JP2002090911A - Image forming method and image forming device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain high-grade digital image data decreased in an image noise arising from silver halide and developing silver even from a silver halide photographic sensitive material of which the processing has been completed in the state of having the silver halide and the developing silver. SOLUTION: In the image forming method reading the image information developed to the sensible image after development of the silver halide photographic sensitive material through an image sensor and converting the image information to digital image information, the reading of the image information in the non-photosensitive wavelength region of the silver halide photographic sensitive material is carried out substantially prior to development processing and the resultant image information in the non-photosensitive wavelength region and the image information read after the development processing are used for arithmetic processing.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION An image forming method for obtaining high-quality digital image data from a silver halide color photographic light-sensitive material which has been processed with silver halide and developed silver, and an image forming method used in the method Related to the device.

[0002]

2. Description of the Related Art Photosensitive materials utilizing silver halide have been increasingly developed in recent years, and it is now possible to easily obtain high-quality color images. For example, in a system generally called a color photograph, a photograph is taken using a color negative film, and image information recorded on the developed color negative film is optically printed on color photographic paper to obtain a color print. In recent years, this process has been highly developed, and with the spread of color labs, which are large-scale centralized bases that produce large amounts of color prints with high efficiency, or so-called mini labs, which are small, simple printer processors installed in stores, But it is easy to enjoy color photos.

[0003] The principle of color photography that is currently widespread employs color reproduction by a subtractive color method. In a general color negative, a light-sensitive layer using a silver halide emulsion, which is a light-sensitive element provided with photosensitivity in the blue, green, and red regions, is provided on a transmission support. So-called color couplers for forming complementary colors of yellow, magenta and cyan dyes are contained in combination.
The color negative film that has been imagewise exposed by photography is developed in a color developer containing an aromatic primary amine developing agent. At this time, the exposed silver halide grains are developed or reduced by the developing agent, and respective dyes are formed by a coupling reaction between the oxidized product of the developing agent and the color coupler described above. Metal silver (hereinafter, referred to as “developed silver”) generated by development and unreacted silver halide (hereinafter, also simply referred to as “silver halide”)
A dye image can be obtained by removing them by bleaching and fixing, respectively. A color photographic paper, which is a color photographic material in which a photosensitive layer having a similar combination of a photosensitive wavelength region and a color hue is coated on a reflective support, is subjected to optical exposure through a color negative film after development processing, and By performing the color development, bleaching, and fixing processes described above, a color print composed of a dye image reproducing the original scene can be obtained.

[0004] Although these systems are now widespread, demands for their simplicity are increasing. First, the processing bath for performing the color development, bleaching, and fixing described above requires precise control of its composition and temperature, and requires specialized knowledge and skilled operations. Second, these processing solutions contain substances that must be environmentally regulated, such as color developing agents and iron chelates, which are bleaching agents. Is often required. Third, although the development process has been shortened in recent years, these development processes require a long time, and it cannot be said that it is still insufficient for a demand for quickly reproducing a recorded image.

[0005] From such a background, there is a demand for reducing the environmental load and improving simplicity by constructing a system that does not use a color developing agent or a bleaching agent used in current color image forming systems. Is growing more and more.

On the other hand, an image formed on a color negative film is optically read by using a scanner or the like, converted into an electric signal, and then subjected to image processing to produce digital image data once. A method of transferring image information to a recording material is known. In this case, it is possible to obtain a finished print through various types of non-silver salt printers such as an inkjet printer, a sublimation printer, or an electrophotographic system, as well as a digital printer that obtains a finished color print by scanning and exposing a photosensitive material such as color paper. It is possible.

In Japanese Patent Application No. Hei 10-324496, the present inventors disclosed visible image information and invisible (infrared) image information from a color negative film in which unreacted silver halide and metallic silver (developed silver) remained. An image forming method for reducing image noise by reading and subtracting invisible (infrared) image information from visible image information is disclosed. Examples of the image noise include electrical noise generated during scanner reading, dust, scratches, and mold on the surface of a photographic film caused by factors such as physical contact during a development process and a scanner reading process and an environment where the image is left. However, in the same application, it refers to unreacted silver halide and developed silver, which cause a reduction in graininess and color reproducibility of an image. That is, in the developing process of a normal color negative film, the residual silver is caused by incomplete processing conditions of the bleaching and fixing processes. Processing conditions and factors that cause image noise are classified into the following six. Residual silver halide grains due to insufficient fixing process. Residual developed silver particles due to insufficient bleaching process. Silver halide grains due to no fixing step (completely omitted). Developed silver particles that have not been bleached (completely omitted). Residual silver halide and developed silver grains due to insufficient bleaching and fixing. Silver halide and developed silver grains due to lack of bleaching and fixing (completely omitted).

The dye image information is read only in the visible wavelength region where the dye has absorption. Therefore, the invisible (infrared) wavelength region of the color negative film after the development processing causes an Information can be read.

Developed silver is formed imagewise with the formation of a dye, and the amount of the developed silver varies greatly depending on the photographing conditions, while the amount of scratches, dust, and unreacted silver halide on the surface of the color negative film is reduced. Is almost constant. Further, the developed silver has a wavelength characteristic that the light absorption is almost constant at any wavelength, whereas the absorption of silver halide is larger on the short-wave side, and gradually decreases as the wavelength shifts to the long-wave side. . As described above, since the properties of silver halide and developed silver are significantly different, under the above-mentioned processing conditions,
A work process in which each is read separately is desired.

As described in Japanese Patent Application No. 10-324496, in the method of reading in the invisible (infrared) wavelength region, image information of unreacted silver halide and image data of developed silver cannot be read separately. The effect of the "arithmetic processing for improving the image quality" is an obvious limitation.

[0011]

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems, and an object of the present invention is to provide a silver halide color photographic light-sensitive material which has been processed with silver halide and developed silver. However, it is an object of the present invention to provide a method for obtaining high-quality digital image data in which image noise derived from silver halide and developed silver is reduced. Another object of the present invention is to provide an apparatus employing the method.

[0012]

The above objects of the present invention have been attained by the following constitutions.

1. In an image forming method of developing a silver halide color photographic light-sensitive material, reading the visualized image information through an image sensor, and converting the image information into digital image information, the silver halide color photographic material is substantially subjected to the silver halide An image forming method comprising: reading image information in a non-photosensitive wavelength region of a color photographic light-sensitive material; and using the obtained image information in the non-photosensitive wavelength region and image information read after development processing in an arithmetic process.

2. 2. The image forming method according to claim 1, wherein the developing process includes a color developing process and a bleaching process without going through a fixing process, and the image information in the non-photosensitive wavelength region is silver halide image information.

3. The development processing comprises only a color development processing step that does not go through both bleaching and fixing steps, the image information in the non-photosensitive wavelength region is silver halide image information, and after the development process, the image information in the non-photosensitive wavelength region 2. The image forming method according to 1, wherein the image reading is performed again to obtain image information including a silver halide image and a developed silver image.

4. The image forming method according to any one of claims 1 to 3, wherein the non-photosensitive wavelength region of the silver halide color photographic light-sensitive material is an infrared wavelength region.

5. Any one of claims 1 to 4, wherein the development processing is a heat development method in which a processing sheet and a silver halide color photographic light-sensitive material are bonded and heated.
Item.

6. In an image forming apparatus which develops a silver halide color photographic light-sensitive material by a developing means, reads the visualized image information through an image sensor, and converts the image information into digital image information, the image forming apparatus substantially develops the image information. Before processing, means for reading image information in the non-photosensitive wavelength region of the silver halide color photographic light-sensitive material, means for using the image information in the non-photosensitive wavelength region and the image information read after the development process for arithmetic processing, An image forming apparatus comprising:

[7] 7. The image forming apparatus according to claim 6, wherein the developing means comprises a color developing process and a bleaching process which do not go through a fixing process, and the image information in the non-photosensitive wavelength region is silver halide image information.

8. The developing means comprises only a color developing step which does not go through both bleaching and fixing steps, the image information in the non-photosensitive wavelength region is silver halide image information, and after the developing process, the image in the non-photosensitive wavelength region 7. The image forming apparatus according to 6, wherein the information is read again to obtain image information including a silver halide image and a developed silver image.

9. The image forming apparatus according to any one of claims 6 to 8, wherein the non-photosensitive wavelength region of the silver halide color photographic material is an infrared wavelength region.

10. The image forming apparatus according to any one of claims 6 to 9, wherein the developing means is a thermal developing method in which a processing sheet and a silver halide color photographic light-sensitive material are bonded and heated.

Hereinafter, the present invention will be described in detail. In the present invention, "silver halide color photographic light-sensitive material"
“Photo film” or “color negative film”) includes, for example, a color negative film known as a conventional photographic film and a Centuria film manufactured by Konica Corporation. Further, in the present invention, as in the case of the conventional photographic film, a color negative film designed to be more suitable for reading by a film scanner, without assuming a photographic print production work by projection exposure to photographic paper using an analog printer, good.

As such a color negative film, for example, as described in Japanese Patent Application No. 11-119701, a photosensitive layer (hereinafter referred to as a luminance layer) for recording luminance information in order to extract luminance information and color information of a digital color image. In one embodiment, the photosensitive layer further includes a photosensitive layer for recording color information (hereinafter, also referred to as a color information recording layer) independently.

The “image sensor” includes a light receiving element (also referred to as a “CCD”) that converts an amount of light energy per unit time projected on a specific surface area into an electric signal.
Examples of such a device include a one-dimensional line sensor in which monochromatic (no color discrimination ability) CCDs having sensitivity to a visible light wavelength region and an infrared wavelength region are arranged in a line, or a monochromatic CCD is arranged vertically and horizontally in two dimensions. And the type of an area sensor arranged in the area.

"Reading through an image sensor and converting it into digital image information" corresponds to the three primary color components of red, green, and blue, respectively, which are color (image) information of a subject recorded on a color negative film. The amount of each of yellow, magenta, and cyan dyes ("dye image information")
Is replaced with electrical signal information using the above-described “image sensor”, “light source”, and “color separation filter”. The electrical signal information obtained in this manner is referred to as “digital image information”. In the present invention, the "image sensor", "light source", and "color separation filter" required for conversion into digital image information are referred to as "image sensor unit". Further, such a process is referred to as an “image forming method”.

"Image information in the non-light-sensitive wavelength region of a silver halide color photographic light-sensitive material" refers to light that does not include light components in the light-sensitive wavelength region of the color negative film so that the color negative film is not exposed to light. Refers to the actual image information of the photographic film observed using. Claims 4 and 9
As described in above, the non-photosensitive wavelength region of the silver halide color photographic light-sensitive material is desirably an infrared wavelength region.

In the present invention, "substantially before the development processing" refers to the process from the production process of the color negative film to immediately before the image is taken (exposed) by the camera, and from the image taken by the camera and then developed and processed. Can be defined in two sections immediately before appears.

In the present invention, "the image information is read in the non-light-sensitive wavelength region of the silver halide color photographic light-sensitive material before the substantial development processing" means that the actual image information of the photographic film is in the range described above. Means that reading is performed.

"Using the obtained image information in the non-photosensitive wavelength region and the image information read after the development processing in the arithmetic processing" means that the image components of silver halide and developed silver which cause image noise are individually determined. In order to perform the arithmetic processing to remove, from the image information read after the development processing consisting of the silver halide image and the developed silver image, only the developed silver image using the image information read before the development processing consisting of only the silver halide image information To achieve the above arithmetic processing.

The "development processing means" in the present invention is a transport and chemical process for converting latent image information of a subject recorded on a photographic film by photographing into optically readable dye image information. Refers to a unit consisting of mechanisms. Even if the chemical processing mechanism is a liquid developing mechanism called “C-41 processing” used for normal color negative film processing, a processing sheet containing a developing agent is used as described in claim 5 or 10. Alternatively, any type of heat development mechanism may be used in which the film is swelled with water and then bonded, and then pressure-bonded and heated by a heat block or a drum. In the present invention, it is preferable to use a heat developing mechanism because the apparatus can be downsized, the amount of processing waste liquid is small, and maintenance can be simplified.

"Reading means" refers to an "image sensor unit" comprising the "image sensor", "light source", and "color separation filter".

The means for reading image information in the non-photosensitive wavelength region of the silver halide color photographic light-sensitive material prior to the substantial development processing as described in claim 6 includes the following embodiments. . Note that “substantially before the development processing” is also simply referred to as “before the development processing”. 1. In addition to an image sensor unit used for reading after development processing, an image sensor unit for reading before development processing is provided. 2. Reading before the development processing is performed using an image sensor unit used for reading after the development processing.

FIG. 1 is a cross-sectional view of an image forming apparatus that is optimal as the image sensor unit described in the above item 1. FIG.
2 shows a cross-sectional view of an image forming apparatus that is optimal as the image sensor unit described in 2 above. FIG. 3 is a schematic view of an image forming process in the image forming apparatus used as the image sensor unit described in 1 above. FIG. 4 is a schematic view of an image forming process in the image forming apparatus used as the image sensor unit described in the above item 2.

The image forming apparatus described as the image sensor unit described in 1 has an advantage that high processing capability can be expected, but has a disadvantage that the cost is increased by providing two image sensor units. Further, the image forming apparatus described as the image sensor unit according to the above 2 requires only one image sensor unit.
It has the advantage of being able to reduce the size of the apparatus, but has the disadvantage that the transport section is somewhat complicated and the processing capacity is reduced.

In the present invention, "reading image information in the non-light-sensitive wavelength region of the silver halide color photographic light-sensitive material before substantially performing development processing" is performed in the image forming apparatus. Rather, for example, the production process of a color negative film or may be performed immediately before handing over to a consumer, but in such an embodiment,
The “image information in the non-light-sensitive wavelength region of the silver halide color photographic light-sensitive material” read in advance by a scanner is stored in a specific storage medium, and means is required to be provided to the image forming apparatus.

As an example of the storage medium, a special film in which an IC chip is incorporated in a color negative film is used.
The “image information in the non-light-sensitive wavelength region of the silver halide color photographic light-sensitive material” previously read by the scanner is stored in the IC chip, and the image information stored in the IC chip is read by the image forming apparatus. An embodiment is mentioned. Alternatively, in place of the IC chip, a color negative film having a magnetic recording layer, in which the magnetic recording layer is used as a storage medium, may be used. Alternatively, the image information is not recorded on the color negative film itself. Instead, the image information is sold with an ID number for checking the image information and the color negative film, a bar code, or the like, and the image forming apparatus accepts the processing. Sometimes, through the means for automatically reading the ID number and the barcode, and the communication means,
The ID number and the image information corresponding to the barcode are automatically searched from a database in which the image information is stored,
An embodiment having a means for acquiring may be used.

The "arithmetic processing" in the present invention refers to the image information generated by the development processing in the image forming apparatus provided with the "development processing means" and the "reading means" according to claim 6. This refers to image processing performed to eliminate unnecessary information other than the above from the image information.

The "means for using the image information in the non-photosensitive wavelength region and the image information read after the development processing for the arithmetic processing" according to the sixth aspect of the present invention is to execute the arithmetic processing represented by the following equations (1) to (3). Software to be used is given as an example.

[0040]

(Equation 1)

In the above formula (1), R, G and B are visible color separation image information read after the development processing, and are image information comprising a dye, silver halide and a developed silver image. IR1 is image information composed of a silver halide image read in a non-photosensitive wavelength region (for example, an infrared wavelength region) of the color negative film before the development processing. R ', G' and B 'are image information composed of a dye and a developed silver image obtained by subtracting the silver halide image information occupying each of R, G and B.

In the above formula (2), IR1 has the same meaning as IR1 in the above formula (1) and is image information composed of a silver halide image. IR2, after the development processing,
This is image information composed of silver halide and developed silver read in a non-photosensitive wavelength region (for example, an infrared wavelength region) of the color negative film. IR2 'is image information substantially consisting only of a developed silver image obtained by subtracting the silver halide image information (IR1) occupying IR2.

In the above formula (3), R ', G' and B 'have the same meaning as R', G 'and B' in the above formula (1), and are image information composed of a dye and a developed silver image. is there. IR
2 'is IR2' in the above equation (2), which is image information substantially consisting only of a developed silver image. R ", G" and B "
Is image information consisting essentially of a dye image obtained by subtracting the image information of the developed silver image occupying R ', G' and B '.

The numerical values in the determinants (1) and (3) and the coefficients in the expression (2) are temporary values, and it is necessary to set an optimum value for each color negative film in advance. Further, in reading a silver halide image from a color negative film before development processing, which is a feature of the present invention, means for aligning frames between frames, which is a prerequisite for performing the above arithmetic processing, is required. As an example of the positioning means, there is a mode in which marking is performed on a portion other than the photographic frame in which the subject information is recorded, and reading of a wide range including an area where the marking exists other than the photographic frame. The marking is desirably made with a specific scratch or a specific shape to remove an edge of the color negative film. The following six processing conditions may cause unnecessary information other than the dye image information. Residual silver halide grains due to insufficient fixing process. Residual developed silver particles due to insufficient bleaching process. Silver halide grains due to no fixing step (completely omitted). Developed silver particles that have not been bleached (completely omitted). Residual silver halide and developed silver grains due to insufficient bleaching and fixing. Silver halide and developed silver grains due to lack of bleaching and fixing (completely omitted).

Since the developed silver is formed imagewise with the formation of the dye, the amount of the developed silver varies greatly depending on the photographing conditions, whereas the amount of unreacted silver halide is almost constant. Furthermore, while the absorption of developed silver is constant at any wavelength,
Silver halide has a wavelength characteristic in which the absorption is higher on the short-wave side and gradually decreases as the wavelength shifts to the long-wave side. As described above, since the properties of silver halide and developed silver are significantly different,
The above-described arithmetic processing using the reading conditions and the read image for separately reading each of them is required.

According to the image forming method of the present invention, in which the color negative film is read in the non-photosensitive wavelength region before the development processing, the silver halide and the developed silver image can be read separately. An improvement in quality under the conditions described above is achieved.

"The developing process comprises a color developing process and a bleaching process, which do not go through a fixing process,"
Refers to the above. Further, "the development processing comprises only the color development processing step which does not go through both the bleaching and fixing steps" according to claims 3 and 8 means the above.

[0048]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The flow chart of the image forming method according to the present invention is shown below.

[0049]

(Equation 2)

An embodiment of the image forming apparatus of the present invention provided with an image sensor unit for reading before development processing, separately from an image sensor unit used for reading after development processing, will be described in further detail with reference to the drawings.

FIG. 1 is a cross-sectional view showing an example of an image forming apparatus most suitable as an image sensor unit.

As shown in FIG. 1, a color negative film 1 is provided from a cartridge 101 set in the image forming apparatus.
06 is automatically conveyed, and the transmitted light from the color negative film irradiated with the infrared light source 104 is transmitted to the CCD camera 103.
Is read by Next, the color negative film 106
Is passed through the processing bath 105, passed through the drying process, and then transported to the image sensor unit. Light emitted from the light source 108 to the color negative film is infrared, red, green,
The light is sequentially switched to blue, and each transmitted light is read by the CCD camera 107. The read transmitted light information is
After the image processing is performed by the signal processing unit 109, a monitor display of the processing terminal 111, storage in a storage medium, and the like are performed. After reading the color negative film, the collection unit 11
0, and then discarded.

Referring to FIG. 3, the details of the image forming process will be described. FIG. 3 is a block diagram showing an example of an image forming process in the image forming apparatus used as the image sensor unit of FIG. Infrared light from a light source (LED) 5 is irradiated onto the color negative film 1 before development through a diffusion plate 6 and a condenser lens 7. The transmitted light from the color negative film 1 passes through a condensing lens 8 and passes through a CCD.
It is projected on nine surfaces. The signal information of the silver halide image projected on the surface of the CCD 9 is amplified by an amplifier 10 and then converted into digital image data by an A / D conversion circuit 11 to perform a gradation correction process (I). 1
After that, the data is temporarily stored in the memory 13. On the other hand, white light from a light source (halogen lamp) 5 ′ is irradiated on the color negative film 1 ′ after the development processing via a diffusion plate 6, a filter turret 14, and a condenser lens 7. The transmitted light from the color negative film 1 ′ is projected on a CCD 9 through a condenser lens 8. CCD9
R, G, and B signal information comprising a dye, a silver halide, and a developed silver image projected on a surface, and silver halide,
The infrared signal information composed of the developed silver image is amplified by an amplifier 10, converted to digital image data by an A / D conversion circuit 11, passed through an image processing process (I) 12 for performing a gradation correction process, and stored in a memory. 13 'is temporarily stored.

The silver halide image information stored in the memory 13, the dye stored in the memory 13 ′, silver halide,
And image information of each of R, G, and B comprising a developed silver image,
The infrared image information composed of silver halide and developed silver is read out by the image processing process (II) 15, and only the dye image information is extracted by the subtraction process 16, and then stored in the external memory 17.

An embodiment of the image forming apparatus of the present invention in which reading is performed before the development process using an image sensor unit used for reading after the development process will be described in further detail with reference to the drawings.

FIG. 2 is a cross-sectional view showing an example of an image forming apparatus which is optimal as another image sensor unit.

As shown in FIG. 2, the patrone 201 set in the image forming apparatus outputs a color negative film 2
06 is automatically conveyed, and the transmitted light from the color negative film irradiated with the infrared light source 204 is transmitted to the CCD camera 203.
Is read by Next, the color negative film 206
After passing through the processing bath 205 and passing through the drying process, the is transported to the image sensor unit again. This time, the light irradiated to the color negative film is sequentially switched to infrared, red, green, and blue, and each transmitted light is transmitted to the CCD camera 20.
3 is read. The read transmitted light information is subjected to image processing by the signal processing unit 207, and is then displayed on a monitor of the processing terminal 209 and stored in a storage medium. After reading the color negative film, the collection unit 208
And then disposed of.

The details of the image forming process will be described with reference to FIG. FIG. 4 is a block diagram showing an example of an image forming process in the image forming apparatus used as the image sensor unit of FIG. As shown in FIG. 4, white light from a light source (halogen lamp) 5 passes through a diffusion plate 6, an infrared filter (IR) of a filter turret 14, and a condenser lens 7, and is then subjected to a color negative film 1 before development processing.
Irradiated on top. The transmitted light from the color negative film 1 is projected onto a CCD 9 via a condenser lens 8.
The signal information of the silver halide image projected on the CCD 9 is amplified by an amplifier 10 and then amplified by an A / D conversion circuit 1.
1 is converted into digital image data by an image processing process (I) 12 for performing gradation correction processing,
Is temporarily stored.

Each of R, G, and B image information composed of silver halide image information, dye, silver halide, and developed silver image stored in the memory 13 and an infrared image composed of silver halide and developed silver Information is in the image processing process (II) 1
5 and only the dye image information is extracted by the subtraction process 16 and stored in the external memory 17.

Referring to FIG. 5, the details of the arithmetic processing will be described.
FIG. 5 is a diagram showing the arithmetic processing in the image formation of the present invention. As shown in FIG. 5A, reading of the infrared image information of the color negative film 307 before the development processing is performed in a wider range than the shooting screen (the area surrounded by wavy lines 301 and 302). Then, an overlap area 303 overlapping with each other is secured. Furthermore, markings 3 for scratches or missing portions having different shapes used for alignment.
05 and 306 are preferably provided between the overlap area 303 and the overlap area 303. Using the markings 305 and 306, a combined image 311 in which the infrared image information before the development processing is combined is generated (image alignment combining processing).

On the other hand, as shown in FIG. 5B, reading of the infrared, red, green, and blue color separation image information of the developed color negative film 310 is performed on a reading screen 309 which is wider than the photographing screen 308. Do with. By using the markings 305 and 306 of the composite image 311 obtained by combining the infrared image information before the development processing and the markings 305 and 306 of the reading screen 309 which are the color separation image information read after the development processing, As shown in c), infrared image information of the photographing screen area 312 is extracted (photographing screen area detection processing). Then, as shown in FIG. 5D, the developed color negative film 310 corresponding to the obtained photographing screen area is obtained.
, Infrared, red, green, and blue color separation image information 313 and the infrared image information 31 of the color negative film 307 before development processing
4 is used for arithmetic processing (image extraction processing for subtraction processing).

[0062]

EXAMPLES The effects of the present invention will be described below with reference to examples, but embodiments are not limited thereto.

Example 1 (Photographing) A Konica Centuria 100 color negative film was loaded into a Nikon single-lens reflex camera (F4).
A Macbeth color chart and a gray standard reflection plate having a surface reflectance of 18% were photographed in the same screen. (Reading before development processing) Four types of LED light sources (manufacturer color: maximum peak wavelength / manufactured by Stanley Infrared: 850 nm, Stanley Red: 635 nm, Nichia Chemical Green: 535 nm, Nichia Chemical Blue: 470 nm) and 2048 × 2048
It is arranged between monochrome CCDs of pixels (KX4 manufactured by Eastman Kodak Company), and only the infrared LED is turned on.
The infrared image information (IR1) before the development process is converted to a monochrome CCD
Read by. (Development) (C-41 color development processing) (Reading after development processing) The developed film obtained is obtained by switching between four types of LED light sources (manufacturer color: maximum peak wavelength / manufactured by Stanley, infrared: 850)
nm, Stanley red: 635 nm, Nichia green: 535 nm, Nichia blue: 470 nm)
And a monochrome CCD of 2048 × 2048 pixels (KX4 manufactured by Eastman Kodak Company)
The light source was sequentially switched, and each color separation image information of infrared (IR2), red (R), green (G), and blue (B) of each sample was read by a monochrome CCD. (Preparation of comparative digital image data)-Operation The following operation was performed using only the infrared (IR2), red (R), green (G), and blue (B) color separation image information read after the development processing. Thereafter, color digital image data was prepared. Further, before performing the arithmetic processing of the following equation (4), each of the infrared (IR2), red (R), green (G), and blue (B) image information is subjected to the following preprocessing. I created a program to apply. 1. Image processing negative → positive reversal processing. 2. Histogram normalization processing to maximize the gradation distribution. 3. Look-up table processing for correcting the camera output characteristics so as to be linear with respect to the amount of incident light. 4. Logarithmic conversion processing of each image information for performing the calculation processing of the following equation (4).

Further, before performing the arithmetic processing, the infrared (IR)
2) In each of the color-separated image information of red (R), green (G), and blue (B), a plurality of missing portions having different shapes attached to the edge of the film are all matched between the color-separated image information. Was subjected to distortion correction processing.

[0065]

(Equation 3)

Print The obtained digital image data is converted to 300 dpi (dpi) using a digital minilab system QD-21 manufactured by Konica Corporation.
Is defined as pixel density per 2.54 cm) and output to Konica Color Paper Type QAA7 at a resolution of
An A4 size comparative digital print 101 was produced. (Preparation of digital image data of the present invention) Calculations Infrared image information (IR1) read before development processing and color separation images of red (R), green (G), and blue (B) read after development processing Using information, R ′,
G 'and B' image data were prepared. In addition, infrared (I
R1), a program for performing the following pre-processing before the arithmetic processing of the following equation (5) was created for each image information of red (R), green (G), and blue (B). . 1. Image processing negative → positive reversal processing. 2. Histogram normalization processing to maximize the gradation distribution. 3. Look-up table processing for correcting the camera output characteristics so as to be linear with respect to the amount of incident light. 4. Logarithmic conversion processing of each image information for performing the arithmetic processing of the following equation (5).

Further, before performing the arithmetic processing, the infrared (IR)
1) In each of the color separation image information of red (R), green (G), and blue (B), all the plurality of missing portions having different shapes attached to the edge of the film match between the color separation image information. Was subjected to distortion correction processing.

[0068]

(Equation 4)

Next, using the infrared image information (IR1) read before the arithmetic processing and the infrared image information (IR2) read after the developing processing, IR2 'image data was produced by the following arithmetic expression. Furthermore, infrared (IR1) and infrared (I
For each image information of R), a program for performing the following pre-processing before creating the arithmetic processing of the following equation (5 ′) was created. 1. Image processing negative → positive reversal processing. 2. Histogram normalization processing to maximize the gradation distribution. 3. Look-up table processing for correcting the camera output characteristics so as to be linear with respect to the amount of incident light. 4. Logarithmic conversion processing of each image information for performing the arithmetic processing of the following equation (5 ').

Before performing the arithmetic processing, distortion correction processing was performed on the IR1 and IR2 image information so that all of the plurality of missing portions having different shapes attached to the edges of the film matched between the respective image information. .

Expression (5 ′) IR2 ′ = IR2−0.21 × IR1 Further, using the R ′, G ′, B ′, and IR2 ′ image data, R ″, G ″, B ″ After producing the image data, color digital image data was produced.
Further, before performing the arithmetic processing of the following equation (6), each of the infrared (IR2 ′), red (R ′), green (G ′), and blue (B ′) image information is A program to perform the preprocessing shown was created. 1. Image processing negative → positive reversal processing. 2. Histogram normalization processing to maximize the gradation distribution. 3. Look-up table processing for correcting the camera output characteristics so as to be linear with respect to the amount of incident light. 4. Logarithmic conversion processing of each image information for performing the arithmetic processing of the following equation (6).

Before performing the arithmetic processing, the infrared (IR2 ')
In each of the red (R '), green (G'), and blue (B ') color separation image information, all of the plurality of missing portions having different shapes attached to the edge of the film match between the color separation image information. Was subjected to distortion correction processing.

[0073]

(Equation 5)

Print The obtained digital image data is output to a Konica color paper type QAA7 at a resolution of 300 dpi using a Konica digital minilab system QD-21.
Four versions of the digital print 102 of the present invention were produced. (Sensory Evaluation) Ten randomly extracted persons were used as evaluation panelists to perform sensory evaluation on color reproducibility from the Macbeth color chart scene of the produced prints and roughness on the gray standard reflector scene. The following is bad:
Good: The average value of the evaluation points of the five-level sensory evaluation of 5 is shown.

[0075] As is clear from the obtained results, there was no significant difference in the sensory evaluation average points regarding the color reproducibility of 101 and 102. However, regarding the roughness, the print of the 102 print of the present invention was clearly different from the comparative 101. Improvement was observed.
As a result, it has been proved that arithmetic processing can be performed using image information read in the non-photosensitive wavelength region of the color negative film before the development processing to reduce image noise caused by a silver halide image.

Example 2 (Photographing) A Konica Centuria 100 color negative film was loaded into a Nikon single-lens reflex camera (F4).
A Macbeth color chart and a gray standard reflection plate having a surface reflectance of 18% were photographed in the same screen. (Preparation of treatment sheet) A treatment sheet was prepared by sequentially coating layers having the following composition on a subbed transparent polyethylene terephthalate (PEN) support having a thickness of 85 µm.
The amount of each compound added is g / g as a coating amount per 1 m ^2.
It is shown in units of m ² . First layer (bottom layer) Gelatin 0.46 Water-soluble polymer (PS-2) 0.02 Surfactant (SU-3) 0.023 Second layer Gelatin 2.4 Water-soluble polymer (PS-3) 0. 36 Water-soluble polymer (PS-1) 0.7 Water-soluble polymer (PS-4) 0.6 High boiling point solvent (OIL-3) 2.0 Guanidine picolinate 3.2 Picolinic acid 0.5 Surfactant (SU -3) 0.024 Third layer (mixing prevention layer) Gelatin 2.4 Water-soluble polymer (PS-1) 0.7 Water-soluble polymer (PS-3) 0.36 Water-soluble polymer (PS-4) 6 Surfactant (SU-3) 0.024 Fourth layer (outermost layer) Gelatin 0.22 Water-soluble polymer (PS-2) 0.06 Water-soluble polymer (PS-3) 0.20 Antifoggant (AF -2) 0.02 Matting agent (PM-22 0.01 Surfactant (SU-3) 0.007 Surfactant (SU-5) 0.007 Surfactant (SU-6) 0.01 Hardener (H-5) 0.37 PS-2 : Κ-carrageenan (manufactured by Wako Pure Chemical Industries) PS-3: dextran (molecular weight = 70,000) PS-4: MP polymer MP102 (manufactured by Kuraray) H-5: (CH ₂ ＣＨCHSO ₂ CH ₂ CONHCH ₂ −) ) ₂ SU-3: sulfosuccinic acid di (2-ethylhexyl) sodium salt _{SU-5: C 8 H 17} SO 2 N (C 3 H 7) CH 2 COOK OIL-3: liquid paraffin AF-2: 1- ( 4-carboxyphenyl) -5-mercaptotetrazole PM-22: polymethyl methacrylate (mass average molecular weight = 50,000)

[0077]

Embedded image

(Preparation of developed film) 20% of gelatin
In an aqueous solution, tricresis phosphate dispersed in oil-in-water so as to have an average particle diameter of 200 nm was used at a solid content ratio of 30% with respect to gelatin, a hardener H-5 was added at 20 mg / g of gelatin, and a developing agent CD-4 was added at 2 mg / g. After the addition, the viscosity measured by a B-type viscometer was 200 g / m ^2.
0 mPa · s, 0.5 mol / L sulfuric acid or 1 mol / L
L sodium hydroxide is added as appropriate to adjust the pH to 6.5, and 3 g of zinc oxide having an average particle diameter of 200 nm is added.
/ M ² and stirred well. Put this solution in P
Cast on ET film, 23 ℃, 50%
Leave for 10 hours under RH (relative humidity) condition, then
After aging at 0 ° C and 80% RH for 14 hours, PET
Peel off the sheet formed from the film, thickness 70μm
Was obtained.

CD-4: 4-amino-3-methyl- (N
-Ethyl-N-β-hydroxyethyl) aniline sulfate (read before development processing) After taking a photograph using the obtained developed film and applying a plurality of missing portions having different shapes to the edge of the photographed film, LED light source (manufacturer color: maximum peak wavelength / Stanley infrared: 850 nm)
And a monochrome CCD of 2048 × 2048 pixels (KX4 manufactured by Eastman Kodak Company)
Is turned on, and the infrared image information (IR
1) was read by a monochrome CCD. (Development) (heat development, color development) already captured after the film and each water processing sheet was ^{10ml / m 2, 50ml / m} 2 applied, and by superimposing both using a heat press machine 6
Heat development was performed at 0 ° C. for 60 seconds. (Read after development processing) Four types of LED light sources (manufacturer color: maximum peak wavelength Stanley infrared: 850 n
m, manufactured by Stanley Red: 635 nm, manufactured by Nichia Corporation
Green: 535 nm, Nichia Corporation blue: 470 nm),
It is placed between monochrome CCDs (KX4 manufactured by Eastman Kodak Co.) of 2048 × 2048 pixels, and the LED light source is sequentially switched to change the infrared (IR2), red (R),
Green (G) and blue (B) color separation image information is converted to monochrome CC.
Read by D. (Preparation of comparative digital image data)-Operation The following operation was performed using only the infrared (IR2), red (R), green (G), and blue (B) color separation image information read after the development processing. Thereafter, color digital image data was prepared. Further, before performing the arithmetic processing of the following equation (7), each of the infrared (IR2), red (R), green (G), and blue (B) image information is subjected to the following preprocessing. I created a program to apply. 1. Image processing negative → positive reversal processing. 2. Histogram normalization processing to maximize the gradation distribution. 3. Look-up table processing for correcting the camera output characteristics so as to be linear with respect to the amount of incident light. 4. Logarithmic conversion processing of each image information for performing the arithmetic processing of the following equation (7).

Further, before performing the arithmetic processing, the infrared (IR)
2) In each of the color-separated image information of red (R), green (G), and blue (B), a plurality of missing portions having different shapes attached to the edge of the film are all matched between the color-separated image information. Was subjected to distortion correction processing.

[0081]

(Equation 6)

Print The obtained digital image data is output to a Konica color paper type QAA7 at a resolution of 300 dpi using a Konica digital minilab system QD-21.
Four editions of the comparative digital print 201 were produced. (Preparation of digital image data of the present invention) Calculations Infrared image information (IR1) read before development processing and color separation images of red (R), green (G), and blue (B) read after development processing Using information, R ′,
G 'and B' image data were prepared. In addition, infrared (I
A program was prepared to perform the following pre-processing on each image information of R1), red (R), green (G), and blue (B) before performing the arithmetic processing of the following equation (8). . 1. Image processing negative → positive reversal processing. 2. Histogram normalization processing to maximize the gradation distribution. 3. Look-up table processing for correcting the camera output characteristics so as to be linear with respect to the amount of incident light. 4. Logarithmic conversion processing of each image information for performing the arithmetic processing of the following equation (8).

Further, before performing the arithmetic processing, the infrared (IR)
1) In each of the color separation image information of red (R), green (G), and blue (B), all the plurality of missing portions having different shapes attached to the edge of the film match between the color separation image information. Was subjected to distortion correction processing.

[0084]

(Equation 7)

Next, using the infrared image information (IR1) read before the arithmetic processing and the infrared image information (IR2) read after the developing processing, image data of IR2 'was produced by the following arithmetic expression. . Furthermore, infrared (IR1) and infrared (I
For each image information of R), a program for performing the following pre-processing before creating the arithmetic processing of the following equation (8 ') was created. 1. Image processing negative → positive reversal processing. 2. Histogram normalization processing to maximize the gradation distribution. 3. Look-up table processing for correcting the camera output characteristics so as to be linear with respect to the amount of incident light. 4. Logarithmic conversion processing of each image information for performing the calculation processing of the following equation (8 ').

Before performing the arithmetic processing, IR1 and IR1
In the image information of No. 2, distortion correction processing was performed such that all of the plurality of missing portions having different shapes attached to the edge of the film matched between the respective pieces of image information.

Equation (8 ′) IR2 ′ = IR2−0.23 × IR1 Further, using the image data of R ′, G ′, B ′, and IR2 ′, R ″, G ″, B After producing the image data, color digital image data was produced.
Further, before the image processing of the infrared (IR2 ′), red (R ′), green (G ′), and blue (B ′) is performed, A program to perform the preprocessing shown was created. 1. Image processing negative → positive reversal processing. 2. Histogram normalization processing to maximize the gradation distribution. 3. Look-up table processing for correcting the camera output characteristics so as to be linear with respect to the amount of incident light. 4. Logarithmic conversion processing of each image information for performing the calculation processing of the following equation (9).

Before performing the arithmetic processing, the infrared (IR)
2 '), red (R'), green (G '), and blue (B') color separation image information includes a plurality of missing portions having different shapes attached to the edges of the film. The distortion correction processing was performed so as to match.

[0089]

(Equation 8)

Print The obtained digital image data is output to a Konica color paper type QAA7 at a resolution of 300 dpi using a Konica digital minilab system QD-21.
Four versions of the digital print 202 of the present invention were produced. (Sensory Evaluation) From the Macbeth color chart scene of the print produced in the same manner as in Example 1, a sensory evaluation was performed on color reproducibility and roughness.

[0091] As is clear from the obtained results, there was no significant difference in the sensory evaluation average points regarding the color reproducibility of 201 and 202. However, regarding the roughness, the print of 202 of the present invention was clearly different from the comparative 201. Improvement was observed.
As a result, it has been proved that arithmetic processing can be performed using image information read in the non-photosensitive wavelength region of the color negative film before the development processing to reduce image noise caused by a silver halide image.

[0092]

According to the present invention, even from a silver halide color photographic light-sensitive material which has been processed in a state having silver halide and developed silver, image noise derived from silver halide and developed silver can be reduced. This is a remarkably excellent effect that reduced, high-quality digital image data can be obtained.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view of an image forming apparatus that is optimal as an image sensor unit.

FIG. 2 is a cross-sectional view of an image forming apparatus that is optimal as another image sensor unit.

FIG. 3 is a schematic diagram of an image forming process in an image forming apparatus used as an image sensor unit.

FIG. 4 is a schematic diagram of an image forming process in an image forming apparatus used as another image sensor unit.

FIG. 5 is a schematic diagram showing a calculation process in image formation of the present invention.

[Explanation of symbols]

 101, 201 patrone 102, 202 control panel 103, 107, 203 CCD camera 104 infrared light source 105, 205 processing tub 106, 206 color negative film 108, 204 infrared, red, green, blue light source 109, 207 signal processing unit 110, 208 Processed film collection unit 111, 209 Processing terminal (monitor, external memory) 2 Perforation 3, 305, 306 Marking 4 Specific position or specific recording information to record information 5, 5 'Light source 12 Image processing process (I) 13 , 13 'memory 14 filter turret 15 image processing process (II) 18 drive circuit 19 sensor 20 scanner setting 21 CPU 22 synchronization signal generation circuit 301, 302, 309 reading screen 303 overlap area 304, 308 Screen 307 developed before color negative film 310 developed processed color negative film 311 composite image 312 captured screen area

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) G06T 5/00 300 G06T 5/00 300 5C062 H04N 1/00 H04N 1/00 G F-term (reference) 2H016 AC00 BA00 BK00 BL00 2H023 AA02 HA04 2H106 BA47 BA55 2H112 AA03 AA11 BA23 5B057 AA20 BA19 CA01 CA08 CA12 CA16 CB01 CB08 CB12 CB16 CD12 CE02 CE17 DA07 DB02 DB06 DB09 DC32 5C062 AB03 AB17 AB22 AC03 AC24 AC61 AE

Claims (10)

[Claims] In an image forming method for developing a silver halide color photographic light-sensitive material, reading the revealed image information through an image sensor, and converting the image information into digital image information, substantially before the development processing, Reading the image information in the non-photosensitive wavelength region of the silver halide color photographic light-sensitive material, and using the obtained image information in the non-photosensitive wavelength region and the image information read after the development process in an arithmetic process. Image forming method. 2. The image forming apparatus according to claim 1, wherein the developing process comprises a color developing process and a bleaching process without passing through a fixing process, and the image information in the non-photosensitive wavelength region is silver halide image information. Image forming method. 3. The developing process comprises only a color developing process which does not go through both bleaching and fixing processes, wherein the image information in the non-photosensitive wavelength region is silver halide image information,
2. The image forming method according to claim 1, wherein after the development processing, the image information in the non-photosensitive wavelength region is read again to obtain image information composed of a silver halide image and a developed silver image. 4. The image forming method according to claim 1, wherein the non-photosensitive wavelength region of the silver halide color photographic light-sensitive material is an infrared wavelength region. 5. The heat development method according to claim 1, wherein said development processing is a heat development method in which a processing sheet and a silver halide color photographic light-sensitive material are bonded and heated. Image forming method. 6. An image forming apparatus for developing a silver halide color photographic light-sensitive material by a developing means, reading the visualized image information through an image sensor, and converting the image information into digital image information. Means for reading image information in the non-photosensitive wavelength region of the silver halide color photographic light-sensitive material before substantially performing the developing process, and calculating image information in the non-photosensitive wavelength region and image information read after the developing process. An image forming apparatus comprising: means for processing. 7. A method according to claim 6, wherein said developing means comprises a color developing process and a bleaching process which do not go through a fixing process, and wherein the image information in the non-photosensitive wavelength region is silver halide image information. The image forming apparatus as described in the above. 8. The developing means comprises only a color developing step which does not go through both bleaching and fixing steps, wherein the image information in the non-photosensitive wavelength region is silver halide image information, and 7. The image information comprising a silver halide image and a developed silver image is obtained by reading image information again in the photosensitive wavelength region.
An image forming apparatus according to claim 1. 9. The image forming apparatus according to claim 6, wherein the non-photosensitive wavelength region of the silver halide color photographic material is an infrared wavelength region. 10. A heat developing system in which said developing means is a heat developing method in which a processing sheet and a silver halide color photographic light-sensitive material are bonded and heated.
The image forming apparatus according to claim 1.