JP5958725B1 - Image processing apparatus, image processing method, and image processing program - Google Patents

Abstract

An image processing apparatus capable of converting RGB data into CMYK data from which a vivid print image can be obtained without changing an achromatic color. A color conversion module refers to a color profile CP1 indicating a correspondence relationship between R, G, B values and L *, a *, b * values. The color conversion module 10 converts only the a * and b * values corresponding to the chromatic R, G, and B values in the direction of increasing the saturation, and the L * corresponding to the achromatic R, G, and B values. , A *, b * values are generated as they are, and modified RGB data is generated. The printing color conversion unit 20 refers to the color profile CP2 indicating the correspondence between the L *, a *, and b * values and the C, M, Y, and K values. The printing color conversion unit 20 selects the L *, a *, and b * values that are closest to the L *, a *, and b * values in the modified RGB data from the color profile CP2, and selects the selected L *, a *. , B * values corresponding to C, M, Y, K values are output as CMYK data for printing. [Selection] Figure 1

Description

  The present invention prints additive color-mixed red (R), green (G), and blue (B) color signals to subtractive color-mixed cyan (C), magenta (M), yellow (Y), and black (K). The present invention relates to an image processing apparatus, an image processing method, and an image processing program for converting into a color signal for use.

  In order to print a digital image composed of RGB data on paper, it is necessary to convert the RGB data into CMYK data. A color space that can be represented by printing based on CMYK data using C, M, Y, and K inks is narrower than a color space that can represent an image composed of RGB data on a display. Therefore, colors that do not fit in the color space of CMYK data in the color space of RGB data are replaced with approximate colors in the color space of CMYK data.

JP 2006-31376 A

  When an image composed of RGB data is converted into CMYK data and printed on paper, the operator may perform a retouching operation to correct the color so that the printed image becomes vivid. The retouching work must be performed by an operator with a wealth of experience and knowledge, and there is a problem that it takes a long time.

  Therefore, it is required to convert RGB data into CMYK data that can provide a vivid print image without experience or knowledge. When the RGB data is converted into CMYK data from which a vivid print image can be obtained, it is not preferable that the achromatic color changes and becomes tinted.

  It is an object of the present invention to provide an image processing apparatus, an image processing method, and an image processing program that can convert RGB data into CMYK data from which a vivid print image can be obtained without changing an achromatic color.

In order to solve the above-described problems of the prior art, the present invention is associated with the RGB data among the pixel data composed of RGB data which are additive color-mixed red, green, and blue color signals. Referring to the first color profile showing the correspondence between the R, G, B values indicating the level of each color signal and the L ^* , a ^* , b ^* values of the L ^* a ^* b ^* color system. Only the values of a ^* and b ^* in the L ^* , a ^* and b ^* values corresponding to the chromatic R, G and B values are converted in the direction of increasing the saturation, and the achromatic R, G and B values are converted. corresponding to L ^*, a ^*, and the color conversion module for generating a concealment RGB data as it is of value without converting b ^* values, L ^* a ^* b ^* color system of L ^*, a ^*, b ^* A second showing the correspondence between the value and the C, M, Y, K values indicating the levels of the subtractive color cyan, magenta, yellow, and black color signals Referring to the color profile, the modification that put into RGB data L ^*, a ^*, b ^* values most approximate to the L ^*, a ^*, and b ^* values selected from the second color profile, are selected An image processing apparatus comprising: a printing color conversion unit that outputs C, M, Y, and K values corresponding to L ^* , a ^* , and b ^* values as CMYK data for printing.

In the image processing apparatus described above, the first cyan hue in the color profile R, G, L corresponding to the B value ^*, a ^*, b ^* values of a ^* values and b ^* of the values a1, b1 When the a ^* value and b ^* value converted by the color conversion module are a2 and b2, the color conversion module indicates that a2 is (−0.0008 × a1 ³ + 0.0065 × a1 ² + 1.596 × a1 is converted to a2 so that the first range is from (a1 + 0.7609) to (−0.0018 × a1 ³ −0.0587 × a1 ² + 0.509 × a1−0.8142), and b2 is (−0.0004 × b1 ³ B1 is converted to b2 so that the second range is from (+ 0.0077 × b1 ² + 1.5267 × b1-1.158) to (−0.0007 × b1 ³ −0.0224 × b1 ² + 0.9027 × b1 + 0.2427) It is preferable to do.

In the image processing apparatus described above, the first hue magenta in color profile R, G, L corresponding to the B value ^*, a ^*, b ^* values of a ^* values and b ^* of the values a1, b1 When the values of a ^* and b ^* converted by the color conversion module are a2 and b2, the color conversion module has a2 of (−0.0006 × a1 ³ + 0.0257 × a1 ² + 1.0074 × a1 is converted to a2 so that the first range is from (a1 + 1.9869) to (−0.0002 × a1 ³ + 0.0103 × a1 ² + 0.9148 × a1−0.6582), and b2 is (+ 0.5015 × b1 ⁴ −0.0698 × b1 ³ −3.6577 × b1 ² −1.17979 × b1 + 1.1221) to (+ 0.1862 × b1 ⁴ −0.0994 × b1 ³ −1.3049 × b1 ² + 0.8372 × b1 + 0.6918) It is preferable to convert b1 to b2 so as to be in the range.

In the image processing apparatus described above, the first of yellow hue in the color profile R, G, L corresponding to the B value ^*, a ^*, b ^* values of a ^* values and b ^* of the values a1, b1 When the values of a ^* and b ^* converted by the color conversion module are a2 and b2, the color conversion module has a2 of (−0.0741 × a1 ³ −0.2281 × a1 ² + 1.5887 × a1 −0.0597) to (−0.169 × a1 ³ −1.2732 × a1 ² −1.6351 × a1−1.6855) so that a1 is converted to a2 and b2 is (+ 0.0002 × b1 ³ − B1 is converted to b2 so that the second range from 0.0557 × b1 ² + 3.8295 × b1-19.174) to (−0.0005 × b1 ³ + 0.0496 × b1 ² −0.1869 × b1 + 9.3544) Is preferred.

In the image processing apparatus described above, the first red hue in the color profile R, G, L corresponding to the B value ^*, a ^*, b ^* values of a ^* values and b ^* of the values a1, b1 When the values of a ^* and b ^* converted by the color conversion module are a2 and b2, the color conversion module has a2 of (−0.0005 × a1 ³ + 0.0216 × a1 ² + 1.0642 × a1 is converted to a2 so that the first range is from (a1 + 0.9702) to (−0.00002 × a1 ³ −0.002 × a1 ² + 1.1574 × a1−1.1551), and b2 is (−0.0188 × b1 ³ B1 is converted to b2 so that the second range is from (−0.7331 × b1 ² −7.7264 × b1 + 36.954) to (−0.0025 × b1 ³ + 0.1078 × b1 ² −0.4953 × b1 + 7.8243) It is preferable.

In the image processing apparatus described above, the first green hue in the color profile R, G, L corresponding to the B value ^*, a ^*, b ^* values of a ^* values and b ^* of the values a1, b1 When the values of a ^* and b ^* converted by the color conversion module are a2 and b2, the color conversion module has a2 of (−0.0002 × a1 ³ + 0.0071 × a1 ² + 1.4745 × a1 is converted to a2 so that the first range is from (a1 + 0.3966) to (−0.0002 × a1 ³ −0.0067 × a1 ² + 1.0257 × a1 + 0.6624), and b2 is (−0.0641 × b1 ³ + 2.0252 × b1 ² −18.747 × b1 + 63.726) to (−0.0054 × b1 ³ + 0.1898 × b1 ² −0.9854 × b1 + 7.2331) b1 is converted to b2 It is preferable.

In the image processing apparatus described above, the first blue hue in a color profile R, G, L corresponding to the B value ^*, a ^*, b ^* values of a ^* values and b ^* of the values a1, b1 When the values of a ^* and b ^* converted by the color conversion module are a2 and b2, the color conversion module has a2 of (+ 0.3214 × a1 ³ −5.6805 × a1 ² + 30.456 × a1 is converted to a2 so that the first range is from (1−41.552) to (+0.1 894 × a1 ³ −3.2752 × a1 ² + 17.774 × a1-24.191), and b2 is (−0.0004 × b1 to b2 so that the second range is from (b1 ³ −0.0137 × b1 ² + 0.9175 × b1-1.1038) to (−0.0001 × b1 ³ −0.004 × b1 ² + 0.985 × b1 + 0.0013) It is preferable to convert.

In addition, in order to solve the above-described problems of the conventional technology, the present invention determines whether or not each pixel data composed of RGB data, which are additive color-mixed red, green, and blue color signals, is chromatic color data. or determines, the is associated with the RGB data, R indicating the level of the respective color signals, G, B values and the L ^* a ^* b ^* color system of L ^*, a ^*, b ^* values and the with reference to the first color profile indicating the relationship, if the pixel data is data chromatic, L ^* corresponding to R, G, B values, a ^*, a in b ^* values ^*, b ^* If the pixel data is achromatic data, the L ^* , a ^* , and b ^* values corresponding to the R, G, and B values are not converted and are converted as they are. The modified RGB data is generated as follows, and the L ^* , a ^* , b ^* values of the L ^* a ^* b ^* color system and the subtractive cyan, magenta Data, yellow, C indicating the level of each color signal of the black, M, Y, with reference to the second color profile showing the correspondence between the K value, that put the concealment RGB data L ^*, a ^*, b ^* most approximate to the value L ^*, a ^*, b ^* values selected from the second color profile, said selected in the second color profile L ^*, a ^*, C corresponding to the b ^* values, Provided is an image processing method characterized by outputting M, Y, and K values as CMYK data for printing.

Furthermore, in order to solve the above-described problems of the prior art, the present invention provides a computer with each pixel data composed of RGB data, which are additive color mixture red, green, and blue color signals, as chromatic data. A determination step for determining whether or not there is present, and R, G, B values and L ^* a ^* b ^* color system L ^* , a ^* associated with the RGB data and indicating the level of each color signal If the pixel data is chromatic color data with reference to the first color profile indicating the correspondence relationship with the, b ^* values, the L ^* , a ^* , b ^* values corresponding to the R, G, B values If only the values of a ^* and b ^* are converted to increase the saturation, and the pixel data is achromatic data, the L ^* , a ^* , and b ^* values corresponding to the R, G, and B values are changed. A generation step for generating modified RGB data as a value without conversion, and L ^* a ^* b ^* color system of L ^*, a ^*, b ^* values and subtractive cyan, magenta, yellow, C indicating the level of each color signal of the black, M, Y, the second showing the correspondence between the K value Referring to the color profiles, L ^* that put the concealment RGB data, a ^*, b ^* most approximate to the value L ^*, a ^*, a selection step of the b ^* value is selected from the second color profile, An output step of outputting C, M, Y, and K values corresponding to the selected L ^* , a ^* , and b ^* values in the second color profile as CMYK data for printing. An image processing program is provided.

  According to the image processing apparatus, the image processing method, and the image processing program of the present invention, it is possible to convert RGB data into CMYK data from which a vivid print image can be obtained without changing the achromatic color.

It is a block diagram which shows the image processing apparatus of one Embodiment. It is a figure for ^{demonstrating} a L ^* a ^* b ^* color system. It is a characteristic view which shows the characteristic of cyan of the standard state before converting the value of a ^* and b ^* by the color conversion module 10 in FIG. 6 is a characteristic diagram showing characteristics of cyan a ^* and b ^{* obtained} by converting the values of a ^* and b ^* by the color conversion module 10. FIG. FIG. 6 is a characteristic diagram showing the characteristics of magenta in a standard state before the values of a ^* and b ^* are converted by the color conversion module 10. FIG. 4 is a characteristic diagram showing the characteristics of m ^* for a ^* and b ^{* obtained} by converting the values of a ^* and b ^* by the color conversion module 10. FIG. 6 is a characteristic diagram showing yellow characteristics of a standard state before the values of a ^* and b ^* are converted by the color conversion module 10. 4 is a characteristic diagram showing characteristics of yellow a ^* and b ^{* obtained} by converting the values of a ^* and b ^* by the color conversion module 10. FIG. FIG. 6 is a characteristic diagram showing characteristics of red in a standard state before the values of a ^* and b ^* are converted by the color conversion module 10. FIG. 6 is a characteristic diagram showing characteristics of red a ^* and b ^{* obtained} by converting the values of a ^* and b ^* by the color conversion module 10. FIG. 5 is a characteristic diagram showing the characteristics of green in a standard state before the values of a ^* and b ^* are converted by the color conversion module 10. FIG. 5 is a characteristic diagram showing characteristics of green a ^* and b ^{* obtained} by converting the values of a ^* and b ^* by the color conversion module 10. FIG. 6 is a characteristic diagram showing blue characteristics in a standard state before the values of a ^* and b ^* are converted by the color conversion module 10. FIG. 4 is a characteristic diagram showing characteristics of blue a ^* and b ^{* obtained} by converting the values of a ^* and b ^* by the color conversion module 10. It is a figure which shows the example of the color image used in order to verify the effect by the image processing apparatus of one Embodiment, an image processing method, and an image processing program. It is a figure for comparing the original data before converting the values of a ^* and b ^* by the color conversion module 10 with the modified data after conversion. It is a figure for comparing the original data before converting the values of cyan a ^* and b ^* by the color conversion module 10 and the modified data after conversion. It is a figure for comparing the original data before converting the values of m ^* for a ^* and b ^* by the color conversion module 10 and the modified data after the conversion. It is a figure for comparing the original data before converting yellow a ^* and b ^* values by the color conversion module 10 with the modified data after conversion. FIG. 16 is a diagram showing a comparison between gray a ^* and b ^* values in the color image shown in FIG. 15 and a comparative example in which a ^* and b ^* values are converted. 3 is a flowchart illustrating an operation of an image processing apparatus according to an embodiment, an image processing method according to an embodiment, and processing executed by an image processing program according to an embodiment. It is a block diagram which shows the structural example of the computer which performs the image processing program of one Embodiment.

  Hereinafter, an image processing apparatus, an image processing method, and an image processing program according to an embodiment will be described with reference to the accompanying drawings.

  As shown in FIG. 1, the image processing apparatus according to an embodiment includes a color conversion module 10 and a printing color conversion unit 20. In FIG. 1, RGB data and a correction amount adjustment signal are input to the color conversion module 10. The RGB data is, for example, image data generated by a digital camera.

  Here, the RGB data and the color profile CP1 describing a table for converting colors are associated with each other. For example, the name of a color profile (such as sRGB described later) used as the color profile CP1 can be described in Exif (Exchangeable image file format) information.

  Managing so that the color does not change as much as possible even if the devices are different, such as a display and a printer, is called color management. Color management is performed by using the color profile CP1 and a color profile CP2 described later.

  As the color profile, an ICC profile that conforms to the format of the International Color Consortium (ICC) is generally used. The color profiles CP1 and CP2 are examples of ICC profiles.

  As an example, it is assumed that the RGB data is expressed by a color space standard called sRGB defined by the International Electrotechnical Commission (IEC). The color profile CP1 corresponds to sRGB. Instead of sRGB, Adobe RGB may be used. Adobe RGB is a color space standard advocated by Adobe Systems Incorporated.

As shown in FIG. 1, the color profile CP1 includes R, G, B values indicating the levels of R, G, B color signals and an L ^* a ^* b ^* color system (CIE L ^* a ^* b ^* ). The correspondence relationship between L ^* , a ^* , and b ^* values is shown. The L ^* a ^* b ^* color system is represented by a three-dimensional color space shown in FIG. FIG. 2B is a cross-sectional view of FIG. 2A and shows a circle formed by the a ^* axis and the b ^* axis.

L ^* represents lightness. + A ^* represents the red direction, −a ^* represents the green direction, + b ^* represents the yellow direction, and −b ^* represents the blue direction. As shown in FIG. 2B, the circumferential direction of the circle represents the hue. As the color space moves from the center to the outside, the saturation increases and the color becomes brighter.

  Since the color profile CP1 cannot hold all the enormous color points that make up the sRGB color space, for example, about 1500 points can be extracted uniformly from the color space and held in the color profile CP1. That's fine. Color data not held in the color profile CP1 is interpolated by calculation.

The color conversion module 10, of the color profile CP1 that is associated with the input RGB data, chromatic R, G, L corresponding to the B value ^*, a ^*, b ^* values of a ^*, b ^* Only the value of is converted by the following conversion formula. The color conversion module 10 does not convert the value of L ^* and does not change the brightness.

If the R, G, and B values are all the same as in (0, 0, 0), (128, 128, 128), (255, 255, 255) The color determined by the values of R, G, and B is an achromatic color. The color conversion module 10 does not convert the achromatic L ^* , a ^* , b ^* values from (0, 0, 0) to (255, 255, 255), and outputs them as they are.

Here, a conversion formula for converting the values of a ^* and b ^* of the chromatic color by the color conversion module 10 suitable for obtaining a vivid print image will be described. As a representative example, a conversion formula for converting the values of a ^* and b ^* for each hue of cyan, magenta, yellow, red, green, and blue will be described.

<Cyan>
L ^* a ^* b ^* a constituting a hue of cyan color system ^*, b ^* has a relation of equation (1).
b ^* = 1.5054a ^* + 6.6189 (1)

The values of a ^* and b ^* of the cyan hue defined in the color profile CP1 are the original data a1 and b1, and the values of a ^* and b ^* when converted to vivid cyan are the modified data a2 and b2. The modified data a2 and b2 are expressed by equations (2) and (3). Equations (2) and (3) are equations for the maximum correction amount.

a2 = −0.0008 × a1 ³ + 0.0065 × a1 ² + 1.596 × a1 + 0.7609 (2)
b2 = −0.0004 × b1 ³ + 0.0077 × b1 ² + 1.5267 × b1−1.7158 (3)

When the values of a ^* and b ^* are converted by the equations (2) and (3), if the degree of change is too large, the original data a1 and b1 are converted to the modified data a2 by the equations (4) and (5). You may convert into b2. Expressions (4) and (5) are expressions with the smallest correction amount.

a2 = −0.0018 × a1 ³ −0.0587 × a1 ² + 0.509 × a1−0.8142 (4)
b2 = −0.0007 × b1 ³ −0.0224 × b1 ² + 0.9027 × b1 + 0.2427 (5)

The color conversion module 10 converts the cyan a ^* value in the range from Equation (2) to Equation (4), and the cyan b ^* value in the range from Equation (3) to Equation (5). Good. The color conversion module 10 converts cyan a ^* and b ^* values according to a correction amount adjustment signal supplied by operating an operation unit (not shown).

When the horizontal axis is −a ^* and the vertical axis is −b ^* , cyan changes as shown in FIG. 3 in a standard state in which cyan is not converted by the color conversion module 10. FIG. 4A shows the relationship between the original data a1 and the modified data a2 according to the equations (2) and (4), where the horizontal axis is the original data a1 and the vertical axis is the modified data a2. The color conversion module 10 changes the value of a ^* of cyan between a solid line curve represented by Expression (2) and a broken line curve represented by Expression (4).

FIG. 4B shows the relationship between the original data b1 and the modified data b2 according to the equations (3) and (5), where the horizontal axis is the original data b1 and the vertical axis is the modified data b2. The color conversion module 10 changes the value of cyan b ^* between a solid curve indicated by Equation (3) and a dashed curve indicated by Equation (5).

<Magenta>
L ^* a ^* b ^* a constituting the hue of magenta color system ^*, b ^* has a relation of equation (6).
b ^* = − 0.2114a ^* + 3.964 (6)

The values of a ^* and b ^* of the magenta hue defined by the color profile CP1 are the original data a1 and b1, and the values of a ^* and b ^* when converted to vivid magenta are the modified data a2 and b2. The modified data a2 and b2 are expressed by equations (7) and (8). Expressions (7) and (8) are expressions for correcting the maximum amount.

a2 = −0.0006 × a1 ³ + 0.0257 × a1 ² + 1.0074 × a1 + 1.9869 (7)
b2 = 0.5015 × b1 ⁴ −0.0698 × b1 ³ −3.6577 × b1 ² −1.17979 × b1 + 1.1221 (8)

When the values of a ^* and b ^* are converted by the equations (7) and (8), if the degree of change is too large, the original data a1 and b1 are converted to the modified data a2 by the equations (9) and (10). You may convert into b2. Expressions (9) and (10) are expressions with the smallest correction amount.

a2 = −0.0002 × a1 ³ + 0.0103 × a1 ² + 0.9148 × a1−0.6582 (9)
b2 = 0.1862 × b1 ⁴ −0.0994 × b1 ³ −1.3049 × b1 ² + 0.8372 × b1 + 0.6918 (10)

The color conversion module 10 converts the magenta a ^* value in the range from Equation (7) to Equation (9) and the magenta b ^* value in the range from Equation (8) to Equation (10). Good. The color conversion module 10 converts the m ^* values of a ^* and b ^* according to the adjustment amount adjustment signal.

When the horizontal axis is −a ^* and the vertical axis is −b ^* , magenta changes as shown in FIG. 5 in the standard state where the color conversion module 10 does not convert magenta. FIG. 6A shows the relationship between the original data a1 and the modified data a2 according to the equations (7) and (9) when the horizontal axis is the original data a1 and the vertical axis is the modified data a2. The color conversion module 10 changes the value of magenta a ^* between the solid curve indicated by Equation (7) and the dashed curve indicated by Equation (9).

FIG. 6B shows the relationship between the original data b1 and the modified data b2 according to the equations (8) and (10) when the horizontal axis is the original data b1 and the vertical axis is the modified data b2. The color conversion module 10 changes the value of magenta b ^* between a solid curve indicated by Expression (8) and a broken curve indicated by Expression (10).

<Yellow>
L ^* a ^* b ^* a constituting a hue of yellow color systems ^*, b ^* has a relation of formula (11).
b ^* = − 8.9895a ^* + 1.3763 (11)

The values of a ^* and b ^* of the yellow hue specified by the color profile CP1 are the original data a1 and b1, and the values of a ^* and b ^* when converted to a bright yellow are the modified data a2 and b2. The modified data a2 and b2 are expressed by equations (12) and (13). Expressions (12) and (13) are expressions for correcting the maximum amount.

a2 = −0.0741 × a1 ³ −0.2281 × a1 ² + 1.5887 × a1−0.0597 (12)
b2 = 0.0002 × b1 ³ −0.0557 × b1 ² + 3.8295 × b1-19.174 (13)

When the values of a ^* and b ^* are converted by the equations (12) and (13), if the degree of change is too large, the original data a1 and b1 are converted to the modified data a2 by the equations (14) and (15). You may convert into b2. Expressions (14) and (15) are expressions with the smallest correction amount.

a2 = −0.169 × a1 ³ −1.2732 × a1 ² −1.6351 × a1−1.6855 (14)
b2 = −0.0005 × b1 ³ + 0.0496 × b1 ² −0.1869 × b1 + 9.3544 (15)

If the color conversion module 10 converts the yellow a ^* value in the range from the expression (12) to the expression (14) and the yellow b ^* value in the range from the expression (13) to the expression (15), Good. The color conversion module 10 converts the yellow a ^* and b ^* values in accordance with the adjustment amount adjustment signal.

When the horizontal axis is −a ^* and the vertical axis is −b ^* , the yellow changes as shown in FIG. 7 in a standard state where the color conversion module 10 does not convert yellow. FIG. 8A shows the relationship between the original data a1 and the modified data a2 according to the equations (12) and (14), where the horizontal axis is the original data a1 and the vertical axis is the modified data a2. The color conversion module 10 changes the value of yellow a ^* between a solid curve indicated by Expression (12) and a broken curve indicated by Expression (14).

FIG. 8B shows the relationship between the original data b1 and the modified data b2 according to the equations (13) and (15), where the horizontal axis is the original data b1 and the vertical axis is the modified data b2. The color conversion module 10 changes the value of yellow b ^* between a solid curve indicated by the equation (13) and a broken curve indicated by the equation (15).

<Red>
L ^* a ^* b ^* a which constitute the hue of the red color system ^*, b ^* has a relation of formula (16).
b ^* = 0.5232a ^* +7.0232 (16)

The values of a ^* and b ^* of the red hue specified by the color profile CP1 are the original data a1 and b1, and the values of a ^* and b ^* when converted to bright red are the modified data a2 and b2. The modified data a2 and b2 are expressed by equations (17) and (18). Expressions (17) and (18) are expressions with the maximum correction amount.

a2 = −0.0005 × a1 ³ + 0.0216 × a1 ² + 1.0642 × a1 + 0.9702 (17)
b2 = −0.0188 × b1 ³ + 0.7331 × b1 ² −7.7264 × b1 + 36.954 (18)

When the values of a ^* and b ^* are converted by the equations (17) and (18), if the degree of change is too large, the original data a1 and b1 are converted to the modified data a2 by the equations (19) and (20). You may convert into b2. Expressions (17) and (18) are expressions with the smallest correction amount.

a2 = −0.00002 × a1 ³ −0.002 × a1 ² + 1.1574 × a1−1.1551 (19)
b2 = −0.0025 × b1 ³ + 0.1078 × b1 ² −0.4953 × b1 + 7.8243 (20)

The color conversion module 10 converts the red a ^* value in the range from Equation (17) to Equation (19), and the red b ^* value in the range from Equation (18) to Equation (20). Good. The color conversion module 10 converts the red a ^* and b ^* values in accordance with the adjustment amount adjustment signal.

When the horizontal axis is -a ^* and the vertical axis is -b ^* , red changes as shown in FIG. 9 in a standard state where the color conversion module 10 does not convert red. FIG. 10A shows the relationship between the original data a1 and the modified data a2 according to the equations (17) and (19), where the horizontal axis is the original data a1 and the vertical axis is the modified data a2. The color conversion module 10 changes the value of red a ^* between a solid curve indicated by Equation (17) and a dashed curve indicated by Equation (19).

FIG. 10B shows the relationship between the original data b1 and the modified data b2 according to the equations (18) and (20), where the horizontal axis is the original data b1 and the vertical axis is the modified data b2. The color conversion module 10 changes the value of b ^* of red between a solid curve indicated by Expression (18) and a broken curve indicated by Expression (20).

<Green>
L ^* a ^* b ^* a constituting the hue of the color system of Green ^*, b ^* has a relation of formula (21).
b ^* = − 0.4037a ^* + 5.5189 (21)

The values of a ^* and b ^* of the green hue defined by the color profile CP1 are the original data a1 and b1, and the values of a ^* and b ^* when converted to bright green are the modified data a2 and b2. The modified data a2 and b2 are expressed by equations (22) and (23). Expressions (22) and (23) are expressions for correcting the maximum amount.

a2 = −0.0002 × a1 ³ + 0.0071 × a1 ² + 1.4745 × a1 + 0.3966 (22)
b2 = −0.0641 × b1 ³ + 2.0252 × b1 ² −18.747 × b1 + 63.726 (23)

When the values of a ^* and b ^* are converted by the equations (22) and (23), if the degree of change is too large, the original data a1 and b1 are converted to the modified data a2 by the equations (24) and (25). You may convert into b2. Expressions (24) and (25) are expressions with the smallest correction amount.

a2 = −0.0002 × a1 ³ −0.0067 × a1 ² + 1.0257 × a1 + 0.6624 (24)
b2 = −0.0054 × b1 ³ + 0.1898 × b1 ² −0.9854 × b1 + 7.2331 (25)

The color conversion module 10 converts the green a ^* value in the range from Equation (22) to Equation (24) and the green b ^* value in the range from Equation (23) to Equation (25). Good. The color conversion module 10 converts the green a ^* and b ^* values in accordance with the adjustment amount adjustment signal.

When the horizontal axis is −a ^* and the vertical axis is −b ^* , green changes as shown in FIG. 11 in the standard state where the color conversion module 10 does not convert green. FIG. 12A shows the relationship between the original data a1 and the modified data a2 according to the equations (22) and (24), where the horizontal axis is the original data a1 and the vertical axis is the modified data a2. The color conversion module 10 changes the value of a ^* of green between the solid curve shown by Expression (22) and the dashed curve shown by Expression (24).

FIG. 12B shows the relationship between the original data b1 and the modified data b2 according to the equations (23) and (25), where the horizontal axis is the original data b1 and the vertical axis is the modified data b2. The color conversion module 10 changes the value of green b ^* between a solid curve indicated by Expression (23) and a dashed curve indicated by Expression (25).

<Blue>
L ^* a ^* b ^* a constituting the hue of blue color system ^*, b ^* has a relation of formula (26).
b ^* = -2.6004a ^* +5.4687 (26)

The a ^* and b ^* values of the blue hue defined by the color profile CP1 are the original data a1 and b1, and the a ^* and b values ^* when converted to bright blue are the modified data a2 and b2. The modified data a2 and b2 are expressed by equations (27) and (28). Expressions (27) and (28) are expressions with the maximum correction amount.

a2 = 0.3214 × a1 ³ −5.6805 × a1 ² + 30.456 × a1−41.552 (27)
b2 = −0.0004 × b1 ³ −0.0137 × b1 ² + 0.9175 × b1-1.1038 (28)

When the values of a ^* and b ^* are converted by the equations (27) and (28), if the degree of change is too large, the original data a1 and b1 are converted to the modified data a2 by the equations (29) and (30). You may convert into b2. Expressions (29) and (30) are expressions with the smallest correction amount.

a2 = 0.1 894 × a1 ³ −3.2752 × a1 ² + 17.774 × a1-24.191 (29)
b2 = −0.0001 × b1 ³ −0.004 × b1 ² + 0.985 × b1 + 0.0013 (30)

The color conversion module 10 converts the blue a ^* value in the range from Equation (27) to Equation (29) and the blue b ^* value in the range from Equation (28) to Equation (30). Good. The color conversion module 10 converts blue a ^* and b ^* values in accordance with the adjustment amount adjustment signal.

When the horizontal axis is -a ^* and the vertical axis is -b ^* , blue changes as shown in FIG. 13 in the standard state where the color conversion module 10 does not convert blue. FIG. 14A shows the relationship between the original data a1 and the modified data a2 according to the equations (27) and (28), where the horizontal axis is the original data a1 and the vertical axis is the modified data a2. The color conversion module 10 changes the value of blue a ^* between a solid curve indicated by Equation (27) and a dashed curve indicated by Equation (29).

FIG. 14B shows the relationship between the original data b1 and the modified data b2 according to the equations (28) and (30), where the horizontal axis is the original data b1 and the vertical axis is the modified data b2. The color conversion module 10 changes the value of b ^* of blue between a solid curve indicated by Equation (28) and a dashed curve indicated by Equation (30).

  The colors of the hues other than cyan, magenta, yellow, red, green, and blue described above are converted by conversion formulas corresponding to the respective hues. If the hue is finely divided and a conversion formula is set for each hue, the hue can be converted into a vivid color in a state suitable for each hue. The number of hue divisions (the number of conversion formulas set) is arbitrary.

  Next, the effect when the chromatic color is converted as described above by the color conversion module 10 will be described. As shown in FIG. 15, the effect was verified with step data of four stages of light, middle, shadow, and solid for cyan, magenta, yellow, red, green, blue, and gray, respectively.

  Let C1, C2, C3, and C4 be cyan, light, middle, shadow, and solid, respectively. The light, middle, shadow, and solid in magenta are M1, M2, M3, and M4, respectively. For yellow, Y1, Y2, Y3, and Y4 are light, middle, shadow, and solid, respectively.

  Let R1, R2, R3, and R4 be the light, middle, shadow, and solid in red, respectively. The light, middle, shadow, and solid in the green are G1, G2, G3, and G4, respectively. Let B1, B2, B3, and B4 be the light, middle, shadow, and solid in blue, respectively.

  The light, middle, shadow, and solid in gray are designated as gr1, gr2, gr3, and gr4, respectively.

  In order to make the data of cyan, magenta, yellow, red, green, blue, and gray close to the actual photographic original, for example, a slight amount of cyan is added to red, for example, a slight amount of turbidity of the opposite color. Ingredients added.

FIG. 16 shows the light, intermediate, shadow, and solid data of cyan, magenta, yellow, red, green, and blue in the color gamut 30 in the a ^* and b ^* planes before conversion by the color conversion module 10. And how it changes after conversion.

  In FIG. 16, ▲ indicates original data before conversion by the color conversion module 10, and ■ indicates modified data after conversion by the color conversion module 10. In the modified data shown in FIG. 16, the color conversion module 10 converts the light, middle, shadow, and solid data of cyan, magenta, yellow, red, green, and blue using the above-described maximum amount of modification. It is data.

  The modified data of C1, C2, C3, and C4 are set as C1 ', C2', C3 ', and C4'. The modified data of M1, M2, M3, and M4 are assumed to be M1 ', M2', M3 ', and M4'. The modified data of Y1, Y2, Y3, and Y4 are Y1 ', Y2', Y3 ', and Y4'. The modified data of R1, R2, R3, and R4 are R1 ', R2', R3 ', and R4'. The modified data of G1, G2, G3, and G4 are G1 ', G2', G3 ', and G4'. The modified data of B1, B2, B3, and B4 are assumed to be B1 ', B2', B3 ', and B4'.

  Cyan, magenta, yellow, red, green, and blue each become more vivid as the saturation increases toward the outside in the color gamut 30. As can be seen by comparing the original data before conversion and the modified data after conversion, in the modified data, the curve from light to solid is longer than that of the original data and converted to a bright color. .

The difference between the original data and the modified data is relatively small in the light data near the intersection of the a ^* axis and the b ^* axis, and the difference between the original data and the modified data is in the middle, shadow, and solid data. It has been converted relatively large.

  The relationship between the original data of cyan, magenta, and yellow shown in FIG. 16 and the modified data will be described again with reference to FIGS. In FIGS. 17 to 19, only three points of light, middle, and shadow are shown. In FIG. 17 to FIG. 19, arrows indicate directions in which the saturation increases.

  As shown in FIG. 17, cyan C1 to C3 are modified to C1 'to C3' in the direction of increasing saturation. As shown in FIG. 18, magenta M1 to M3 are modified to M1 'to M3' in the direction of increasing saturation. As shown in FIG. 19, yellow Y1 to Y3 are corrected to Y1 'to Y3' in the direction of increasing saturation.

  Red, green, and blue are not shown again, but they are corrected in the direction of increasing the saturation, like cyan, magenta, and yellow.

On the other hand, the data of gray light, middle, shadow, and solid is not converted by the color conversion module 10. Therefore, as indicated by ▲ in FIG. 20, gr1, gr2, gr3, gr4 do not change in the a ^* , b ^* plane and remain as the original data.

  In FIG. 20, as a comparative example, when the saturation of the color image shown in FIG. 15 is increased by Photoshop (registered trademark) which is image processing software provided by Adobe Systems, gray gr1 to gr4. Shows how changes occur. ● indicates the state of gray gr1 to gr4 as a comparative example.

  In the comparative example, the gray hue, which is originally an achromatic color, shifts and becomes tinted. In the present embodiment, the gray hue does not shift and does not have a tint.

Returning to FIG. 1, the modified RGB data obtained by converting only the chromatic color a ^* and b ^* values by the color conversion module 10 as described above is supplied to the printing color conversion unit 20. The color conversion unit 20 for printing includes L ^* a ^* b ^* color system L ^* , a ^* , b ^* values, and C, M, and C indicating the levels of subtractive color signals of cyan, magenta, yellow, and black, respectively. It has a color profile CP2 indicating a correspondence relationship with Y and K values.

The print color converter 20, with reference to the color profile CP2 selected by the color conversion module 10, L at concealment RGB data ^*, a ^*, b ^* most approximate to the value L ^*, a a ^*, b ^* values To do. Then, the printing color conversion unit 20 outputs C, M, Y, and K values corresponding to the selected L ^* , a ^* , and b ^* values.

Since the achromatic L ^* , a ^* , and b ^* values are supplied to the printing color conversion unit 20 as they are, the printing color conversion unit 20 is L that most closely approximates the achromatic L ^* , a ^* , and b ^* values. ^* , A ^* , b ^* values are selected, and C, M, Y, K values corresponding to the selected L ^* , a ^* , b ^* values are output.

  The printing color conversion unit 20 converts all the pixel data of the modified RGB data into C, M, Y, and K values, and outputs them as CMYK data for printing using C, M, Y, and K inks.

In FIG. 1, (96, 0, 0) of the L ^* , a ^* , b ^* values in the color profile CP1 is (90, 0, -2) of the L ^* , a ^* , b ^* values in the color profile CP2. Suppose that it is the most approximate. If the values of a ^* and b ^* are not converted by the color conversion module 10, (90, 0, -2) of the color profile CP2 is selected, and C, M, Y, K values are (5, 3). , 3, 0) will be output.

However, the L ^* , a ^* , and b ^* values (96, 0, 0) in the color profile CP 1 are supplied to the printing color conversion unit 20 after the color conversion module 10 converts the a ^* and b ^* values. Therefore, the other L ^* , a ^* , b ^* values of the color profile CP2 are selected, and other C, M, Y, K values are output.

In FIG. 1, (0, 0, 0) of the L ^* , a ^* , b ^* values in the color profile CP1 is the largest (10, 0, 3) of the L ^* , a ^* , b ^* values in the color profile CP2. Approximately, (100, 0, 0) of L ^* , a ^* , b ^* values in the color profile CP1 is the most (94, 0, -1) of L ^* , a ^* , b ^* values in the color profile CP2. Approximate.

Since the achromatic L ^* , a ^* , and b ^* values are supplied to the printing color conversion unit 20 as they are, the printing color conversion unit 20 uses (10, 0, 3), (94, 0, -1) is selected, and (100, 100, 100, 100) and (0, 0, 0, 0) are output as C, M, Y, and K values.

  The operation of the image processing apparatus of this embodiment shown in FIG. 1 and the image processing method of one embodiment will be described using the flowchart shown in FIG.

  In step S11, the color conversion module 10 determines whether the pixel data of the input RGB data is a chromatic color. If the color conversion module 10 is a chromatic color (YES), the process proceeds to step S12. If the color conversion module 10 is not a chromatic color (NO), the process proceeds to step S14.

In step S12, the color conversion module 10 converts only the values of a ^* and b ^* among the L ^* , a ^* , and b ^* values of the color profile CP1 corresponding to the R, G, and B values of the pixel data. To generate modified RGB data. The color conversion module 10 converts the values of a ^* and b ^* so as to increase the saturation. At this time, it is preferable to use the conversion formula described above.

In step S13, the printing color conversion unit 20 selects L ^* , a ^* , b ^* values that are closest to the L ^* , a ^* , b ^* values of the modified RGB data from the color profile CP2.

In step S14, the printing color conversion unit 20 converts the L ^* , a ^* , b ^* values closest to the R ^* , a ^* , b ^* values corresponding to the R, G, and B values of the pixel data to a color profile. Select from CP2.

In step S15, the printing color conversion unit 20 outputs C, M, Y, and K values corresponding to the L ^* , a ^* , and b ^* values selected in step S13 or S14 as CMYK data. The processing in steps S11 to S15 is executed for all the pixel data constituting the input RGB data.

  You may comprise so that a computer may perform the process shown in FIG. 21 by an image processing program (computer program).

  In FIG. 22, the computer 50 includes a CPU 51 and a storage unit 52. The storage unit 52 stores an image processing program. The storage unit 52 is a ROM, a hard disk drive, or the like. The image processing program may be recorded on a recording medium such as an optical disk, and the recording medium may be reproduced by a recording medium reproducing device, and the image processing program may be read out.

  RGB data is input to the CPU 51. The CPU 51 generates CMYK data by executing the processing of each step shown in FIG. 21 by the image processing program. The CMYK data is supplied to the printing apparatus 60. The printing apparatus 60 prints CMYK data on a paper surface using C, M, Y, and K inks.

  The computer 50 may be a microcomputer or a personal computer. An image processing program may be provided to the computer 50 via a network.

  The printing device 60 may be a home or office printer such as an inkjet printer, or may be a business printing machine. The printing device 60 may be an offset printing machine that prints newspapers.

  As described above, according to the image processing apparatus, the image processing method, and the image processing program of the present embodiment, it is possible to convert RGB data into CMYK data from which a vivid print image can be obtained without changing the achromatic color. it can. According to the image processing apparatus, the image processing method, and the image processing program of the present embodiment, a vivid print image can be easily obtained without experience or knowledge.

  The present invention is not limited to the embodiment described above, and various modifications can be made without departing from the scope of the present invention. The use of hardware and software in the image processing apparatus is arbitrary. The color conversion module 10 and the printing color conversion unit 20 may be individually configured by an integrated circuit, or the entire color conversion module 10 and the printing color conversion unit 20 may be configured by an integrated circuit. .

10 color conversion module 20 color conversion unit for printing 50 computer 51 CPU
52 Storage Unit 60 Printing Device CP1, CP2 Color Profile

Claims (15)

R, G, B values indicating the level of each color signal are associated with the RGB data among the pixel data composed of RGB data that are additive color-mixed red, green, and blue color signals. L ^* a ^* b ^* color system of L ^*, a ^*, with reference to the first color profile indicating the relationship between b ^* values, chromatic R, G, corresponding to the B value L ^*, Only the a ^* and b ^* values in the a ^* and b ^* values are converted in the direction of increasing the saturation, and the L ^* , a ^* , and b ^* values corresponding to the achromatic R, G, and B values are not converted. A color conversion module that generates modified RGB data with the same values;
The correspondence between the L ^* , a ^* , b ^* values of the L ^* a ^* b ^* color system and the C, M, Y, K values indicating the levels of the subtractive cyan, magenta, yellow, and black color signals. with reference to the second color profile shown, that put the concealment RGB data L ^*, a ^*, b ^* most approximate to the value L ^*, a ^*, and b ^* values selected from the second color profile A color conversion unit for printing that outputs C, M, Y, and K values corresponding to the selected L ^* , a ^* , and b ^* values as CMYK data for printing;
An image processing apparatus comprising: Said first cyan hue in the color profile of R, G, L ^* corresponding to the B value, a ^*, b ^* values of a ^* values and b ^* of the value and a1, b1, by the color conversion module When the converted a ^* and b ^* values are a2 and b2,
The color conversion module includes:
a2 is the first range from (−0.0008 × a1 ³ + 0.0065 × a1 ² + 1.596 × a1 + 0.7609) to (−0.0018 × a1 ³ −0.0587 × a1 ² + 0.509 × a1−0.8142) So that a1 is converted to a2,
b2 is the second range from (−0.0004 × b1 ³ + 0.0077 × b1 ² + 1.5267 × b1−1.7158) to (−0.0007 × b1 ³ −0.0224 × b1 ² + 0.9027 × b1 + 0.2427) The image processing apparatus according to claim 1, wherein b1 is converted to b2. Said first hue magenta in color profile R, G, L ^* corresponding to the B value, a ^*, b ^* values of a ^* values and b ^* of the value and a1, b1, by the color conversion module When the converted a ^* and b ^* values are a2 and b2,
The color conversion module includes:
a2 is a first range from (−0.0006 × a1 ³ + 0.0257 × a1 ² + 1.0074 × a1 + 1.9869) to (−0.0002 × a1 ³ + 0.0103 × a1 ² + 0.9148 × a1−0.6582) So that a1 is converted to a2,
From (+ 0.5015 × b1 ⁴ −0.0698 × b1 ³ −3.6577 × b1 ² −1.17979 × b1 + 1.1221) to (+ 0.1862 × b1 ⁴ −0.0994 × b1 ³ −1.3049 × b1 ² + 0.8372 × b1 + 0. The image processing apparatus according to claim 1, wherein b1 is converted to b2 so as to be in the second range up to 6918). The first of yellow hue in the color profile R, G, L ^* corresponding to the B value, a ^*, b ^* values of a ^* values and b ^* of the value and a1, b1, by the color conversion module When the converted a ^* and b ^* values are a2 and b2,
The color conversion module includes:
a2 is in the first range from (−0.0741 × a1 ³ −0.2281 × a1 ² + 1.5887 × a1−0.0597) to (−0.169 × a1 ³ −1.2732 × a1 ² −1.6351 × a1−1.6855) , A1 is converted to a2,
b2 is the second range from (+ 0.0002 × b1 ³ −0.0557 × b1 ² + 3.8295 × b1-19.174) to (−0.0005 × b1 ³ + 0.0496 × b1 ² −0.1869 × b1 + 9.3544) The image processing apparatus according to claim 1, wherein b1 is converted to b2. The first red hue in the color profile R, G, L ^* corresponding to the B value, a ^*, b ^* values of a ^* values and b ^* of the value and a1, b1, by the color conversion module When the converted a ^* and b ^* values are a2 and b2,
The color conversion module includes:
a2 is the first range from (−0.0005 × a1 ³ + 0.0216 × a1 ² + 1.0642 × a1 + 0.9702) to (−0.00002 × a1 ³ −0.002 × a1 ² + 1.1574 × a1-1.551) So that a1 is converted to a2,
b2 is in the second range from (−0.0188 × b1 ³ + 0.7331 × b1 ² −7.7264 × b1 + 36.954) to (−0.0025 × b1 ³ + 0.1078 × b1 ² −0.4953 × b1 + 7.8243) The image processing apparatus according to claim 1, wherein b1 is converted into b2. The first green hue in the color profile R, G, L ^* corresponding to the B value, a ^*, b ^* values of a ^* values and b ^* of the value and a1, b1, by the color conversion module When the converted a ^* and b ^* values are a2 and b2,
The color conversion module includes:
a2 is the first range from (−0.0002 × a1 ³ + 0.0071 × a1 ² + 1.4745 × a1 + 0.3966) to (−0.0002 × a1 ³ −0.0067 × a1 ² + 1.0257 × a1 + 0.6624) So that a1 is converted to a2,
b2 is in the second range from (−0.0641 × b1 ³ + 2.0252 × b1 ² −18.747 × b1 + 63.726) to (−0.0054 × b1 ³ + 0.1898 × b1 ² −0.9854 × b1 + 7.2331) The image processing apparatus according to claim 1, wherein b1 is converted into b2. The first blue hue in a color profile R, G, L ^* corresponding to the B value, a ^*, b ^* values of a ^* values and b ^* of the value and a1, b1, by the color conversion module When the converted a ^* and b ^* values are a2 and b2,
The color conversion module includes:
a2 is a first range from (+ 0.3214 × a1 ³ −5.6805 × a1 ² + 30.456 × a1−41.552) to (+0.1 894 × a1 ³ −3.2752 × a1 ² + 17.774 × a1-24.191) A1 is converted to a2 so that
b2 is in the second range from (−0.0004 × b1 ³ −0.0137 × b1 ² + 0.9175 × b1-1.1038) to (−0.0001 × b1 ³ −0.004 × b1 ² + 0.985 × b1 + 0.0013) The image processing apparatus according to claim 1, wherein b1 is converted into b2. It is determined whether or not each pixel data constituted by RGB data which is each color signal of additive color mixing red, green and blue is chromatic color data.
Wherein is associated with the RGB data, R indicating the level of the respective color signals, G, B values and the L ^* a ^* b ^* color system of L ^*, a ^*, first shows the relationship between b ^* values If the pixel data is chromatic color data with reference to the color profile 1, only the values of a ^* and b ^* in the L ^* , a ^* , and b ^* values corresponding to the R, G, and B values are colored. If the pixel data is achromatic data, the modified RGB data is converted into the L ^* , a ^* , b ^* values corresponding to the R, G, B values as they are without conversion. Produces
The correspondence between the L ^* , a ^* , b ^* values of the L ^* a ^* b ^* color system and the C, M, Y, K values indicating the levels of the subtractive cyan, magenta, yellow, and black color signals. with reference to the second color profile shown, that put the concealment RGB data L ^*, a ^*, b ^* most approximate to the value L ^*, a ^*, and b ^* values selected from the second color profile ,
An image processing method comprising outputting C, M, Y, and K values corresponding to selected L ^* , a ^* , and b ^* values in the second color profile as CMYK data for printing. On the computer,
A determination step of determining whether or not each pixel data constituted by RGB data which is each color signal of additive color mixing red, green and blue is chromatic color data;
Wherein is associated with the RGB data, R indicating the level of the respective color signals, G, B values and the L ^* a ^* b ^* color system of L ^*, a ^*, first shows the relationship between b ^* values If the pixel data is chromatic color data with reference to the color profile 1, only the values of a ^* and b ^* in the L ^* , a ^* , and b ^* values corresponding to the R, G, and B values are colored. If the pixel data is achromatic data, the modified RGB data is converted into the L ^* , a ^* , b ^* values corresponding to the R, G, B values as they are without conversion. A generation step for generating
The correspondence between the L ^* , a ^* , b ^* values of the L ^* a ^* b ^* color system and the C, M, Y, K values indicating the levels of the subtractive cyan, magenta, yellow, and black color signals. with reference to the second color profile showing the modification that put into RGB data L ^*, a ^*, b ^* values most approximate to the L ^*, a ^*, and b ^* values selected from the second color profile A selection step;
An output step of outputting C, M, Y, and K values corresponding to the selected L ^* , a ^* , and b ^* values in the second color profile as CMYK data for printing;
An image processing program for executing Said first cyan hue in the color profile of R, G, L ^* corresponding to the B value, a ^*, b ^* values of a ^* values and b ^* of the value and a1, b1, in said generating step When the converted a ^* and b ^* values are a2 and b2,
In the computer, as the generation step,
a2 is the first range from (−0.0008 × a1 ³ + 0.0065 × a1 ² + 1.596 × a1 + 0.7609) to (−0.0018 × a1 ³ −0.0587 × a1 ² + 0.509 × a1−0.8142) So that a1 is converted to a2,
b2 is the second range from (−0.0004 × b1 ³ + 0.0077 × b1 ² + 1.5267 × b1−1.7158) to (−0.0007 × b1 ³ −0.0224 × b1 ² + 0.9027 × b1 + 0.2427) The image processing program according to claim 9, further comprising: executing a process of converting b1 into b2. Said first hue magenta in color profile R, G, L ^* corresponding to the B value, a ^*, b ^* values of a ^* values and b ^* of the value and a1, b1, in said generating step When the converted a ^* and b ^* values are a2 and b2,
In the computer, as the generation step,
a2 is a first range from (−0.0006 × a1 ³ + 0.0257 × a1 ² + 1.0074 × a1 + 1.9869) to (−0.0002 × a1 ³ + 0.0103 × a1 ² + 0.9148 × a1−0.6582) So that a1 is converted to a2,
From (+ 0.5015 × b1 ⁴ −0.0698 × b1 ³ −3.6577 × b1 ² −1.17979 × b1 + 1.1221) to (+ 0.1862 × b1 ⁴ −0.0994 × b1 ³ −1.3049 × b1 ² + 0.8372 × b1 + 0. 6918) The image processing program according to claim 9, wherein a process of converting b1 into b2 is executed so as to be in the second range up to 6918). The first of yellow hue in the color profile R, G, L ^* corresponding to the B value, a ^*, b ^* values of a ^* values and b ^* of the value and a1, b1, in said generating step When the converted a ^* and b ^* values are a2 and b2,
In the computer, as the generation step,
a2 is in the first range from (−0.0741 × a1 ³ −0.2281 × a1 ² + 1.5887 × a1−0.0597) to (−0.169 × a1 ³ −1.2732 × a1 ² −1.6351 × a1−1.6855) , A1 is converted to a2,
b2 is the second range from (+ 0.0002 × b1 ³ −0.0557 × b1 ² + 3.8295 × b1-19.174) to (−0.0005 × b1 ³ + 0.0496 × b1 ² −0.1869 × b1 + 9.3544) The image processing program according to claim 9, further comprising: executing a process of converting b1 into b2. The first red hue in the color profile R, G, L ^* corresponding to the B value, a ^*, b ^* values of a ^* values and b ^* of the value and a1, b1, in said generating step When the converted a ^* and b ^* values are a2 and b2,
In the computer, as the generation step,
a2 is the first range from (−0.0005 × a1 ³ + 0.0216 × a1 ² + 1.0642 × a1 + 0.9702) to (−0.00002 × a1 ³ −0.002 × a1 ² + 1.1574 × a1-1.551) So that a1 is converted to a2,
b2 is in the second range from (−0.0188 × b1 ³ + 0.7331 × b1 ² −7.7264 × b1 + 36.954) to (−0.0025 × b1 ³ + 0.1078 × b1 ² −0.4953 × b1 + 7.8243) The image processing program according to claim 9, further comprising: executing a process of converting b1 into b2. The first green hue in the color profile R, G, L ^* corresponding to the B value, a ^*, b ^* values of a ^* values and b ^* of the value and a1, b1, in said generating step When the converted a ^* and b ^* values are a2 and b2,
In the computer, as the generation step,
a2 is the first range from (−0.0002 × a1 ³ + 0.0071 × a1 ² + 1.4745 × a1 + 0.3966) to (−0.0002 × a1 ³ −0.0067 × a1 ² + 1.0257 × a1 + 0.6624) So that a1 is converted to a2,
b2 is in the second range from (−0.0641 × b1 ³ + 2.0252 × b1 ² −18.747 × b1 + 63.726) to (−0.0054 × b1 ³ + 0.1898 × b1 ² −0.9854 × b1 + 7.2331) The image processing program according to claim 9, further comprising: executing a process of converting b1 into b2. The first blue hue in a color profile R, G, L ^* corresponding to the B value, a ^*, b ^* values of a ^* values and b ^* of the value and a1, b1, in said generating step When the converted a ^* and b ^* values are a2 and b2,
In the computer, as the generation step,
a2 is a first range from (+ 0.3214 × a1 ³ −5.6805 × a1 ² + 30.456 × a1−41.552) to (+0.1 894 × a1 ³ −3.2752 × a1 ² + 17.774 × a1-24.191) A1 is converted to a2 so that
b2 is in the second range from (−0.0004 × b1 ³ −0.0137 × b1 ² + 0.9175 × b1-1.1038) to (−0.0001 × b1 ³ −0.004 × b1 ² + 0.985 × b1 + 0.0013) The image processing program according to claim 9, further comprising: executing a process of converting b1 into b2.

Images