JP2001260407A - Chart for calibrating image processing apparatus, forming method and processing method for color data for calibration and image processing apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To realize a color chart for calibrating an image processing apparatus from which effects by characteristics of a recording head, etc., can be eliminated as much as possible and which can be corrected later so as to highly accurately adjust a gray balance, gradation characteristics, etc., to any image output unit. SOLUTION: This color chart for calibrating or adjusting the gray balance and gradation characteristics at the image output unit has a patch array 100 of a plurality of patches of the same color and the same density embedded to an arbitrary position of the chart.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color chart for calibration of an image processing apparatus, a method for creating color data for calibration, a method for processing color data for calibration, and an image processing apparatus.
More specifically, the present invention relates to an image processing apparatus calibration color chart, a calibration color data creation method, a calibration color data processing method, and an image processing apparatus for the purpose of calibrating or adjusting gray balance and gradation characteristics in an image output apparatus.

[0002]

2. Description of the Related Art Recently, the bottom of image output apparatuses has been widened, and image output apparatuses corresponding to various output methods and paper sizes have been commercialized. Especially in terms of paper size, A
From large format sizes such as 0 and A1 to those specializing in normal silver halide photographic sizes such as A6, they have been developed according to the purpose and use.

In order to calibrate or adjust the gray balance of an image output device of this type, a step chart of gray and each primary color is output and printed by the image output device, and the deviation amount of the gray is discriminated based on visual and measured values. It is common to calibrate or adjust the balance in various ways.

[0004] The configuration of the step chart used at this time is not particularly determined, and at present, each company uses its own chart. For example, a color chart used when calibrating a silver salt photographic printer called Pictography, which is commercially available from Fuji Photo Film Co., Ltd., has a configuration shown in FIG.

The size of this color chart is approximately A4
Is the size of Then, patches having different densities of the respective primary colors (cyan Cy, magenta Mg, yellow Ye) are arranged in two rows in parallel with the printing progress direction. The gray balance can be adjusted by measuring these six rows of patches with a calibrator.

In the technique disclosed in Japanese Patent Application Laid-Open No. 1-160152, a patch of 729 colors constituted by dividing 8-bit image data into nine equal parts for each RGB is output at the time of gray balance adjustment, and a gray point is extracted. A way to do that has been proposed.

Incidentally, a spectrometer or a colorimeter used for measuring such a step chart has a measurement diameter of several
mm (approximately 2.5 mm). In addition, taking into account the installation deviation during measurement and the setting deviation of the measurement area during automatic measurement, even if the measurement diameter of a spectrometer or the like becomes smaller in the future, one point is required to ensure accuracy in measurement. Patches cannot be forcibly reduced.

Taking a measuring instrument having a measuring diameter of about 4 mm as an example, it is considered safe to set the size of the patch to 6 mm square or more.

[0009]

When performing gray balance adjustment of an image output apparatus that can print only a small size, such as a print for exclusive use of the A6 size, a chart as shown in FIG. It is impossible to output and print a chart as proposed in JP-A-160152 at a time while maintaining the size of a patch that can be measured by a spectrometer or a colorimeter. Although it is possible to output the chart in a plurality of times, it is desirable to avoid splitting the chart in a plurality of times in consideration of variations in characteristics of color materials and image receiving paper.

Further, depending on a printing method for outputting a print, the output density may be slightly changed depending on a position or a peripheral image even in the same print. For example, in the case of a sublimation printer that heats an ink sheet with a thermal head or the like to transfer a dye to an image receiving sheet, the above-described phenomenon occurs due to errors in thermal history correction and resistance value correction of the thermal head. Also, in an ink-jet printer or the like, unevenness of a stripe due to variations in a head greatly affects the output density.

In this case, it is necessary to output the chart for adjusting the characteristics of the image output apparatus at a time, and to eliminate factors affecting the gray balance adjustment or the like as much as possible or to make corrections later. However, no chart has ever addressed such issues.

Therefore, in the present invention, in order to perform gray balance adjustment and gradation characteristic adjustment with respect to an arbitrary image output device with high accuracy, the influence of the characteristics of the recording head or the like is eliminated as much as possible or the correction is performed later. It is an object of the present invention to realize a color chart for calibration of an image processing apparatus that can be performed. It is another object of the present invention to realize a color chart that can be applied to an image output apparatus having a small paper size. It is still another object of the present invention to realize a method of compensating the characteristics of the recording head of the image output device from the measured values of the color chart for calibration and creating color data for calibration of the image output device.
Still another object of the present invention is to realize a calibration color data processing method for deriving correction data of gray balance and gradation characteristics from created color data, and an image processing apparatus capable of performing the methods.

[0013]

That is, the above-mentioned problem is solved by the following constitution. (1) An invention according to claim 1 is a color chart for the purpose of calibrating or adjusting gray balance and gradation characteristics in an image output device, wherein a plurality of the same colors and 9 is a color chart for calibrating an image processing apparatus, in which a patch row composed of patches of the same density is embedded.

According to the present invention, by arranging patches of the same color and the same density at any position on the color chart, it is possible to obtain information on unevenness in correction of characteristics of the image output apparatus, unevenness in print density, and the like. . In addition, it is also possible to determine whether the print can be used as data for calibration.

(2) The color chart for calibrating an image processing apparatus according to claim 1, wherein the patch row is embedded in a peripheral portion and inside of the color chart. .

According to the present invention, by arranging patch rows of the same color and the same density in the periphery and inside of the color chart, it is possible to obtain information on unevenness in correction of characteristics of the image output apparatus, unevenness in print density, and the like. . In addition, it is also possible to determine whether the print can be used as data for calibration.

(3) The invention according to claim 3 is constituted by patches of primary colors and mixed colors of the image processing apparatus having different digital data values, wherein each primary color and mixed colors are constituted by one or more rows of patches. 2. The color chart for calibrating an image processing apparatus according to claim 1, wherein the patch row is embedded at least in an upper part of the chart.

According to the present invention, by forming a patch of a primary color and a mixed color, it is possible to cope with a change in the glue of the ink at the time of the mixed color and a gray shift caused by reverse transfer to an ink sheet or the like. In addition, by combining the patches in a row, the nozzles, thermal heads, and the like used for each color can be fixed, and it becomes easy to deal with density unevenness in each recording unit. In addition, by providing a plurality of columns for each color, it is possible to cope with a change in print size while maintaining the number of output gradations. Furthermore, by inserting such a patch row indicating the print progress direction, it is easy to grasp the positional relationship between the patches, and when the chart is automatically measured, the position data of the chart can be input to the calibrator. Prevention of incorrect insertion of prints and smooth measurement are possible.

(4) The invention according to claim 4 is the color chart for calibrating an image processing apparatus, wherein the patch row is gray or black of high density mixed color or gray of maximum density.

According to the present invention, by arranging gray or black patches, the state of the recording head can be made uniform for all primary colors, and information such as density unevenness of the print can be obtained from the density of each patch. can do. It is also possible to cope with an image processing apparatus that expresses a gradation by dense dots like an ink-jet printer by using high density or black.

(5) According to the fifth aspect of the present invention, the entire color chart can be output by one print, and each patch is constituted by a size of a measurement diameter of a spectrometer or a colorimeter + 2 mm. 2. A color chart for calibrating an image processing apparatus according to claim 1, wherein:

According to the present invention, by outputting the entire chart with one print, it is possible to obtain data irrelevant to changes in the paper surface and changes in the characteristics of the recording head between prints. Also, by configuring the chart so that the size of each patch guarantees about +2 mm of the measurement diameter of the spectrometer or colorimeter, small prints such as A5 and A6, regardless of the large format and normal A3 and A4 sizes, Even
It is possible to obtain color data capable of reducing the influence of density unevenness and the like, and it is possible to adjust the gray balance and the gradation characteristics more favorably for such prints.

(6) The invention according to claim 6 is characterized in that the calibration or adjustment of the gray balance and gradation characteristics in the image processing apparatus is performed using the color chart for image processing apparatus calibration according to claim 1. This is a calibration color data creation method characterized in that color data is created by referring to a column to reduce the influence of print density unevenness and streak unevenness caused by printhead variations and others.

According to the present invention, the calibration and adjustment of the gray balance and the gradation characteristics can be performed more favorably by using the color data in which the influence of the print density unevenness and the stripe unevenness is reduced.

(7) The calibration color data creating method according to claim 6, wherein the color data is created by referring to the measurement data in the patch sequence according to claim 1. is there.

According to the present invention, it is possible to obtain information on unevenness in correction of characteristics of an image output device, unevenness in print density, and the like by referring to measurement data of patch rows having the same color and the same density, and to reduce the influence thereof. The calculated color data can be calculated.

(8) The invention according to claim 8 refers to the patch array when calibrating or adjusting gray balance and gradation characteristics using the color chart for image processing apparatus calibration according to claim 1. Thus, a calibration color data processing method is characterized in that color data is created and calibration is performed while reducing the influence of print density unevenness and stripe unevenness caused by variations in recording heads and other factors.

According to a ninth aspect of the present invention, when the gray balance and gradation characteristics are calibrated or adjusted using the color chart for calibrating the image processing apparatus according to the first aspect, the patch array is referred to. An image processing apparatus characterized in that color data is created and calibration is performed while reducing the influence of print density unevenness and streak unevenness caused by printhead variations and other factors.

According to the present invention, the calibration and adjustment of the gray balance and the gradation characteristics can be performed more favorably by using the color data in which the influence of the print density unevenness and the stripe unevenness is reduced.

(9) The invention according to claim 10 relates to the adjustment of gradation characteristics and gray balance using color data for image processing device calibration, and inverts the current gradation characteristics with respect to the characteristics of the reference. By doing so, it is possible to adjust to an arbitrary gradation characteristic by creating gradation correction data.
And a calibration color data processing method.

The invention according to claim 11 relates to the adjustment of the gradation characteristics and the gray balance using the color data for calibration of the image processing apparatus, and inverts the current gradation characteristics with respect to the reference characteristics. An image processing apparatus comprising: a calibration color data processing unit that adjusts to an arbitrary gradation characteristic by creating gradation correction data.

According to the present invention, the user can easily adjust the gradation characteristics and the gray balance of the image processing apparatus.
The tone characteristics can also be changed to the characteristics desired by the user, so that the image processing apparatus can output a wider range of image modes, and can output an image having a tone according to the user's desire.

(11) According to a twelfth aspect of the present invention, correction data for adjusting gradation characteristics and gray balance is created from the color data created by the color data creating method for calibration according to the sixth aspect. A color data processing method for proofreading, wherein, for each of the primary colors and gray, color data of a combination having the largest difference in shading of each color is used as the color data. .

According to the present invention, by using color data of primary colors and grays, it is possible to perform gradation adjustment according to the actual state of the primary color system or the mixed color system. Further, by using a combination of color data having a large difference due to shading, it is possible to adjust the gradation by using a wide data string having a small influence on the measurement error.

[0035]

Embodiments of the present invention will be specifically described below with reference to the drawings. FIG. 1 shows an image processing apparatus 100 for handling a color chart according to an embodiment of the present invention. Reference numeral 110 denotes a control unit for controlling the entire system, 120 denotes a ROM serving as a data holding unit in which data of a color chart described later is stored, 130 denotes an image processing unit that performs image processing, and 140 denotes a print engine that performs print output. Reference numeral 150 denotes a measuring unit such as a spectrometer or a colorimeter.
Is sent to the control unit 110. 200 is the image processing apparatus 10
This is a print output from 0, and corresponds to a color chart on which a patch is formed in this embodiment.

The image processing apparatus 100 normally receives image data from an external device and
After the image processing is performed at 0, the print engine 140 prints out.

At the time of calibration, the image processing apparatus 100 transmits a color chart, which will be described later, to the measuring means 150.
When calibration or adjustment of gray balance and gradation characteristics is performed by referring to the result and referring to the patch row of the color chart, uneven print density and stripes caused by printhead variations and other factors are obtained. Color data is created and calibrated while reducing the effects of unevenness. Note that an embodiment of the image processing apparatus will be described later in the fifth embodiment.
The embodiment will be described in detail.

Hereinafter, the color chart 200 output from the image processing apparatus 100 will be described. One patch size is 7 mm square, digital data value gradation is 0 to 25
If the interval between digital data values between patches is set to 8 in 5, patches of 33 gradations are required for one color, and 23c
A patch row having a size of about m is obtained. Therefore, when printing in a large size of A4 or more, one row of each primary color and mixed color patch row is sufficient.

The color chart is composed of square or rectangular patches of all primary colors and mixed colors of the image output device. Cy (cyan), Mg (magenta),
If Ye (yellow) is the primary color, Cy patch row 1
0, Mg patch row 20, Ye patch row 30, and gray (including black) patch row 40 which is a mixed color of these.
When an image is output using special colors, these special colors are also included.

The reason for including the mixed color (gray) data is as follows.
It is difficult to apply the setting of single color to the mixed color as it is because the color material paste and density on the receiving paper may change between the single color and the mixed color. This is because it is necessary to make adjustments using a gray chart.

The color chart is configured by arranging patches in a row parallel to the printing direction for each color. this is,
This is for fixing a nozzle, a thermal head, and the like used for each color. In addition, a patch row 210 composed of a plurality of patches of the same color and the same density is embedded in the upper part of the chart, that is, in the portion printed first in the chart.

This situation is shown in FIGS. 2A and 2B. In FIG. 2A, patches of the same color and density are provided in accordance with the positions of the patches of each color. In FIG. 2B, patches of the same color and density in a continuous state are provided so as to cover the positions of the patches of each color.

From the measured values of the patches of the same color and the same density, the distribution of density unevenness and stripe unevenness contributed by the recording head corresponding to each patch can be determined. It is effective to use high-density gray or maximum-density black for the patches of the same color and the same density. This is because density unevenness and streak unevenness can be corrected irrespective of the color of the patch row following this, and the print head state corresponding to each patch should be made uniform during each primary color printing immediately before printing the chart. Because you can do it.

Further, patch rows 220 of the same color and the same density may be arranged along the printing direction of the print around and inside the chart (FIG. 3A). In this case, information such as density unevenness at each patch position in the print progress direction can be obtained from the measured values of the patch row.

It is possible to prepare a plurality of patches for each primary color and mixed color. However, there is a space limitation and it is possible to support all the primary colors. Any concentration may be used. Further, it is even better if gray patch rows of the same density are evenly arranged in the chart along the printing progress direction (see FIG. 3B).

The patch array 220 having the same density in the print direction of printing cannot be used for correction calculation of density unevenness unlike the patch array in the print head direction, but the density in the print direction is visually or measured. You can know the situation of unevenness. It is possible to determine whether or not the print can be used as data for calibration based on the state of the unevenness.

<Second Embodiment: In the case of printing smaller than A4> When printing in a size smaller than A4 (A5, A6, etc.) with respect to the first embodiment, one row of each color is used. In this state, a patch of 33 gradations cannot be printed. In that case, each of these patches is constituted by a plurality of columns for each color.

The arrangement of patch rows of the same color and the same density around and inside the chart is the same as in the first embodiment. However, in the case of the second embodiment, patches having the highest density of each color are arranged in each row as shown in FIG. As shown in FIG. 4 (a), only the column with the highest density may be used, but as shown in FIG. In the case of FIG. 4B, more detailed density unevenness correction can be performed.

The arrangement in each column is arranged so that the intervals and the magnitude relation between the digital data values of adjacent patches are as similar as possible. This is to prevent the recording head from locally vibrating or having heat, thereby causing the influence to be exerted on a nearby portion.

By constructing the chart such that the size of each patch guarantees about +2 mm of the measurement diameter of the spectrometer or the colorimeter, a small size such as A5 or A6 is obtained regardless of the large format and the normal A3 and A4 sizes. Color data with reduced characteristics of the image processing apparatus can be obtained for printing, and better gray balance and gradation characteristics can be adjusted for such printing.

The color chart according to the second embodiment can be applied to a printer of a size smaller than A4 as well as a printer of A4 size or more.

<Third Embodiment: Method of Creating Color Data> An embodiment of a method of creating color data for calibration from the measured values of the chart described above will be described. As the measured value, the spectral reflectance, XYZ value, reflection density, L ^* a ^* b ^*, etc. of each patch can be considered. Here is the gray X
Assume that the YZ value has been obtained as a measurement value. If there is only one patch row for each primary color, the obtained measurement value may be used as it is as the color data. Further, the density unevenness may be corrected using the measurement value of the uniform density portion on the top of the chart. The creation of color data can be basically performed in the same manner in one row or a plurality of rows for each color.

As an example, a method for deriving color data of each color when there are three rows of patches for one color will be described. Assume that measured values of XYZ values as shown in FIG. 5 are obtained for the chart of FIG.

Here, (X ₂₅₅ ^t , Y ₂₅₅ ^t , Z ₂₅₅ ^t ) and (X ₀ ^t , Y ₀ ^t , Z ₀ ^t ) (t = (1), (2), (3)) are The XYZ values at the highest density and the lowest density, respectively, are measured in each row. In this should take ^{_{(X 0 t, Y 0 t}} , Z 0 t) is equal Without unevenness in the state of the paper is the XYZ value of the sheet of receiving paper. However, in reality, there are few ideal papers so there is usually some variation. Then, (X ₀ ^t , Y ₀ ^t , Z ₀ ^t )
The color data (X ′ ₀ , Y ′ ₀ , Z ′ ₀ ) is derived by averaging three values as shown in FIG. However, since the variation of the paper surface is usually negligible compared to the density unevenness of black, a chart as shown in FIG. 4B is output, and a patch of the lowest density portion is used to output (X ′ ₀ , Y ′ _0). , Z ′ ₀ ) may be represented.

(X ₂₅₅ ^t , Y ₂₅₅ ^t , Z ₂₅₅ ^t ) are the XYZ values of the maximum density, which are all the same values in an ideal state where there is no density unevenness or streaks caused by the recording head or the like. Should be taken. However, the values are usually slightly different from each other, and it is necessary to correct the density difference and the like in order to combine the measured values in the three columns into color data of the entire primary color. Therefore,
For example, the other rows are adjusted to match the density of the center row.

In this case, the calculation is performed as shown in an example in FIG. 7, and the following calculation is similarly performed. When each primary color has two rows, the difference in density between the other rows is corrected based on one of the rows. Further, the density unevenness between the colors can be similarly corrected by using the measured values in the uniform color and uniform density patches on the top of the chart. When a plurality of patches of uniform density are inserted as shown in FIG. 4B, the range of data values is further subdivided (0 to 255 in FIG. 4A). ) Is 0-9
5, 95-175, and 175-255).

The color data of each primary color created as described above can be input to various gray balance adjustment routines. <Fourth Embodiment: Color Data Processing Method for Calibration> A color for calibration that simply adjusts the gradation characteristics and the gray balance using the color data obtained in the third embodiment described above. The data processing method will be described below.

Here, the target of the gradation characteristic is an initial setting value unique to the image processing apparatus, a plurality of representative characteristic values such as "photo-tone" and "print-tone", and characteristics required by the user of the apparatus. The value can be freely selected.

In the fourth embodiment, a method of creating correction data for adjusting the above-mentioned gradation characteristics and gray balance from color data of each primary color and mixed color (gray) of the image output device will be described.

The calibration color data of the fourth embodiment
The color data used in the data processing
The primary color and gray color data of the
Reflectance, XYZ value, reflection density, L^*a^*b^*of
Various data are given as examples. Also easy to understand
In order to explain well, the gray gradation characteristic is represented by lightness proportion (L ^*
The case of adjustment to (value proportional) will be described below.

As the color data obtained in the third embodiment, L ^* of each primary color or mixed color is used, and the reference (setting) of the gradation characteristic is a proportional straight line (broken line) shown in FIG.

Assuming that the current gradation characteristic obtained from the color data is curve 1, gradation correction data (curve 2) for correcting the current gradation is obtained by inverting the curve 1 with respect to the reference. be able to.

When the primary color data is used, a combination of the primary color data having a large difference in data value depending on shading, for example, when the XYZ values are used as the color data, the X value and the magenta It is effective and desirable to use the Y value for the primary color of Mg and the X, Y, and Z values for gray. In this case, the gradation characteristic can be corrected using data having a wide range with little influence of a measurement error or the like.

In the gray balance adjustment, similar processing is performed on gray color data values. The reason why gray is used is that the adjustment can be performed according to the actual state of the mixed color system and that the number of measurement points on the chart is reduced to improve the efficiency.

<Fifth Embodiment: Image Processing Apparatus> An example of an image processing apparatus for realizing the above-described first to fourth embodiments will be described below.

FIG. 9 shows an example (basic configuration # 1) of the image processing apparatus, and FIG. 10 shows another example (basic configuration # 2) of the image processing apparatus. Here, the basic configuration # 1 shown in FIG.
0, an example of a configuration in which an image processing device is configured using an image measurement device 500 that measures an output image and an external control device 300 that performs various controls. Also, FIG.
The image output device 400 includes an image measuring unit 408 and various data holding units (a chart data holding unit 402, a gradation correction data holding unit 405, a color data holding unit 409, and a reference gradation data holding unit 411). Is the case.

In the case of the basic configuration # 1 shown in FIG. 9, data of the color chart for calibrating the image processing apparatus is transmitted to the image output apparatus 400 by the external control apparatus 300, and the color chart formed by the image output apparatus 400 is formed. Is measured by the image measuring device 500 based on the color patch position information and the like. In this case, calibration color data is created from the measurement values obtained by the external control device 300, and gray balance correction data and gradation correction data are created based on the above-described calibration color data processing method.

In the case of the basic configuration # 2 shown in FIG. 10, image formation of image data output from the external control device is normally performed. However, when the image output device 400 is switched to the calibration mode by the system setting section 412, the image is formed. Image formation and image measurement of the processing device calibration color chart are performed, and gray balance correction data and gradation correction data are created based on the above-described calibration color data processing method. Although the control unit is not shown in FIG. 10, it is of course possible to control the flow of data in each unit by the control unit.

The gray balance correction data and the gradation correction data created in both the configurations of FIGS. 9 and 10 are held in the external control device 300 or the image output device 400, and the image output device 400 Used in forming.

Next, FIG. 11 shows a processing flow chart when the color data is created in the calibration color data creating method in the image processing apparatus. For the purpose of fine adjustment for correcting temporal deterioration or the like of the image output device 400, if the grayscale correction data already held when outputting the chart image data is enabled and output, the adjustment time can be reduced. .

That is, the image data (chart image data) and position information data of the color chart shown in the above-described embodiment are held in the chart data holding unit 402, and are derived by calculation in the calculation processing unit 410. The obtained gradation correction curve is stored in the gradation correction data storage unit 405, and the image data processing unit 403 performs predetermined image processing based on the chart image data and the gradation correction data (S1 in FIG. 11). Then, the image forming unit 406 forms an image to form a color chart on the image receiving paper (S2 in FIG. 11). This image receiving paper is transported by the image receiving paper transport unit 407 in the direction of the image measuring unit 408 (FIG. 11S).
3). Here, the image measurement unit 408 performs spectral measurement or color measurement, and sends the measurement values to the arithmetic processing unit 410 (FIG. 11).
S4). The arithmetic processing unit 410 creates and outputs color data from the measured values (S6 in FIG. 11).

FIG. 12 is a flowchart of a process performed by the image processing apparatus when generating gradation correction data and gray balance correction data. The color data values created as described above with reference to FIG. 11, the reference tone characteristic data held in the reference tone data holding unit 411, and the current floor held in the tone correction data holding unit 405. Based on the tone correction data and the color data processing method described in the fourth embodiment, the arithmetic processing unit 41
0 creates new gradation correction data. This new gradation correction data is stored in the gradation correction data holding unit 405 and the data is updated.

[0073]

As described above, according to the present invention, the following effects can be obtained.

(1) According to the first aspect of the present invention, by arranging patch rows of the same color and the same density at any position of the color chart, unevenness in correction of characteristics of the image output device, unevenness in print density, etc. You can get information about In addition, it is also possible to determine whether the print can be used as data for calibration.

(2) According to the second aspect of the present invention, by arranging patches of the same color and the same density in the periphery and inside of the color chart, unevenness in correction of characteristics of the image output apparatus, unevenness in print density, etc. You can get information about In addition, it is also possible to determine whether the print can be used as data for calibration.

(3) According to the third aspect of the present invention, by forming a patch of a primary color and a mixed color, it is possible to cope with a change in paste of the ink at the time of the mixed color and a gray shift due to reverse transfer to an ink sheet or the like. be able to. In addition, by combining the patches in a row, the nozzles, thermal heads, and the like used for each color can be fixed, and it becomes easy to deal with density unevenness in each recording unit.
In addition, by providing a plurality of columns for each color, it is possible to cope with a change in print size while maintaining the number of output gradations. Furthermore, by inserting such a patch row indicating the print progress direction, it is easy to grasp the positional relationship between the patches, and when the chart is automatically measured, the position data of the chart can be input to the calibrator. Prevention of incorrect insertion of prints and smooth measurement are possible.

(4) According to the fourth aspect of the invention, by arranging gray or black patches, the state of the recording head can be made uniform for all primary colors, and the print density can be determined based on the density of each patch. Information such as density unevenness can also be obtained. It is also possible to cope with an image processing apparatus that expresses a gradation by dense dots like an ink-jet printer by using high density or black.

(5) According to the fifth aspect of the invention, by outputting the entire chart with one print, data irrelevant to changes in the paper surface and changes in the characteristics of the recording head between prints can be obtained. In addition, the chart can be configured so that the size of each patch guarantees about +2 mm of the measurement diameter of the spectrometer or the colorimeter.
Regardless of the size, even for small prints such as A5 and A6, it is possible to obtain color data capable of reducing the influence of uneven density, etc. It is possible to adjust the gradation characteristics.

(6) According to the sixth aspect of the invention, the use of the color data in which the influence of the print density unevenness and the stripe unevenness is reduced enables the calibration and adjustment of the gray balance and the gradation characteristics to be more excellently performed.

(7) According to the seventh aspect of the present invention, it is possible to obtain information on unevenness in correction of characteristics of the image output apparatus, unevenness in print density, and the like by referring to measurement data of patch rows having the same color and the same density. It is possible to calculate color data in which the influence is reduced.

(8) In the invention according to claims 8 and 9, the use of color data in which the influence of print density unevenness and stripe unevenness has been reduced is used, so that the gray balance and gradation characteristics can be better corrected and corrected. Adjustment is possible.

(9) According to the tenth and eleventh aspects of the present invention, the user can easily adjust the gradation characteristics and the gray balance of the image processing apparatus, and the gradation characteristics are also desired by the user. Since the characteristics can be changed, the image processing apparatus can output a wider range of image modes, and can output an image having a tone according to a user's desire.

(10) According to the twelfth aspect of the present invention, by using the color data of the primary colors and grays, the gradation can be adjusted according to the actual state of the primary color system or the mixed color system. Further, by using a combination of color data having a large difference due to shading, it is possible to adjust the gradation by using a wide data string having a small influence on the measurement error.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of an image processing apparatus according to an embodiment of the present invention.

FIG. 2 is an explanatory diagram showing a state of a color chart according to the first embodiment of the present invention.

FIG. 3 is an explanatory diagram showing a state of a color chart according to the first embodiment of the present invention.

FIG. 4 is an explanatory diagram showing a state of a color chart according to a second embodiment of the present invention.

FIG. 5 is an explanatory diagram showing how color data is derived according to a third embodiment of the present invention.

FIG. 6 is an explanatory diagram showing how color data is derived according to a third embodiment of the present invention.

FIG. 7 is an explanatory diagram illustrating a state of density correction according to a third embodiment of the present invention.

FIG. 8 is an explanatory diagram showing a state of processing according to a fourth embodiment of the present invention.

FIG. 9 is a configuration diagram illustrating an example (basic configuration # 1) of a basic configuration of an image processing apparatus according to a fifth embodiment of the present invention;

FIG. 10 is a configuration diagram illustrating another example (basic configuration # 2) of the basic configuration of the image processing apparatus according to the fifth embodiment of the present invention.

FIG. 11 is a flowchart showing processing at the time of creating color data in a calibration color data creating method in the image processing apparatus according to the fifth embodiment of the present invention.

FIG. 12 is a flowchart of a process when creating gradation correction data and gray balance correction data according to a fifth embodiment of the present invention.

FIG. 13 is an explanatory diagram showing a state of a conventional color chart.

[Explanation of symbols]

10 Patches in Cy (cyan) row 20 Patches in Mg (magenta) row 30 Patches in Ye (yellow) row 40 Patches in Gray (gray) row 200 Color chart 210 Patches of the same color and density (chart of the chart) Upper part) 220 Patches of the same color and density (printing direction)

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification code FI Theme coat ゛ (Reference) B41J 29/46 B41J 3/04 101A 2G020 G01J 3/52 3/20 117 5C077 H04N 1/60 H04N 1/40 D 5C079 1/46 1/46 Z F term (reference) 2C056 EA11 EB27 EB29 EC79 EE03 2C061 AQ04 AQ05 KK18 KK25 KK33 2C065 AB02 AB10 DC32 2C066 AA06 AD01 CD02 CD07 2C262 AA24 AB11 DA09 BB36 FA04 DA05 020 MP08 PP15 PP37 PP43 PP74 PQ18 5C079 LA12 MA10 NA05 NA21 NA29

Claims (12)

[Claims] 1. A color chart for calibrating or adjusting gray balance and gradation characteristics in an image output device, comprising a plurality of patches of the same color and same density at any position of the color chart. A color chart for calibrating an image processing apparatus, wherein a patch array is embedded. 2. A color chart for calibrating an image processing apparatus according to claim 1, wherein said patch row is embedded in a peripheral portion and inside of the color chart. 3. The image processing apparatus comprises patches of primary colors and mixed colors of different digital data values, wherein each of the primary colors and the mixed colors is composed of one or more patch rows. 2. The color chart for calibrating an image processing apparatus according to claim 1, wherein the color chart is embedded. 4. The color chart for image processing apparatus calibration according to claim 1, wherein the patch row is gray or black of high density mixed color or gray of maximum density. 5. The patch according to claim 1, wherein the whole color chart can be output by one print, and each patch is configured to have a size of a measurement diameter of a spectrometer or a colorimeter + 2 mm. 2. A color chart for calibrating the image processing apparatus according to 1. 6. A recording head by referring to the patch row when calibrating or adjusting gray balance and gradation characteristics in an image processing apparatus using the color chart for image processing apparatus calibration according to claim 1. A color data creation method for proofreading, wherein color data is created by reducing the influence of print density unevenness and stripe unevenness caused by variations in print quality and others. 7. The calibration color data creating method according to claim 6, wherein the color data is created by referring to the measurement data in the patch sequence according to claim 1. 8. When calibration or adjustment of gray balance and gradation characteristics is performed using the color chart for image processing apparatus calibration according to claim 1, variations in the print head and other factors are obtained by referring to the patch array. A color data processing method for calibration, wherein color data is created and calibration is performed while reducing the influence of print density unevenness and stripe unevenness caused by the image. 9. When calibrating or adjusting gray balance and gradation characteristics using the color chart for calibrating an image processing apparatus according to claim 1, variations in print heads and other factors are obtained by referring to the patch array. An image processing apparatus, wherein color data is created and calibration is performed while reducing the influence of print density unevenness and streak unevenness caused by the image processing. 10. Concerning adjustment of gradation characteristics and gray balance using color data for image processing device calibration, gradation correction data is created by inverting the current gradation characteristics with respect to reference characteristics. A calibration color data processing method characterized in that the color data can be adjusted to an arbitrary gradation characteristic. 11. Concerning adjustment of gradation characteristics and gray balance using color data for image processing device calibration, gradation correction data is created by inverting the current gradation characteristics with respect to reference characteristics. An image processing apparatus comprising: a calibration color data processing unit that adjusts to an arbitrary gradation characteristic. 12. A calibration color data processing method for creating correction data for adjusting gradation characteristics and gray balance from color data created by the calibration color data creation method according to claim 6. As the color data, for each primary color and gray,
A color data processing method for calibration, characterized by using color data of a combination in which the difference in shade of each color is the largest.