JP2001136397A - Color matching method, recording medium with program for executing color matching processing recorded thereon and photographic printer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To properly execute color matching of a display picture on a monitor and a print picture in accordance with the kind of a negative film to be used. SOLUTION: A picture fetching part fetches the picture of a negative film and reads the DX code of the negative film to send it to a picture processing part (S1). A display correction value arithmetic part calculates a display correction value based on picture data on the read picture. An exposure correction value arithmetic part discriminates the kind of the negative film from the DX code and specifies the film density of the used negative film by a prescribed expression based on the picture data. After that, the exposure correction value arithmetic part selects each print correction coefficient of BGR in accordance with the kind of the negative film and the film density to calculate each print correction value of RGB (S2). A display part displays the picture based on the display correction value (S3) and an exposure part exposes a photographic paper based on the display correction value and the print correction value (S5).

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color matching method for matching a color density between a monitor image and a print image based on image data obtained by reading a photographic film such as a negative film, and a program for performing a color matching process. The present invention relates to a recording medium on which recording is performed and a photographic printing apparatus.

[0002]

2. Description of the Related Art Conventionally, in an operation of printing an image recorded on a photographic film onto photographic paper, a film image is generally captured by, for example, a CCD (Charge Coupled Device) camera, and the image is captured as a finished image of a print. The image is displayed on the monitor. And
The loss print is reduced by inspecting the display image on the monitor before printing.

[0003] In a limited area such as a photograph, the color and density usually have a bias, and the bias is often extreme. For this reason, in analog printers, there is a problem with color feria that good color reproduction cannot be expected even if LATD exposure is performed based on Evans' theorem. In the scene image, there is a problem of density feria in which a person's part is printed in black. However, since the color feria and the density feria can be recognized before printing by the above inspection work, if the correction is performed before printing, loss print can be reduced as a result.

In a digital printer, for example, when an image recorded on a photographic film has a portion having a large difference in luminance, a so-called dodging operation in which the difference in luminance is reduced and printed on photographic paper can be performed. . By performing the above inspection work, it is possible to determine the necessity of dodging just by looking at the display image on the monitor without actually printing, so dodging must be performed from the beginning in the printing work This can reduce loss print. Also, for example, the necessity of image processing such as color correction and gradation correction can be determined by looking at the display image on the monitor in the same manner. Prints can be reduced.

If the color densities of the monitor image and the print image corresponding to the same frame image on the photographic film are not originally matched, even if the monitor image has a proper color density, the color density of the print image will not be sufficient. May be inappropriate, resulting in an increase in loss print. Therefore, it is most important that the two images are color-matched in performing the inspection work.

The basic process in color matching is to match the spectral sensitivity characteristics of a CCD camera for photometry of an image displayed on a monitor with the spectral sensitivity characteristics of photographic paper.
That is, a CCD camera and a photographic paper having the same spectral sensitivity characteristics are used. But what C
At present, spectral sensitivity characteristics cannot be completely matched even when a CD camera and photographic paper are used.

For this reason, conventionally, a CCD camera and a photographic paper having similar spectral sensitivity characteristics are used,
By correcting the image data read by the camera using, for example, a matrix coefficient or an LUT (look-up table), the influence of the difference between the spectral sensitivity characteristics of the two is reduced. Specifically, matrix coefficients and LU
An exposure correction value is calculated from the image data by T, and an image is printed on photographic paper with an exposure amount based on the exposure correction value, while a display correction value is calculated from the image data by a matrix coefficient or LUT different from the above. By performing monitor display based on the display correction value, the print image and the display image on the monitor are color-matched as much as possible.

As described above, by separately obtaining the exposure correction value and the display correction value and separately correcting the monitor image and the print image, for example, the monitor image and the print image can be corrected based on only the display correction value. Compared to the method of correcting both, the two images can be color matched more.
Here, Equation 1 indicates an equation for calculating an exposure correction value or a display correction value using, for example, a matrix coefficient.

[0009]

(Equation 1)

Regarding the matrix coefficient for calculating the exposure correction value, the density values for each of B (blue), G (green), and R (red) read once by printing an image of a photographic film and read by a densitometer are used as input values. By previously obtaining an ideal value in a printer (exposure unit) as an output value, it can be easily obtained based on the input value and the output value. This matrix coefficient is usually set at the stage of shipment from a device maker, but can be set and changed by an operator. In the case of analog exposure, the input value BGR is an average value of all pixels constituting an image. However, in the case of digital exposure, the input value BGR may be a value for each pixel.

On the other hand, the matrix coefficient for calculating the display correction value can be obtained as follows.
The operator visually compares the print result of the image of a certain photographic film with the display result on the monitor,
The operator changes the image data of the display image on the monitor by key operation so that the print image and the color density become equal. If the numerical value (the ideal value) corresponding to the print result is set as the input value and the image data of the final display image of the monitor is set as the output value, the matrix coefficient is obtained based on the input value and the output value. be able to.

When an LUT is used, for example, BG
By converting an input value using a three-dimensional LUT in which R is a polar coordinate, a display correction value or an exposure correction value can be obtained. Further, for example, if the saturation and the hue are calculated based on the BGR data and a two-dimensional LUT using these as XY coordinates is created, the display correction value or the exposure correction value can be reduced with a smaller data amount than the three-dimensional LUT. Can be requested.

[0013]

However, in the above-described conventional color matching processing, the above matrix coefficients and LUTs are commonly used for a variety of photographic films. In some cases, the color matching between the monitor image and the print image becomes inappropriate, and there arises a problem that appropriate color matching corresponding to each photographic film cannot be performed stably.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and has as its object to provide a color matching method and a program for performing a color matching process capable of appropriately performing color matching according to a photographic film to be used. And a photographic printing apparatus.

[0015]

According to a first aspect of the present invention, there is provided a color matching method for solving the above problems.
The color of an image printed on a photosensitive material with an exposure amount based on the exposure correction value of image data for different colors corresponding to an arbitrary frame image of a photographic film, and an image displayed based on the display correction value of the image data A color matching method for matching densities, in which correction coefficients corresponding to individual photographic films of different types are stored, and a correction coefficient corresponding to the type of photographic film used is extracted from the stored correction coefficients. One of the exposure correction value and the display correction value is corrected using the corrected correction coefficient.

According to the above arrangement, the correction coefficient corresponding to the type of the photographic film used is extracted from the correction coefficients stored corresponding to each photographic film, and based on the correction coefficient, The display correction value or the exposure correction value is corrected, for example, for each different color (for example, BGR) of the image data. As described above, since the correction coefficient corresponding to the type of the photographic film used is reflected in the display correction value or the exposure correction value, when the display correction value is corrected, the display image is optimized for each photographic film used. When the exposure correction value is corrected and the exposure correction value is corrected, a print image printed on a photosensitive material with an exposure amount based on the exposure correction value has an optimum color density for each photographic film used.

As described above, the color density of the display image or the print image can be adjusted for each photographic film used, so that the color density of the display image corresponding to the frame image and the print image can be adjusted. Matching can be performed for each photographic film used. As a result, it is possible to reliably reduce the loss print that occurs due to the color density mismatch between the display image and the print image, and to accurately perform the inspection operation based on the display image.

According to a second aspect of the present invention, there is provided a color matching method according to the first aspect, wherein the exposure correction value is corrected using the correction coefficient, and the corrected exposure correction value is set. Is characterized in that the photosensitive material is exposed at an exposure amount based on

According to the above arrangement, since the correction coefficient corresponding to the type of the photographic film used is reflected in the exposure correction value, the print image printed on the photosensitive material with the exposure amount based on the exposure correction value can be used. The optimum color density is obtained for each photographic film. This makes it possible to match the color density of the print image with the display image for each photographic film used.

Here, even if the photosensitive material is exposed with an exposure amount based on the exposure correction value, an error at the time of exposure (for example, an error in the amount of light transmitted through a photographic film) affects the printed image. Rather, the display image is reproduced more faithfully to the image data of the frame image. Therefore, according to the above configuration, for each photographic film used, the color density of the print image is adjusted to the display image,
The effect of color matching can be further enhanced.

According to a third aspect of the present invention, there is provided a color matching method according to the second aspect, wherein the exposure correction value includes the display correction value. .

According to the above arrangement, the exposure correction value is:
For example, it is expressed as the sum of the display correction value and a correction value (for example, a print correction value) set based on the correction coefficient. As described above, since the exposure correction value includes the display correction value, for example, it is determined that image processing such as color correction is necessary by looking at a display image, and even if the display correction value is corrected, The display correction value after correction, that is, the final display correction value can be reflected on the exposure correction value. Thus, even when the image processing is performed, a print image having the same color density as the display image after the image processing can be reliably obtained.

A color matching method according to a fourth aspect of the present invention provides a color matching method according to the first to third aspects.
In any one of the above structures, the correction coefficient is set according to the density of the photographic film.

According to the above arrangement, the correction coefficient is set in accordance with the density of the photographic film. Therefore, for each of the photographic films having different densities, different display correction values or different display correction values are set based on the correction coefficient. An exposure correction value can be obtained. As described above, since it is possible to cope with the difference in the density of the photographic film used, the effect of the color matching between the display image and the print image can be further enhanced.

The color matching method according to the fifth aspect of the present invention solves the above-mentioned problems.
In any one of the above structures, the correction coefficient is set for each color corresponding to the image data.

According to the above arrangement, since the correction coefficient is set for each color (for example, BGR) corresponding to the image data, the display correction value or the exposure correction value is set based on the correction coefficient for each BGR. It can be obtained for each BGR. This makes it possible to appropriately change the color density balance between the display image and the print image, and to reliably perform color matching between the display image and the print image.

According to a sixth aspect of the present invention, there is provided a color matching method for solving the above problems.
Wherein the correction coefficient is set based on a color corresponding to the image data and a density of the photographic film, and is stored as one table for each photographic film. It is characterized by:

According to the above arrangement, one table is constituted by the correction coefficient set based on the color (for example, BGR) corresponding to the image data and the density of the photographic film. For example, it is stored in a memory for each film. This makes it easy to manage the correction coefficients for each photographic film.

For example, if a conventional matrix coefficient for calculating an exposure correction value is provided separately for each different color and according to the density of a photographic film, the amount of data becomes enormous. As a result, it is necessary to configure a memory for storing the matrix coefficients with an expensive memory having a large storage capacity. In particular, when an LUT is used instead of the matrix coefficient, the storage capacity is further increased.

However, in the present invention, since the correction coefficient is set based on the color corresponding to the image data and the density of the photographic film, the correction coefficient is set for each different color and the density of the photographic film. The data amount can be reduced as compared with the case where they are separately set according to. As a result, the memory does not need to be configured with an expensive memory having a large storage capacity, and the calculation of the display correction value and the exposure correction value based on the correction coefficient does not become complicated.

According to a seventh aspect of the present invention, a recording medium for performing a color matching process is based on an exposure correction value of image data for each different color corresponding to an arbitrary frame image of a photographic film. A recording medium on which a program for performing a color matching process for matching a color density of an image printed on a photosensitive material with an exposure amount and an image displayed based on a display correction value of the image data is recorded. A process of storing a correction coefficient corresponding to each of the photographic films, a process of extracting a correction factor corresponding to the type of the photographic film used from the stored correction factors, and the above-described exposure correction using the extracted correction factor. A program for causing a computer to execute a process of correcting one of the value and the display correction value. It is characterized by a door.

When a computer is executed using the above-mentioned recording medium, a correction coefficient corresponding to each photographic film is stored in, for example, a memory. Then, a correction coefficient corresponding to the type of the photographic film used is extracted from the stored correction coefficients, and based on the correction coefficient, the display correction value or the exposure correction value is changed, for example, to a different color ( For example, it is set for each BGR. As described above, since the correction coefficient corresponding to the type of the photographic film used is reflected in the display correction value or the exposure correction value, when the display correction value is corrected, the display image is optimized for each photographic film used. When the exposure correction value is corrected and the exposure correction value is corrected, a print image printed on a photosensitive material with an exposure amount based on the exposure correction value has an optimum color density for each photographic film used.

As described above, since the color density of the print image can be adjusted for each photographic film used, the color density of the display image corresponding to the frame image and the color density of the print image can be adjusted. Matching can be performed for each film. As a result, it is possible to reliably reduce the loss print that occurs due to the color density mismatch between the display image and the print image, and to accurately perform the inspection operation based on the display image.

According to an eighth aspect of the present invention, in order to solve the above-mentioned problems, an exposure correction value for calculating an exposure correction value of image data for each color corresponding to an arbitrary frame image of a photographic film is provided. A photographic printing apparatus comprising: an arithmetic unit, an exposure unit that exposes a photosensitive material with an exposure amount based on the exposure correction value, and a display unit that displays an image corresponding to the frame image. Storage means for storing exposure information corresponding to each of the above, the exposure correction value calculation means extracts exposure information corresponding to the type of photographic film used from the storage means, and performs the exposure based on the extracted exposure information. It is characterized in that a correction value is set.

According to the above arrangement, the exposure information corresponding to each photographic film is stored in the storage means. Then, the exposure correction value calculating means extracts the exposure information corresponding to the type of the photographic film used from the exposure information stored in the storage means, and based on the exposure information, for example, a different color of the image data. The exposure correction value is calculated for each (for example, BGR). Therefore, since the exposure information corresponding to the type of the photographic film used is reflected in each exposure correction value, a print image obtained by exposing the photosensitive material with the exposure unit based on the exposure amount based on each of the exposure correction values is: The optimum color density is obtained for each photographic film used.

As described above, according to the above configuration, the color density of the print image can be adjusted for each photographic film used, so that the display image corresponding to the frame image displayed by the display means can be adjusted. The color density with the print image is matched for each photographic film used. As a result, it is possible to reliably reduce the loss print that occurs due to the color density mismatch between the display image and the print image, and to accurately perform the inspection operation based on the display image.

[0037]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described.
This will be described below with reference to FIGS.

The photographic printing apparatus according to the present embodiment prints an image recorded on, for example, a negative film as a photographic film on a photographic paper as a photosensitive material. As shown in FIG. Unit 1 and image processing unit 2
And an exposure unit 3 (exposure unit) and a display unit 4 (display unit). In FIG. 1, arrows passing through the image capturing unit 1 and the exposing unit 3 indicate a transport path of the negative film transported by a transport unit (not shown).

The image capturing unit 1 is a scanner that captures an image recorded on the negative film by measuring light transmitted through the negative film, and includes, for example, a light source for irradiating the negative film with light, and color filters of BGR. And a CCD (Charge Coupled Device) camera (hereinafter simply referred to as CCD).
The rotating filter is rotated so that the light of each color of BGR sequentially reaches the CCD, and the light transmitted through the negative film is converted to BGR.
The CCD transmits an electric signal corresponding to the amount of received light to the image processing unit 2 for each BGR.
As a result, image data corresponding to the density of each pixel of the image recorded on the negative film is obtained for each BGR. When the CCD is constituted by a three-plate CCD, the above-mentioned rotary filter is unnecessary.

The image capturing section 1 also has a reading section for reading a DX code, which is a number unique to the negative film, from the negative film. The reading unit reads D
The X code information is sent to the image processing unit 2. Accordingly, the image processing unit 2 determines which negative film is used by which manufacturer based on the above information,
In addition, it is possible to recognize the degree of sensitivity.

If the operator inputs a DX code to the image processing unit 2 via input means such as a mouse or a keyboard, the reading unit can be dispensed with.

The image processing unit 2 calculates a display correction value and an exposure correction value, which will be described later, for each BGR based on the image data for each BGR sent from the image capturing unit 1, and displays the display correction value. 4 and the exposure correction value including the display correction value is transmitted to the exposure unit 3, the details of which will be described later. The image processing unit 2 includes a microprocessor and / or a DSP (Dig
ital Signal Processor) or a PC (Personal Computer) provided outside the device.
May be configured. The image processing unit 2 includes a memory for temporarily storing image data from the image capturing unit 1 and a control unit for controlling display on the display unit 4 and exposure operation by the exposure unit 3 (both not shown). ).

The exposure unit 3 exposes a negative film with an exposure amount based on each exposure correction value of BGR calculated by the image processing unit 2 and performs analog exposure for printing an image recorded on the negative film on photographic paper. And includes, for example, a light source, a light control filter unit, a film arranging unit, and a printing lens.

The light source is, for example, a halogen lamp. The dimming filter unit is configured with filters of each color of yellow (Y), magenta (M), and cyan (C), and performs dimming by a color reduction method. Each of these color filters consists of two filters, and the two filters are arranged so as to sandwich the optical path of the light emitted from the light source. By changing the amount of each color filter inserted in the optical path, the BGR exposure amount and color balance can be adjusted.

The film arranging means has a function of moving an image to be printed on the negative film conveyed into the exposure section 3 to an exposure position and shielding light around the image. Auto N
ega-Mask). The printing lens is an optical member for emitting light from the light source, temporarily collecting light transmitted through the negative film, and projecting the light on photographic paper.

The display unit 4 is a monitor that displays an image corresponding to an arbitrary frame image of a negative film based on the display correction value obtained by the image processing unit 2.

Next, the image processing unit 2 which is a feature of the present invention will be described.

The image processing unit 2 includes a display correction value calculation unit 2a
And a print correction coefficient storage unit 2b (storage means) and an exposure correction value calculation unit 2c (exposure correction value calculation means).

The display correction value calculation section 2a calculates a display correction value for displaying the frame image on the display section 4 based on image data for each different color corresponding to an arbitrary frame image of the negative film. It is. Specifically, photometric values (image data) for each BGR sent from the image capturing unit 1
Is multiplied by a matrix coefficient for display correction to obtain a display correction value. In the present embodiment, since analog exposure is assumed, the display correction value calculation unit 2
a is the BGR value of the average value of one frame from the photometric value of each pixel.
And these are used as input values in the matrix operation.

The above matrix coefficients can be obtained in advance by a method similar to the conventional one. That is, the operator visually compares a print image of a frame of a certain photographic film with a display image on the display unit 4, and operates the key by operating the key so that the color density of the display image becomes equal to the print image. The image data of the display image is changed. If the image data of the print image is set as the input value and the final image data of the display image is set as the output value, the matrix coefficient can be obtained based on the input value and the output value. Only one type of matrix coefficient for display correction is prepared regardless of the type of negative film used.

The print correction coefficient storage unit 2b stores print correction coefficients (exposure information) set based on the color (BGR) corresponding to the image data and the density of the negative film as one table for each negative film. I remember.
Specifically, the print correction coefficient storage unit 2b sets the density of the negative film to, for example, normal (normal; hereinafter, sometimes simply referred to as N) or under (lightly; sometimes simply referred to as U). , Over (dark; hereafter simply O
The print correction coefficients of BGR at the respective densities are stored in a table as shown in FIG. 3, and such a table is stored in accordance with the type of the negative film. I remember.

Therefore, theoretically, there are nine print correction coefficients of (B, G, R) × (U, N, O) per table. However, when the film density is N, the print correction coefficient storage unit 2b stores
Since the print correction coefficient 0 is stored for each color of GR and the reference values a, b, and c are stored together for each color of BGR, 12 print correction coefficients are actually stored. Become. The above reference value a
b and c are values arbitrarily set according to the type of the negative film.

It should be noted that even if the negative films are of the same maker but have different sensitivities, it is assumed that the types of the negative films are different. Further, the value of each print correction coefficient is not always a positive value, and may take a negative value. Further, the division of the film density is not limited to the above three stages, but may be a plurality of divisions.

There are about 2,048 types of photographic films currently on the market, depending on the manufacturer and the difference in sensitivity. If individual print correction coefficients are stored for each of these photographic films, the amount of data is enormous. Therefore, it is necessary to configure the print correction coefficient storage unit 2b with a special memory having a large storage capacity. Therefore, in the present embodiment, for example, a frequently used photographic film (approximately 1
000) are stored, thereby reducing the storage capacity of the print correction coefficient storage unit 2b.

The exposure correction value calculator 2c calculates an exposure correction value based on the image data obtained by the image reader 1. The exposure correction value is represented by the sum of the display correction value and the print correction value.

Here, the print correction value is a BGR based on image data obtained by reading a negative film by the image capturing unit 1 and a print correction coefficient corresponding to the type and film density of the negative film. It is obtained every time. In the exposure correction value calculation unit 2c, the type of the negative film is recognized based on, for example, DX code information sent from the image capturing unit 1, but the film density is recognized based on, for example, the following equation. .

(AVE-D) <0 → film density; over (AVE-D)> 0 → film density; under (AVE-D) = 0 → film density; normal Note that the above AVE indicates the luminance of each pixel. This is a value obtained by adding the value (density value) for all pixels and dividing by the total number of pixels. The density value can be obtained, for example, by adding each value of BGR and dividing by 3. D is a density value of a film having a reference density, which is a known value.

The exposure correction value calculation unit 2c reads out a table having print correction coefficients corresponding to the type of the negative film used from the print correction coefficient storage unit 2b, and stores a BGR corresponding to the film density recognized by the above equation. A print correction coefficient is selected from the above table, and a print correction value is obtained for each color of BGR by the following calculation.

Print correction value = (AVE-D) × Print correction coefficient + n The above n is a reference value (a, b or c) corresponding to each color of BGR.

Therefore, the print correction value always includes the reference value (n in the above formula) corresponding to each color of BGR, regardless of the film density. Also, the correction of the exposure amount corresponding to the reference value is minimized.

FIG. 4 shows a difference in print correction value for each film density when, for example, exposure to B light is performed. FIG. 4 shows the case where B ₁ > 0 and B ₂ <0. As can be seen from FIG.
It can be seen that the reference value a is included for all film densities of U, N, and O. When the film density is U, while the adding further print correction coefficient B ₁ is, if the film density is O are taken into account more print correction coefficient B _2, film density approaches the U and O The more the correction, the stronger the correction.

Next, the operation of the photographic printing apparatus will be described mainly with reference to the flowchart of FIG.

First, when a negative film is inserted into the image capturing unit 1, the CCD of the image capturing unit 1 measures light from a light source that transmits a predetermined frame of the negative film, and outputs a signal for each pixel of the CCD. Is transmitted to the image processing unit 2 (Step 1; hereinafter, the steps are simply abbreviated as S). Then, in the image processing unit 2, the BGR photometric values of all frames are stored in the memory. The negative film for which photometry has been completed for all frames is transported to the exposure unit 3 by a transport unit (not shown). Further, in the image capturing section 1, the DX code of the negative film is read by the reading section, and this information is sent to the exposure correction value calculating section 2c of the image processing section 2.

Next, the display correction value calculation section 2 of the image processing section 2
a is BG using a matrix coefficient for calculating a display correction value.
The display correction value of R is calculated and sent to the display unit 4. On the other hand, the exposure correction value calculation unit 2c determines the type of the negative film from the DX code, and specifies the film density of the used negative film by the above equation. afterwards,
The exposure correction value calculation unit 2c extracts a table corresponding to the type of the negative film from the print correction coefficient storage unit 2b, selects a print correction coefficient corresponding to the film density from the table, and calculates a BGR print correction value. (S2).

Next, when the display unit 4 displays an image based on the display correction value (S3), the operator looks at the display image, inspects the image, and performs image processing such as color correction and gradation correction as necessary. Is applied to the display correction value, and the sum of the final display correction value and the print correction value is used as an exposure correction value.
(S4).

The above-described image processing is performed when an operator gives an input instruction to the image processing unit 2 via input means such as a mouse or a keyboard. The image processing unit 2 may send the final display correction value and the print correction value to the exposure unit 3 separately and sequentially.

Finally, the exposure unit 3 adjusts the light control filter unit so as to obtain an exposure amount based on the exposure correction value of BGR, and adjusts the predetermined frame of the negative film conveyed from the image capturing unit 1 to a predetermined frame. The image of the frame is printed on photographic paper by irradiating light from a light source (S5).

According to the above arrangement, the print correction value calculated using the information (print correction coefficient) corresponding to the type of the negative film is reflected on each exposure correction value of BGR, and based on these exposure correction values. Since the image is printed with the exposure amount, an appropriate exposure correction value according to the type of the negative film to be used can be obtained depending on the setting of the print correction value. Thus, the color density of the print image can be adjusted for each negative film to be used, so that the display image and the print image can be color-matched for each negative film to be used. As a result, when the inspection work is performed based on the displayed image, it is possible to reliably reduce the occurrence of inadvertent loss printing depending on the negative film used, and to perform the inspection work before burning more accurately. .

That is, in the present invention, the color shift caused by the difference between the film type and the film density which cannot be absorbed only by the conventional matrix calculation or LUT is eliminated by considering the print correction value according to the film type and the film density. be able to.

Generally, the display correction value sent to the display unit is digital data, and the display unit displays an image based on the digital data. Therefore, this display image is faithfully reproduced with the display correction value which is digital data. On the other hand, in the exposure unit, the light from the light source passes through the negative film and the filter for light control, so that an error easily occurs in the amount of transmitted light. Therefore, the actual exposure amount corresponding to the exposure correction value is reduced. It cannot be obtained as calculated, and it is easy to obtain a printed image as calculated.

However, since the present invention has a configuration in which the exposure correction value is changed according to the type of the negative film to be used, the present invention is particularly useful in color matching between a display image and a print image. It can be said that the configuration is such that the color density of the image is adjusted to the display image. Therefore, a print correction coefficient is set in consideration of the above error,
If the exposure correction value is set using the print correction coefficient, the color density of the printed image matches the color density of the display image faithfully reproduced with the display correction value, and the effect of color matching is further improved. Get higher.

In an analog printer, problems such as color feria and density feria tend to occur. However, by changing the exposure correction value according to the type of negative film used in the present invention, such problems can be solved. To
It can be performed appropriately for each negative film used. Therefore, the present invention is particularly effective for use in an analog printer.

In this embodiment, the exposure correction value is the sum of the display correction value and the print correction value, and only the print correction value is changed according to the photographic film used. The calculation may be performed in exactly the same manner as in the related art. Therefore, in the present invention, color matching can be realized using the conventional method as it is.

Further, in the present invention, since the table shown in FIG. 3 is created for each negative film, the input setting of the print correction coefficient can be easily performed even by the user at the user level. That is, according to the present invention, it is possible to relatively easily perform the adjustment that is difficult with the conventional matrix coefficients and LUT.

Since the exposure correction value is the sum of the display correction value and the print correction value, for example, when inspecting a display image on the display unit 4, color correction is performed on the display correction value. Even when image processing such as is performed, the display correction value after correction, that is, the final display correction value can be reflected on the exposure correction value. This makes it possible to reliably obtain a print image having the same color density as the display image after the image processing.

In general, when the matrix coefficient operates by multiplication, if the original data is 0, the result obtained by multiplying the matrix coefficient is also 0. Therefore, in the related art in which an exposure correction value is calculated only by multiplication using a matrix coefficient, an appropriate exposure correction value may not be obtained depending on original data.

However, in the present invention, the exposure correction value is the sum of the display correction value and the print correction value, and the print correction value includes at least the reference value as described above. Therefore, the exposure correction value does not become 0 irrespective of the original data. That is, according to the present invention,
There is no case where an exposure correction value cannot be obtained depending on the original data as in the related art.

A program for causing the image processing section 2 to execute the above-described color matching processing is recorded on a recording medium such as an optical disk, a magnetic disk, or an IC card, and the image is recorded using such a recording medium. The processing unit 2 may be configured to operate automatically.

In the above description, the case where the exposure correction value is corrected according to the type of photographic film so that the display image and the print image are color-matched has been described. The effect of the color matching of the present invention can be obtained even if the display correction value is corrected by using the above. However, if the effect of color matching is to be further enhanced by taking into account the error at the time of exposure as described above, a configuration in which the exposure correction value is corrected is more preferable.

In other words, in order to obtain the effect of the color matching of the present invention, correction coefficients corresponding to different types of photographic films are stored, and from the stored correction coefficients,
The correction coefficient corresponding to the type of photographic film used is extracted, and one of the exposure correction value and the display correction value is corrected using the extracted correction coefficient so that the displayed image and the print image are color-matched. Then, printing or display may be performed using the final exposure correction value or display correction value.

In the above description, the exposure unit 3 irradiates the negative film with light to print the image of each frame of the negative film on photographic paper, that is, the exposure unit 3 performs the so-called analog exposure. The present invention can be applied even when 3 is configured to perform digital exposure. In the case of digital exposure, the exposure unit 3 has a configuration including a light modulation element that modulates irradiation light on photographic paper based on digital image data of BGR. What is necessary is just to send each exposure correction value of BGR calculated in this way, and to perform exposure based on the above-mentioned exposure correction value in each pixel. In addition, as the above-mentioned light modulation element,
For example, PLZT exposure head, DMD (digital micromirror device), LCD (liquid crystal display), LC
S (liquid crystal shutter) LED panel, laser, FOCR
T (Fiber Optic Cathode Ray Tube) and CRT.

In the above, the color matching method using a negative film has been described. However, it goes without saying that the present invention can be similarly applied to a case where a positive film is used.

[0083]

As described above, the color matching method according to the first aspect of the present invention stores the correction coefficients corresponding to different types of photographic films, and uses the photographic film used from the stored correction coefficients. The correction coefficient corresponding to the type is extracted, and one of the exposure correction value and the display correction value is corrected using the extracted correction coefficient.

Therefore, since the correction coefficient corresponding to the type of the photographic film used is reflected in the display correction value or the exposure correction value, when the display correction value is corrected, the display image is displayed for each photographic film used. Is the optimum color density, and when the exposure correction value is corrected, the print image printed on the photosensitive material with the exposure amount based on the exposure correction value has the optimum color density for each photographic film used.

As described above, the color density of the display image or the print image can be adjusted for each photographic film used, so that the color density of the display image corresponding to the frame image and the print image can be adjusted. Matching can be stably performed for each photographic film used. As a result, it is possible to reliably reduce the loss print that occurs due to the color density mismatch between the display image and the print image, and to perform the inspection work based on the display image accurately.

According to the color matching method of the present invention, the exposure correction value is corrected by using the correction coefficient and the exposure amount based on the corrected exposure correction value. Is to expose the photosensitive material.

Therefore, since the correction coefficient corresponding to the type of the photographic film used is reflected in the exposure correction value, the print image printed on the photosensitive material at the exposure amount based on the above-mentioned exposure correction value is obtained for each photographic film used. Color density is optimal. This makes it possible to match the color density of the print image with the display image for each photographic film used.

Here, even if the photosensitive material is exposed with an exposure amount based on the exposure correction value, an error at the time of exposure (for example, an error in the amount of light when transmitted through a photographic film) affects the printed image, and therefore, the exposure is performed more than the printed image. Rather, the display image is reproduced more faithfully to the image data of the frame image. Therefore, according to the above configuration, for each photographic film used, the color density of the print image is adjusted to the display image,
There is an effect that the effect of color matching can be further enhanced.

The color matching method according to the third aspect of the present invention is, as described above, in the configuration of the second aspect, wherein the exposure correction value includes the display correction value.

Therefore, for example, when it is determined that image processing such as color correction is necessary by looking at a display image and the display correction value is further corrected, the corrected display correction value, that is,
The final display correction value can be reflected on the exposure correction value. Accordingly, in addition to the effect of the first aspect, even when image processing is performed, a print image having the same color density as the display image after image processing can be reliably obtained.

According to a fourth aspect of the present invention, there is provided a color matching method according to any one of the first to third aspects, wherein the correction coefficient is set according to the density of the photographic film. It is.

Therefore, for each of the photographic films having different densities, different display correction values or exposure correction values can be obtained based on the correction coefficients. in this way,
Since it is possible to cope with the difference in the density of the photographic film to be used, there is an effect that the effect of the color matching between the display image and the print image can be further enhanced in addition to the effect of the configuration of claim 1 or 2. .

In the color matching method according to the fifth aspect of the present invention, as described above, in any one of the first to fourth aspects, the correction coefficient is set for each color corresponding to the image data. Configuration.

Therefore, a display correction value or an exposure correction value can be obtained for each BGR based on a correction coefficient for each color (for example, BGR) according to the image data. In this way, in addition to the effect of any one of the first to third aspects, the color matching between the display image and the print image is reliably achieved by appropriately changing the color density balance of the display image or the print image. This has the effect that it can be performed.

As described above, in the color matching method according to the sixth aspect of the present invention, in the configuration according to any one of the first to fifth aspects, the correction coefficient is determined based on the color corresponding to the image data and the color of the photographic film. It is set based on the density and stored as one table for each photographic film.

Therefore, in addition to the effect of any one of the first to fourth aspects, there is an effect that the management of the correction coefficient for each photographic film can be facilitated.

Further, since the correction coefficient is set based on the color corresponding to the image data and the density of the photographic film, the correction coefficient is set separately for each different color and further according to the density of the photographic film. The data amount can be reduced as compared with the case of setting. As a result, it is not necessary to configure the memory with an expensive memory having a large storage capacity,
In addition, there is an effect that the calculation of the display correction value and the exposure correction value based on the correction coefficient is not complicated.

According to a seventh aspect of the present invention, a recording medium for performing a color matching process stores a correction coefficient corresponding to each of different types of photographic films,
A process of extracting a correction coefficient corresponding to the type of photographic film used from the stored correction coefficients, and correcting one of the exposure correction value and the display correction value by using the extracted correction coefficient. And a program for causing a computer to execute the processing to be performed.

Therefore, when the computer is executed using the above-described recording medium, the correction coefficient corresponding to the type of the photographic film used is reflected in the display correction value or the exposure correction value. In this case, the displayed image has the optimum color density for each photographic film used, and when the exposure correction value is corrected, the print image printed on the photosensitive material with the exposure amount based on the exposure correction value is used. The optimum color density is obtained for each photographic film.

As described above, it is possible to adjust the color density of the display image or the print image for each photographic film used. Matching can be stably performed for each photographic film used. As a result, it is possible to reliably reduce the loss print that occurs due to the color density mismatch between the display image and the print image, and to perform the inspection work based on the display image accurately.

The photographic printing apparatus according to the eighth aspect of the present invention is provided with the storage means for storing the exposure information corresponding to each of the different types of photographic films, and the exposure correction value calculating means is used. The exposure information corresponding to the type of the photographic film is extracted from the storage means, and the exposure correction value is set based on the extracted exposure information.

Therefore, the exposure information corresponding to the type of the photographic film used, which is extracted from the storage means by the exposure correction value calculating means, is reflected in each exposure correction value. The print image obtained by the exposure means exposing the photosensitive material has an optimum color density for each photographic film used.

As described above, the color density of the print image can be adjusted for each photographic film used. Therefore, the color between the display image corresponding to the frame image displayed by the display means and the print image can be adjusted. The density is matched for each photographic film used. As a result, it is possible to reliably reduce the loss print that occurs due to the color density mismatch between the display image and the print image, and to perform the inspection work based on the display image accurately.

[Brief description of the drawings]

FIG. 1 is a flowchart showing a flow of an operation in a photographic printing apparatus according to the present invention.

FIG. 2 is an explanatory diagram showing a schematic configuration of the photo printing apparatus.

FIG. 3 is an explanatory diagram showing an example of a table stored in a print correction coefficient storage unit of the image processing unit of the photo printing device.

FIG. 4 is an explanatory diagram showing a difference in a print correction value according to a film density of a negative film when light B is exposed.

[Explanation of symbols]

 2 Image processing section (computer) 2b Print correction coefficient storage section (storage means) 2c Exposure correction value calculation section (exposure correction value calculation means) 3 Exposure section (exposure means) 4 Display section (display means)

Claims (8)

[Claims] An image printed on a photosensitive material with an exposure amount based on an exposure correction value of image data for each different color corresponding to an arbitrary frame image of a photographic film, and displayed based on a display correction value of the image data. This is a color matching method for matching the color density with the image to be processed, in which correction coefficients corresponding to individual photographic films of different types are stored, and a correction corresponding to the type of photographic film used is selected from the stored correction coefficients. A color matching method comprising extracting coefficients and correcting one of the exposure correction value and the display correction value using the extracted correction coefficient. 2. The color matching method according to claim 1, wherein the exposure correction value is corrected using the correction coefficient, and the photosensitive material is exposed with an exposure amount based on the corrected exposure correction value. 3. The color matching method according to claim 2, wherein said exposure correction value includes said display correction value. 4. The color matching method according to claim 1, wherein said correction coefficient is set according to the density of said photographic film. 5. The color matching method according to claim 1, wherein said correction coefficient is set for each color corresponding to said image data. 6. The method according to claim 1, wherein the correction coefficient is set based on a color corresponding to the image data and a density of the photographic film, and is stored as one table for each photographic film. The color matching method according to any one of claims 1 to 5, wherein: 7. An image printed on a photosensitive material with an exposure amount based on an exposure correction value of image data for each color corresponding to an arbitrary frame image of a photographic film, and displayed based on a display correction value of the image data. A recording medium storing a program for performing a color matching process for matching a color density with an image to be processed, wherein a process of storing correction coefficients corresponding to each of different types of photographic film; and A computer executes a process of extracting a correction coefficient corresponding to the type of photographic film used, and a process of correcting one of the exposure correction value and the display correction value using the extracted correction coefficient. Recording a program for performing a color matching process, characterized by recording a program for performing the color matching process. 8. An exposure correction value calculating means for calculating an exposure correction value of image data for each different color corresponding to an arbitrary frame image of a photographic film, and an exposure for exposing a photosensitive material with an exposure amount based on the exposure correction value. And a display means for displaying an image corresponding to the frame image, comprising: a storage means for storing correction coefficients respectively corresponding to different types of photographic films; A photographic printing apparatus, wherein the calculating means extracts a correction coefficient corresponding to the type of the photographic film used from the storage means, and sets the exposure correction value based on the extracted correction coefficient.