JP2004147257A - Color prediction model creation method, color prediction model creation device, program, and storage medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To constitute a highly accurate color prediction model even in an output device to which total amount restriction is applied in a method for creating a color prediction model. <P>SOLUTION: Output values after correction for the respective color components are calculated so that a device color signal of a color patch does not exceed predetermined total amount restriction based on an initial output value as an output value of the color patch of which the total amount restriction is not considered. In this case, for the initial output value located on or in the vicinity of a color gamut outline, the initial output value is corrected so that it is located on or in the vicinity of the color gamut outline even after the correction. For example, color component other than the one having 100% of ink amount is reduced so as to satisfy the total amount restriction without reducing the color component having 100% of the ink amount. When combination of initial output values of Y, M, C except K is achromatic color of 1:1:1, the output value is corrected so that ratio of the initial output values of Y, M, C, K is maintained and the total amount restriction is satisfied. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention provides a method and apparatus for performing color conversion (also referred to as color matching processing or color management) for improving color reproducibility in a color image output device such as a CRT (Cathode Ray Tube), a liquid crystal (LCD), or a printer. In addition, the present invention relates to a computer-readable storage medium storing a program and a patch image used for the program and a color prediction model creation / correction process.
[0002]
More specifically, a color prediction model for creating or modifying a color prediction model for performing color conversion between a device color signal and a device-independent color signal of a printer or the like in which the total amount of color materials that can be output is limited. Method.
[0003]
[Prior art]
In a color image display device such as a liquid crystal display or a CRT, the appearance of colors differs for each display method due to differences in contrast, luminance characteristics, or a reproducible color gamut (Gamut; gamut; color gamut). In addition, the appearance and feeling of colors change depending on the lighting conditions in the environment where the display device is installed and the angle or distance when viewing the display device. Further, since the device characteristics change due to aging, even if the characteristics at the time of shipment are the same, the color reproduction characteristics change depending on the subsequent use.
[0004]
Further, when exchanging data with peripheral devices such as a printer and a scanner, it is natural that input / output characteristics and gamut are different. For example, in an information processing system using the Internet, etc., color matching of images between monitors in each terminal device such as a personal computer or color matching between a color image of a monitor and a color image printed out by a printer is an important issue. is there.
[0005]
For example, in a system used in DTP (Desk Top Publishing), an image is usually generated and edited on an image display device such as a CRT, and a final document is output in a form of printing. Various types of display devices and output devices have been developed, and a plurality of types and a plurality of devices have been used.
[0006]
In such an environment, for example, the color of an image displayed on a CRT is reproduced by a printer, the color of a print is reproduced by a printer, or a photo is read by a scanner, and the color of the photo is read by a CRT. Various methods have been proposed for techniques for reproducing and matching colors between different devices.
[0007]
2. Description of the Related Art In recent years, in the field of handling color images, in order to uniformly manage colors output by each device, that is, even if devices (color image input devices and color image output devices) are different, images (especially colors) are different. In order to make the appearance the same, a mechanism for realizing color matching processing as the whole system has been considered. Such a mechanism is called a color management system (CMS; Color Management System).
[0008]
A typical example of the CMS is a method using an ICC (International Color Consortium) profile. The ICC profile is a format for describing the characteristics of a device standardized by the ICC, and its substance is usually independent of devices such as CIEXYZ and CIELAB defined by CIE (Commission Internationale de L'Eclairage). It is a conversion table or a conversion matrix between a device independent color space that is a color space and a device color space that is a color space unique to a target device.
[0009]
Then, the device color signal of the reproduction source is converted into a device independent color signal using the ICC profile of the device as the reproduction source, and the device independent color signal is converted into the device color of the reproduction destination using the ICC profile of the device as the reproduction destination. By converting the color into a signal, the color of the reproduction source device can be reproduced by the reproduction destination device. As described above, in the CMS, color matching between the reproduction source device and the reproduction destination device is often realized through the device independent color space.
[0010]
As a color conversion method between a device-specific color space and a device-independent color space, a method using a linear matrix such as a color masking method or a theoretical expression typified by Neugebauer equation is used. There is a way. However, with these methods, it is difficult to accurately describe the characteristics of an actual device.
[0011]
For this reason, recently, in order to perform colorimetrically consistent color reproduction, in order to understand the relationship between device signals and colorimetric values, an arbitrary A technique of constructing a color prediction formula for predicting a colorimetric value for a device signal has been adopted.
[0012]
For example, a colorimetric value (device-independent color signal such as an XYZ or CIELAB color signal) obtained by measuring a color image of a patch image composed of a color patch based on a known device color signal by a target device. A multidimensional table created directly from the correspondence between the device and the color signal of the corresponding color patch, or a multidimensional table created based on a color conversion (prediction) model using a neural network learned from the correspondence. It has become common to perform color conversion.
[0013]
For example, there are various techniques such as a neural network and a method based on a regression model described in Patent Document 1 as a color prediction model created from a relationship between a device color signal of a color output device and a corresponding colorimetric value.
[0014]
[Patent Document 1]
JP-A-10-262157
[0015]
Here, in order to perform highly reliable color prediction, it is desirable to output as many color patches as possible and to perform color prediction based on the colorimetric results. However, in a printer such as a C (cyan), M (magenta), Y (yellow), and K (black / black) (hereinafter collectively referred to as CMYK) printer, for example, when it is desired to output color patches of eight levels for each color, Reaches 4,096 patches, which greatly increases the load required for the colorimetric work. Therefore, in general, the number of patches is reduced as much as possible, and a lacking point is dealt with by interpolation or extrapolation.
[0016]
On the other hand, in a color image output device, for example, a printing machine or an ink jet printer using ink, or a xerography printer using toner, the total amount of ink (toner) at the same position is limited due to transfer performance and fixing performance. Some are provided.
[0017]
For example, in the case of an electrophotographic printer, if the total amount of CMYK inks (the total amount of attached toner) is too large, poor transfer of ink (toner) to a recording sheet, poor fixing, and the like occur, resulting in significant color unevenness. Will be. Also, in the case of an ink jet printer, if the ink amount is too large, the ink may not be properly absorbed (anchored) by the recording paper and may bleed.
[0018]
The total amount limit is set to avoid these phenomena, and the controller or engine for printing a color image forcibly sets the amount of ink so that ink (toner) exceeding the transfer capability and fixing performance does not reach the same position. Restrict to
[0019]
When the total amount limit is determined, the total amount limit value is defined based on the capability inherent to the machine. In a device capable of switching the print mode, the total amount limit value is defined according to the print mode. Ink (toner) or print medium There are various types such as those that limit the total amount in consideration of the characteristics of (for example, paper).
[0020]
However, in relation to the above-described color prediction model creation, since the total amount limit value has not been considered in the related art, a color patch that exceeds the restriction condition of the total amount of ink has been output. That is, even if a color patch that exceeds the total ink amount regulation is output to a printer that has a restriction on the total ink amount of CMYK, stable color reproduction cannot be performed as a printer. Therefore, if a color prediction model is created using the colorimetric data of a color patch that exceeds the total ink amount regulation, a prediction formula with extremely low reliability results.
[0021]
For example, in a CMYK xerographic printer having a total amount limit value of 280%, when device color signals of 100% for C (cyan), M (magenta), Y (yellow), and K (black) are all given, for example, While the ratio of each color component is kept, it is converted into a device color signal of C = 70%, M = 70%, Y = 70%, and K = 70% and output.
[0022]
Naturally, even if it is intended to output C, M, Y, K = 100% device color signals as color patches, actually, C, M, Y, K = 70% device color signals will be output. For this reason, there is a problem that the correspondence between the output color patch and the colorimetric values acquired by colorimetry is not correct, and an appropriate color prediction model cannot be created.
[0023]
Therefore, as a method for solving the above-mentioned problem in relation to the creation of the color prediction model and the total amount limit value, for example, Japanese Patent Application Laid-Open No. H11-163873 discloses the output of a color patch so that each color patch does not exceed a predetermined total amount of ink (toner). Have been proposed.
[0024]
[Patent Document 2]
JP-A-9-261492
[0025]
The method described in Patent Document 2 corrects a device color signal of a color patch exceeding the total amount limit within the total amount limit. In particular, in a CMYK printer, the amount of ink of K, which is the color component, is not reduced. Alternatively, by increasing and decreasing the remaining C, M, and Y color components, a color patch of a dark portion is secured without exceeding the total amount limit, and a high-precision color prediction model is obtained in the entire CMYK color space. How to create
[0026]
[Problems to be solved by the invention]
Here, when creating a color prediction model, the device color signal of the color patch used as the relationship between the device color signal and the corresponding colorimetric value is determined by the target color output device regardless of the method used. It is considered preferable that a sufficient number be distributed over the entire color gamut that can be reproduced when the total amount limit is satisfied, and also on the color gamut outline that can be reproduced when the total amount limit is satisfied. . That is, it is desirable that the population is uniformly distributed over the entire area.
[0027]
This is because if there is a missing part in the reproducible color gamut after satisfying the total amount limit, the color prediction of that part will be performed with the device color signal located far away from the position actually calculated and the corresponding colorimetric value This is because the calculation (interpolation) is performed using the relationship with, and the prediction accuracy may be reduced.
[0028]
If there is no relationship between a sufficient number of device color signals and the corresponding colorimetric values on the color gamut that can be reproduced after satisfying the total amount limitation, the color gamut is located inside the color gamut. ), Extrapolation is performed using the relationship between the device color signal and the corresponding colorimetric value to perform color prediction on the color gamut outline. However, in general, the precision of extrapolation is considerably worse than the precision of interpolation.
[0029]
Here, the method described in Patent Document 2 described above is a method that focuses on securing a color patch in a dark portion when correcting a color component so as to satisfy the total amount restriction. In other words, this only considers distributing the color patches over the entire color gamut, and does not consider securing a sufficient number of color patches on the color gamut contour of a color output device that satisfies the total amount limit. There is a problem.
[0030]
In particular, when the ink amount of K is fixed, or the ink amount of K is increased and the ink amounts of C, M, and Y are decreased so as to satisfy the total amount limit, the color of the color patch becomes near the gray axis. As a result, the number of color patches in the vicinity of the color gamut contour in a relatively dark portion is reduced, and the prediction accuracy is reduced. For this reason, there is a problem that a device model (color prediction model for the device) different from the characteristics of the original output device is obtained.
[0031]
In addition, since there is almost no color on the outline of the color gamut that can be reproduced after satisfying the total toner amount limit of the output device, extrapolation or a process similar thereto is required when the created device model is applied. As a matter of course, as described above, if the extrapolation is performed to predict the color on the color gamut outline, there is a problem that the accuracy of the device model is reduced.
[0032]
Further, in the correction method described in Patent Document 2 described above, it is necessary to know information on the total amount limit value determined by the apparatus alone or the relation between the apparatus and the print medium, but it is troublesome for the user to specify and input the information. In addition, there is a problem in accuracy. In other words, asking a general user to specify the total amount limit value and then outputting the patch image on the apparatus not only causes trouble of the operation but also outputs an erroneous patch image due to an operation error or the like. It can be a thing. If a color prediction model is created or corrected based on an erroneous patch image, the accuracy of the device model is reduced.
[0033]
Today, an information processing system is provided by combining an arbitrary number of various color image display devices such as a liquid crystal display and a CRT, and various color image output devices such as an ink jet printer and a xerography printer. Is building. In this case, a color prediction model must be constructed according to the system configuration.
[0034]
At this time, it is also conceivable that the user himself / herself sets the color gamut reproduction range (in spite of the total amount limit value) to create a preferable device model so as to conform to the combination of devices at the time of system construction or every time the model is switched. However, it is difficult to obtain and set many pieces of corresponding point information (grid point data of a lookup table) one by one. This is even more so if a device model is created by setting a coverage limit taking into account the total amount limit value.
[0035]
The present invention has been made in view of the above circumstances, and creates or modifies a more accurate color prediction model even when the total amount limit value is determined by the apparatus alone or the relation between the apparatus and the print medium. It is an object to provide a method and an apparatus that can
[0036]
The present invention also provides a program for realizing the method and the apparatus using a computer, and a computer-readable storage medium storing a patch image that can be used when creating or modifying a color prediction model. The purpose is to:
[0037]
[Means for Solving the Problems]
That is, the color prediction model creating method according to the present invention outputs a plurality of color patches representing a predetermined color whose output value is known in advance by a color image output device, and measures the output plurality of color patches. Then, based on the correspondence between the colorimetric value obtained by the colorimetry and the device color signal of the color patch, the color difference between the device color signal in the color image output device and the device independent color signal independent of the color image output device is determined. In a color prediction model creating method for creating a color prediction model representing a color signal conversion relationship, a device color signal of a color patch is previously determined based on an initial output value which is an output value of a color patch in which a total amount limitation is not considered. The corrected output value for each color component is determined so as not to exceed the defined total amount limit, and the initial output value located on or near the color gamut outline is By calculating the corrected output value so that it is located on or near the color gamut outline after correction, a plurality of color patches for measurement are created, and the created plurality of color patches are output by a color image output device. A color prediction model was created by measuring the color.
[0038]
The dependent claims define further advantageous specific examples of the method for creating a color prediction model according to the present invention.
[0039]
Further, a color prediction model creation device according to the present invention includes components necessary for implementing the color prediction model creation method according to the present invention.
[0040]
Further, the program according to the present invention is suitable for implementing the method and apparatus for creating a color prediction model according to the present invention by software using an electronic computer (computer). The program may be provided by being stored in a computer-readable storage medium, or may be distributed via a wired or wireless communication unit.
[0041]
Further, a storage medium according to the present invention stores color conversion coefficients generated by using the color prediction model creating method according to the present invention.
[0042]
[Action]
In the color prediction model creation method having the above configuration, first, based on an initial output value which is an output value of a color patch in which the total amount limitation is not taken into consideration, a device color signal of each color patch is subjected to a predetermined total amount limitation. Correct the output value of each color component so that it does not exceed. In this respect, it is common to the method described in Patent Document 2.
[0043]
However, the present invention is characterized in that at the time of this correction, the initial output value located on or near the color gamut is corrected so as to be located on or near the color gamut after the correction.
[0044]
In the subsequent color prediction model creation process, the color gamut outline is taken into account, and color measurement is performed using only the corrected patches that satisfy the total amount limitation to create a color prediction model.
[0045]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0046]
In the following description, it is assumed that the device-independent color space used in the color prediction model is CIELAB, and the CIELAB colorimetric value data is directly acquired by the colorimeter. However, the present invention is not limited to this, and other device-independent color spaces such as XYZ and CIELUV can be used. For example, it is also possible to obtain a colorimetric value data set in XYZ by performing colorimetric measurement so that colorimetric values can be obtained in XYZ, or by calculating XYZ by mathematical formulas from colorimetric values obtained in CIELAB, for example. Can be.
[0047]
<Color prediction model creation method>
FIG. 1 is a process chart showing one embodiment of a color prediction model creation method according to the present invention. By configuring hardware (for example, circuit elements) according to this process diagram, a color prediction model creation device that implements the color prediction model creation method is configured.
[0048]
As shown in the figure, all the steps include a patch color measurement step 1, a patch data set selection step 2, and a color prediction model creation step 3.
[0049]
In the patch colorimetry step 1, a user selects a patch image suitable for a target color output device from a plurality of patch images prepared in advance, and outputs the patch image using the target color output device. At this time, the system may present an appropriate patch image to the user by designating a color output device and output conditions (output paper and output mode) to be used by the user via the user interface.
[0050]
FIG. 2 is a diagram illustrating an example of a user interface for selecting a patch image. Here, FIG. 2A is a diagram illustrating an example of a user interface that presents a user with a patch image to be measured by selecting a combination of a target color output device and an output medium. FIG. 2B is a diagram illustrating an example of a user interface presented after being instructed by FIG. 2A.
[0051]
In this user interface, the selection of the combination of the color output device and the output medium is displayed by clicking the black inverted triangle button, and a list of the combination of the color output device supported by the system and the output medium is displayed. Can select one of them.
[0052]
When the user selects a combination of the target color output device and the output medium from the user interface of FIG. 2A, the location of the appropriate patch image can be presented to the user as shown in FIG. 2B. The user can output the presented patch image using a target color output device and an output medium, measure the output patch image, and create a colorimetric value data set.
[0053]
As a method for the system to present an appropriate patch image from the color output device designated by the user and the output medium, for example, a combination of a color output device supported by the system as shown in FIG. A correspondence table that associates patch images that are considered appropriate with the corresponding patch image is created in advance, and an appropriate patch image can be presented from a combination of a color output device and an output medium designated according to the correspondence table.
[0054]
Then, the user measures each color patch in the output patch image in a predetermined order, and colorimetric values (CIELAB in the present embodiment), which are device-independent color signals independent of devices, are arranged in a predetermined order. Get the colorimetric value data set that exists. This colorimetric value data set is passed to the next step, a color prediction model creation step 3.
[0055]
In the patch data set selection step 2, the user specifies a patch data set corresponding to the patch image selected and measured in the patch color measurement step 1 from the patch data sets prepared in advance in pairs with the patch images. This patch data set is a data set in which device color signals (for example, CMYK color signals and RGB color signals) of color patches in a patch image are arranged in a predetermined order. The patch data set specified by the user is passed to the next step, a color prediction model creation step 3.
[0056]
In the present embodiment, the patch image and the patch data set are prepared in advance as a pair. However, only the patch data set is prepared in association with the device and the output condition, and the patch image is stored in the patch data set. May be automatically generated from the arrangement of the device color signals constituting the device and presented to the user.
[0057]
FIG. 3 shows a total amount limit value corresponding to a combination of various color output devices and output media supported by the system in the color prediction model creation method according to the present embodiment, and a corrected measurement amount corresponding to the total amount limit value. FIG. 7 is a diagram showing a correspondence table of a patch data set / patch image including a plurality of color patches.
[0058]
Here, the total amount limit value itself is merely inserted to explicitly indicate that the patch data set / patch image is created based on the corresponding total amount limit value, and should be deleted from the correspondence table. Can be.
[0059]
According to the correspondence table of FIG. 3, four types of patch data sets CMYK400, CMYK320, CMYK280, and RGB300 generated based on the initial output values in which the total amount limitation is not considered, and the patch data of these patch data sets The composed patch image is prepared in advance.
[0060]
Of course, the patch data in the CMYK320 and CMYK280 patch data sets are configured so that their total amounts are 320% and 280% or less, respectively. This configuration method will be described in detail in the section “Configuration of Patch Data Set”.
[0061]
FIG. 4 is a diagram showing an example of a user interface for specifying a colorimetric value data set acquired in the patch colorimetric process 1 and selecting a patch data set in the patch data set selecting process 2.
[0062]
In this user interface, a patch data set is selected by clicking a black inverted triangle button, and a list of combinations of color output devices and output media supported by the system is displayed. You can choose one. In the colorimetric value data set, a file of the colorimetric value data is directly specified.
[0063]
In this example, the user selects the target patch data set with the combination of the target color output device and its output medium, and the system uses the combination of the selected color output device and its output medium as shown in FIG. Get the appropriate patch dataset using the correspondence table.
[0064]
Of course, the user must also select the same combination of the target color output device and the output medium in the user interface shown in FIG. 2A in the selection of the patch data set of this user interface. Further, the user specifies the colorimetric value data set acquired in the patch colorimetric process 1. The system can acquire the colorimetric value data set by reading the specified colorimetric value data set.
[0065]
By selecting a combination of a target color output device and its output medium, a patch data set including an appropriate color patch according to the combination can be automatically selected. This eliminates the need for the user to output an inappropriate patch image and perform colorimetry or to specify a patch data set other than the patch data set corresponding to the patch image.
[0066]
Here, the configuration is adopted in which the user selects the combination of the target color output device and the output medium in the two user interfaces shown in FIGS. 2A and 4, but only once in the patch colorimetry process 1. The system allows the user to select the combination of the target color output device and the output medium, and stores the combination of the selected target color output device and the output medium in the patch data selection step 2. It can also be configured to use a combination of the target color output device and the output medium.
[0067]
The color prediction model creation step 3 creates a color prediction model of the target device using the colorimetric value data set received from the patch color measurement step 1 and the patch data set received from the patch data set selection step 2.
[0068]
This color prediction model creation step 3 may be any method that creates a model from the relationship between the colorimetric value data set and the arrangement of device color signals in the target device color space.
[0069]
Examples of a method of creating a color prediction model include a method of determining a coefficient of each neuron of the neural network by learning using a colorimetric value data set and a patch data set as teacher data, which is a color prediction model using a neural network, For example, a color transfer characteristic prediction method described in Patent Document 1 (Japanese Patent Laid-Open No. 10-262157) using a data set and a patch data set as actual input / output data can be used.
[0070]
<How to configure the patch data set>
Next, the configuration of an appropriate patch data set that satisfies the total ink (toner) amount limit value that can be determined by the color output device and its output medium will be described in detail.
[0071]
Here, based on the ISO12642 pattern, which is an initial output value that does not take into account the total amount limitation used in color reproduction printing of Japan Color, etc., a combination of a color output device “Printer A / plain paper” and an output medium is used. An example will be described in which a corresponding patch data set (CMYK320) having a total amount limit value of 320% is configured.
[0072]
The ISO12642 pattern is composed of 928 CMYK color signals. This does not take into account the total amount limitation, and therefore includes a combination of CMYK color signals in which the total amount of ink exceeds 320%.
[0073]
FIG. 5 is a list of only 928 CMYK color signals of the ISO12642 pattern extracted from combinations having a total ink amount exceeding 320% (columns of C, M, Y, and K). Then, by the method described in Patent Document 2 (Japanese Patent Application Laid-Open No. 9-261492), that is, without reducing the ink amount of K, the C, M, Y Corrected ink amounts when the ink amount is reduced are shown as C ′, M ′, Y ′, and K ′.
[0074]
If the ink amounts of C, M, and Y are corrected without decreasing the ink amount of K by the method described in Patent Literature 2 in order to satisfy the total amount limitation, the ink amounts of C, Y that originally had 100% ink amount , M are reduced as shown in FIG. In such a case, when there is no total amount limit (in the case of a CMYK device, the total amount limit value is 400%), the CMYK data that was on the outline of the reproducible color gamut is corrected so as to satisfy the total amount limit. In many cases, the color becomes more inward from the outer periphery of the reproducible color gamut.
[0075]
In order to solve this problem, in the present embodiment, the device color signal of the color patch of each color exceeds the predetermined total amount limit based on the initial output value which is the output value of the color patch in which the total amount limit is not considered. The output values after correction for each color component are determined so that there is no correction, and the initial output values located on or near the color gamut are corrected so that they are still on or near the color gamut after correction. . In other words, the correction is performed such that the color signals on / in the vicinity of the color gamut before the correction substantially maintain the state. A specific method of correcting the color signal on / in the vicinity of the color gamut so as to substantially maintain the state will be described below.
[0076]
FIG. 6 shows that the CIELAB color signal corresponding to the CMYK data on the outline of the color gamut when there is no total amount limitation is corrected to become the CIELAB color signal inside the color gamut that can be reproduced after satisfying the total amount limitation. FIG.
[0077]
As described in "Problems to be Solved by the Invention", data on the outline of the color gamut is important in creating a color prediction model based on colorimetric value data and device color signals (patch data). However, if there is not enough data on the color gamut outline, the prediction accuracy of the created color prediction model may decrease.
[0078]
On the other hand, the CMYK data on the color gamut outline that can be reproduced after satisfying the total amount limit means that the total amount of ink does not exceed the total amount limit value and at least one of C, M, Y, and K is 100%. In most cases.
[0079]
Therefore, it can be seen that, for a color component (including a black component) that is approximately 100% of the initial output value, the corrected output value should be obtained so that approximately 100% is substantially maintained. Therefore, when the CMYK color signal is changed to satisfy the total amount limitation, the change is performed by reducing the other color components so as to satisfy the total amount limit without reducing the color component having the ink amount of 100%. Is more desirable. In this case, for the other color components to be reduced, the remaining amount of the total amount limit value may be allocated so that the ratio of the initial output values of the other color components to be reduced is maintained.
[0080]
However, depending on the total amount limit value to be satisfied, there may be a case where the total amount limit cannot be satisfied unless the color component of 100% is reduced. In this case, the 100% color component is not reduced as much as possible in the initial stage. By modifying the output value, the CMYK color signal may be changed to satisfy the total amount limit.
[0081]
The above-described method of not reducing the 100% color component as much as possible is performed when the color signal to be changed is a chromatic color, that is, the combination of the initial output values of each color component (Y, M, C) except K is 1: This is particularly effective when the ratio is not 1: 1.
[0082]
When the combination of the initial output values of the respective color components represents an achromatic color, that is, when the combination of the initial output values of the respective color components (Y, M, C) excluding the black component (K) is 1: 1: 1, The output values are corrected so that the ratio of the initial output values of the respective color components including the component (K) is substantially maintained and the total amount limit is satisfied. That is, in the case of a CMYK color signal in which neutral gray (C = M = Y) and K ≠ 100%, the value of the initial output value is corrected while maintaining the ratio of C: M: Y: K. Then, the CMYK color signals may be changed to satisfy the total amount limit.
[0083]
Also in the case of a chromatic color, the CMYK color signal that satisfies the total amount limit may be changed by modifying the value of the initial output value while maintaining the ratio of C: M: Y: K.
[0084]
FIG. 7 is a diagram showing an example in which the CMYK color signals of the combination in which the total ink amount of 928 CMYK color signals of the ISO12642 pattern exceeds 320% are corrected by the above-described method. Here, in the case of neutral gray (C = M = Y) and K = 100%, the method of Patent Document 2 is used.
[0085]
As can be seen by comparing FIG. 5 and FIG. 7, the initial output value of C = M = Y = K = 100% is the same as the result using the method of Patent Document 2, even after the correction. In other combinations, 100% of the color components are maintained at 100% after the correction.
[0086]
Therefore, color patches can be distributed over the entire color gamut, and a sufficient number of color patches can be included on the color gamut outline. In other words, the patch data set (arrangement of CMYK data) is composed of only CMYK data that does not exceed the total amount limit that can be determined from the combination of the color output device and its output medium, and can be reproduced after satisfying a sufficient number of total amount restrictions. It is possible to prepare a patch data set including data on the color gamut outline (not limited to one arranged in one sheet, but may be a combination of data to be output individually).
[0087]
The color patch after such correction is output by the target color output device, colorimetrically measured, and a colorimetric value data set obtained by colorimetry and a device color signal set corresponding to a color patch group of the patch image are obtained. If a color prediction model is created from the relationship, a highly accurate color prediction model can be created.
[0088]
The series of processes described above can be executed by hardware, but can also be executed by software. When a series of processing is executed by software, a program constituting the software can execute various functions by installing a computer incorporated in dedicated hardware or installing various programs. It is installed from a recording medium into a possible general-purpose personal computer or the like.
[0089]
This recording medium is a computer-distributed magnetic disk (including a flexible disk) and an optical disk (CD-ROM (Compact Disc-Read Only Memory)) on which the program is recorded, which is distributed to provide the program to the user. , A DVD (including a Digital Versatile Disc), a magneto-optical disk (including an MD (Mini Disc)), or a package medium formed of a semiconductor memory, etc. It may be constituted by a provided ROM or hard disk in which a program is recorded. Alternatively, a program constituting software may be provided via a communication network.
[0090]
For example, a storage medium storing a program code of software for realizing the functions of the above-described embodiments is supplied to a system or apparatus, and a computer (or CPU or MPU) of the system or apparatus stores the program code stored in the storage medium. , The effect described in the above embodiment can be achieved. In this case, the program code itself read from the storage medium implements the functions of the above-described embodiment.
[0091]
When the computer executes the readout program code, not only the functions of the above-described embodiments are realized, but also an OS (Operating System) running on the computer based on the instruction of the program code. A case where some or all of the actual processing is performed, and the functions of the above-described embodiments are realized by the processing.
[0092]
Further, after the program code read from the storage medium is written into a memory provided in a function expansion card inserted into the computer or a function expansion unit connected to the computer, the function expansion is performed based on the instruction of the program code. The CPU or the like provided in the card or the function expansion unit may perform part or all of the actual processing, and the processing may realize the functions of the above-described embodiments.
[0093]
As described above, the present invention has been described using the embodiment. However, the technical scope of the present invention is not limited to the scope described in the embodiment. Various changes or improvements can be made to the above-described embodiment without departing from the spirit of the invention, and embodiments with such changes or improvements are also included in the technical scope of the present invention.
[0094]
Further, the above embodiments do not limit the invention according to the claims (claims), and all combinations of the features described in the embodiments are not necessarily essential to the means for solving the invention. Absent. The embodiments described above include inventions at various stages, and various inventions can be extracted by appropriately combining a plurality of disclosed constituent features. Even if some components are deleted from all the components shown in the embodiment, as long as the effect is obtained, a configuration from which some components are deleted can be extracted as an invention.
[0095]
For example, in the above-described embodiment, a patch sheet that outputs a patch image including a plurality of color patches with a color image output device using the output values of the color patches in which the total amount limitation is not considered is measured, but it takes time. However, it is also possible to output each color patch and measure each color.
[0096]
In the above embodiment, a target device selection step of selecting a target color image output device is performed as a first step, and a medium to be output using the target color image output device is selected as a second step. The target medium selection step is a third step, in which a plurality of color images for measurement corresponding to the color image output device selected in the target device selection step and the “total amount limit value” specific to the medium selected in the target medium selection step. Although a patch set setting step of setting a patch set including a patch (after correction) is included, the third step does not necessarily include a patch set including a corrected color patch corresponding to the “total amount limit value”. May not be set.
[0097]
What is necessary is just to be able to automatically set a required patch set in relation to the selected color image output device and the output medium. To this end, as in the above embodiment, a correspondence table of a patch data set including predetermined color patches corresponding to combinations of various color output devices and output media supported by the system is prepared, and In this case, the configuration may be such that the table is presented, and an instruction of a desired combination is received to automatically select the combination. As described above, the individual color patches of the prepared patch data set do not necessarily need to consider the total amount limit value in the combination.
[0098]
When creating a device model at the time of system construction or model changeover, a patch data set that can be supported is automatically provided simply by specifying the system configuration. Is much simpler. The patch data set may be provided by being stored in a computer-readable storage medium (for example, a CD-ROM or a DVD-ROM), or may be distributed via a wired or wireless communication unit.
[0099]
Further, as apparent from the above description, the following configuration can be proposed as the invention. They are listed below (including those overlapping with the claims).
* A patch pattern and a patch image, wherein the total amount of toner of each patch constituting the patch pattern is within the total toner amount limit value of the target output device.
* Patch patterns and patch images having patches whose total toner amount is equal to or smaller than the total toner amount limit value of the target output device.
A patch pattern, wherein the patch is a process gray patch;
A patch pattern, wherein the patch is a patch in which one of the color components constituting the patch is 100%.
* By modeling the characteristics of the target output device using the colorimetric values and patch patterns obtained by printing and measuring the patch image as described above, the color profile of the output device and the output device PROCESSING METHOD AND IMAGE PROCESSING APPARATUS FOR CREATING A COLOR CONVERSION PROFILE BETWEEN DEVICE AND OTHER DEVICES, AND A PROGRAM FOR IMPLEMENTING THE IMAGE PROCESSING METHOD AND A RECORDING MEDIUM CONTAINING A COLOR CONVERSION PROFILE CREATED BY THE IMAGE PROCESSING METHOD .
* A patch pattern correction method for deleting a patch whose total toner amount exceeds a total toner amount limit value of a target output device from a base patch pattern that does not consider the total toner amount limit.
* A patch is configured such that the total amount of toner is equal to or smaller than and substantially equal to the total amount limit of toner while maintaining the ratio of each color component constituting the patch exceeding the total amount limit of toner of the target output device. A patch pattern correction method for correcting each color component.
* Whether or not the total toner amount is equal to the total toner amount limit value while maintaining the ratio of each color component except for the black (K) and / or 100% color components constituting the patch exceeding the total toner amount limit of the target output device; Alternatively, a patch pattern correction method for correcting each color component constituting a patch so as to be small and substantially equal.
* When creating a device model of an output device from a patch pattern and corresponding colorimetric values, after removing the set of patches and colorimetric values corresponding to the total toner amount limit value of the target output device, An image processing method and an image processing apparatus for creating a device model of an output device.
[0100]
【The invention's effect】
As described above, in the present invention, based on the initial output value which is the output value of the color patch in which the total amount limit is not considered, each color is controlled so that the device color signal of the color patch does not exceed the predetermined total amount limit. The corrected output value of the component was determined. At this time, with respect to the initial output value located on or near the color gamut outline, the initial output value is corrected so as to be located on or near the color gamut outline even after the correction.
[0101]
As a result, the patch data set (arrangement of data) is composed of only data that does not exceed the total amount limit that can be determined from the combination of the color output device and its output medium, and can be reproduced after satisfying a sufficient number of total amount restrictions. It becomes possible to prepare a patch data set including data on the color gamut outline.
[0102]
Therefore, in order to prevent a failure in an output device to which the total amount limit is applied, a patch by a device color combination that is forcibly corrected to satisfy the total amount limit in a device or a controller can be excluded from the patch pattern. , It is possible to create a device model that matches the actual device.
[0103]
Further, since a sufficient number of color patches can be secured on or near the color gamut boundary, a more accurate device model can be created. That is, if a color prediction model is created from a colorimetric value data set obtained by output and colorimetry with a color output device based on such patch data, a color prediction model with higher accuracy than the conventional method can be constructed. can do.
[0104]
In addition, by selecting a combination of a target color output device and its output medium so that a patch set including an appropriate color patch according to the combination can be automatically selected, the user can select an inappropriate patch image. This eliminates the need to output and perform colorimetry or to specify a patch data set that is not the patch data set corresponding to the patch image, making it possible to more reliably create a target color output device color prediction model. it can.
[Brief description of the drawings]
FIG. 1 is a process chart showing one embodiment of a color prediction model creation method according to the present invention.
FIG. 2 is a diagram illustrating an example of a user interface for selecting a patch image.
FIG. 3 is a diagram showing an example of a correspondence table for associating a color output device, an output medium, and a patch data set;
FIG. 4 is a diagram illustrating an example of a user interface for selecting a patch data set.
FIG. 5 is a diagram showing an example of a table showing an example of correction of CMYK data according to a conventional method.
FIG. 6 is a diagram illustrating an example of correction of CMYK data according to a conventional method.
FIG. 7 is a diagram showing an example of a table showing an example of correction of CMYK data according to the embodiment.
[Explanation of symbols]
1. Patch colorimetry step 2: Patch data set selection step 3: Color prediction model creation step

Claims (8)

A plurality of color patches representing predetermined colors whose output values are known in advance are output by a color image output device, the output color patches are measured, and the colorimetric values obtained by the colorimetry and A color signal conversion relationship between a device color signal in the color image output device and a device independent color signal independent of the color image output device is determined based on a correspondence relationship between device colors of the color patches corresponding to colors. A color prediction model creation method for creating a color prediction model to represent,
Based on an initial output value that is an output value of a color patch in which the total amount limit is not considered, a corrected output value for each color component so that the device color signal of the color patch does not exceed the predetermined total amount limit. And, for the initial output value located on or near the color gamut outline, by obtaining the output value after the correction so as to be located on or near the color gamut outline after the correction, a plurality of measurement for A color prediction model creation method, wherein a color patch is created, and the created color patches are output by the color image output device and colorimetrically measured to create the color prediction model. The color prediction model according to claim 1, wherein a patch image including a plurality of the color patches is output by the color image output device, and individual color patches of the output patch image are measured. How to make. 3. The modified output value is determined so that a color component that is approximately 100% of the initial output value is substantially maintained at approximately 100%. How to create a color prediction model. When the combination of the initial output values of the respective color components represents an achromatic color, the corrected output value is determined such that the ratio of the initial output values of the respective color components including the black component is substantially maintained. Item 3. The color prediction model creation method according to item 1 or 2. A target device selecting step of selecting a target color image output device;
A target medium selection step of selecting a medium to be output using the target color image output device,
A patch for setting a patch set including the plurality of color patches for measurement corresponding to the total amount limit value specific to the color image output device selected in the target device selection step and the output medium selected in the target medium selection step 5. The method for producing a color prediction model according to claim 1, further comprising a set setting step. An apparatus for creating a color prediction model, comprising a component necessary for performing the method for creating a color prediction model according to any one of claims 1 to 5. A program for performing a color gamut mapping process for converting a color image input from a color image input device as a first device according to a color gamut of a color image output device as a second device,
A program comprising program code describing processing steps for causing a computer to execute the color prediction model creation method according to any one of claims 1 to 5. A computer-readable storage medium storing a color conversion coefficient for converting a color image input from a color image input device as a first device according to a color gamut of a color image output device as a second device. ,
A color signal of the color space of the first device generated by using the color prediction model creating method according to any one of claims 1 to 5, is converted into a color signal of a color space of the second device. A storage medium storing the color conversion coefficient for use.

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