JP2020029101A - Color patch creation device, image forming apparatus, and program - Google Patents

Abstract

To provide an apparatus that can reduce the man-hours for color measurement compared with a case where color patches for acquiring a first color space (RGB) value over a plurality of sheets are measured as they are by a colorimeter to acquire a second color space (Lab) value.SOLUTION: An image forming apparatus 10 measures the color of a color patch printed by a print engine 102 with a color patch reading part 103 and a colorimeter to create profile data. A control part 105 causes the print engine to print color patches for acquiring the RGB value in certain areas over a plurality of sheets with a predetermined number of patches at a predetermined patch size, and print a color patch for acquiring the Lab value in a different area of at least one of the plurality of sheets with the predetermined number of patches at a patch size smaller than the predetermined patch size.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a color patch generation device, an image forming device, and a program.

  In an image forming apparatus such as a printer, it is conceivable that a Lab result is obtained by reading a print result of the image forming apparatus with a colorimeter in order to periodically check whether or not a color shift is in a normal state. However, since the colorimetry is performed manually, it is complicated. Therefore, it has been proposed that the print result is read automatically by an inline sensor or the like of the image forming apparatus instead of the colorimeter to obtain the RGB values and convert the RGB values into Lab values.

  Japanese Patent Application Laid-Open No. H11-163873 aims to improve the generation efficiency of color conversion information used for color conversion while reducing the influence on the accuracy of color conversion, and obtains RGB values by printing color patches and obtaining RGB values. It is described that the patch data is deleted so that the number of patches becomes a predetermined number, the remaining patches are measured to obtain Lab values, and a color prediction model is generated using the obtained RGB and Lab values. Have been.

JP 2012-248934 A

  Color patches for reading RGB values with an in-line sensor or the like are printed on multiple sheets due to mounting and technical restrictions, and the same multiple color patches are used when acquiring Lab values with a colorimeter. Therefore, there is a problem that the colorimetric man-hour is large. Although the labor of colorimetry is reduced by deleting the number of patch data, there is a limit to the number of patches that can be deleted, so further improvement is desired.

  An object of the present invention is to obtain a second color space value such as a Lab value by directly measuring a plurality of color patches for obtaining a first color space value such as an RGB value with a colorimeter. An object of the present invention is to provide an apparatus and a program capable of reducing the number of colorimetric steps as compared with the method.

  According to the first aspect of the present invention, a plurality of color patches for acquiring a first color space value are printed on a predetermined area of a sheet with a predetermined number of patches and a predetermined patch size, and the predetermined number of patches, and The color patch generation device includes a printing unit that prints a color patch for acquiring a second color space value with a patch size smaller than a predetermined patch size in an area different from the fixed area on at least one of the plurality of sheets. .

  The invention according to claim 2 is the color patch generation device according to claim 1, wherein the first color space is a device-dependent color space, and the second color space is a device-independent color space.

  The invention according to claim 3 is the color patch generation device according to claim 2, wherein the first color space is RGB and the second color space is Lab.

  According to a fourth aspect of the present invention, there is provided the color patch device according to any one of the first to third aspects, an RGB value obtained by reading the color patch for acquiring the RGB value, and a color patch for acquiring the Lab value. And a control unit that generates color conversion profile data from a pair of Lab values obtained by performing colorimetry on the image.

  According to a fifth aspect of the present invention, there is provided the image forming apparatus according to the fourth aspect, further comprising a reading unit provided in the apparatus for reading the first color space value acquisition color patch.

  The invention according to claim 6 is a step of causing a computer to print a plurality of color patches for obtaining a first color space value in a predetermined area on a sheet of paper with a predetermined number of patches and a predetermined patch size; And printing a second color space value acquisition color patch with a patch size smaller than the predetermined patch size in an area different from the fixed area on at least one of the plurality of sheets. is there.

  According to the first, second, and sixth aspects of the present invention, a plurality of color patches for acquiring the first color space value are measured as they are to acquire the second color space value. And the number of colorimetric steps can be reduced.

  According to the third aspect of the invention, in particular, the number of colorimetric steps can be reduced as compared with a case where a plurality of color patches for acquiring RGB values are measured as they are to acquire Lab values.

  According to the fourth aspect of the present invention, color conversion profile data can be generated with a reduced number of colorimetric man-hours.

  According to the fifth aspect of the present invention, the first color space value can be automatically read.

FIG. 1 is a configuration diagram of an image forming apparatus according to an embodiment. FIG. 3 is an explanatory diagram of a color patch according to the embodiment. It is an explanatory view of a color patch of another embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

<Basic principle>
The basic principle of the present embodiment is that a color patch for acquiring a first color space value and a color patch for acquiring a second color space value are separate from each other, and a color patch for acquiring a second color space value is used. The patch size of the patch is reduced, and a color patch for acquiring the second color space value is also arranged on a sheet on which the color patch for acquiring the first color space value is printed, that is, a chart. Here, the first color space is a color space (device-dependent color space) that depends on the image forming apparatus, and corresponds to, for example, RGB. The second color space is a color space that does not depend on the image forming apparatus (device-independent color space), and corresponds to, for example, Lab. Hereinafter, the first color space will be described as RGB and the second color space as Lab.

  A color patch for obtaining an RGB value is provided in an image forming apparatus such as an in-line sensor or the like, and a specific patch is provided in a specific area of a sheet due to mounting and technical restrictions of a reading unit for obtaining a color in a device-dependent color space. It is required to print in a size, and as a result, a plurality of sheets are printed. When colorimetry is performed by using a colorimeter using the color patches for obtaining RGB values over a plurality of sheets as they are, the colorimetry is performed over a plurality of sheets, which is troublesome.

  Therefore, in the present embodiment, the color size of the color patch for Lab value acquisition is relatively reduced by utilizing the fact that the influence of the cavity effect when acquiring the RGB values by the in-line sensor is relatively small in the color measurement with the colorimeter. By reducing the number of color patches for Lab value acquisition to reduce the number of color patches for Lab value acquisition and arranging them on the same paper as the color patches for RGB value acquisition, the color patches for RGB value acquisition and the color patches for Lab value acquisition are reduced. Even if the patches are separated, the number of colorimetric steps can be significantly reduced without increasing the total number of sheets (charts).

When the number of RGB value acquisition color patches in the present embodiment is M, the number of patches is m, the number of charts of Lab value acquisition color patches is N, and the number of patches is n,
M> N
m = n
It is.
However, M ≧ N may be satisfied instead of M> N. The reason why M = N is included is that the arrangement of the color patches for acquiring Lab values may be made redundant.

  In the following description, the case where M = 18, N = 2, and m = n = 1584 is exemplified, but it is needless to say that the present invention is not necessarily limited to this.

  Further, in the present embodiment, the color patch for acquiring the RGB value and the color patch for acquiring the Lab value are arranged at different positions on the same sheet (the same chart). It is not necessary to include a patch and a color patch for acquiring a Lab value. That is, it is only necessary that at least one of a plurality of sheets (charts) on which color patches for acquiring RGB values are arranged includes a color patch for acquiring Lab values.

  Further, in the present embodiment, the color patches for acquiring the RGB values and the color patches for acquiring the Lab values are arranged separately on the upper and lower sides of the same paper (chart). And the position can be set arbitrarily.

<Structure>
Next, the configuration of the present embodiment will be specifically described.

  FIG. 1 is a configuration diagram of an image forming apparatus according to the present embodiment. Note that the image forming apparatus 10 may be connected to a management server via a network.

  The image forming apparatus 10 is a printer, a multifunction peripheral, or the like, and includes a color conversion unit 101, a print engine 102, a color patch reading unit 103, a storage unit 104, a control unit 105, and a user interface unit 106. The colorimeter 107 may be a part of the image forming apparatus 10 or may be provided separately therefrom.

  The image forming apparatus 10 executes a process for printing out the input print image data. The print image data is, for example, bitmap image data or image data described in PDL (Page Description Language). When the image forming apparatus 10 includes a scanner, image data read by the scanner may be used as print image data. The print image data is converted into a raster image that can be processed by the print engine 102 by an interpreter (not shown) or another image processing unit.

  The color conversion unit 101 performs color conversion on a raster image according to profile data. The profile data is data including information indicating the correspondence between the color coordinates of each grid point in the input color space and the color coordinates in the output color space corresponding to the grid point. The output color space is the color space of the print engine 102, and is typically represented by a combination of four colors of cyan (C), magenta (M), yellow (Y), and black (K). The profile data is generated by the control unit 105 and stored in the storage unit 104. For example, profile data may be generated for each type of paper and stored in the storage unit 104, and the user may select and use data suitable for the paper to be used from a plurality of profile data. The color conversion unit 101 calculates, for each pixel of the raster image, the color coordinate of the output color space when the value (color coordinate) of the pixel is used as the color coordinate of the input color space according to the profile data.

  The print engine 102 prints the image of the color conversion result output by the color conversion unit 101 on a sheet.

  The color patch reading unit 103 reads the color patches printed by the print engine 102 under the control of the control unit 105, acquires RGB values, and outputs the RGB values to the control unit 105. The color patch reading unit 103 includes an in-line sensor (ILS) and the like. The in-line sensor has substantially the same configuration as a known image reading scanner, and specifically includes an imaging unit, an illumination unit, an image processing unit, and a sensor calibration unit. The mounting position in the image forming apparatus 10 is preferably in the vicinity of a paper discharge unit where the printing of the printed color patches is completed, the curl of the paper is removed, and the posture is stabilized. The image processing unit includes a three-color CCD, and performs read variation correction in real time to calculate color information of a color patch.

  The control unit 105 controls the entire image forming apparatus 10 according to the processing program stored in the program memory. The control unit 105 receives a print instruction from a user via the user interface unit 106, and controls the color conversion unit 101, the print engine 102, and the like to execute printing of the target image of the print instruction. Further, control unit 105 executes a process for generating profile data. The profile data is obtained by causing the print engine 102 to print a color patch serving as a color reference, reading the print result with the color patch reading unit 103, and measuring the color with the colorimeter 107. Generated based on Lab value data group. The generated profile data is stored in the storage unit 104. The color patch is an image pattern in which color patches having different densities in a plurality of stages are arranged for each of CMYK colors. The color patch data is stored in the storage unit 104 as a chart pattern, and the control unit 105 reads out the data and causes the print engine 102 to print the data in accordance with the processing program.

  A known algorithm can be used as a method for calculating a profile indicating conversion from RGB values to Lab values. For example, it may include a first step of performing a brightness conversion by a look-up table (LUT) and a second step of performing a linear conversion by a matrix calculation (for example, a 3 × 10 matrix calculation). It is calculated from a large number of color patch read values by a certain calculation algorithm. These LUTs and determinant coefficients are stored in the storage unit 104 as parameters.

  The user interface unit 106 notifies the user of the state of the image forming apparatus 10 and receives an instruction input from the user. The user interface unit 106 may include a display device such as a liquid crystal touch panel and input buttons such as a keypad.

  Here, the chart pattern stored in the storage unit 104 is data that defines an array of color patches to be printed by the print engine 102 in order to acquire RGB values and Lab values. Due to the above restrictions, only half of the printing paper can arrange color patches, and the light emitted from the light source is reflected not only by the color patches to be measured but also by adjacent color patches, and The light returned to the light source is further reflected and illuminated on the color patch to be measured, so that the reflected light affected by the reflectance of the adjacent color patch is received by the image reading element. In consideration of this, it is necessary to secure a patch area, so that a plurality of color patches, for example, 18 color patches are provided. In this case, in order to obtain the RGB values, reading must be performed at the time of outputting 18 color patches, and furthermore, the color measurement of the 18 color patches has to be performed by the colorimeter 107, which requires a long time in the color measurement process.

  Therefore, according to the processing program, the control unit 105 uses the same combination (but smaller in size) as the RGB value acquisition color patch for obtaining the Lab value, separately from the color patch for acquiring the RGB value. A color patch is set, and the color patch for acquiring the Lab value is arranged on the same sheet as the color patch for acquiring the RGB value.

  Next, the color patch of the present embodiment will be described.

  FIG. 2 schematically shows a color patch for acquiring RGB values and a color patch for acquiring Lab values according to the present embodiment. Although the color patches are shown as rectangular areas without painting in the drawing, they are actually patches in which the density changes in a plurality of steps for each of CMYK colors.

<Color patch for obtaining RGB values>
As described above, the color patches for obtaining the RGB values are printed on a plurality of sheets under the technical restrictions of mounting the color patch reading unit (in-line sensor) 103 and the cavity effect. Specifically, only half of a single sheet can have patches arranged thereon. If the area of one color patch is 2 cm x 2 cm or more and the number of patches is 1584, the number of color patches is 18 Become. Sheets (charts) on which these 18 RGB value acquisition color patches are printed are designated as 20-1, 20-2, 20-3,..., 20-18 (in the figure, 20-1, 20-20). −2, 20-3 only). A color patch 22 for acquiring RGB values is printed on the upper half of these 18 sheets of paper 20-1, 20-2, 20-3,..., 20-18. Of course, the pattern of the color patches 22 printed on the paper 20-1 and the pattern of the color patches 22 printed on the paper 20-2 or 20-3 are different from each other.

<Color patch for acquiring Lab value>
On the other hand, since the color patch for acquiring the Lab value is not affected by the cavity effect as much as the color patch reading unit (in-line sensor) 103, the area of one color patch is smaller than the color patch 22 for acquiring the RGB value. For example, the size can be reduced to about 0.7 cm × 0.7 cm.

  Therefore, by utilizing the fact that the area of one patch is small while using the same number of patches (1584) as the color patch 22 for acquiring the RGB value, the color patch 24 for acquiring the Lab value is divided into two and the Lab value is acquired. The color patches 24a and 24b for acquisition are printed on the lower half of the paper 20-1 on which the color patches 22 are printed on the upper half, and the color patches 24b for acquiring Lab values are printed in color. The patch 22 is printed on the lower half of the sheet 20-2 on which the upper half is printed.

  It is not necessary to print the Lab value acquisition color patches 24 on the other sheets 20-3, 20-4,..., 20-18, but the Lab value acquisition color patches 24a and 24b You may print.

  As described above, the color patch 24 for acquiring the Lab value is made separate from the color patch 22 for acquiring the RGB value, and the color patch 24 for acquiring the Lab value is the same as the color patch 22 for acquiring the RGB value. By arranging them on the same sheet (or the same chart), the number of colorimetric steps for acquiring the Lab value can be reduced from 18 sheets to 2 sheets.

  That is, in a case where the RGB value and the Lab value are acquired by using the same color patch for acquiring the RGB value and the color patch for acquiring the Lab value, reading is performed on the 18 color patches to acquire the RGB values, and Although it is necessary to measure the color of 18 color patches, in the present embodiment, it is sufficient to read the 18 color patches and to measure the color of only 2 color patches to obtain the RGB values. Will be. In addition, in the present embodiment, the total number of sheets (the number of chart patterns) remains 18 even if the color patches 24 for acquiring Lab values are separate from the color patches 22 for acquiring RGB values. Please note.

  Table 1 shows the number of color patches 22 for acquiring RGB values and the number of color patches 24 for acquiring Lab values, the number of chart patterns, the print area, and the patch size in the present embodiment.

  In Table 1, the ILS reading area of the printing area means the range of reading by the color patch reading unit (in-line sensor: ILS) 103, and specifically shows the upper half of the paper in FIG. Also, the large and small patch sizes are relative, and one patch size of the color patch 24 for Lab value acquisition is relative to one patch size of the color patch 22 for RGB value acquisition. Means smaller.

  In the present embodiment, the color patch 24 for Lab value acquisition is divided into two to obtain color patches 24a and 24b for Lab value acquisition, and the color patch 24a for Lab value acquisition is arranged on the paper 20-1. At the same time, the color patch 24b for acquiring the Lab value is arranged on the paper 20-2, but if there is room in the margin depending on the size of the paper and the size of the color patch 22 for acquiring the RGB value, FIG. As shown in (1), the color patches 24 for acquiring Lab values may be arranged only on the paper 20-1. In this case, the number of putters of the color patch 24 for Lab value acquisition is further reduced to one.

  The image forming apparatus 10 of the present embodiment is connected to a color management server via a network, outputs color patches in the image forming apparatus 10, measures colors, transmits colorimetric data to the color management server, and The present invention can also be applied to a system in which the state of the image forming apparatus 10 is remotely managed on a regular basis.

Reference Signs List 10 image forming apparatus, 22 color patches for obtaining RGB values, 24, 24a, 24b color patches for obtaining Lab values, 101 color conversion unit, 102 print engine, 103 color patch reading unit, 104 storage unit, 105 control unit, 106 user interface unit, 107 colorimeter.

The invention according to claim 1 prints a plurality of color patches for obtaining a first color space value that is a device-dependent color space with a predetermined number of patches and a predetermined patch size in a fixed area of a sheet, and
Printing for printing a color patch for obtaining a second color space value, which is a device-independent color space with the predetermined patch number and the predetermined patch size , in an area different from the fixed area on at least one of the plurality of sheets of paper It is a color patch generation device including a unit.

The printing unit according to claim 2, wherein the printing unit is configured to print the first color space value acquisition color patch and the second color space value acquisition color patch on at least one of the plurality of sheets. After printing, the first color space value acquisition color patch is printed on a sheet to be printed next to at least one of the plurality of sheets, and the second color space value acquisition color patch is printed. The color patch generation device according to claim 1, wherein the patch is not printed on a sheet to be printed next to at least one of the plurality of sheets .

According to a third aspect of the present invention, there is provided the color patch generation device according to any one of the first and second aspects, and a value obtained by reading the first color space value acquisition color patch; And a control unit for generating color conversion profile data from values obtained by measuring the color patches for acquiring color space values of the color.

According to a fourth aspect of the present invention, a step of causing a computer to print a plurality of color patches for obtaining a first color space value, which is a device-dependent color space, with a predetermined number of patches and a predetermined patch size in a fixed area of a sheet. Printing a color patch for obtaining a second color space value that is a device-independent color space with the predetermined number of patches and the predetermined patch size in an area different from the fixed area on at least one of the plurality of sheets of paper And a program for executing the steps.

The invention according to claim 5 is a device-dependent color space that reads a first color space value acquisition color patch printed in a predetermined area on a plurality of sheets with a predetermined number of patches and a predetermined patch size. A first reading unit that obtains one color space value, and a second color printed in an area different from the fixed area on the at least one of the plurality of sheets with the predetermined patch number and the predetermined patch size A second reading unit that reads a color patch for obtaining a space value and obtains a second color space value that is a device-independent color space; and a color reading unit that obtains a color from the first color space value and the second color space value. A color conversion profile data generation device including a control unit for generating conversion profile data.

According to a sixth aspect of the present invention, a computer reads a first number of color patches for obtaining a first color space value, which are printed on a predetermined area of a sheet over a plurality of sheets with a predetermined number of patches and a predetermined patch size. Obtaining a first color space value , and a second color space printed in an area different from the fixed area on the at least one of the plurality of sheets with the predetermined patch number and the predetermined patch size Reading a value acquisition color patch to obtain a second color space value that is a device-independent color space; and generating color conversion profile data from the first color space value and the second color space value. And a program for executing the steps.
According to a seventh aspect of the present invention, a color patch for obtaining a first color space value obtained by printing a plurality of sheets with a predetermined number of patches and a predetermined patch size on a predetermined area of a sheet is a device-dependent color space. A first reading unit for acquiring one color space value, and at least one of the plurality of sheets having a predetermined number of patches and a predetermined patch size for generating color conversion profile data together with the first color space value. A second reading unit that reads a color patch for obtaining a second color space value printed on an area different from the fixed area of the paper and obtains a second color space value that is a device-independent color space. This is a color patch reading device.
According to an eighth aspect of the present invention, a computer reads color patches for obtaining a first color space value, which are printed in a predetermined area on a plurality of sheets with a predetermined number of patches and a predetermined patch size, and reads the device-dependent color space. Obtaining a first color space value, and generating a color conversion profile data together with the first color space value by using a predetermined number of patches and a predetermined patch size. Reading a color patch for obtaining a second color space value printed in an area different from the fixed area and obtaining a second color space value that is a device-independent color space.
According to a ninth aspect of the present invention, there is provided a device-dependent color space obtained by reading a color patch for obtaining a first color space value, which is printed in a predetermined area on a plurality of sheets with a predetermined number of patches and a predetermined patch size. A first color space value, a predetermined number of patches, and a second color space value acquisition color patch printed in an area different from the fixed area on at least one of the plurality of sheets with a predetermined patch size Is a color conversion profile data generation device that includes a control unit that generates color conversion profile data from a second color space value that is a device-independent color space obtained by reading the image data.
According to a tenth aspect of the present invention, an apparatus is provided in which a computer reads a color patch for obtaining a first color space value, which is printed on a predetermined area of a sheet over a plurality of sheets with a predetermined number of patches and a predetermined patch size. A first color space value that is a dependent color space, a predetermined number of patches, and a second color space value that is printed in an area different from the fixed area on at least one of the plurality of sheets with a predetermined patch size. Is a program for executing a step of generating color conversion profile data from a second color space value which is a device-independent color space obtained by reading the color patch of FIG.

According to the first, second, fourth, seventh and eighth aspects of the present invention, a second color space value is obtained by directly measuring a plurality of color patches for obtaining a first color space value. Compared with the case, the number of colorimetric steps can be reduced.

According to the third , fifth, sixth, ninth, and tenth aspects of the present invention, a second color space value is obtained by directly measuring a plurality of color patches for obtaining the first color space value. Color conversion profile data can be created with a reduced number of colorimetric man-hours as compared with the case where a color conversion profile is generated.

SUMMARY OF THE INVENTION An object of the present invention is to measure a plurality of color patches for obtaining a first color space value such as an RGB value without using a colorimeter as it is, and to use a first color such as an RGB value on the same paper. An object of the present invention is to provide an apparatus and a program for acquiring a second color space value such as a space value and a Lab value .

According to one aspect of the present invention, a first color space values for obtaining an equipment-dependent color space, the color patches not for a second color space value acquisition device is independent color space to the paper printed, and a color patch generator apparatus comprising a printing unit for printing a color patch of the second color space values for obtaining prior SL paper.

The invention according to claim 2, wherein the printing unit, the first color patch and the second at least one of the sheet color patches several sheets multiple of color space values for the acquisition of color space values for obtaining After printing, the first color space value acquisition color patch is printed on a sheet to be printed next to at least one of the plurality of sheets, and the second color space value acquisition 2. The color patch generation device according to claim 1, wherein the color patch is not printed on a sheet to be printed next to at least one of the plurality of sheets. 3.

Invention of claim 4, the computer, a first color space values for obtaining an equipment-dependent color space, the color patch device not in a second color space values for obtaining an independent color space a step of printing on paper, and a program for executing the step of printing a color patch of the second color space values for obtaining prior SL paper.

The invention according to claim 5 is a first reading unit that reads a color patch for obtaining a first color space value, which is a device-dependent color space printed on paper, and obtains the first color space value. Reading the color patch for obtaining the first color space value printed on the paper, and reading the color patch for obtaining the second color space value which is the device-independent color space printed on the paper. a second reading unit for acquiring the second color space values, the color conversion profile data generation and a control unit for generating a color conversion profile data from the first color space value and the second color space values Device.

The invention according to claim 6, the computer, acquiring a first of said first color space values by reading the color patches of the color space values for obtaining a device-dependent color space, which is printed on the paper, wherein the paper without reading color patches printed the first color space values for acquired, by reading the color patch of the second color space values for obtaining a printed device independent color space to the paper A program for executing a step of acquiring a second color space value and a step of generating color conversion profile data from the first color space value and the second color space value.
The invention according to claim 7, wherein a first reading unit that reads a color patch for obtaining a first color space value, which is a device-dependent color space printed on paper, and obtains the first color space value; In order to generate the color conversion profile data together with the first color space value, the color patch for obtaining the first color space value printed on the paper is not read, and the device-independent printing on the paper is not performed. A second reading unit that reads a color patch for obtaining a second color space value, which is a color space, and obtains the second color space value.
In the invention according to claim 8, a computer reads a color patch for obtaining a first color space value, which is a device-dependent color space printed on paper, and obtains the first color space value; In order to generate the color conversion profile data together with the first color space value, the device independent color printed on the paper is not read without reading the color patch for obtaining the first color space value printed on the paper. is a program for executing the step of acquiring the second color space values by reading the color patch of the second color space values for obtaining a space.
Invention according to claim 9, wherein the first color space values first obtained by reading the color patches of the color space values for obtaining a device-dependent color space, which is printed on the paper, printed on the paper without reading a color patch of the first color space values for acquisition is, the obtained by reading the second color patches of the color space values for obtaining a printed device independent color space to the sheet first 2 is a color conversion profile data generation device including a control unit that generates color conversion profile data from two color space values.
The invention of claim 10 causes a computer, said a first color space value first obtained by reading the color patches of the color space values for obtaining a device-dependent color space, which is printed on the paper, said Instead of reading the first color space value acquisition color patch printed on the paper, the second color space value acquisition color patch that is a device-independent color space printed on the paper is acquired. wherein the second color space values, a program for executing the step of generating a color conversion profile data.

According to the first, second, fourth, seventh and eighth aspects of the present invention, the first color space value which is a device-dependent color space is obtained, and the second color which is a device-independent color space. A color patch for acquiring a space value and a color patch for acquiring a second color space value can be arranged on the same sheet.

According to the third, fifth, sixth, ninth, and tenth aspects of the present invention, the first color space value, which is a device-dependent color space, which is arranged on the same sheet of paper, is obtained. Color conversion profile data can be generated by reading a color patch that is not for acquiring a second color space value as a color space and a color patch for acquiring a second color space value.

Claims (6)

Printing a plurality of color patches for obtaining the first color space value in a predetermined area on a predetermined number of patches and a predetermined patch size, and
A printing unit that prints a color patch for obtaining a second color space value in an area different from the fixed area on at least one of the plurality of sheets with the predetermined number of patches and a patch size smaller than the predetermined patch size. Color patch generation device provided. The first color space is a device-dependent color space;
The second color space is a device-independent color space;
The color patch generation device according to claim 1. The first color space is RGB;
The color patch generation device according to claim 2, wherein the second color space is Lab. A color patch device according to any one of claims 1 to 3,
Color conversion profile data is generated from a pair of a value obtained by reading the first color space value acquisition color patch and a value obtained by measuring the color of the second color space value acquisition color patch. A control unit to
An image forming apparatus comprising: The image forming apparatus according to claim 4, further comprising: reading means provided in the apparatus for reading the color patch for acquiring the first color space value. On the computer,
Printing a plurality of color patches for obtaining a first color space value in a predetermined area on a sheet of paper with a predetermined number of patches and a predetermined patch size;
Printing the color patch for second color space value acquisition in an area different from the fixed area of at least one of the plurality of sheets, with the predetermined number of patches and a patch size smaller than the predetermined patch size;
A program that executes

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