JP2009284107A - Color processing apparatus and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To suppress a decrease in color reproducibility regardless of the chromaticity of a form that serves as a ground, when color data is measured. <P>SOLUTION: Color data to be converted in a first color space is acquired, and a mapping processing unit 30 maps the color data to be converted into a predetermined color gamut or on a predetermined color gamut surface set in the first color space. Furthermore, a plurality of color data pairs of a plurality of color data in a second color space as a conversion destination of the color data to be converted and color data in the first color space, corresponding to the respective color data in the second color space are acquired, and the acquired color data in the first color space are corrected according to color differences from reference color coordinates set in the specified color gamut, or on the predetermined color gamut surface of the mapping processing unit 30. Then a color conversion table generation unit 70 generates a color conversion coefficient for associating color data to be converted which has been mapped, using the color data in the second color data and the corrected color data in the first color space with the converted color data in the second color space. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a color processing apparatus and a program.

In an apparatus for inputting / outputting a color image, such as an image forming apparatus such as a printer, a display apparatus such as a liquid crystal display, an image reading apparatus such as a scanner, etc., an input color signal of an RGB color space, for example, L ^* a ^* is independent of the apparatus ^. b ^* Conversion into a color signal such as a color space, and further processing for conversion into a color signal such as a CMYK color space, which is an output color space of each device. At that time, for example, the correspondence between the CMYK color space and the L ^* a ^* b ^* color space is predicted based on the color data actually measured, and the color data measured includes the background color at the time of color measurement. The chromaticity of the new paper is affected. Therefore, the correspondence between the color spaces based on the color data measured using one paper as a background is different from the correspondence based on the color data using another paper having a different chromaticity as a background.
For example, Patent Document 1 obtains the color difference between first paper color data representing the standard paper color used in the printing apparatus and second paper color data representing the paper color actually used for output. A method of performing color correction of color image data in accordance with the difference using a color difference as a parameter is described.

Japanese Patent Laid-Open No. 10-341348

Here, in general, the color data that derives the correspondence between the color spaces has a degree of difference depending on the lightness in the influence received from the paper, and the color region with higher lightness is larger and the color region with lower lightness is smaller. As a result, when the color data is corrected to reduce the influence of the chromaticity of the paper, the correction amount increases as the chromaticity of the paper decreases, so the color measured using the paper with low chromaticity. There is a tendency that the brightness of the reproduced color increases as the data. For this reason, the color reproducibility deteriorates particularly in a high lightness region that is easily affected by lightness.
An object of the present invention is to suppress a decrease in color reproducibility regardless of the chromaticity of a sheet as a base when color data is measured.

  According to the first aspect of the present invention, the conversion target color data acquisition unit that acquires the conversion target color data of the first color space, and the conversion target color data acquired by the conversion target color data acquisition unit are the first A mapping processing unit that performs mapping processing within a predetermined color gamut set in the color space or on the surface of the predetermined color gamut, a plurality of color data in the second color space that is the conversion destination of the conversion target color data, A color data pair acquisition unit that acquires a plurality of color data pairs that are a pair of the color data of the first color space corresponding to each color data of two color spaces, and acquired by the color data pair acquisition unit The color data of the first color space is determined according to a color difference between the color data of the first color space and a reference color coordinate set in the predetermined color gamut of the first color space or on the surface of the predetermined color gamut. In the correction unit for correction and the color data pair acquisition unit Mapping is performed by the mapping processing unit using the obtained color data of the second color space and the color data of the first color space corrected by the correction unit paired with the color data of the second color space. A color processing apparatus comprising: a color conversion coefficient generation unit that generates a color conversion coefficient for associating the processed color data to be converted with the converted color data in the second color space.

According to a second aspect of the present invention, the mapping processing unit is generated by a colorimetric value in the first color space of a color sample printed on a predetermined standard paper based on specific data in the second color space. The correction gamut is set as the predetermined color gamut, and the correction unit sets the chromaticity of the predetermined standard paper constituting the maximum brightness coordinate of the predetermined color gamut set by the mapping processing unit as the reference color. The color processing apparatus according to claim 1, wherein the color processing apparatus is set as a color coordinate.
According to a third aspect of the present invention, the mapping processing unit is configured to measure color values in the first color space of color samples printed on a plurality of predetermined standard papers based on specific data in the second color space. A plurality of color gamuts generated by the above-mentioned color gamut are held, and the color data of the first color space acquired by the color data pair acquisition unit from the plurality of color gamuts is a base when colorimetry is performed. Setting the color gamut generated by the colorimetric values of the color sample printed on the predetermined standard paper having the chromaticity that minimizes the color difference from the chromaticity of the paper as the predetermined color gamut, 2. The unit according to claim 1, wherein the unit sets the chromaticity of the predetermined standard paper constituting the maximum brightness coordinate of the predetermined color gamut set by the mapping processing unit as the reference color coordinate. A color processing apparatus.
According to a fourth aspect of the present invention, the mapping processing unit includes a chromaticity of a paper serving as a base when the color data of the first color space acquired by the color data pair acquisition unit is measured. The predetermined standard paper having the chromaticity that minimizes the color difference is extracted on condition that the predetermined standard paper has a lightness greater than the lightness of the paper, and is printed on the extracted predetermined standard paper. 4. The color processing apparatus according to claim 3, wherein the color gamut generated based on the colorimetric value of the color sample is set as the predetermined color gamut.

The invention according to claim 5 is characterized in that the mapping processing unit holds a plurality of color gamuts including a color gamut having a color coordinate having the highest brightness in the first color space and a maximum brightness coordinate. One of the color gamuts is set as the predetermined color gamut, and the correction unit uses the color coordinate having the highest lightness in the first color space held in the mapping processing unit as the maximum lightness. The color processing apparatus according to claim 1, wherein the maximum brightness coordinate of the color gamut that is set as a coordinate is set as the reference color coordinate.
According to a sixth aspect of the present invention, the correction unit sets the reference color coordinate to the maximum brightness coordinate of the predetermined color gamut set by the mapping processing unit, and the color data of the first color space Normalizing means for normalizing the color data having the highest brightness among the reference color coordinates, and a composition ratio for the color data of the first color space normalized by the normalizing means is Normalized so as to monotonously decrease in accordance with the color difference from the reference color coordinate, and to increase monotonically in accordance with the color difference, the composition ratio for the color data of the first color space acquired by the color data pair acquisition unit. The color processing apparatus according to claim 1, further comprising a combining unit that combines the color data and the color data acquired by the color data pair acquisition unit.
The conversion target color data acquisition unit converts the input color signal of a predetermined color space input from an external device into a color signal of the first color space that is a device-independent color space. The color processing apparatus according to claim 1, wherein the converted color data to be converted is acquired.

  According to an eighth aspect of the present invention, there is provided a computer having a function of acquiring conversion target color data in a first color space, and a predetermined color gamut inside the acquired conversion target color data set in the first color space. Alternatively, the function of performing mapping processing on the surface of the predetermined color gamut, the plurality of color data in the second color space that is the conversion destination of the conversion target color data, and the color data corresponding to each color data in the second color space A function of acquiring a plurality of color data pairs that are paired with color data of one color space; and the acquired color data of the first color space is the color data of the first color space and the color data of the first color space. A function of performing correction according to a color difference from a reference color coordinate set in a predetermined color gamut or on the surface of the predetermined color gamut, the acquired color data of the second color space, and color data of the second color space; A pair of corrected color data of the first color space. The converted target color data mapped processed have a program for causing and a function of generating a color conversion coefficient to be associated with converted color data of the second color space.

According to a ninth aspect of the present invention, the mapping processing function is generated by colorimetric values in the first color space of a color sample printed on a predetermined standard paper based on specific data in the second color space. A function for setting the determined color gamut as the predetermined color gamut, and the function for correcting the chromaticity of the predetermined standard paper constituting the maximum brightness coordinate of the predetermined color gamut as the reference color coordinate. 9. The program according to claim 8, which has a setting function.
According to a tenth aspect of the present invention, the function of performing the mapping process is a color measurement in the first color space of a color sample printed on each of a plurality of predetermined standard papers based on specific data in the second color space. Among the plurality of color gamuts generated by the values, the predetermined color having a chromaticity that minimizes the color difference from the chromaticity of the paper that is the background when the color data of the first color space is measured. The color gamut generated from the colorimetric values of the color sample printed on the standard paper has a function of setting the predetermined color gamut, and the function for correcting the maximum brightness coordinate of the predetermined color gamut. 9. The program according to claim 8, wherein the program has a function of setting chromaticity of the predetermined standard paper constituting the reference color coordinates.
According to an eleventh aspect of the present invention, the function of performing the mapping processing has a chromaticity that minimizes a color difference from the chromaticity of the paper as a base when the color data of the first color space is measured. The predetermined standard paper is extracted on condition that the predetermined standard paper has a lightness greater than the lightness of the paper, and is generated based on the colorimetric value of the color sample printed on the extracted predetermined standard paper The program according to claim 10, wherein the program has a function of setting the determined color gamut as the predetermined color gamut.

According to a twelfth aspect of the present invention, the function to perform the mapping process is one color among a plurality of color gamuts including a color gamut having a color coordinate having the highest lightness in the first color space as a maximum lightness coordinate. A function of setting a gamut as the predetermined color gamut, and the function of correcting the maximum brightness coordinate of the color gamut with a color coordinate having the highest brightness in the first color space as a maximum brightness coordinate. 9. The program according to claim 8, wherein the program has a function of setting as reference color coordinates.
According to a thirteenth aspect of the present invention, the correcting function sets the reference color coordinate to the maximum brightness coordinate of the predetermined color gamut and has the highest brightness in the color data of the first color space. The color data is normalized so as to be associated with the reference color coordinate, the composition ratio with respect to the normalized color data of the first color space is monotonously decreased according to the color difference from the reference color coordinate, and the acquired first color is obtained. The function of performing the correction by combining the normalized color data and the acquired color data so that a combination ratio with respect to the color data of the space monotonously increases according to the color difference. 8. The program according to 8.

According to the first aspect of the present invention, a decrease in color reproducibility is suppressed as compared with the case where the present invention is not adopted regardless of the chromaticity of the paper as the base when the color data is measured. can do.
According to the second aspect of the present invention, the correction amount applied to the color data can be reduced by correcting the color data when calculating the color conversion coefficient in accordance with the color difference from the chromaticity of the standard paper. Compared with the case where the color conversion is not adopted, it is possible to suppress a decrease in color conversion accuracy when the conversion target color is converted into the conversion color.
According to the third aspect of the present invention, since the color gamut having the smallest color difference is set, the correction amount to be applied to the color data used when calculating the color conversion coefficient can be suppressed to be small, compared with the case where the present invention is not adopted. Thus, it is possible to suppress a decrease in color conversion accuracy when converting the conversion target color into the conversion color over the entire color reproduction range of the conversion target color.
According to the fourth aspect of the present invention, since the color data used when calculating the color conversion coefficient is suppressed from being corrected in the darkness direction, it is calculated as compared with the case where the present invention is not adopted. It is possible to suppress a decrease in the brightness of the converted color in the low brightness area reproduced based on the color conversion coefficient.

According to the fifth aspect of the present invention, compared to the case where the present invention is not adopted, in a color area having a high brightness, a color close to the color itself excluding the reflection density from the paper which is the background when the color data pair is measured. Data can be generated.
According to the sixth aspect of the present invention, a smaller correction amount is set as the color difference from the reference color coordinate is smaller, and a smaller correction amount is set as the color difference is larger. Therefore, when calculating the color conversion coefficient, the brightness is high. In the color region, the chromaticity of the paper that is the base when the color data pair is measured is corrected, and in the color region with low lightness, the color data pair substantially following the color data can be used.
According to the seventh aspect of the present invention, the color used when converting the conversion target color into the converted color, as compared with the case where the present invention is not adopted, regardless of the type of the color space of the input color signal input from the external device. A decrease in conversion accuracy can be suppressed.

According to claim 8 of the present invention, it is possible to suppress a decrease in color reproducibility as compared with the case where the present invention is not adopted regardless of the chromaticity of the paper as the base when the color data is measured. can do.
According to the ninth aspect of the present invention, the correction amount applied to the color data can be reduced by correcting the color data when calculating the color conversion coefficient in accordance with the color difference from the chromaticity of the standard paper. Compared with the case where the color conversion is not adopted, it is possible to suppress a decrease in color conversion accuracy when the conversion target color is converted into the conversion color.
According to the tenth aspect of the present invention, since the color gamut with the smallest color difference is set, the correction amount to be applied to the color data used when calculating the color conversion coefficient can be kept small, compared with the case where the present invention is not adopted. Thus, it is possible to suppress a decrease in color conversion accuracy when converting the conversion target color into the conversion color over the entire color reproduction range of the conversion target color.
According to the eleventh aspect of the present invention, since the color data used when calculating the color conversion coefficient is suppressed from being corrected in the darkness direction, it is calculated as compared with the case where the present invention is not adopted. It is possible to suppress a decrease in the brightness of the converted color in the low brightness area reproduced based on the color conversion coefficient.

According to the twelfth aspect of the present invention, compared to the case where the present invention is not adopted, in a color region having a high brightness, a color close to the color itself excluding the reflection density from the paper which is the background when the color data pair is measured. Data can be generated.
According to the thirteenth aspect of the present invention, a smaller correction amount is set as the color difference from the reference color coordinate is smaller, and a smaller correction amount is set as the color difference is larger. Therefore, when calculating the color conversion coefficient, the brightness is high. In the color region, the chromaticity of the paper that is the base when the color data pair is measured is corrected, and in the color region with low lightness, the color data pair substantially following the color data can be used.

Embodiments of the present invention will be described below in detail with reference to the accompanying drawings.
[Embodiment 1]
FIG. 1 is a block diagram illustrating a configuration of a color processing apparatus 1 to which the exemplary embodiment is applied. A color processing device 1 shown in FIG. 1 includes a color signal input unit 10 that receives input of image data (input color signal) in, for example, an sRGB color space from a personal computer (PC) or the like as an example of an external device, and an input color signal as a device. First color signal conversion unit 20 that converts color signals (L ^* a ^* b ^* signals) in an L ^* a ^* b ^* color space, which is an example of a color space that does not depend on the device (device-independent color space), L ^* a A mapping processing unit 30 that performs mapping processing of an input color signal converted into a ^* b ^* signal into a color reproduction gamut (color gamut) of an output device (device), and a mapped L ^* a ^* b ^* signal as a device color space A second color signal conversion unit 40 that converts a color signal (CMYK color signal) in a CMYK color space, which is an example of (device color space), and a color signal output unit 50 that outputs the converted CMYK color signal are provided.
Further, the color processing apparatus 1 converts the standard color gamut generation unit 60 that generates the standard color gamut (see later stage) of the device set by the mapping processing unit 30 into a CMYK color signal from the L ^* a ^* b ^* signal. A color conversion table generation unit 70 that generates a color conversion table (color conversion coefficient) called a direct look-up table (DLUT) used at the time is provided.

Here, FIG. 2 is a diagram illustrating a hardware configuration of the color processing apparatus 1 according to the present embodiment. As shown in FIG. 2, the color processing apparatus 1 is a CPU 101 as an example of an arithmetic unit that executes digital arithmetic processing according to a predetermined processing program when executing color conversion processing, and a processing program executed by the CPU 101. RAM 102 in which data is stored, ROM 103 in which data such as setting values used in processing programs executed by CPU 101 are stored, EEPROM, flash memory, etc. that can be rewritten and can retain data even when power supply is interrupted And an interface unit 105 that controls input / output of signals to / from each unit connected to the color processing apparatus 1.
An external storage unit 100 is connected to the color processing apparatus 1. The external storage unit 100 stores a processing program to be executed by the color processing apparatus 1, and the color processing apparatus 1 reads the processing program, whereby the color in the color processing apparatus 1 of the present embodiment is read. Conversion processing is executed.

  That is, the above-described color signal input unit 10, first color signal conversion unit 20, mapping processing unit 30, second color signal conversion unit 40, color signal output unit 50, standard color gamut generation unit 60, and color conversion table generation unit A program that realizes each function of 70 is read into the RAM 102 in the color processing apparatus 1 from, for example, a hard disk or a DVD-ROM as the external storage unit 100. Then, based on the program read into the RAM 102, the CPU 101 performs various processes. As another providing form regarding this program, there is a form in which the program is provided in a state stored in the ROM 103 in advance and loaded into the RAM 102. Further, when the rewritable ROM 103 such as an EEPROM is provided, after the color processing apparatus 1 is set, only the program is installed in the ROM 103 and loaded into the RAM 102. Further, there is a form in which a program is transmitted to the color processing apparatus 1 via a network such as the Internet, installed in the ROM 103 of the color processing apparatus 1 and loaded into the RAM 102.

The color signal input unit 10 is an example of a color signal to be subjected to color conversion processing (conversion target color data), for example, image data (R, G, B) (input color) in an sRGB color space from a personal computer (PC) or the like. Signal, sRGB signal).
The first color signal conversion unit 20 performs an L ^* a ^* b ^* color space (first color space), which is an example of a device-independent color space, by performing predetermined arithmetic processing on the sRGB signal acquired by the color signal input unit 10. Color data (L ^* , a ^* , b ^* ).
The mapping processing unit 30 is an example of a conversion target color data acquisition unit, and is converted from the first color signal conversion unit 20 into color data (L ^* , a ^* , b ^* ) in the L ^* a ^* b ^* color space. The input color signal (conversion target color data) is acquired. The mapping processing unit 30 is an example of a mapping processing unit, acquires standard color gamut data representing the color gamut of the output device (device) from the standard color gamut generation unit 60, and stores the predetermined color gamut data in the mapping processing unit 30. Sets the standard color gamut of the device, which is an example of the color gamut. Then, the color data (L ^* , a ^* , b ^* ) acquired from the first color signal conversion unit 20 is mapped into the color data in the standard color gamut of the device or on the surface of the standard color gamut (outside).

Here, the standard color gamut generation unit 60 that generates the standard color gamut of the device set by the mapping processing unit 30 will be described.
The standard color gamut generation unit 60 of the present embodiment combines color coordinate values regularly arranged in a CMYK color space as an example of an output color space (second color space) of a device such as an image forming apparatus. The converted grid point data and a color sample (color patch) printed on a predetermined standard paper (for example, coated paper) by the device using the grid point data as an input color signal are converted into a device-independent color space (L ^* a) ^* B ^* A standard actual data pair (color data pair) that is a pair with color data actually measured (colorimetric) in the color space (first color space) is acquired. Then, based on the acquired standard actual data pair, color gamut data (color gamut outline polygon body) expressing the device color gamut in the L ^* a ^* b ^* color space is generated. The color gamut of the device generated based on the standard actual data pair is referred to as “standard color gamut”, and the data representing the standard color gamut is referred to as “standard color gamut data”.
As the standard paper, a predetermined paper, a paper having a median value (mode) of various papers, a representative paper in an assumed market, or the like is designated.

An example of a method for generating color gamut data in the standard color gamut generation unit 60 will be described below. Here, the range of CMYK color signals, which are color signals in the device color space (second color space), is 0 to 100 for all of C (cyan), M (magenta), Y (yellow), and K (black). To do.
First, in the CMY color space excluding black (K), the coordinate values of vertex sets regularly arranged on the surface of the gamut of a device that can be reproduced with three colors of CMY are calculated. In general, when a device color space is expressed by an orthogonal coordinate system using a three-dimensional color signal, the color gamut in the device color space is always a rectangular parallelepiped or a cube. Therefore, the color gamut that can be reproduced with three CMY colors in the CMY color space is a rectangular parallelepiped or a cube. That is, for example, if C, M, and Y are all 0 to 100 as described above, coordinate points (0, 0, 0), (100, 0, 0), in the CMY color space excluding black (K), 8 points of (0,100,0), (0,0,100), (100,100,0), (100,0,100), (0,100,100), (100,100,100) Is a device color gamut that can be reproduced with three CMY colors in the CMY color space.

The vertices are regularly arranged on the surface of the cubic color gamut. For example, a lattice point on the surface of the color gamut formed by dividing the cubic color gamut into a lattice pattern with an arbitrary step width using a plane perpendicular to each axis is defined as a vertex.
FIG. 3 is a diagram illustrating an example of vertices regularly arranged in a cubic color gamut in the CMY color space. In the example shown in FIG. 3, the range of 0 to 100 of all axes of C, M, and Y is equally divided into five, and lattice points (black circles) regularly arranged on the surface of the color gamut are all vertexes. Show. In addition, you may set the space | interval of each axis | shaft arbitrarily. If the vertices are regularly arranged on the surface of the cubic color gamut, the coordinates of the regularly arranged grid points in the CMY color space are registered as a list (vertex list) so as not to overlap.

Next, a set of four vertices (referred to as “four sets”) constituting a polygon (polygon: here, a quadrangle) covering the surface of the color gamut reproducible with CMY three colors in the CMY color space. Create and store this as a sub-polygon list. In this quadrilateral quadrilateral, all sides are shared with the other quadruple quadrilaterals, and a plane is not shared with any other quadrilateral quadrilateral. At the same time, the coordinates of the barycentric points of the four vertices in the CMY color space are calculated and stored as a barycentric point list in association with each set of four.
Specifically, for all rectangles that are the smallest units on the surface of the color gamut generated by dividing the cubic color gamut in the CMY color space into a grid, a set of four vertex lists corresponding to the vertices of the rectangle is obtained. A sub-polygon list is created by registration. Further, the coordinates of the barycentric point corresponding to each of these four sets are registered as a barycentric point list, and this barycentric point list is stored together with the corresponding four sets. For example, in the example shown in FIG. 3, a set of four vertex lists corresponding to the four vertices as shown by being surrounded by dotted lines is registered as a subpolygon list. Although only two sets are shown in FIG. 3, each quadrangle that covers the cubic color gamut surface without excess or deficiency is registered in the subpolygon list.

Subsequently, the vertex coordinates of the CMY color space are mapped to the device-independent color space (L ^* a ^* b ^* color space) assuming that K = 0, that is, black is not added, and the coordinate values of the vertex list and the barycentric point list Is updated with colorimetric values (color data) in the L ^* a ^* b ^* color space. As a method of performing this mapping, for example, a method of performing linear regression analysis, a method of using a neural network that has learned real data, or the like may be used, and other C, M, Y, K to L ^* , a Any method for predicting ^* and b ^* may be used.

Next, each vertex on the color gamut surface that can be reproduced with three colors of CMY except for black (K) is converted to a vertex on the device color gamut surface including black (K). In general, when black (K) is added to a color expressed using a chromatic color material, the saturation and lightness do not increase even though the saturation and lightness are lowered. That is, among the color gamut boundaries in the L ^* a ^* b ^* color space that can be reproduced with three CMY color materials, the color gamut boundaries reproduced with the primary and secondary colors of CMY are the color gamut boundaries that can be reproduced with CMYK. Is considered the same. Therefore, only the vertices that are tertiary colors among the vertices on the surface of the gamut in the L ^* a ^* b ^* color space that can be reproduced with the three CMY color materials excluding black (K), the device color gamut boundary (outline) ) May be calculated. Then, by replacing the vertex coordinates of the corresponding vertex list with the coordinates of the device gamut boundary points in the calculated L ^* a ^* b ^* color space, a polyhedron (standard gamut) representing the device gamut is calculated. The
Subsequently, if necessary, the calculated polyhedron vertex adjustment process is performed, and standard color gamut data expressing the device color gamut in the L ^* a ^* b ^* color space is generated based on the standard real data pair.

In this way, in the standard color gamut generation unit 60, the polyhedron (color gamut data) representing the color gamut of the device color space is an L ^* a ^* b ^* color space (first color space) as an example of a device-independent color space. ). In this case, when a color gamut of a four-dimensional color space such as the CMYK color space is obtained in a three-dimensional device-independent color space, one color (for example, black (K)) in the device color space is searched for. Will be asked.
Then, the standard color gamut data representing the polyhedron (standard color gamut) in the device-independent color space (L ^* a ^* b ^* color space) obtained in this way is sent to the mapping processing unit 30, and the standard color gamut is set. Is done.

The mapping processing unit 30 acquires the input color signal (L ^* , a ^* , b ^* ) in the L ^* a ^* b ^* color space acquired from the first color signal conversion unit 20 from the standard color gamut generation unit 60. Is mapped to the color data of the standard color gamut inside or the surface (outside) of the standard color gamut.
Here, FIG. 4 is a diagram for explaining the mapping process performed by the mapping processor 30. FIG. 4A shows the standard color gamut of the device before the mapping process and the color gamut of the input color signal, and FIG. 4B shows the standard color gamut of the device after the mapping process and the input color. It shows the color gamut of the signal. In FIG. 4, each color gamut is expressed as a cross section cut by a plane of b ^* = 0.

As described above, the “standard color gamut” of the device is printed on predetermined standard paper (for example, coated paper) by the device using grid point data in the CMYK color space and grid point data as input color signals. The color patch is generated based on a standard actual data pair (standard color data pair) which is a pair with color data obtained by measuring colors in the L ^* a ^* b ^* color space. Therefore, as shown in FIG. 4A, the color coordinate having the highest brightness value (L ^* value) in the standard color gamut of the device matches the chromaticity (standard paper white) of the standard paper. That is, chromaticity data (y _1s , y _2s , y _3s ) (“reference color coordinates” in the _subsequent stage) obtained by measuring the color of a standard paper using, for example, illumination (D50) with a color temperature of 5000K.
On the other hand, when the input color signal is, for example, image data in the sRGB color space from a personal computer (PC) or the like, the color coordinate having the highest lightness value (L ^* value) in the color gamut of the input color signal is L ^*. The reference white in the a ^* b ^* color space (L ^* = 100, a ^* = b ^* = 0).
Therefore, in the mapping processing in the mapping processing unit 30, as shown in FIG. 4B, the reference white (L ^* = 100, a ^* = b ^* = 0) of the input color signal is in the standard color gamut of the device. The color gamut of the input color signal is compressed so as to coincide with the chromaticity data (y _1s , y _2s , y _3s ) of the standard paper. As another method, a process of expanding the device standard color gamut to match the reference white color may be performed.

Here, in the standard color gamut of the device, the color coordinate (y _1s , y _2s , y _3s ) with the highest lightness value (L ^* value) is S2, and the color coordinate with the lowest lightness value is G2 (y _1g2 , y _2g2). , y _3g2 ), b ^* = 0, the color coordinate of the maximum saturation a ^* is B2, and the color coordinate of the minimum saturation a ^* is A2. Similarly, in the color gamut of the input color signal, the reference white (L ^* = 100, a ^* = b ^* = 0) having the highest lightness value (L ^* value) is S1, and the color coordinate having the lowest lightness value is G1 ( y _1g1 , y _2g1 , y _3g1 ), the color coordinate of the maximum saturation b ^{* in} the plane of b ^* = 0 is B1, and the color coordinate of the minimum saturation b ^* is A1.
Then, in the mapping process in the mapping processing unit 30, as shown in FIG. 4B, the input value for matching the color coordinate S1 of the input color signal with the color coordinate S2 of the standard color gamut with respect to the lightness value L ^* . Mapping processing for the color gamut of the color signal is performed. Similarly, mapping processing is performed so that the color coordinate G1 of the input color signal matches the color coordinate G2 of the standard color gamut. Further, a process of converting the saturation values a ^* and b ^* at each lightness value after compression into color coordinates in the standard color gamut is performed. For example, mapping processing is performed for the color gamut of the input color signal such that the color coordinate A1 of the input color signal matches the color coordinate A2 of the standard color gamut, and the color coordinate B1 of the input color signal matches the color coordinate B2 of the standard color gamut. .

An example of calculation processing in the mapping processing unit 30 in this case is shown. First, a compression operation is performed on the lightness value (L _i ^* value) of the input color signal (L _i ^* , a _i ^* , b _i ^* ). That is, for the L _i ^* value of each input color signal, the following equation (1) is calculated to calculate the m_L _i ^* value of each input color signal.
After calculating the m_L _i ^* value of each input color signal, the lightness value = m_L _i ^* and the calculated a _i ^* value and b _i ^* value of each input color signal are expressed by the following equations (2) and (3): By calculating the equation, m_a _i ^* value and m_b _i ^* value of each input color signal are calculated. Here, the a ^* value of the standard color gamut where the lightness value = m_L _i ^* is y _2m2 , and the b ^* value is y _{3m 2} . Further, the a ^* value of the color gamut contour of the input color signal with the lightness value = m_L _i ^* is set to a _m ^* , and the b ^* value is set to b _m ^* .

As described above, the mapping processing unit 30 compresses the input color signal (L _i ^* , a _i ^* , b _i ^* ) into the standard color gamut of the device or the outline of the device (m_L _i ^* , m_a _i ^*). , m_b _i ^* ). As a result, as shown in FIG. 4B, the color gamut of the input color signal is compressed, and for the lightness value (L ^* value), the color coordinate S1 which is the maximum lightness of the input color signal is the standard color gamut. It matches the color coordinate S2 which is the chromaticity of the standard paper. Further, the color coordinate G1 that is the minimum brightness of the input color signal is compressed so as to coincide with the color coordinate G2 that is the minimum brightness of the standard color gamut. Further, the saturation value (a ^* value, b ^* value) at each lightness value is also compressed inside or outside the standard color gamut. For example, the color coordinate A1 of the input color signal is the color coordinate A2 of the standard color gamut, and the input color signal. The color coordinates B1 are converted to match the color coordinates B2 of the standard color gamut.
That is, in the color processing apparatus 1 according to the present embodiment, the mapping processing unit 30 inputs a standard color gamut generated based on actual data obtained from a color patch printed on a predetermined standard paper. Mapping the color signal. Thereby, the input color signal is associated with color data in the standard color gamut of the device.

  By the way, when the input color signal is color-converted to the device color signal, a color conversion table (color conversion coefficient) called DLUT that associates the input color signal with the device color signal is usually used. The color conversion coefficient is calculated based on actual data obtained from color patches printed on paper. In general, the paper on which color patches are printed is often paper other than standard paper. In that case, as for the color itself excluding the reflection density from the paper, as long as the device that generated the color on the paper is the same, regardless of the chromaticity of the paper, the color reproduction gamut (color gamut) and color reproduction The characteristics are constant. However, the actual data obtained by actually measuring the color is influenced by the chromaticity of the paper, particularly in a high brightness area, because the chromaticity of the paper on which the color patch is printed is added. Therefore, even if the actual data obtained from paper other than the standard paper is printed by the same device, it is measured with a data value different from the actual data obtained from the standard paper. As a result, the color conversion coefficient calculated based on actual data obtained from paper other than standard paper differs from that based on actual data obtained from color patches printed on standard paper, resulting in the standard color of the device. This is different from the color conversion coefficient in the area. Therefore, when the input color signal mapped to the standard color gamut of the device is color-converted by the mapping processing unit 30 using the color conversion coefficient calculated from the actual data, the color of the standard paper An error corresponding to the color difference between the degree and the chromaticity of the paper other than the standard paper whose actual data has been measured is generated.

However, by correcting the actual data obtained from color patches printed on paper other than standard paper in accordance with the color difference from the chromaticity of standard paper, even in areas with high brightness, Real data can be approximated to real data using standard paper. As a result, the color conversion coefficient generated using the actual data corrected in accordance with the color difference from the chromaticity of the standard paper is the color conversion coefficient in the standard color gamut of the device, that is, the color printed on the standard paper. Match or approximate the color conversion coefficient calculated based on the actual data obtained from the patch.
Then, even if the actual data is obtained from a color patch printed on paper having any chromaticity, this correction is possible if the actual data is corrected in accordance with the color difference from the chromaticity of the standard paper. The color conversion coefficient calculated from the actual data thus obtained substantially matches the color conversion coefficient in the standard color gamut. As a result, when color conversion processing is performed on an input color signal mapped to the standard color gamut of a device based on standard paper, the color of the standard paper is used regardless of the chromaticity of the paper on which the color patch is based. By using the color conversion coefficient calculated from the actual data corrected in correspondence with the color difference from the degree, a decrease in color conversion accuracy is suppressed.

  Therefore, in the color processing apparatus 1 of the present embodiment, first, the color gamut of the input color signal is mapped to the standard color gamut of the device generated based on the actual data obtained from the color patch printed on a predetermined standard paper. To process. Furthermore, when the actual data prepared for obtaining the color conversion coefficient used for color conversion of the input color signal is actual data obtained from a color patch printed on paper other than standard paper The actual data is corrected in accordance with the color difference from the chromaticity of the standard paper. Then, a color conversion coefficient for color-converting the input color signal into a device color signal is calculated using the corrected actual data. As a result, even if the chromaticity of the paper that is the base of the color patch for which the actual data is measured is different from that of the standard paper, degradation of color reproducibility when converting the input color signal to the device color signal is suppressed. Is done.

In addition, by adopting such a method, when the actual data is actual data obtained from color patches printed on paper having various chromaticities, the actual data is based on paper of different chromaticity. There is no need to obtain the device color gamut for each data. In other words, if only a predetermined standard color gamut is set as the device color gamut, the actual data when calculating the color conversion coefficient is corrected in accordance with the color difference from the chromaticity of the standard paper, thereby correcting the input color. A decrease in color conversion accuracy when converting a signal into a device color signal is suppressed.
Furthermore, for example, even when the chromaticity of the paper on which the color patch is printed is low, the color conversion accuracy when converting the input color signal to the device color signal is maintained within a predetermined range in the entire color gamut of the input color signal. Is done. For example, in consideration of the influence of paper chromaticity, white (paper chromaticity) of actual data is set to the reference white coordinate (100, 0, 0) in the L ^* a ^* b ^* color space which is the white of the input color signal. ) Is corrected to match. In this case, since the color difference between the paper chromaticity and the reference white coordinates (100, 0, 0) is large, the correction amount for the actual data is large. Therefore, when the input color signal is converted into the device color signal based on the color conversion coefficient calculated using the corrected actual data, for example, the difference in conversion amount between the high brightness area and the low brightness area increases. There are cases where the color conversion accuracy deteriorates in any region (for example, a low brightness region) of the color gamut of the input color signal. In contrast, in the color processing apparatus 1 according to the present embodiment, actual data is based on the chromaticity of standard paper having a lightness lower than the reference white coordinate (100, 0, 0) in the L ^* a ^* b ^* color space. Therefore, the correction amount for the actual data can be kept low. As a result, for example, the increase in the difference in the conversion amount between the high brightness area and the low brightness area is suppressed, and the color of the input color signal to the device color signal by the color conversion coefficient generated using the corrected actual data Conversion accuracy is maintained throughout the color gamut of the input color signal.

Next, a color conversion table generation unit 70 as an example of a color conversion coefficient generation unit that generates a color conversion table (color conversion coefficient) corresponding to the standard color gamut of the device will be described.
The color conversion table generation unit 70 of the present embodiment generates a color conversion coefficient (color conversion table) that is used when color conversion of an input color signal into a device color signal. At this time, if the actual data prepared to generate the color conversion table is actual data obtained from color patches printed on paper other than standard paper, the color difference from the chromaticity of the standard paper The actual data is corrected in accordance with. Then, a color conversion table corresponding to the standard color gamut of the device is generated using the corrected actual data.

FIG. 5 is a block diagram illustrating a configuration of the color conversion table generation unit 70. As shown in FIG. 5, the color conversion table generation unit 70 is a reference corresponding to the standard color gamut of the device generated by the actual data pair input unit 71 and the standard color gamut generation unit 60 that accept input of actual data pairs. A reference color coordinate setting unit 72 for setting color coordinates (see the subsequent stage), and a combined actual data pair generating unit 73 for generating a combined real data pair (see the subsequent stage) obtained by combining the actual data pair and the normalized actual data pair. A combined real data pair storage unit 74 that stores the combined real data pair, a weight generation unit 75 that generates a weight to be applied to the combined real data pair, and a color conversion characteristic model calculation unit 76 that calculates a color conversion characteristic model.
Further, the color conversion table generation unit 70 is calculated by a grid point data generation unit 77 and a color conversion characteristic model calculation unit 76 that generate grid point data in a CMYK color space as an example of a device color space (device color space). The color conversion processing unit 78 that performs color conversion processing on the grid point data using the color conversion characteristic model that has been performed, the grid point data received by the grid point data generation unit 77, and the color that has undergone color conversion processing by the color conversion processing unit 78 A color conversion coefficient output unit 79 that outputs data in association with data is provided.

The actual data pair input unit 71 is an example of a color data pair acquisition unit that acquires a colorimetric actual data pair (color data pair), and various color coordinate values in the CMYK color space that is a device color space. The color data (x _1i , x _2i , x _3i , x _4i ) of the plurality of color samples (color patches) generated by combining them and the generated plurality of color patches in the L ^* a ^* b ^* color space For example, a plurality of real data pairs (actual data pair groups) that are pairs with color data (y _1i , y _2i , y _3i ) obtained by color measurement using illumination (D50) with a color temperature of 5000K are acquired. . Here, n and i are integers, and i = 1 to n (the same applies hereinafter).
The reference color coordinate setting unit 72 sets coordinates (reference color coordinates) serving as a reference when normalizing the actual data pair in the combined actual data pair generating unit 73. Specifically, the reference color coordinate setting unit 72 sets the chromaticity of a predetermined paper (for example, coated paper) used as the standard paper when the standard color gamut of the device is generated from the standard color gamut generation unit 60, for example, as color. Chromaticity data (y _1s , y _2s , y _3s ) obtained by color measurement using illumination (D50) at a temperature of 5000K is acquired. Then, the chromaticity data (y _1s , y _2s , y _3s ) is set as reference color coordinates. Note that s is an integer, and 1 ≦ s ≦ n.

The composite actual data pair generation unit 73 is an example of a correction unit that corrects actual data according to the color difference from the chromaticity of the standard paper. Then, actual data (y _1i , y _2i , y _3i ) in the L ^* a ^* b ^* color space is extracted from the actual data pair acquired by the actual data pair input unit 71. Then, the actual data in the L ^* a ^* b ^* color space is normalized with reference to the reference color coordinates set by the reference color coordinate setting unit 72. Since the reference color coordinate setting unit 72 sets the chromaticity data (y _1s , y _2s , y _3s ) of the standard paper as the reference color coordinates, the actual data about the white color of the paper that is the background color from the actual data. The color coordinates (the chromaticity of the paper itself) are extracted, normalization is performed to match the reference color coordinates (y _1s , y _2s , y _3s ), and a new normalized actual data pair is generated. Here, normalized actual data in the L ^* a ^* b ^* color space is expressed as (r_y _1i , r_y _2i , r_y _3i ). Therefore, this normalized real data pair includes real data (x _1i , x _2i , x _3i , x _4i ) in the CMYK color space and normalized real data (r_y _1i , r_y in the L ^* a ^* b ^* color space. _2i , r_y _3i ) are associated with each other.

The composite actual data pair generation unit 73 then converts the actual data pair group acquired by the actual data pair input unit 71 and the newly generated normalized actual data pair group between the reference color coordinates and each actual data. A composite real data pair group is generated by combining them at a ratio (composition ratio) corresponding to the Euclidean distance (color difference). Here, the actual data (y _1i , y _2i , y _3i ) of the L ^* a ^* b ^* color space and the normalized actual data (r_y _1i , r_y _2i , r_y _3i ) are combined (y ^* _1i , y ^* _2i , y ^* _3i ). Therefore, the composite real data pair includes real data (x _1i , x _2i , x _3i , x _4i ) in the CMYK color space and composite real data (y ^* _1i , y ^* _2i ) in the L ^* a ^* b ^* color space. , y ^* _3i ) are associated with each other.
The composite real data pair generation unit 73 sends the generated composite real data pair group to the composite real data pair storage unit 74.

Here, the composite real data pair generation unit 73 will be described in further detail.
FIG. 6 is a block diagram showing a configuration of the combined real data pair generation unit 73. As shown in FIG. As shown in FIG. 6, the combined real data pair generation unit 73 performs actual data on the white color of the paper in the L ^* a ^* b ^* color space in the actual data pair group acquired by the actual data pair input unit 71. An XYZ conversion unit 731 and an XYZ conversion unit 731 convert (y _1w , y _2w , y _3w ) and reference color coordinates (y _1s , y _2s , y _3s ) into tristimulus values (X, Y, Z). The normal data pair group obtained by the normalization unit 732 and the real data pair input unit 71 that normalize the real data in the L ^* a ^* b ^* color space using the converted tristimulus values (X, Y, Z) The Euclidean distance for calculating the Euclidean distance (color difference) between the actual data (y _1i , y _2i , y _3i ) in the L ^* a ^* b ^* color space and the reference color coordinates (y _1s , y _2s , y _3s ) L ^* a ^* b ^* color according to the Euclidean distance calculated by the calculation unit 733 and the Euclidean distance calculation unit 733 A composition ratio setting unit 734 that calculates a composition ratio (weighting amount) between the actual data of space and the normalized actual data, and the composition ratio calculated by the composition ratio setting unit 734, and using the composition ratio calculated in the L ^* a ^* b ^* color space A synthesis unit 735 is provided that synthesizes the actual data and the normalized actual data (r_y _1i , r_y _2i , r_y _3i ).
Here, the XYZ conversion unit 731 and the normalization unit 732 constitute normalization means. In addition, the Euclidean distance calculation unit 733 and the combining unit 735 constitute a combining unit.

First, the XYZ conversion unit 731 acquires a real data pair group from the real data pair input unit 71. Then, actual data (y _1w , y _2w , y _3w ) (= paper chromaticity) obtained by measuring the white color of the paper as the background color in the L ^* a ^* b ^* color space from the actual data pair group. To extract. Further, with respect to the actual data of the chromaticity of the extracted paper, the L ^* value (y _1w ), a ^* value (y _2w ), b ^* value (y _3w ) are expressed as tristimulus values ( X, Y, Z). The tristimulus values (X, Y, Z) obtained here are assumed to be (X _W , Y _W , Z _W ).
Further, the XYZ conversion unit 731 acquires reference color coordinates (y _1s , y _2s , y _3s ) from the reference color coordinate setting unit 72. Then, for the reference color coordinates (y _1s , y _2s , y _3s ), the L ^* value (y _1s ), a ^* value (y _2s ), b ^* value (y _3s ) are expressed using the following equation (4): Convert to tristimulus values (X, Y, Z). The tristimulus values (X, Y, Z) obtained here are defined as (X _S , Y _S , Z _S ).
This equation (4) is a conversion formula from L ^* values (y _1i ), a ^* values (y _2i ), b ^* values (y _3i ), which are generally defined, to tristimulus values X, Y, Z. is there. X ₅₀ , Y ₅₀ , and Z ₅₀ in the equation (4) are tristimulus values of the completely diffuse reflection surface under the illumination (for example, D ₅₀ ) used for the measurement, and usually Y ₅₀ = 100. This is a standardized value.

The next normalization unit 732 first acquires the actual data pair from the actual data pair input unit 71. Then, real data (y _1i , y _2i , y _3i ) in the L ^* a ^* b ^* color space is extracted from the real data pair group, and these values are converted into tristimulus values (X _i ) using the XYZ conversion unit 731. , Y _i , Z _i ). Further, the tristimulus values (X _W , Y _W , Z _W ) of paper chromaticity and the tristimulus values (X _S , Y _S , Z _S ) of reference color coordinates are acquired from the XYZ conversion unit 731. Then, from the tristimulus values (X _W , Y _W , Z _W ) of the chromaticity of the paper and the tristimulus values (X _S , Y _S , Z _S ) of the reference color coordinates, X _S / X _W , Y _S / Y _{W 1} , Z _S / Z _W is calculated. Then, from the tristimulus values (X _W , Y _W , Z _W ) of the chromaticity of the paper and the tristimulus values (X _S , Y _S , Z _S ) of the reference color coordinates, X _S / X _W , Y _S / Y _{W 1} , Z _S / Z _W is calculated. Furthermore, for the tristimulus values (X _i , Y _i , Z _i ) of the actual data (y _1i , y _2i , y _3i ), X _S / X _W , Y _S / Y _W , Z _S / Z respectively normalized by multiplying the _W, calculate these ^L * ^a * ^{b *} and data to convert again the color space ^L * ^a * ^{b *} normalized color space actual data _{(r_y 1i, r_y 2i, r_y} 3i) the To do.
That is, normalized actual data (r_y _1i , r_y _2i , r_y _3i ) in the L ^* a ^* b ^* color space is calculated by the following equations (5) and (6).

Here, FIG. 7 is a diagram for conceptually explaining normalization processing of actual data (y _1i , y _2i , y _3i ) in the normalization unit 732. FIG. 7A shows a distribution region of actual data (y _1i , y _2i , y _3i ) in the L ^* a ^* b ^* color space. Since the reference color coordinate setting unit 72 sets the color coordinate S2 (y _1s , y _2s , y _3s ) having the highest lightness value (L ^* value) in the standard color gamut of the device (see FIG. 4). ), The reference color coordinate of FIG. 7 is “S2”. In the actual data distribution area, the white color of the paper (paper chromaticity) that is the background of the color measurement is the actual data (maximum lightness coordinate) indicating the highest lightness. W ″ (y _1w , y _2w , y _3w ). Furthermore, the coordinate of the lowest brightness point that has the lowest brightness and is located farthest from the reference color coordinate S2 is “G”.
On the other hand, FIG. 7B shows a distribution region of normalized real data (r_y _1i , r_y _2i , r_y _3i ) in the L ^* a ^* b ^* color space. As shown in FIG. 7 (b), the actual data in the actual data distribution area of FIG. 7 (a) is converted into normalized actual data by the above equations (5) and (6). The white coordinate W of the color coincides with the reference color coordinate S2. Further, in the normalized actual data distribution region of FIG. 7B, the amount of coordinate movement decreases as the actual data moves away from the reference color coordinate S2 by the normalization process using the equations (5) and (6). Thereby, the coordinate movement amount when converting the white coordinate W of the paper to the reference color coordinate S2 is the largest, and the coordinate movement amount at the lowest lightness point G having the lowest lightness farthest from the reference color coordinate S2 is the smallest.
Therefore, as shown in FIG. 7B, in the normalized actual data distribution area, the entire actual data distribution area is moved in the reference color coordinate S2 direction so that the white coordinate W of the paper matches the reference color coordinate S2. An area whose coordinate movement amount is set to be smaller as the brightness is lower.

By the way, the input color signal is subjected to the mapping process in the mapping processing unit 30, so that the coordinates of the input color signal in the white L ^* a ^* b ^* color space are the reference color coordinates S2 shown in FIG. (Standard paper chromaticity). On the other hand, as shown in FIG. 7 (a), the color of the paper used as the base when measuring the actual data (y _1i , y _2i , y _3i ) measured in the L ^* a ^* b ^* color space When the degree W is different from that of the standard paper, the white coordinate W of the paper does not coincide with the reference color coordinate S2. Therefore, the colorimetric value is shifted in the direction of low lightness in the color region with high lightness. Thereby, for example, when performing color reproduction of the input color signal using a color conversion characteristic model generated based on such actual data, the color of the high brightness area of the input color signal (for example, white), The color (for example, brightness) shifts from the color of the high brightness area reproduced using the color conversion characteristic model.
On the other hand, as shown in FIG. 7B, in the normalized real data pair group in which normalization is performed so that the white coordinate W of the paper matches the reference color coordinate S2 in the L ^* a ^* b ^* color space. The correction corresponding to the color difference between the chromaticity W of the paper used as a base during color measurement and the chromaticity of the standard paper is performed. As a result, the normalized actual data of the normalized actual data pair group approximates the actual data measured on the standard paper in a color region with high brightness.
For this reason, in a color region with high brightness, using the normalized real data pair group reduces color misregistration from the input color signal of the reproduced color.

In addition, the actual data (y _1i , y _2i , y _3i ) measured in the L ^* a ^* b ^* color space is less affected by the chromaticity of the underlying paper in a low-brightness color region. Therefore, for the color region with low lightness, the actual data pair group obtained by performing color measurement using a paper different from the standard paper as a background approximates the actual data measured on the standard paper. On the other hand, it is assumed that the above normalized real data pair is used in a color region with low brightness. In that case, as described above, in the normalized actual data distribution area, the actual data is moved in the direction of the reference color coordinate S2 even in the color area with low brightness. For this reason, when color reproduction is performed using a color conversion characteristic model generated based on such actual data, the color area with low lightness reproduces with high lightness even though the influence from the paper chromaticity is small. As a result, a deviation occurs in the color (for example, lightness) in the color region with low lightness. This is particularly noticeable when the color on the L ^* axis is reproduced with a single K color.
Therefore, in this color region with low lightness, the color reproducibility is better when the actual data pair group obtained by colorimetry in the L ^* a ^* b ^* color space is used.

Therefore, the combined real data pair generation unit 73 newly combines the actual data pair in the L ^* a ^* b ^* color space and the normalized actual data pair as the actual data pair used when generating the color conversion characteristic model. A simple composite real data pair is generated. In the composite real data pair in that case, the normalized real data pair group is treated with a large specific gravity in the color area with high lightness, and the actual data pair group obtained by colorimetry in the color area with low lightness Is treated as a large specific gravity. Specifically, the Euclidean distance (color difference) between the reference color coordinate S2 in the L ^* a ^* b ^* color space and the actual data (y _1i , y _2i , y _3i ) is calculated, and the calculated Euclidean distance is small Then, the ratio of the normalized real data to the group is high, and the ratio is set so that the ratio of the real data to the group is high in the region where the Euclidean distance is large. As a result, a composite real data pair is generated which is actual data corrected in accordance with the color difference from the chromaticity of the standard paper. Then, a color conversion characteristic model is generated using the composite real data pair.
The data to be combined with the actual data pair in the L ^* a ^* b ^* color space is obtained by performing non-linear conversion in addition to the linearly converted data such as the normalized actual data pair. Also good.

For this purpose, the Euclidean distance calculation unit 733 of the combined actual data pair generation unit 73 first acquires the actual data pair group from the actual data pair input unit 71. Then, the actual data (y _1i , y _2i , y _3i ) in the L ^* a ^* b ^* color space is extracted from the acquired actual data pair group. Further, the Euclidean distance d _i between the actual data (y _1i , y _2i , y _3i ) and the reference color coordinates S2 (y _1s , y _2s , y _3s ) is calculated. That is, the Euclidean distance d _i of each actual data (y _1i , y _2i , y _3i ) is calculated by the following equation (7).

The next composition ratio setting unit 734 acquires the Euclidean distance d _i calculated for each real data (y _1i , y _2i , y _3i ) from the Euclidean distance calculation unit 733. Then, in accordance with the acquired Euclidean distance d _i , the weighted amount when combining the normalized real data pair (r_y _1i , r_y _2i , r_y _3i ) and the real data pair (y _1i , y _2i , y _3i ) A certain composition ratio is calculated. At this time, as described above, the ratio of the normalized real data pair group is high in the region where the Euclidean distance d _i is small, and the ratio of the real data pair group is high in the region where the Euclidean distance d _i is large. Set the ratio. Therefore, the combining ratio setting unit 734, for example, Euclidean distance a _{d i} a function monotonically decreases with respect to f _{(d i),} the Euclidean distance f _{(d i)} when _{d i} is _d i = 0 = 1 A monotonically decreasing function f (d _i ) that satisfies f (d _g ) = 0 when d _i = d _g is the Euclidean distance between the reference color coordinate S2 and the minimum lightness point G (see FIG. 4) is used. Then, the composition ratio of the actual data pair group is set to 1-f (d _i ), and the composition ratio of the normalized actual data pair group is set to f (d _i ). In this manner, the synthesis ratio of the actual data pair group is set to increase monotonically with respect to the Euclidean distance d _i.

FIG. 8 is a diagram illustrating an example of a monotone decreasing function set by the synthesis ratio setting unit 734. As shown in FIG. 8A, in the composition ratio setting unit 734 of the present embodiment, a monotone decreasing function f (d _i ) that monotonously decreases over the entire region from the reference color coordinate S2 to the lowest lightness point G. Is used. Further, as shown in FIG. 8 (b), and monotonically decreases in a predetermined region of the reference color coordinate side S2 between the reference color coordinate S2 to the minimum lightness point _{G (d i = 0~d m)} , a predetermined area Alternatively, a function g (d _i ) in which g (d _i ) = 0 may be used in a region with lower brightness (d _i = d _{m to} d _g ). That is, in the color region with low lightness (d _i = d _{m to} d _g ), the color reproducibility is sufficiently ensured by the actual data pair group. Therefore, the color region with high lightness (d _i = 0 to d _m). ) Only in the real data pair (r_y _1i , r_y _2i , r_y _3i ) and the real data pair (y _1i , y _2i , y _3i ), a function g (d _i ) may be used. In this case, the actual data pair group itself (correction amount = 0) is used in an area where the brightness is lower than the predetermined area. This shortens the processing time when performing the synthesis process.

By setting the composite ratio of the actual data pair and the normalized actual data pair in this way, the ratio of the normalized actual data pair group is high in the region where the Euclidean distance d _i from the reference color coordinate S2 is small. In the region where the Euclidean distance d _i from the color coordinate S2 is large, the ratio of the actual data pair is set high. In addition, in the reference color coordinate S2 where the Euclidean distance d _i = 0, only the normalized real data of the normalized real data pair group is used, and in the lowest lightness point G which is the Euclidean distance d _g , the actual data pair group is real. Only data is used. Furthermore, in the region between the reference color coordinate S2 and the minimum lightness point G, the sum of the composition ratios for both is 1, and the linearity of the composite real data (y ^* _1i , y ^* _2i , y ^* _3i ) is ensured. The

As a result, the actual data pair is corrected according to the color difference between the standard paper and the white color (chromaticity) of the paper used as the background when measuring the actual data pair, and the actual data measured using the standard paper as the background. To approximate.
Furthermore, since the correction amount for the actual data pair is set according to the Euclidean distance d _i from the reference color coordinate S2, the correction amount in a specific color direction in the color space is unlikely to vary. Thereby, the continuity of the actual data pairs used when generating the color conversion characteristic model is ensured.
Further, since the composite real data is generated in the L ^* a ^* b ^* color space, which is a device-independent color space that does not depend on the device, special colors such as corporate colors can be handled in the same manner as other colors. Thereby, the same color reproduction on the same device with respect to a special color is also improved.

The subsequent synthesizing unit 735 acquires the actual data pair group from the actual data pair input unit 71. Also, a normalized actual data pair group is acquired from the normalizing unit 732. Further, the composition ratio 1-f (d _i ) set for the actual data pair and the composition ratio f (d _i ) set for the normalized actual data pair group are acquired from the composition ratio setting unit 734. Then, the composition ratio 1-f (d _i ) is weighted to the actual data (y _1i , y _2i , y _3i ) of the L ^* a ^* b ^* color space in the actual data pair group by the following equation (8). Then, the normalization actual data (r_y _1i , r_y _2i , r_y _3i ) in the L ^* a ^* b ^* color space in the normalized actual data pair group is weighted with the composition ratio f (d _i ) to synthesize both Then, synthetic real data (y ^* _1i , y ^* _2i , y ^* _3i ) is generated.

Thereafter, the combining unit 735 _{combines the} actual real data (y ^* _1i , y ^* _2i , y ^* _3i ) of the L ^* a ^* b ^* color space generated by the equation (8) and the corresponding actual data of the CMYK color space. n sets of combined real data pairs (combined real data pair groups) with (x _1i , x _2i , x _3i , x _4i ) as a set are sent to and stored in the combined real data pair storage unit 74.

Subsequently, the lattice point data generation unit 77 of the color conversion table generation unit 70 generates lattice point data regularly arranged in the device color space (CMYK color space). Then, the generated grid point data is output to the weight generation unit 75, the color conversion characteristic model calculation unit 76, and the color conversion processing unit 78.
The color conversion characteristic model calculation unit 76 uses the grid point data input from the grid point data generation unit 77 and the combined real data pair group stored in the combined real data pair storage unit 74 to perform a color conversion processing unit 78. A color conversion characteristic model for performing color conversion processing on the grid point data set in is generated. When generating a color conversion characteristic model, there are a method of performing linear regression analysis using weighted actual data, which is statistical processing, a method of performing interpolation by simply performing weighted averaging on actual data which is interpolation processing, and statistical processing. A known method for predicting a color conversion characteristic model such as a method using a neural network that has learned weighted actual data is used.
Further, the color conversion characteristic model calculation unit 76 generates color data (C, M, Y, K) in the four-dimensional CMYK color space from color data (C, M, Y, K) in the three-dimensional L ^* a ^* b ^* color space ( L ^* , a ^* , b ^* ) color conversion characteristic model and color conversion characteristics from color data in the three-dimensional L ^* a ^* b ^* color space to color data in the four-dimensional CMYK color space Calculate the model.
Here, the “color conversion characteristic model” is, for example, a color signal (device color signal) in the CMYK color space which is a device color space and a color signal (L in the L ^* a ^* b ^* color space which is a device-independent color space). ^{* A *} b ^* color signal) is a formula that defines and defines the correspondence between device color signals and L ^* a ^* b ^* color signals.

The color conversion processing unit 78 performs color conversion processing on the grid point data acquired from the grid point data generation unit 77 based on the color conversion characteristic model generated by the color conversion characteristic model calculation unit 76. That is, the grid point data of the CMYK color space acquired from the grid point data generation unit 77 is converted into an L ^* a ^* b ^* which is a device-independent color space based on the color conversion characteristic model generated by the color conversion characteristic model calculation unit 76 ^. Convert to color space color data. Then, the color conversion processed color data is output to the color conversion coefficient output unit 79.
The color conversion coefficient output unit 79 performs color conversion processing on the grid point data received by the grid point data generation unit 77 and the grid point data received by the grid point data generation unit 77 by the color conversion processing unit 78. Correlate with color data. Then, a data group in which the associated grid point data and the color data subjected to the color conversion process are paired is output to the second color signal conversion unit 40.

The second color signal conversion unit 40 acquires a data group from the color conversion coefficient output unit 79 and configures a color conversion table (color conversion coefficient, DLUT). Then, for example, image data that is an input color signal input from an external device such as a personal computer (PC) is color-converted into a CMYK color space color signal that is a device color signal using a color conversion table. The device color signal generated by the color conversion processing by the second color signal conversion unit 40 is sent to the color signal output unit 50.
The color signal output unit 50 outputs the device color signal (output color signal) generated by the second color signal conversion unit 40 to a device such as a color image forming apparatus.

  As described above, in the color processing apparatus 1 of the present embodiment, first, the standard of the device generated based on the actual data obtained from the color patch printed on the predetermined standard paper for the color gamut of the input color signal. Map to the color gamut. Furthermore, when the actual data prepared for obtaining the color conversion coefficient used for color conversion of the input color signal is actual data obtained from a color patch printed on paper other than standard paper The actual data is corrected in accordance with the color difference from the chromaticity of the standard paper. Then, a color conversion coefficient for color-converting the input color signal into a device color signal is calculated using the corrected actual data. Thereby, regardless of the chromaticity W of the paper that is the base of the color patch whose actual data is color-measured, a decrease in color reproducibility when the input color signal is color-converted to the device color signal is suppressed. . Further, variation in color reproducibility due to the difference in chromaticity W of the paper serving as the base of the color patch whose actual data is color-measured is reduced.

[Embodiment 2]
In the first embodiment, a predetermined standard paper is determined in advance, and a color gamut generated based on actual data obtained from a color patch printed on the predetermined standard paper is set as the standard color gamut of the device. A configuration in which actual data prepared for obtaining a color conversion coefficient is corrected in accordance with the color difference from the chromaticity of the standard paper on which the color patch is printed, and the color conversion coefficient is calculated using the corrected actual data. explained. In this embodiment, a plurality of predetermined standard papers are determined in advance, a plurality of standard color gamuts of the device are set, and actual data prepared for obtaining a color conversion coefficient is stored on a paper other than a plurality of standard papers. If the actual data is obtained from the color patch printed on the paper, it is made to correspond to the chromaticity of the standard paper with the smallest color difference from the chromaticity W of the paper on which the actual data was obtained. A configuration for correcting the color conversion coefficient using the corrected actual data will be described. In addition, the same code | symbol is used about the structure similar to Embodiment 1, and the detailed description is abbreviate | omitted here.

First, the standard color gamut generation unit 60 according to the present embodiment uses a device to create a predetermined first standard paper (for example, a coat) using lattice point data in the device color space (CMYK color space) and lattice point data as input color signals. A first standard actual data pair which is a pair with color data obtained by actually measuring the color patch printed on the paper in the conversion destination device-independent color space (L ^* a ^* b ^* color space). To get. Then, based on the acquired first standard actual data pair, first standard color gamut data expressing the device color gamut in the L ^* a ^* b ^* color space is generated.
Similarly, grid point data in the device color space (CMYK color space) and a color patch printed on a predetermined second standard paper (for example, plain paper) by the device using the grid point data as an input color signal are converted into the conversion destination. A second standard actual data pair that is a pair with color data obtained by actually measuring colors in the device-independent color space (L ^* a ^* b ^* color space) is acquired. Then, based on the acquired second standard actual data pair, second standard color gamut data expressing the device color gamut in the L ^* a ^* b ^* color space is generated.

Further, the standard color gamut generation unit 60 converts the color data of the L ^* a ^* b ^* color space in the first standard actual data pair used when generating the first standard color gamut data, for example, to L ^* a, for example ^{. *} B ^* Correction is performed in correspondence with the color difference from the reference white coordinate S1 (100, 0, 0) in the color space. As a correction method in this case, for example, a method implemented by the above-described combined real data pair generation unit 73 is used. The device color gamut is expressed in the L ^* a ^* b ^* color space based on the corrected first standard actual data pair corrected in accordance with the color difference from the reference white coordinate S1 (100, 0, 0). Third standard color gamut data is generated.
Then, the standard color gamut generation unit 60 sends the first standard color gamut data, the second standard color gamut data, and the third standard color gamut data to the mapping processing unit 30.
The mapping processing unit 30 sets the standard color gamut 1 in the mapping processing unit 30 based on the third standard color gamut data acquired from the standard color gamut generation unit 60. A standard color gamut 2 is set based on the first standard color gamut data. Further, the standard color gamut 3 is set based on the second standard color gamut data.

FIG. 9 is a diagram illustrating the standard color gamut 1, the standard color gamut 2, and the standard color gamut 3 set in the mapping processing unit 30. As shown in FIG. 9, the standard color gamut 1 is generated based on the corrected first standard actual data pair corrected in accordance with the color difference from the reference white coordinate S1 (100, 0, 0). Therefore, the color gamut whose highest brightness value (L ^* value)) (maximum brightness coordinate) coincides with the reference white coordinate S1 (100, 0, 0). The standard color gamut 2 is generated based on the first standard actual data pair obtained by measuring the color patch printed on a predetermined first standard paper (for example, coated paper). The highest lightness value (L ^* value) is the color gamut that matches the chromaticity S2 of the first standard paper. The standard color gamut 3 is generated based on the second standard actual data pair obtained by measuring the color patch printed on a predetermined second standard paper (for example, plain paper). The highest lightness value (L ^* value) is the color gamut that matches the chromaticity S3 of the second standard paper. However, reference white coordinates S1 (100,0,0)> chromaticity S2 of first standard paper> chromaticity S3 of second standard paper.

Next, the mapping processing unit 30 selects the standard color gamut of the device that performs the mapping process of the input color signal from any one of the standard color gamut 1, the standard color gamut 2, and the standard color gamut 3. In that case, the chromaticity of the paper as the base when the actual data prepared for obtaining the color conversion coefficient is measured, and the standard color gamut 1, the standard color gamut 2, and the standard color gamut 3, respectively. The selection is made based on the color difference between the reference white coordinate S1 (100, 0, 0), the chromaticity S2 of the first standard paper, and the chromaticity S3 of the second standard paper, which is the highest lightness value (L ^* value).
Specifically, the mapping processing unit 30 calculates the white color of the paper on which the color patch is printed from the actual data pair group for obtaining the color conversion coefficient input to the color conversion table generation unit 70 as L ^* a ^* b. ^* Acquire actual data W (= paper chromaticity) obtained by color measurement in the color space. Then, a color difference between the chromaticity W of the acquired paper and the reference white coordinate S1 (100, 0, 0), the chromaticity S2 of the first standard paper, and the chromaticity S3 of the second standard paper is calculated, and the acquired paper Which chromaticity W is closest to, that is, which is the smallest color difference from the chromaticity W of the paper. Then, the standard color gamut generated based on the colorimetric value of the standard paper having the smallest color difference from the chromaticity W of the paper is selected.

FIG. 10 is a flowchart showing an example of a procedure for searching for a standard paper having a minimum color difference from the paper when the actual data pair group for obtaining a color conversion coefficient is measured by the mapping processing unit 30. It is. As shown in FIG. 10, the mapping processing unit 30 first determines the chromaticity of the paper on which the color patch is printed when the actual data pair group for obtaining the color conversion coefficient from the color conversion table generating unit 70 is measured. W is acquired (step 101). Then, the color difference between the obtained paper chromaticity W and the reference white coordinate S1 (100, 0, 0), the first standard paper chromaticity S2, and the second standard paper chromaticity S3 is calculated (step 102). . Next, the calculated color differences are compared (step 103). Then, the minimum color difference is extracted (step 104), and a standard color gamut generated based on the extracted standard paper having the minimum color difference is selected (step 105).
In step 104, the minimum color difference may be extracted under the condition that the brightness value is larger than the chromaticity W of the paper. Accordingly, when the actual data is corrected when the color conversion table generation unit 70 in the subsequent stage calculates the color conversion coefficient, the actual data is suppressed from being corrected in the dark (low) direction of lightness. Therefore, it is possible to suppress a decrease in color brightness in a low brightness area reproduced based on the calculated color conversion coefficient.

Subsequently, when the standard color gamut is selected, the mapping processing unit 30 performs a mapping process on the input color signal in the selected standard color gamut. For example, when the selected standard color gamut is the standard color gamut 2, the input color signal is mapped to the standard color gamut 2.
Further, the mapping processing unit 30 sends information regarding the selected standard color gamut to the color conversion table generating unit 70.

The color conversion table generation unit 70 acquires information regarding the standard color gamut from the mapping processing unit 30. When the actual data prepared for generating the color conversion table is actual data obtained from color patches printed on paper other than the standard paper of the standard color gamut selected by the mapping processing unit 30 The actual data is corrected in accordance with the color difference with the chromaticity of the standard paper in the standard color gamut selected by the mapping processing unit 30. Then, a color conversion table corresponding to the standard color gamut of the device is generated using the corrected actual data.
For example, when the standard color gamut selected by the mapping processing unit 30 is the standard color gamut 1, the color conversion table generation unit 70 corresponds to the color difference from the reference white coordinate S1 (100, 0, 0). To correct the actual data. In this case, the reference color coordinate S2 in FIG. 7 is set to the reference white coordinate S1. Further, when the standard color gamut selected by the mapping processing unit 30 is the standard color gamut 2, the color conversion table generation unit 70 corresponds to the color difference from the chromaticity S2 of the first standard paper. Correct the data. In this case, the reference color coordinate S2 in FIG. 7 is set as it is. Furthermore, when the standard color gamut selected by the mapping processing unit 30 is the standard color gamut 3, the color conversion table generation unit 70 corresponds to the color difference from the chromaticity S3 of the second standard paper. Correct actual data. In this case, the reference color coordinate S2 in FIG. 7 is set to the chromaticity S3 of the second standard paper. Then, a color conversion table corresponding to the standard color gamut of the device is generated using the corrected actual data.

In this case, when the standard gamut 1 is set by the mapping processing unit 30, for example, L ^* a ^* b ^{* in} the first standard actual data pair used when generating the first standard gamut data ^. When correcting the color data of the color space, the chromaticity W of the paper when the color conversion coefficient input to the color conversion table generation unit 70 is obtained without using the reference white coordinate S1 (100, 0, 0) is used. It may be used. That is, the color data in the L ^* a ^* b ^* color space in the first standard actual data pair is corrected in accordance with the color difference from the chromaticity W of the paper. The actual data prepared for generating the color conversion table in the color conversion table generation unit 70 is higher in color than the chromaticity S2 of the first standard paper in the standard color gamut 2 set in the mapping processing unit 30. When the actual data is obtained from the color patch printed on the paper of degree W, the mapping processing unit 30 selects the standard color gamut 1 and performs the mapping process on the input color signal in the standard color gamut 1. Further, the color conversion table generation unit 70 corrects the actual data in accordance with the color difference from the reference white coordinate S1 (100, 0, 0) higher than the chromaticity S2 of the first standard paper, and corrects the corrected actual data. A color conversion table is generated using the data.

  Thereby, the color gamut of the device on which the input color signal is mapped by the mapping processing unit 30 is the standard color gamut 1 generated using the chromaticity W of the paper, and is generated by the color conversion table generating unit 70. The color conversion table uses actual data corrected in accordance with the color difference from the reference white coordinate S1 (100, 0, 0). Therefore, the color reproducibility when the input color signal is converted into the device color signal is not optimal. However, in the actual data obtained from the color patch printed on the paper having the chromaticity W between the reference white coordinate S1 (100, 0, 0) and the chromaticity S2 of the first standard paper, the reference white coordinate S1 Since the color difference between (100, 0, 0) and the chromaticity W of the paper is not large, the correction amount in the color conversion table generation unit 70 is small. For this reason, a decrease in color reproducibility is substantially suppressed.

  As described above, in the color processing apparatus 1 of the present embodiment, a plurality of predetermined standard papers are determined in advance, and a plurality of standard color gamuts of the device are set. A standard color gamut of a device for mapping the input color signal is prepared for obtaining a color conversion coefficient from a plurality of standard color gamuts (standard color gamut 1, standard color gamut 2, standard color gamut 3). The actual data is selected based on the color difference from the chromaticity W of the paper that is the base when the actual data is obtained. In addition, if the actual data prepared for obtaining the color conversion coefficient is actual data obtained from color patches printed on paper other than a plurality of standard papers, the background when the actual data was obtained Correction is performed in correspondence with the chromaticity of the standard paper having the smallest color difference from the chromaticity W of the paper, and the color conversion coefficient is calculated using the corrected actual data. Thereby, regardless of the chromaticity W of the paper that is the base of the color patch whose actual data is color-measured, a decrease in color reproducibility when the input color signal is color-converted to the device color signal is suppressed. . In addition, the correction amount of each actual data is suppressed to be small, and a decrease in color reproducibility is suppressed over the entire color gamut of the input color signal. For this reason, variation in color reproducibility in the entire color gamut due to the difference in chromaticity W of the paper serving as the base of the color patch whose actual data has been measured is reduced.

In the color processing apparatus 1 of the present embodiment, the standard color gamut of the device that performs the mapping process of the input color signal is used as the base paper when the actual data prepared for obtaining the color conversion coefficient is obtained. The color difference was selected based on the color difference from the chromaticity W. However, as another method for selecting the standard color gamut of the device, for example, the user may select the standard color gamut of the device set by a plurality of predetermined standard papers.
In addition to the method of setting from the viewpoint of paper chromaticity as the predetermined standard paper used when setting the standard color gamut of the device, for example, a plurality of predetermined standard papers are set from the viewpoint of paper quality. Also good. That is, the standard color gamut of the device may be determined by setting a plurality of predetermined standard papers based on differences in various characteristics of the paper.

It is a block diagram explaining the structure of the color processing apparatus to which this Embodiment is applied. It is the figure which showed the hardware constitutions of the color processing apparatus. It is a figure explaining an example of the vertex regularly arranged in the cube-shaped color gamut in CMY color space. It is a figure explaining the mapping process performed in a mapping process part. It is a block diagram which shows the structure of a color conversion table production | generation part. It is a block diagram which shows the structure of a synthetic | combination real data pair production | generation part. It is a figure which illustrates notionally the normalization process of the real data in a normalization part. It is the figure which showed an example of the monotone decreasing function set in a synthetic | combination ratio setting part. It is a figure explaining the standard color gamut 1, the standard color gamut 2, and the standard color gamut 3 set in the mapping processor. It is the flowchart which showed an example of the procedure of the process which searches the standard paper in the minimum color difference with the paper at the time of measuring the actual data pair group for calculating | requiring the color conversion coefficient performed in a mapping process part.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Color processing apparatus, 10 ... Color signal input part, 20 ... 1st color signal conversion part, 30 ... Mapping processing part, 40 ... 2nd color signal conversion part, 50 ... Color signal output part, 60 ... Standard color gamut generation 70: Color conversion table generation unit, 71 ... Actual data pair input unit, 72 ... Reference color coordinate setting unit, 73 ... Composite real data pair generation unit, 74 ... Composite real data pair storage unit, 75 ... Weight generation unit, 76 ... color conversion characteristic model calculation unit, 77 ... lattice point data generation unit, 78 ... color conversion processing unit, 79 ... color conversion coefficient output unit

Claims (13)

A conversion target color data acquisition unit that acquires conversion target color data of the first color space;
A mapping processing unit that performs mapping processing on the conversion target color data acquired by the conversion target color data acquisition unit within a predetermined color gamut set in the first color space or on the surface of the predetermined color gamut;
A plurality of colors in which a plurality of color data in the second color space that is the conversion destination of the color data to be converted and a pair of color data in the first color space corresponding to each color data in the second color space A color data pair acquisition unit for acquiring data pairs;
The color data of the first color space acquired by the color data pair acquisition unit is set in the color data of the first color space and the inside of the predetermined color gamut of the first color space or the surface of the predetermined color gamut. A correction unit that performs correction according to the color difference from the reference color coordinate that has been set,
Using the color data of the second color space acquired by the color data pair acquisition unit and the color data of the first color space corrected by the correction unit paired with the color data of the second color space. A color conversion coefficient generation unit that generates a color conversion coefficient for associating the conversion target color data mapped by the mapping processing unit with the conversion color data of the second color space. apparatus. The mapping processing unit converts a color gamut generated by colorimetric values in the first color space of a color sample printed on a predetermined standard paper based on specific data in the second color space to the predetermined color gamut. Set as
The correction unit sets the chromaticity of the predetermined standard paper constituting the maximum brightness coordinate of the predetermined color gamut set by the mapping processing unit as the reference color coordinate. The color processing apparatus as described. The mapping processing unit includes a plurality of color gamuts generated by colorimetric values in the first color space of color samples printed on a plurality of predetermined standard papers based on specific data in the second color space. The color difference with the chromaticity of the paper that is the background when the color data of the first color space acquired by the color data pair acquisition unit is measured from the plurality of color gamuts is minimized. Setting the color gamut generated by the colorimetric value of the color sample printed on the predetermined standard paper having the chromaticity to be as the predetermined color gamut,
The correction unit sets the chromaticity of the predetermined standard paper constituting the maximum brightness coordinate of the predetermined color gamut set by the mapping processing unit as the reference color coordinate. The color processing apparatus as described.   The mapping processing unit has a chromaticity that minimizes a color difference from the chromaticity of the paper as a base when the color data of the first color space acquired by the color data pair acquisition unit is measured. The predetermined standard paper is extracted on condition that the predetermined standard paper has a lightness greater than the lightness of the paper, and the extracted color sample printed on the predetermined standard paper is used as a colorimetric value. The color processing apparatus according to claim 3, wherein the generated color gamut is set as the predetermined color gamut. The mapping processing unit holds a plurality of color gamuts including a color gamut whose maximum brightness coordinate is a color coordinate having the highest brightness in the first color space, and one color from the plurality of color gamuts Set the area as the predetermined color gamut,
The correction unit sets, as the reference color coordinate, the maximum brightness coordinate of the color gamut in which the color coordinate having the highest brightness in the first color space held in the mapping processing unit is the maximum brightness coordinate. The color processing apparatus according to claim 1.   The correction unit sets the reference color coordinate to the maximum brightness coordinate of the predetermined color gamut set by the mapping processing unit, and the color having the highest brightness in the color data of the first color space A normalizing unit that normalizes the data so as to be associated with the reference color coordinate, and a composition ratio for the color data of the first color space normalized by the normalizing unit is in accordance with a color difference from the reference color coordinate. The normalized color data and the color data pair acquisition unit that monotonously decreases and the composition ratio with respect to the color data of the first color space acquired by the color data pair acquisition unit monotonously increases according to the color difference. The color processing apparatus according to claim 1, further comprising a synthesizing unit that synthesizes the color data acquired in step 1.   The conversion target color data acquisition unit acquires the conversion target color data obtained by converting an input color signal of a predetermined color space input from an external device into a color signal of the first color space that is a device-independent color space. The color processing apparatus according to claim 1, wherein: On the computer,
A function of acquiring color object color data in the first color space;
A function of mapping the acquired color data to be converted in a predetermined color gamut set in the first color space or on the surface of the predetermined color gamut;
A plurality of colors in which a plurality of color data in the second color space that is the conversion destination of the color data to be converted and a pair of color data in the first color space corresponding to each color data in the second color space The ability to retrieve data pairs;
The obtained color data of the first color space is the color difference between the color data of the first color space and the reference color coordinates set in the predetermined color gamut of the first color space or on the surface of the predetermined color gamut. And a function to correct according to
The conversion target color data mapped using the acquired color data of the second color space and the corrected color data of the first color space paired with the color data of the second color space A program for realizing a function of generating a color conversion coefficient associated with converted color data in a two-color space. The function of performing the mapping process is that the color gamut generated by the colorimetric value in the first color space of a color sample printed on a predetermined standard paper based on the specific data in the second color space is the predetermined color. Has a function to set as a range,
9. The program according to claim 8, wherein the correcting function has a function of setting the chromaticity of the predetermined standard paper constituting the maximum brightness coordinate of the predetermined color gamut as the reference color coordinate. The mapping processing function includes a plurality of color gamuts generated by colorimetric values in the first color space of color samples printed on a plurality of predetermined standard papers based on specific data in the second color space. The color sample printed on the predetermined standard paper having a chromaticity that minimizes the color difference from the chromaticity of the paper that is the background when the color data of the first color space is measured A function to set the color gamut generated by the colorimetric value of the predetermined color gamut,
9. The program according to claim 8, wherein the correcting function has a function of setting the chromaticity of the predetermined standard paper constituting the maximum brightness coordinate of the predetermined color gamut as the reference color coordinate.   The mapping processing function is characterized in that the predetermined standard paper having the chromaticity that minimizes the color difference from the chromaticity of the paper that is the base when the color data of the first color space is measured is used for the paper. The color gamut generated based on the colorimetric values of the color sample printed on the predetermined standard paper extracted on the condition that the predetermined standard paper has a lightness greater than the lightness is used as the predetermined color. The program according to claim 10, having a function of setting as a region. The mapping processing function sets one color gamut as a predetermined color gamut from a plurality of color gamuts including a color gamut having a maximum lightness coordinate as a color coordinate having the highest lightness in the first color space. Has the function to
The correction function has a function of setting, as the reference color coordinate, the maximum brightness coordinate of the color gamut having a color coordinate having the highest brightness in the first color space as a maximum brightness coordinate. Item 9. The program according to item 8.   The correcting function sets the reference color coordinate to the maximum brightness coordinate of the predetermined color gamut, and associates the color data having the highest brightness among the color data in the first color space with the reference color coordinate. The composite ratio with respect to the normalized color data of the first color space is monotonously decreased according to the color difference from the reference color coordinate, and the acquired composite ratio with respect to the color data of the first color space is 9. The program according to claim 8, wherein the correction is performed by combining the normalized color data and the acquired color data so as to monotonously increase in accordance with a color difference.

Images