transmission subject image for observing the transmission subject image of the reversal film F that is observed by a viewer or a projector. The observation illumination condition of the reproduction image (reflection image) in which the transmission subject image is reproduced is acquired, and the reproduction image observation condition acquisition unit 20 for setting and the colorimetric value D6 of the transmission subject image are sequentially set using the transmission image observation condition. A color appearance attribute value (hue h, lightness J, saturation C) D2 is obtained by conversion, and the appearance attribute value D2 obtained in this way is inversely converted using reproduction image observation conditions to be faithful to the appearance. A faithful reproduction conversion unit 22 (22a, 22b) that obtains the colorimetric value D3 (tristimulus value (X′Y′Z ′) of the output image) of the converted image subjected to reproduction correction.

The transmission image observation condition acquisition unit 18 is for acquiring an observation illumination condition when observing the transmission subject image on the reversal film F, and the tristimulus value of the illumination light of the light source illuminating the transmission subject image, the subject For obtaining the brightness and the ambient condition of the subject. In the present invention, in particular, the chromaticity value and the absolute illuminance value of the illumination light of the illumination light source are measured and recorded.
The observation condition acquisition unit 20 is for acquiring and setting an observation illumination condition when observing a reproduction image (reflection print image) in which a transmission subject image is reproduced in advance. The observation condition acquisition unit 20 is a light source that illuminates the reproduction image. This is for obtaining the tristimulus value of illumination light, the brightness of the subject, and the ambient conditions of the subject.In the present invention, in particular, the chromaticity value and absolute illuminance value of the illumination light during reproduction image observation are measured and recorded in advance. It is for keeping.

The appearance faithful reproduction conversion unit 22 forward-converts the colorimetric value D6 of the transparent subject image (the converted tristimulus value (XaYaZa) of the transparent subject image) using the transmission image observation condition, and the color appearance attribute value D2 ( Hue h, lightness J, and saturation C) are obtained, and the attribute value D2 of the appearance thus obtained is inversely converted using the reproduction image observation conditions, and the colorimetry of the converted image subjected to the faithful reproduction reproduction of the appearance is performed. The value D3 (tristimulus value (X'Y'Z ') of the output image) is obtained. In the present invention, CIECAM02 ("Commission Internationale de l'Eclairage") 2002 A color adaptation conversion unit 26 that performs chromatic adaptation correction and a contrast, and is constructed based on a color appearance model (CIECAM02 Color Appearance Model; see IS & T / SID 10th Color Imaging Conference Proceedings pp.23-27)) A nonlinear signal conversion unit 28 for performing correction, And a color attribute conversion portion 30 performs correction.
In CIECAM02, as an attribute value of appearance, in addition to hue h, lightness J, and saturation C respectively corresponding to the HVC of the Munsell color system, absolute brightness, that is, an absolute sense of brightness that a person feels There are five types of brightness Q, which is an index representing quantity, and colorfulness M, which is an index representing the absolute sense of vividness felt by humans. In this embodiment, hue h, brightness J, and saturation C are set as follows. set to target.

Here, the chromatic adaptation conversion unit 26 uses the chromaticity information (chromaticity value) and illuminance information (absolute illuminance value) of the illumination light source acquired by the transmission image observation condition acquisition unit 18 to convert the colorimetric value D6 of the transmissive subject image. In this case, color adaptation correction is performed on the color image, and colorimetric values reproduced under the reproduced image observation conditions acquired by the reproduced image observation condition acquisition unit 20 are obtained. Here, specifically, for example, in the forward conversion, the chromatic adaptation conversion unit 26 calculates the degree of adaptation (D) with respect to the illumination color of the transmission subject image from the absolute illuminance value of the transmission subject image at the time of observation of the transmission image. Then, a colorimetric value of a corresponding color for reproducing the appearance of the transparent subject image at the time of reverse conversion under illumination when observing a reproduced image such as a print is calculated.
In the illustrated example, the chromatic adaptation conversion unit 26 uses the one recommended by CIECAM02. However, the present invention is not limited to this, and various methods can be used as long as they are proposed as chromatic adaptation conversion. Any of the above can be employed.

Next, the nonlinear signal converter 28 performs contrast correction on the colorimetric value D6 of the transmitted subject image from the illuminance information (absolute illuminance value) of the illumination light source acquired by the transmitted image observation condition acquisition unit 18, and reproduces the reproduced image. Colorimetric values that are reproduced under the reproduced image observation conditions acquired by the observation condition acquisition unit 20 are obtained.
Here, specifically, for example, in the forward conversion, the non-linear signal conversion unit 28 obtains a contrast conversion characteristic from the absolute illuminance value of the illumination during observation of the transmission image and the absolute illuminance value of the illumination during observation of the reproduced image. The contrast conversion is performed on the colorimetric values of the corresponding colors calculated and subjected to the color adaptation correction by the color adaptation conversion unit 26.

In the illustrated example, the nonlinear signal converter 28 recommended by CIECAM02 is used. However, the present invention is not limited to this, and various methods can be used as long as they are proposed as contrast conversion. Anything to do can be employed.
Thus, the appearance faithful reproduction conversion unit 22 can obtain a transparent subject image subjected to the appearance faithful reproduction correction, that is, the colorimetric value D3 of the converted image, and the colorimetric value D3 of the converted image is the flare correction. Input to the unit 24.

By the way, in the appearance faithful reproduction conversion unit 22 in the illustrated example, at the time of forward conversion, the chromatic adaptation conversion unit 26, the nonlinear signal conversion unit 28, and the color attribute conversion unit 30 sequentially perform chromatic adaptation conversion and nonlinear signal conversion according to the transmission image observation conditions. (Contrast conversion) and color attribute conversion (saturation conversion) are performed to calculate an appearance attribute value D2 (hue h, lightness J, saturation C), and at the time of reverse conversion, the calculated appearance attribute value D2 (hue) h, lightness J, saturation C), in each of the conversion units 30, 28 and 26, color attribute conversion (saturation conversion), nonlinear signal conversion (contrast conversion) and chromatic adaptation conversion are sequentially performed according to the reproduction image observation conditions. The colorimetric value D3 of the converted image is calculated, but the present invention is not limited to this, and each of the conversion units 26, 28, and 30 performs forward conversion according to the transmission image observation condition and It may be subjected to reverse conversion by the current image viewing conditions.
Alternatively, in the illustrated example, the appearance faithful reproduction conversion unit 22 is used which is the same during forward conversion and reverse conversion. However, the present invention is not limited to this, and as shown in FIG. The conversion unit 22 includes an appearance faithful reproduction order conversion unit 22a and an appearance faithful reproduction order conversion unit 22b. The appearance faithful reproduction order conversion unit 22a includes a chromatic adaptation conversion unit 26a, a nonlinear signal conversion unit 28a, and a color attribute. The conversion unit 30a may be configured, and the appearance faithful reproduction inverse conversion unit 22b may be configured by a color attribute conversion unit 30b, a nonlinear signal conversion unit 28a, and a chromatic adaptation conversion unit 26b.

Next, a preferable color reproduction processing unit 34 that performs pre-processing before the appearance faithful reproduction processing unit 32 will be described.
FIG. 3 is a block diagram of one embodiment of a preferred color reproduction processing unit. The preferred color reproduction processing unit 34 uses the colorimetric values D1 of the respective points on the transmission subject image in advance so that the processing in the faithful reproduction processing unit 32 of the appearance in the subsequent stage becomes a preferable color reproduction in addition to the faithful reproduction. Predetermined chromatic adaptation conversion, contrast and / or saturation conversion is performed.

  As shown in FIG. 3, the preferred color reproduction processing unit 34 uses the colorimetric value D1 (the tristimulus value (XYZ) of the color of the transparent subject image) of the transparent subject image input from the imaging unit 16 as the attribute value D5 of the appearance. Color appearance order conversion unit 36a to convert to (hue h, lightness J, colorfulness M) and colorimetric value D6 of the transparent subject image converted from the input appearance attribute value D5 (transparent subject image conversion tristimulus A contrast / saturation conversion unit 36 including a color appearance reverse conversion unit 36b to be converted into a value (XaYaZa), and a transmission image observation condition setting unit 38a for setting a transmission image observation condition used in the color appearance order conversion unit 36a. And a transmission image observation condition setting unit 38b for setting transmission image observation conditions used in the color appearance inverse conversion unit 36b. In addition to this, in the preferable color reproduction processing unit 34 as well as the appearance faithful reproduction processing unit 32, the transmission image observation condition acquisition unit 18 that acquires the transmission image observation conditions, and the reproduction image that sets the reproduction image observation conditions. The observation condition acquisition unit 20 may be included, but the transmission image observation condition acquired by the transmission image observation condition acquisition unit 18 from the faithful reproduction processing unit 32 of the appearance and the reproduction image observation set by the reproduction image observation condition acquisition unit 20 It is preferable to acquire the conditions.

Here, the color appearance order conversion unit 36a and the color appearance reverse conversion unit 36b of the contrast / saturation conversion unit 36 shown in FIG. 3 are basically faithful reproduction of the appearance of the appearance faithful reproduction conversion unit 22, respectively. The forward conversion unit 22a and the appearance faithful reproduction inverse conversion unit 22b have the same configuration, and the transmission image observation condition setting units 38a and 38b have basically the same configuration as the transmission image observation condition acquisition unit 18. Although the detailed description is omitted, the function of each unit will be described.
Unlike the transmission image observation condition acquisition unit 18, the transmission image observation condition setting units 38 a and 38 b do not acquire the transmission image observation conditions of the actual transmission subject image, but respectively perform the appearance faithful reproduction conversion unit 22 performed at the subsequent stage. The transmission image observation conditions are set so that the processing results in the units 22a and 22b become a preferable color reproduction in addition to the faithful reproduction. On the other hand, the color appearance order conversion unit 36a and the color appearance reverse conversion unit 36b of the contrast / saturation conversion unit 36 have the same configuration as the units 22a and 22b of the appearance faithful reproduction conversion unit 22, and the transmission image observation conditions. It is not used for faithful reproduction conversion of appearance under the observation illumination condition of the transmission subject image obtained by the acquisition unit 18 and the observation illumination condition of the reproduction image obtained by the acquisition image observation condition acquisition unit 20. This is used for the appearance conversion under the predetermined transmission image observation conditions set by the transmission image observation condition setting units 38a and 38b so that preferable color reproduction can be achieved even if the conversion is performed.

Note that, in the color appearance conversion of the color appearance order conversion unit 36a, the subject luminance value (luminance ratio) is changed in a range of 10 to 100 times the actual value, and the value of saturation C is set to 1. By changing in the range of 00 to 1.20 times, it is possible to obtain the attribute value D5 of the transparent subject image that has undergone preferable color reproduction conversion, and the color appearance reverse conversion unit 36b performs reverse conversion to obtain a preferable color. The colorimetric value D6 of the transparent subject image that has been reproduced and converted can be obtained.
In this embodiment, the value of saturation C is changed in the color appearance order conversion unit 36a of the preferred color reproduction processing unit 34. However, the present invention is not limited to this, and the latter stage shown in FIG. The appearance faithful reproduction processing unit 32 may change the appearance faithful reproduction order conversion unit 22a. That is, in the appearance faithful reproduction order conversion unit 22a, by changing the value of the saturation C in a range of 1.00 to 1.20 times, the appearance is faithfully reproduced and the transmission in which preferable color reproduction conversion is performed. The attribute value D2 of the subject image may be obtained.

  Thus, the colorimetric value D6 (transmission subject image conversion tristimulus value (XaYaZa)) of the transparent subject image that has been subjected to the preferred color reproduction conversion in the preferred color reproduction processing unit 34 shown in FIG. As described above, the appearance faithful reproduction processing unit 32 shown in FIG. 2 performs the appearance faithful reproduction processing and converts it into the colorimetric value D3 of the converted image, thereby correcting the flare. Input to the unit 24.

The flare correction unit 24 corrects the flare amount according to the observation environment of the reproduced image with respect to the colorimetric value of the transparent subject image subjected to chromatic adaptation correction and contrast correction, that is, the colorimetric value D3 of the converted image, The colorimetric value D4 (tristimulus value (XYZ) of the reproduced image) of the transparent subject image to be output as a reproduced image (hard copy image (print)) is obtained. Here, specifically, the flare correction unit 24 calculates, for example, the degree of density reduction due to flare from the surrounding situation when the reproduced image is observed, and measures the converted image obtained by the faithful reproduction processing unit 32 for appearance. Density correction is performed on the color value D3 so as to compensate for the decrease in density due to flare.
In this way, the image processing unit 12 can faithfully reproduce the appearance of the transparent subject image and obtain a transparent subject image with a preferable color reproduction, that is, a colorimetric value D4 (tristimulus value (XYZ)) of the reproduced image. it can. The colorimetric value D4 of the reproduced image thus obtained is input to the image output unit 14.

The image output unit 14 is subjected to preferable color reproduction processing and appearance faithful reproduction correction processing in the image processing unit 12, and the colorimetric value D4 of the image to be reproduced finally obtained is a hard copy image (print) or the like. A reproduction image such as a photographic print is created and output so as to be reproduced on the visual reproduction image.
The reproduced image output in this manner is a hard copy image such as a photographic print in which the appearance of the subject is faithfully reproduced as it is and a preferable color reproduction is made. That is, the reproduced image obtained in this way is an image that is not only faithfully reproduced in appearance but also has a preferable color reproduction and is naturally felt by humans.
The image output unit 14 may output a visual reproduction image such as a soft copy image displayed on a monitor or the like instead of a hard copy image such as a photo print or in addition to the hard copy image. .
The image processing apparatus according to the second aspect and the image forming apparatus according to the third aspect of the present invention are basically configured as described above.

Next, the preferred color reproduction process performed in the preferred color reproduction processing unit 34 shown in FIG. 3 will be described in detail, and the operation of the image processing apparatus according to the second aspect and the image forming apparatus according to the third aspect of the present invention, and The image processing method according to the first aspect will be described.
1) As described above, in the image forming apparatus 10 shown in FIG. 1, first, the transmission subject image of the reversal film is imaged by the imaging unit 16 and digitized, and the colorimetric values of each point on the transmission subject image D1 (tristimulus value (XYZ) of the transparent subject image) is calculated.
2) Illuminance information such as the absolute illuminance value of illumination light that illuminates the transmitted subject image when the transmitted subject image is observed by the transmitted image observation condition acquisition unit 18 (see FIG. 2) of the image processing unit 12. And chromaticity information such as chromaticity values are measured and recorded.
3) Furthermore, the reproduction image observation condition acquisition unit 20 (see FIG. 2) sets illuminance information such as an absolute illuminance value of illumination and chromaticity information such as a chromaticity value when a reproduction image such as a print is observed in advance. Has been.

4) The calorimetric values D1 (tristimulus values (XYZ) of the transparent subject image) of each point on the transparent subject image calculated by the imaging unit 16 are input to the preferred color reproduction processing unit 34.
In the preferred color reproduction processing unit 34 shown in FIG. 3, the colorimetric values D1 (tristimulus values (XYZ) of the subject image) of each point on the transparent subject image are input to the contrast / saturation conversion unit 36.
Here, the appearance order conversion unit 36a of the contrast / saturation conversion unit 36 uses the color appearance conversion formula based on the transmission image observation condition set by the transmission image observation condition setting unit 38a to perform contrast conversion and saturation. Conversion is performed, and values of brightness J, hue h, and colorfulness M are obtained as the appearance attribute value D5. At this time, the observer adapts to the illumination color with the degree of adaptation (Da) when the adaptation brightness is higher than the adaptation brightness determined by the transmission image observation condition obtained by the transmission image observation condition acquisition unit 18. Preferably, chromatic adaptation conversion is performed by the chromatic adaptation conversion unit 40a of the appearance order conversion unit 36a on the assumption that the adaptation is almost or completely (D = 1), and the contrast and colorfulness M have a luminance of 5 -150 times, preferably 15-150 times, and in human skin color priority, more preferably 5-20 times, and a change amount corresponding to about 10-100 times, respectively, contrast conversion by the nonlinear signal conversion unit 42a Saturation conversion is performed by the color attribute conversion unit 44a.
Here, the color appearance conversion formulas in the appearance order conversion unit 36a and the appearance order conversion unit 36b are described in IS & T / SID 10th Color Imaging Conference Proceedings pp.23-27 “CIECAM02 Color Appearance Model”. Use what you have.

That is,
1. In the color adaptation conversion by the color adaptation conversion unit 40a, the adaptability D Da (adaptability when set to the luminance value L _A higher than adaptation luminance defined by transparent image viewing conditions adaptation luminance; in later-described formula (1) Most preferably, Da = 1,
2. In contrast conversion by the nonlinear signal conversion unit 42a (non-linear response conversion), calculated by the luminance value L _A higher adaptation luminance than adaptation luminance determined value of the parameter F _L (described below Formula (2)) a transmission image viewing conditions,
3. In the saturation conversion (color perception attribute calculation) by the color attribute conversion unit 44a, the luminance value L _A of the transparent subject image used for the calculation of the colorfulness M (formula (3) described later) is an adaptation luminance determined by the transmission image observation conditions. The brightness value of the higher adaptation brightness is set to 5 to 150 times, and approximately 10 to 100 times the brightness value of the actual transmitted subject image.
The values of brightness J, hue h, and colorfulness M are obtained by the above procedure.
Further, the value of saturation C is changed by 1.00 to 1.20 times.
Here, the luminance ratio and the saturation C are used as enhancement parameters for obtaining a preferable color reproduction and faithful reproduction of the appearance of the transmission image of the reversal film to the photographic print image, but the present invention is not limited to these. Alternatively, one of the luminance ratio and the saturation C may be used, or one or both of the contrast and the colorfulness M may be used in place of or in addition to at least one of the luminance ratio and the saturation C.

Here, degree of adaptation D, parameters F _L and the colorfulness M is, IS according & T / SID 10th Color Imaging Conference Proceedings pp.23-27 "CIECAM02 color appearance model", the following formula (1), (2) and ( It shall be given in 3). In addition, the hue h, the lightness J, chroma C, colorfulness M, brightness Q, similar to the degree of adaptation D and the parameter F _L, the appearance of IS & T / SID 10th Color Imaging Conference Proceedings pp.23-27 "CIECAM02 colors Although it is given in accordance with the “Model”, it is described in detail in the IS & T / SID 10th Color Imaging Conference Proceedings pp.23-27 “CIECAM02 Color Appearance Model”, so its description is omitted.
Incidentally, as those related to the contrast, as shown in the following formula (2), with respect to the change of the luminance value L _A, the value of the parameter F _L, monotonically increasing. Further, as being associated with colorfulness (saturation perception), as shown in the following formula (3), colorfulness M, since in proportion to (1/4) square of parameter F _L, these from relations also virtually, setting a higher luminance value L _a, and improved colorfulness M, it can be seen that vivid impression is obtained.

5) Next, from the appearance attribute value D5 (values of lightness J, hue h, and colorfulness M) obtained in this way by the appearance order conversion unit 36a, color appearance conversion is inversely converted by the color appearance inverse conversion unit 36b. The colorimetric value D6 of the transparent subject image (subject tristimulus value (XaYaZa) of the subject), which is an image value corresponding to the tristimulus value of the transparent subject image, is obtained again.
At this time, the observation condition parameters set by the transmission image observation condition acquisition unit 38b are obtained by the transmission image observation condition acquisition unit 18 except that the adaptation degree Da used in the appearance conversion unit 36a is used as the adaptation degree D. The transmission image observation condition itself is used.
Therefore, specifically, the appearance inverse conversion unit 36b performs saturation conversion by the color attribute conversion unit 44b and contrast conversion by the nonlinear signal conversion unit 42b using the luminance value of the actually observed transmission subject image, The adaptation degree D is set to the aforementioned Da, and the chromatic adaptation conversion is performed by the chromatic adaptation conversion unit 40a.
By doing so, the transparent subject image has data that has a virtual contrast under the observation environment, and the saturation is increased by a predetermined amount.
This kind of contrast / saturation conversion mimics the sensation of contrast / saturation change that accompanies changes in human brightness, and is a contrast / saturation conversion method that realizes a desirable color reproduction that is naturally felt by humans. It can be said that there is.

6) In the preferred color reproduction processing unit 34 shown in FIG. 3, the colorimetric value D6 (transparent subject image conversion tristimulus value (XaYaZa)) of the transparent subject image that has been subjected to the preferred color reproduction conversion in the contrast / saturation conversion unit 36. ) And is input to the faithful reproduction processing unit 32 as shown in FIG.
As described above, the colorimetric value D6 of the transparent subject image input to the appearance faithful reproduction processing unit 32 is input to the appearance faithful reproduction conversion unit 22 of the appearance faithful reproduction processing unit 32 shown in FIG.

In the appearance faithful reproduction conversion unit 22 (appearance faithful reproduction order conversion unit 22a and inverse conversion unit 22b), first, the degree of adaptation to the illumination color of the transmission subject image from the absolute illuminance value of the transmission subject image when the transmission image is observed. (D) is calculated, and color adaptation conversion is performed to calculate a colorimetric value of a corresponding color for reproducing the appearance of the transparent subject image under illumination when observing a reproduced image such as a print (color adaptation conversion unit 26 ( 26a and 26b)).
Next, a contrast conversion characteristic is calculated from the absolute illuminance value of the illumination during observation of the transmitted image and the absolute illuminance value of the illumination during observation of the reproduced image (printed image), and the chromatic adaptation correction is performed by the chromatic adaptation conversion unit 26. Contrast conversion is performed on the colorimetric values of the colors (see the nonlinear signal converters 28 (28a and 28b)).
Thus, the appearance faithful reproduction processing unit 32 can obtain the colorimetric value D3 of the converted image subjected to the faithful reproduction reproduction of the appearance from the colorimetric value D6 of the transparent subject image, and the colorimetric value of the converted image. D3 is input from the faithful reproduction processing unit 32 to the flare correction unit 24.

7) The flare correction unit 24 shown in FIG. 1 calculates the degree of density reduction due to flare from the surrounding situation when observing the reproduced image (printed image), and measures the converted image obtained by the appearance faithful reproduction processing unit 32. The color value D3 is subjected to density correction so as to compensate for the decrease in density due to flare, so that the appearance of the transparent subject image can be faithfully reproduced, and the transparent subject image in which a preferable color reproduction of the appearance is made, that is, the reproduced image is reproduced. A colorimetric value D4 (tristimulus value (XYZ)) can be obtained.
Thus, the colorimetric value D4 of the reproduced image obtained in the image processing unit 12 is input to the image output unit 14.

8) In the image output unit 14, the colorimetric value D4 of the image to be reproduced finally obtained by the image processing unit 12 is reproduced on a visual reproduction image such as a hard copy image (print image). Create and output reproducible images such as photo prints.
The reproduced image output in this manner is a hard copy image such as a photographic print in which the appearance of the subject is faithfully reproduced as it is and a preferable color reproduction is made. That is, the reproduced image obtained in this way is an image that is not only faithfully reproduced in appearance but also has a preferable color reproduction and is naturally felt by humans.

  In the example described above, the value of saturation C is changed in the color appearance order conversion unit 36a of the contrast / saturation conversion unit 36 of the preferred color reproduction processing unit 34 shown in FIG. The present invention is not limited to this, and the appearance may be changed in the appearance faithful reproduction order conversion unit 22a of the appearance faithful reproduction processing unit 32 shown in FIG. That is, in the forward conversion unit 22a, by changing the value of saturation C in the range of 1.00 to 1.20 times (up 20%), faithful reproduction of appearance and preferable color reproduction conversion were performed. The attribute value D2 of the transparent subject image, and further the inverse conversion by the inverse conversion unit 22b, may be used to obtain the tristimulus value D3 of the converted image.

  Hereinafter, the image processing method according to the first aspect of the present invention, the image processing apparatus according to the second aspect, and the image forming apparatus according to the third aspect will be specifically described with reference to examples.

[Example 1]
In the following, the R, G, B signals calculated by the image processing method according to the first aspect of the present invention are input to the color digital printer as the image forming apparatus according to the third aspect of the present invention, and the preferred saturation as a reproduced image. A case of obtaining a conversion (contrast conversion) print image will be described with reference to FIG.
FIG. 4 is a flowchart for explaining a flow of a series of processes in the present embodiment when a silver salt photographic light-sensitive material is used.

Step S1:
A transmission image taken with a color reversal film RPOVIA 100F professional made by Fuji Photo Film was recorded with a scanner SG-1000 made by Dainippon Screen to obtain digital image data as a density value.

Step S2:
Measure the light-emitting surface of an illuminator (create viewer manufactured by Prolab Create, Inc., using a color evaluation fluorescent lamp with a color temperature of 5000K as a light source) to observe the transmission image of the color reversal film, using SR-3 manufactured by Topcon, Spectral luminance and luminance XYZ tristimulus values were measured. In addition, an absolute illuminance value of 3000 Lux was obtained.

Step S3:
For the transmission image of the color reversal film, SPIE vol. Using a laser color printer described in 1079 pp90-98, a plurality of patches with different RGB exposure amounts are output, recorded by the scanner SG-1000, and each exposure amount applied to the photosensitive material A table (1) describing the relationship of the color density was created.
The spectral reflectance of the patch was measured spectrophotometrically with TC-1800M manufactured by Tokyo Denshoku. From this spectral colorimetric data, considering the data of step S2 as the spectral distribution of the observation light source, CIE XYZ tristimulus values of each patch are obtained, and the relationship between each exposure amount applied to the photosensitive material and the CIE XYZ tristimulus values is described. Table (2) was created.

Step S4:
The exposure (R, G, B) given to each point of the image data was calculated by applying the table (1) created in step S3 to the digital image data having the density obtained in step S1.

Step S5:
The CIE XYZ tristimulus values observed at each point of the image data were obtained by applying the table (2) created in step S3 to the exposure amounts R, G, and B obtained in step S4.

Step S6:
A standard white plate was installed at the same position as the print printing environment illuminated by a color evaluation fluorescent lamp with a color temperature of 5000 K and an illuminance of 300 Lux, and tristimulus values were measured with a color luminance meter CS-100.

Step S7:
Using the formula described in IS & T / SID 10th Color Imaging Conference Proceedings pp.23-27, chroma conversion (contrast conversion) is applied to the transparent subject image (colorimetric value D1; tristimulus value (XYZ)). An image (appearance attribute value D5) was created. Here, the tristimulus values X ′, Y ′, and Z ′ to be reproduced in the print observation environment are calculated from the X, Y, and Z values in the transmission image observation environment of the color reversal film, and the observer uses the color reversal film. The calculation is performed so as to completely adapt to the light source that illuminates the transmitted image (the value of the adaptability D represented by the above formula (1) is forcibly set to 1) (setting observation condition). LA = 1000 cd / m2 (set observation conditions; equivalent to a color reversal film transmission image observation environment), and an image with three appearance attribute values D5 of hue h, lightness J, and colorfulness M is calculated. did.

Step S8:
Next, using the formula described in IS & T / SID 10th Color Imaging Conference pp.23-27, color is calculated from the three appearance attribute values D5 of hue h, brightness J, and colorfulness M calculated in step S7. A series of images represented by tristimulus values (XaYaZa) (colorimetric values D6) of the transmitted subject image after saturation conversion were calculated using the illumination conditions (setting observation conditions) of the transmission image of the reversal film.

Step S9:
Thereafter, starting from the image of the tristimulus value (XaYaZa) (colorimetric value D6) obtained in step S8, the method described in IS & T / SID 10th Color Imaging Conference Proceedings pp.23-27 is used in step S2. Using the obtained transmission image observation conditions, chromatic adaptation conversion and contrast conversion were performed, and a series of images in which three appearance attribute values D2 of hue h, brightness J, and saturation C were calculated were produced.

Step S10:
Next, using the appearance conversion formula described in IS & T / SID 10th Color Imaging Conference pp.23-27, the three appearance attribute values of hue h, lightness J, and saturation C calculated in step S9. Tristimulus values (X ′, Y ′, Z ′) (colorimetric values D3) of the converted image to be output on the print using the observation illumination condition for observing the print obtained in step S6 from D2. A series of reproducible images on which the faithful reproduction process and the preferred color reproduction process represented by

Step S11:
The laser color printer described in SPIE vol.1079 pp90-98 is used as the printing device, and patches with different R, G, and B input signals are pre-assigned to Fuji Photo Film's professional color paper. -It output to the pro laser crystal TYPE II-E, and the spectral reflectance of each patch was spectrophotometrically measured by TC-1800M made by Tokyo Denshoku Co., Ltd.

Step S12:
For the spectral reflectance data R (λ) measured in step S11, the spectral reflectance R ′ (λ) after flare correction was calculated by the following equation (4).

  Here, h is a flare rate in the spectrocolorimeter TC-1800M, and h ′ is a flare rate in a print observation environment.

Step S13:
The spectral reflectance R ′ (λ) after flare correction obtained in step S12 is multiplied by the spectral distribution of the print observation illumination to obtain X, Y, Z tristimulus values, and the printer input signal and flare correction are calculated. A table showing the relationship of the later X, Y, Z tristimulus values (colorimetric value D4) was created.

Step S14:
Tristimulus values X ′, Y ′, Z ′ (colorimetric values D3) to be output under the observation environment calculated in step S10 and R, G, B signals to be input to the printer from the table obtained in step S13 Was calculated and input to the printer to obtain a final output image (print image).

Step S15:
The obtained output image was observed under print observation conditions and compared with the appearance of the original transmission image of the color reversal film. As a result, it was confirmed that the print image was very well matched.

[Example 2]
Next, a case will be described in which the image processing method of the present embodiment shown in FIG. 4 is performed, a print image is obtained as a reproduced image by a color digital printer, and the optimum value of contrast conversion / saturation conversion is evaluated.

Step S1:
Except for recording 11 types of transmission images of different scenes photographed on the same color reversal film as in Example 1, 11 types of transmission images of Daishin Screen Manufacturing Co., Ltd. Digital image data was obtained by recording with a scanner SG-1000.

Steps S2 to S6:
In exactly the same manner as in Example 1, the transmission image observation conditions (illumination conditions) when observing the transmission image of the color reversal film, the observation conditions (illumination conditions) during print observation, and the measurement of the transmission subject images of 11 types of scenes The color value D1 (tristimulus value (XYZ) of the subject) was obtained.

Step S7:
IS & T / SID 10th Color Imaging Conference Proceedings pp.23-27 Using the formulas described in pp.23-27, contrast and saturation for 11 types of scene images (colorimetric values D1; tristimulus values (XYZ)) An image (appearance attribute value D5) subjected to degree conversion was created. Here, the tristimulus values X ′, Y ′, and Z ′ to be reproduced in the print observation environment are calculated from the X, Y, and Z values in the transmission image observation environment of the color reversal film, and the observer uses the color reversal film. The calculation is performed so as to completely adapt to the light source that illuminates the transmitted image (the value of the adaptability D represented by the above formula (1) is forcibly set to 1) (setting observation condition). , changing the value of L _a viewing illuminance value a constant multiple of the transmission original image has been changed to (luminance ratio) (the formula for use in calculating the F _L (2) of the color reversal film (set viewing conditions )) Substituting multiple equivalent values, calculating the values of three appearance attribute values D5 of hue h, lightness J, and colorfulness M, and creating a series of images in which only saturation C is changed by a constant multiple did.

Step S8:
Next, using the formula described in IS & T / SID 10th Color Imaging Conference Proceedings pp.23-27, three values of hue h, lightness J, and saturation C of appearance attribute value D5 calculated in step S7 A series of images represented by tristimulus values (XaYaZa) (colorimetric values D6) of the transmitted subject image after saturation conversion were calculated using the illumination conditions (setting observation conditions) of the transmission original image of the color reversal film. .

Step S9:
Thereafter, starting from the image of the tristimulus value (XaYaZa) (colorimetric value D6) obtained in step S8, the method described in IS & T / SID 10th Color Imaging Conference Proceedings pp.23-27 is used in step S2. Using the obtained transmission image observation conditions, chromatic adaptation conversion and contrast conversion were performed to calculate three appearance attribute values D2 of hue h, lightness J, and saturation C, and a series of images was produced.

Step S10:
Next, using the appearance conversion formula described in IS & T / SID 10th Color Imaging Conference pp.23-27, the three appearance attribute values of hue h, lightness J, and saturation C calculated in step S9. From the D2, the tristimulus values (X ′, Y ′, Z ′) (colorimetric values D3) of the converted image to be output on the print using the observation illumination conditions for observing the print obtained in step S56. A series of reproducible images that were subjected to the faithful reproduction processing of the appearance and the preferred color reproduction processing were calculated.

Steps S11 to S14:
In exactly the same manner as in Example 1, the image represented by the tristimulus values (X ′, Y ′, Z ′) (colorimetric values D3) of the converted image to be output on the print obtained in step S10 is obtained. A series of calculations were performed to calculate R, G, B signals to be input to the printer, and these were input to the printer described above to obtain final output images (all 11 types of scenes).

Step S15:
The output images (11 types of scenes) obtained under print viewing conditions are preferred by 10 observers (both employees of Fuji Photo Film Co., Ltd. who are engaged in the design and development of color reversal film). A psychological evaluation was performed. The result is shown in FIG. From FIG. 5, the average of all the scenes was obtained, and the value obtained by improving the luminance ratio by 30 times and the saturation C2.5% was determined as the optimum value of the intensity parameter.
Step 16:
Using the optimal value of the intensity parameter obtained in this way, with a brightness ratio of 30 times and saturation C2.5% improved, a print is created from the transmission image of the color reversal film and is preferred by the above 10 observers. As a result of psychological evaluation, it was found that it was preferable for all observers.

Incidentally, also in the above-described embodiment and Examples 1 and 2 described above, the image processing unit 12 uses the colorimetric values D1 (tristimulus values of the transparent subject image) of each point on the transparent subject image calculated by the imaging unit 16. (XYZ)) is color-converted by the preferred color reproduction processing unit 34 so as to achieve a preferable color reproduction, and color conversion is performed by the faithful reproduction reproduction processing unit 32 so that the appearance is faithfully reproduced. The color value D4 (tristimulus value (XYZ)) is output. That is, in the image processing unit 12, the observation illumination condition for the transmission image of the color reversal film and the observation illumination condition for the photographic print image are set, and the degree of adaptation (D), saturation C, and luminance value in the color appearance conversion formula are set. By appropriately setting various enhancement parameters such as brightness ratio, contrast, brightness J, hue h, colorfulness M, etc., colorimetric values D1 (tristimulus values of the transparent subject image ( XYZ)) to a color conversion table (profile) from the colorimetric value D4 (tristimulus value (XYZ)) of the reproduced image can be created.
Therefore, in the present invention, the color conversion table with the same appearance produced in this way, for example, the color conversion table produced using the optimum value obtained by improving the luminance ratio 30 times and the saturation C2.5% of the second embodiment. By using it, it is possible to obtain digital image data in which the appearance of the transparent original image of the color reversal film is reproduced on the photographic print in a preferable and faithful color reproduction.
In the above-described example, the color conversion table for converting the colorimetric value D1 into the colorimetric value D4 summarizes all conversions and corrections of contrast conversion, saturation conversion, chromatic adaptation correction, contrast correction, and flare correction. However, the present invention is not limited to this, and it may be defined for each of the conversions and corrections described above, or some of them may be combined into one color conversion table. Two color conversion tables may be used.

  For example, the processing process in the image processing method of the present invention includes a preferable appearance reproduction process having contrast conversion and saturation conversion in the preferable color reproduction processing unit 34, and a chromatic adaptation correction and contrast correction in the appearance faithful reproduction processing unit. It can be considered as three processes: a faithful reproduction process of appearance and a flare correction process in the flare correction unit 24. For this reason, the three processes of the preferable appearance reproduction process, the faithful reproduction process of the appearance, and the flare correction process may be used as one color conversion table. The conversion table may be used, but the faithful appearance reproduction processing and flare correction processing are fixedly determined by the observation environment of the reflection image such as the transmission image and the photographic print, whereas the preferable appearance reproduction processing is Therefore, it is possible to use one color conversion table as a preferable appearance reproduction process and three processes as a faithful reproduction process and a flare correction process as another color conversion table.

By the way, as a further preferred embodiment of the present invention, it is possible to change the color conversion table (color conversion profile) created in this way.
this is,
1. From the relationship between the goal of color conversion mapping by the image processing method of the present invention and the color gamut of the system,
This is because a) a phenomenon in which the color is saturated (a case where the contrast of light and dark colors of a high chroma color is not expressed well) and b) a case in which a contrast is generated more than necessary in a high chroma region may occur.
2. This is to achieve more preferable image reproduction by making it possible to reproduce the reproduced color in a desired direction (hue, saturation, brightness).
That is, in the case of reason 1 above, when only the color conversion of the image processing method of the present invention is performed, mapping outside the color gamut may be required due to the limitation of the color reproduction range of the system. is there. Therefore, in the present invention, it is more preferable to perform color conversion in consideration of the color gamut of the system.

As a method of changing the created color conversion table (color conversion profile), the following method is used, that is, the color conversion table (three-dimensional look-up disclosed in Japanese Patent Application Laid-Open No. 11-205620 related to the application of the present applicant). Uptable; 3DLUT) correction method can be used.
In this correction method, the current color and the target color are given to the color conversion table, and the color conversion table (3DLUT) is partially changed.

FIG. 6 shows a flowchart of an example of the present correction method.
First, it is assumed that a high-precision 3DLUT (M × M × M stages) is generated and stored in the memory. On the other hand, the target color and the desired color are determined in advance, the density thereof is measured, and input as target color data and desired color data, respectively, stored in a memory, or a working memory such as a CPU of the image processing unit 12 And is available at any time.

  For example, the target color may be any color as long as the user wants to change the finished color, and is not particularly limited. For example, skin color, blue sky color, plant color (green), etc. May be an important color. Further, the desired color which is the target of color conversion and finishing of these target colors may be set as appropriate according to user preference, color appearance, color reproduction fidelity, and observation conditions, and is not particularly limited. For example, in the method of the present invention, a skin color reproduced on an arbitrary photosensitive material may be set as a target color, and the target color may be matched with a target skin color of another photosensitive material, or reproduced on an arbitrary photosensitive material. The target blue color of the target color chart may be matched with the target blue color. Here, the target color may be one point for the same color when a color chart is used, but preferably when a different type of photosensitive material is used, a plurality of points are obtained for the same color and the average value is obtained. Should be used as data. It is also possible to select a plurality of colors as the target color.

Next, the 3DLUT is read from the memory, and using the 3DLUT grid point data and the acquired target color data, the distance between the 3DLUT grid point and the target color in the color space is expressed by, for example, the following equation: Calculate according to (5) and (6). The color space for calculating the distance between the grid point and the target color is not particularly limited. For example, even in a colorimetric space such as an L ^* a ^* b ^* space or an XYZ space, a density space such as an RGB color space or a CMY color space. It may be.

The distance between two colors in such a color space is defined as follows in the L ^* a ^* b ^* space and the RGB density space, for example.
-Distance of L ^* a ^* b ^* space The definition of the distance between two points (L1, a1, b1) and (L2, a2, b2) on the color space is the same as the equation of color difference, and the following equation (5) Defined.
ΔE = √ {(L1-L2) ² + (a1-a2) ² + (b1-b2) ² } (5)
In the case of density, the distance between two points (Db1, Dg1, Dr1) and (Db2, Dg2, Dr2) on the color space is defined by the following formula (6).
ΔD = √ {(Db1−Db2) ² + (Dg1−Dg2) ² + (Dr1−Dr2) ² } (6)

  A conversion amount necessary to convert the target color into the target desired color is calculated according to the calculated distance. It is possible to correct the corresponding grid point data by the conversion amount calculated in this way, determine the corrected grid point data, and create a corrected 3DLUT (M × M × M stages).

As a simple method for calculating the conversion amount according to the distance, determining the correction grid point data, and creating the correction 3DLUT, a density change for converting a density point of a target color in the color space into a target desired color. Operation may be performed so that the density change data decreases in proportion to the distance from the center around the data. For example, the density data is temporarily converted into L ^* a ^* b ^* values so that the distance from the data point corresponds to vision, and the above operation is performed on the L ^* a ^* b ^* color space. it can.

  Note that the method of changing the color conversion table in the present invention is not limited to the 3DLUT correction method described above, and the color conversion table may be changed by a matrix conversion method or other color conversion methods. Further, this color conversion change may be realized as a multi-stage process that produces the same effect as this, other than changing the color conversion table itself.

Example 3
Next, color conversion from a transparent image of a color reversal film to a print image is performed using one of a plurality of color conversion tables obtained by performing the image processing method of the present embodiment shown in FIG. The red reproduction was saturated, and the image reproduction was poor in light and dark.
A combination of the current color before correction shown in Table 1 and the target color was given, and a color conversion table corrected by the correction method shown in FIG. 6 was created.

  In Table 1, the color data No. 2-No. Up to 12 indicates red, and the difference between the target color and the current color (color difference, brightness difference, ab difference) is large, and it is desired to change, but other color data should not be changed I understand.

  As shown in Table 2, the corrected color conversion table thus obtained could be created with the following accuracy for the target color.

  In Table 2, the color data No. 2-No. In the red region up to 12, the difference between the target color and the output color after correction (color difference, brightness difference, ab difference) becomes small, and the output color after correction approaches the target color and is greatly improved, but the change is It can be seen that the difference between the target color and the corrected output color (color difference, brightness difference, ab difference) remains small, does not increase, and has not been changed so much even with other undesired color data.

  The image created using the color conversion table (profile) corrected in this way is richer in contrast in the target red region (No. 2 to No. 12 in the color data in Table 2) than the image before correction. A more preferable image was obtained.

Each of the above-described embodiments is merely an example of the present invention, and the present invention is not limited to these examples, and various modifications and improvements may be made without departing from the spirit of the present invention. Needless to say, it is good.
For example, the illuminance of the light source for observing the transmission image of the reversal film can be estimated from the performance value of the viewer or projector that observes the transmission image of the reversal film.
Further, the transmission image is not limited to the transmission image of the reversal film, and any transmission image or soft copy image may be used as long as observation illumination conditions for observing the transmission image can be acquired.

In addition, the flare rate of the aforementioned observation environment is usually indicated by the ratio of light directly reflected on the surface of the monitor or print. This value greatly depends on the surrounding environment of the environment in which the print is observed, and the flare rate is high when the periphery is covered with a white wall. By the way, the print flare rate in an environment where the surroundings are covered with a gray wall with illumination from directly above is about 2%. If the flare rate of the observation environment cannot be predicted in advance, this value should be used. It is preferable to use it.
Furthermore, the flare correction represented by the equation (4) can be implemented as so-called gradation change, and can usually be handled by preparing a plurality of 1DLUTs corresponding to the flare rate.

  The image processing method according to the first aspect of the present invention described above can be executed by computer control, and the technical scope of the present invention is such a program for computer control, further The present invention extends to a computer-readable recording medium that records this program.

1 is a block diagram of an embodiment of an image forming apparatus of the present invention including the image processing apparatus of the present invention. It is a block diagram of one Embodiment of the faithful reproduction processing unit of appearance of the image processing apparatus shown in FIG. It is a block diagram of one Embodiment of the preferable color reproduction processing unit of the image processing apparatus shown in FIG. It is a flowchart explaining an example of the flow of a process in one Embodiment of the image processing method of this invention. It is a graph which shows the result of the psychological evaluation of the print output image obtained in Example 2 of this invention. It is a flowchart explaining an example of the flow of the process of the correction method of the color conversion table used for the image processing method of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Image forming apparatus 12 Image processing unit 14 Image output unit 16 Imaging unit 18 Transmission image observation condition acquisition unit 20 Reproduction image observation condition acquisition unit 22 Appearance faithful reproduction conversion unit 22a Appearance faithful reproduction order conversion unit 22b Appearance faithful reproduction reverse Conversion unit
24 Flare correction unit 26, 26a, 26b, 40a, 40b Color adaptation conversion unit 28, 28a, 28b, 42a, 42b Nonlinear signal conversion unit 30, 30a, 30b, 44a, 44b Color attribute conversion unit 32 Faithful faithful reproduction processing unit 34 Preferred color reproduction processing unit 36 Contrast / saturation conversion unit 36a Color appearance order conversion unit 36b Color appearance reverse conversion units 38a, 38b Transmission image observation condition setting unit

Claims (20)

Obtain digital data of a transparent image of a color reversal film, calculate a colorimetric value of the transparent image from this digital data,
Obtaining chromaticity information and illuminance information of a light source that illuminates the transmitted image of the color reversal film to be observed;
Contrast conversion and saturation conversion are performed on the colorimetric value of the transmission image based on the chromaticity value when the adaptive luminance is higher than the adaptive luminance obtained from the acquired chromaticity information and illuminance information of the light source. At least one is performed to obtain a converted colorimetric value of the observed transmission image,
Chromatic adaptation correction is performed on the converted colorimetric values of the observed transmission image from the chromaticity information and illuminance information of the light source,
Contrast correction is performed on the converted colorimetric value of the observed transmission image from the illuminance information of the light source,
A colorimetric value to be output by correcting the converted colorimetric value of the transparent image subjected to the color adaptation correction and the contrast correction from the flare amount when the observed transmission image is output as a photographic print image An image processing method characterized in that:   2. The image processing method according to claim 1, wherein in the contrast conversion, a conversion corresponding to an observation illuminance of the transmission image of the color reversal film being virtually in a range of 30,000 to 300,000 lux is performed.   In the saturation conversion, an increase ratio of saturation is 1.0 to 1.2 times, and an observation illuminance of the transmission image of the color reversal film is 30,000 to 300,000 lux. An image processing method described in 1.   In the saturation conversion, as an optimal value, the increase ratio of saturation is in the range of 1.0 to 1.05 times, and the observation illuminance of the transmission image of the color reversal film is 50,000 to 200,000 lux. The image processing method according to claim 1, wherein the image processing method is a range.   2. The chromaticity value when an adaptation brightness higher than the adaptation brightness obtained from the chromaticity information and the illuminance information of the light source is a chromaticity value when it is assumed that the adaptation is completely or substantially adapted to the light source. The image processing method in any one of -4.   The image processing method according to claim 1, wherein an enhancement parameter set in at least one of the contrast conversion and the saturation conversion is at least one of a luminance ratio, saturation, contrast, and colorfulness. .   The image processing method according to claim 1, wherein the colorimetric value is a tristimulus value.   At least one of the contrast conversion and the saturation conversion, the chromatic adaptation correction, the contrast correction, and the flare amount correction are performed by measuring the colorimetric value of the transparent image from the colorimetric value of the transparent image. The image processing method according to claim 1, wherein the image processing method is created as a three-dimensional color conversion table for conversion into values.   The image processing method according to claim 8, wherein color conversion that changes a part of the three-dimensional color conversion table is added. The three-dimensional color conversion table is a color conversion three-dimensional lookup table;
Necessary for obtaining the distance from the color correction target color to the grid point of the three-dimensional lookup table in the color space and converting the target color to the target desired color according to the obtained distance. The image processing method according to claim 9, wherein a color conversion that changes a part of the three-dimensional color conversion table is added to the three-dimensional color conversion table by obtaining a conversion amount of the grid points and correcting the three-dimensional lookup table. . An image pickup means for photoelectrically reading a transmission image of a color reversal film, obtaining digital data of the transmission image, and calculating a colorimetric value of the transmission image from the digital data;
Obtaining means for obtaining chromaticity information and illuminance information of a light source that illuminates a transmitted image of the color reversal film to be observed;
Contrast conversion and saturation for the colorimetric value of the observed transmission image based on the chromaticity value when the adaptation luminance is set higher than the adaptation luminance obtained from the acquired chromaticity information and illuminance information of the light source. Conversion means for obtaining a converted colorimetric value of the transmission image by performing at least one of degree conversion;
Chromatic adaptation correction means for performing chromatic adaptation correction on the converted colorimetric value of the observed transmission image from the chromaticity information and illuminance information of the acquired light source;
Contrast correction means for performing contrast correction on the converted colorimetric value of the observed transmission image from the illuminance information of the light source;
Flare correction for correcting a flare amount according to the observation environment of the photographic print image of the observed transmission image with respect to the converted colorimetric value of the observed transmission image subjected to the chromatic adaptation correction and the contrast correction And an image processing apparatus.   The said conversion means performs conversion equivalent to that the observation illumination intensity of the said transmission image of the said color reversal film exists in the range of 30,000-300,000 Lux virtually as said contrast conversion. Image processing device.   As the saturation conversion, the conversion means has a saturation increase ratio of 1.0 to 1.2 times, and an observation illuminance of the transmission image of the color reversal film is 30,000 to 300,000 lux. The image processing apparatus according to claim 11 or 12, which performs conversion.   The conversion means has an increase ratio of saturation of 1.0 to 1.05 times as an optimum value of the saturation conversion, and an observation illuminance of the transmission image of the color reversal film is 50,000 to 200. The image processing apparatus according to claim 11, wherein the conversion is performed in a range of 1,000 lux.   12. The chromaticity value when an adaptation brightness higher than the adaptation brightness obtained from the chromaticity information and the illuminance information of the light source is a chromaticity value when it is assumed that the adaptation to the light source is complete or almost complete. The image processing apparatus in any one of -14.   The image processing apparatus according to claim 11, wherein an enhancement parameter set in at least one of the contrast conversion and the saturation conversion is at least one of a luminance ratio, saturation, contrast, and colorfulness. .   The image processing apparatus according to claim 11, wherein the colorimetric value is a tristimulus value. An image processing apparatus according to any one of claims 11 to 17,
An image forming apparatus comprising: image output means for outputting a photographic print image based on output image data subjected to correction processing by the image processing apparatus.   An image processing program for executing the image processing method according to claim 1 by computer control.   A computer-readable recording medium on which the image processing program according to claim 19 is recorded.

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