JP6922503B2 - Color adjustment judgment method, color adjustment judgment program, and information processing device - Google Patents

Description

The present invention relates to a color adjustment determination method, a color adjustment determination program, and an information processing apparatus.

An inkjet printing machine known as an image forming apparatus discharges minute droplets of ink from an ink head onto a recording medium to perform recording. In recent years, the inkjet method, which is excellent in terms of cost, has been adopted not only for home and office use but also for commercial printing machines.

Inkjet printers have a color unevenness adjustment technique that reduces the color difference of colors in a printed image. For example, Patent Document 1 discloses a method of obtaining a correction value from an average value of brightness or density of a plurality of gradation patterns for the purpose of correcting the density in a printing machine.

However, Patent Document 1 does not describe color adjustment of an image printed by a plurality of heads in an inkjet device in which a plurality of heads are arranged in the main scanning direction.

Therefore, in view of the above circumstances, an object of the present invention is to provide a color adjustment determination method capable of quantitatively and highly accurately determining whether or not to adjust the color of an image printed by a plurality of heads.

In order to solve the above problems, in one aspect of the present invention, a plurality of heads provided with a plurality of nozzles for discharging a liquid and the recording medium are relatively moved and orthogonal to the relative moving direction. A forming step of ejecting liquid from the plurality of heads arranged in a plurality of directions to form a color adjustment image on a recording medium, and
In the color adjustment image, an acquisition step of acquiring a color measurement value of a portion formed by each of a plurality of heads arranged at different positions in the orthogonal direction, and an acquisition step.
A color difference calculation step for calculating a color difference between at least two locations from the color measurement value for each location, and
A determination step for determining whether or not adjustment of the head that discharges the liquid is necessary using the color difference, and
A plurality of head rows in which the heads are arranged in the relative moving direction are arranged to form a plurality of head rows, and the plurality of head rows are arranged so as to be arranged in a direction orthogonal to the relative moving direction.
Liquids of different colors are discharged from the plurality of heads included in each head row, and images of colors composed of the liquids of different colors are formed on the recording medium.
In the formation step, liquids of different colors are discharged from at least a plurality of heads for each head row to form the color adjustment image on a recording medium.
In the color difference calculation step, the color difference between two locations formed by the plurality of head rows arranged at different positions in the orthogonal direction in the color adjustment image is calculated.
For the color difference, the allowable color difference is stored and stored.
In the determination step, the two images forming the predetermined two locations are formed only when the color difference between the predetermined two locations is larger than the allowable color difference among the color differences between the one or a plurality of the two locations. Judging that it is necessary to adjust one of the head rows,
The step of acquiring the hue angle of the color adjustment image and
The hue angle corresponding to the desired target color, and the hue angle of a portion of the color adjustment image formed by a plurality of heads included in each head row of the two head rows determined to require the adjustment. The hue angle difference calculation step for calculating the hue angle difference, which is the difference between, and
A head row determination step for determining which of the two head rows to adjust the head based on the hue angle difference, and
Provided is a color adjustment determination method.

According to one aspect, it is possible to quantitatively and highly accurately determine whether or not the color of the image printed by the plurality of heads should be adjusted.

The whole view explaining the color measurement and the color adjustment of the color adjustment image on the recording medium formed by a printing system. Overall schematic of the printing system. The schematic diagram which shows an example which arranged the recording head which concerns on embodiment of this invention in a line head configuration. Hardware block diagram of information processing device. Functional block diagram of the information processing device. An overall schematic flow to which the color adjustment determination method of the present invention is applied. Explanatory drawing of a color adjustment image in which a plurality of gradations are set for acquiring color information. Outline flow of manual adjustment of primary color. A detailed flow of manually adjusting a primary color in an information processing apparatus, which is the first embodiment of the present invention. A table for acquiring color measurement values in multiple sections of the head displayed by the information processing device when the color adjustment target is the primary color. It is a primary color adjustment value calculation table displayed by the information processing device, and (a) the color difference between heads, (b) the difference between the average value of the CMYK densities of all the heads and the KCMY densities of each head, and (c) calculation. Adjusted value of the CMYK concentration. Conceptual diagram of adjustment using hue angle in secondary color. Outline flow of manual adjustment of secondary color. A detailed flow of manually adjusting a secondary color in an information processing apparatus, which is a second embodiment of the present invention. A table for acquiring color measurement values in multiple sections of the head displayed by the information processing device when the color adjustment target is a secondary color. In the secondary color adjustment value calculation table displayed by the information processing device, (a) the difference in the hue angle between the heads, (b) the difference between the average value of the hue angles of all the heads and the hue angle of each head, ( c) Specified adjustment target and adjustment direction. Outline flow of color adjustment method in printing system when scanner is given color measurement performance.

Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. In each of the drawings below, the same components may be designated by the same reference numerals and duplicate description may be omitted.

<Overview>
FIG. 1 is an overall explanatory view of a system capable of realizing a color adjustment determination method formed by the printing system of the present invention.

In FIG. 1, a printing system 1 to which a signal is sent from DFE (Digital Front End) 2 forms a color adjustment image (evaluation image, inspection image) on a recording medium P. At this time, ink droplets (droplets) of a predetermined color are ejected from a plurality of heads (see FIG. 3) of the printing mechanism (image forming unit) 120, 160 (see FIG. 2) to produce an image for color adjustment. Is formed on the recording medium, and the recording medium P on which the color adjustment image is formed is output. The ink is an example of a liquid, for example, the liquid may be water-based or oil-based. Further, it may be a photocurable liquid that is cured by UV or the like. Further, it may contain a dye or a pigment.

The operator (operator, customer engineer, etc.) 6 measures (evaluates) the color of the image for color adjustment on the recording medium P by using the colorimeter 5, and acquires the color information.

In the colorimeter 5, the spectral reflectance of each wavelength of the part of the color adjustment image of each color on the recording medium P is obtained, and the color measurement values L * a * b * and the KSMY density information (solid) are used as the color information. Concentration) is measured.

As for the color information, the color measurement value may be obtained directly without passing through the spectral reflectance. Further, the color measurement value may be any value as long as it is not an L * a * b * value but a value in a uniform color space or a value that can be converted into a uniform color space. For example, it may be an L * u * v * value or a CIE XYZ value in CIE Luv. In the following, for convenience, the color measurement values are described as L * a * b * values in CIE Lab, and some explanations with L * u * v * values are added.

Further, the CMYK concentration information may be obtained directly without passing through the spectral reflectance. Further, for example, the L * value in the L * a * b * value or the L * u * v * value of each color may be used as the density. Further, the density associated with the color of the ink is not limited to the information of four colors of K (black), C (cyan), M (magenta), and Y (yellow). For example, if the device is equipped with violet or orange ink, the solid density of violet or orange may also be measured.

The color information measured by the colorimeter 5 is transferred to the information processing device 3. Alternatively, the worker 6 manually inputs the color information measured by the colorimeter 5 into the information processing device 3.

The information processing device 3 calculates the adjustment values of the heads H1Y to H7Y and the like for manual color unevenness adjustment (see FIG. 3) and the head rows HC1 to HC7 from the color information transferred or manually input. indicate. The information processing device 3 is a terminal that can be confirmed and calculated by the worker 6, and is a personal computer, a tablet, a smartphone, another dedicated wireless terminal, or the like.

At this time, a color adjustment determination program capable of executing the color adjustment determination method of the present invention is installed in the information processing apparatus 3 in advance. For example, this color adjustment determination program may be applicable by a CD-ROM4 or the like, or may be distributed by a telecommunication line such as the Internet.

Then, the information processing apparatus 3 transfers the calculated adjustment value to the input unit 201 of the DFE2 or the input unit 101 of the printing system 1. Alternatively, the operator 6 may manually input the adjustment value displayed on the information processing device 3 into the input unit 201 or the input unit 101.

<Printing system>
FIG. 2 shows an overall schematic view of the printing system 1. An inkjet continuous book machine is shown as an example of the printing system 1 according to the embodiment of the present invention.

The printing system 1 includes a paper feeding mechanism 110, a front side printing mechanism 120, a post-drying mechanism 130, an image inspection mechanism 140, a reversing mechanism 150, a back side printing mechanism 160, a post-drying mechanism 170, an image inspection mechanism 180, and a winding device. It is equipped with 190.

The recording medium P made of paper, film, or the like is unwound by the unwinder, which is the paper feeding mechanism 110, and reaches the printing mechanism 120 that prints the front surface (first surface).

A mechanism for applying a treatment liquid (pretreatment liquid) that controls the permeability of ink, for example, may be inserted into the front stage of the printing mechanism 120 on the recording surface of the recording medium P.

The recording medium P that has passed through the printing mechanism 120 passes through the drying mechanism 130, which is a drying device on the front surface side, and passes through the image inspection mechanism 140.

In the present embodiment, an example will be described in which the drying mechanism 130 is a heat drum 131 that performs contact heating from the back surface of the recording medium P. The heating temperature of the heat drum 131 is set to about 50 ° C. to 100 ° C., although it depends on the printing speed and the drying property of the ink. In addition to this, the drying mechanism 130 can be changed to means such as warm air, infrared rays, pressurization, ultraviolet rays, and high frequency, or these mechanisms can be combined. When the ink is a curable ink, it may have a curing mechanism instead of the drying mechanism.

The image inspection mechanism (automatic inspection mechanism) 140 arranged after the drying mechanism 130 performs an automatic inspection for adjusting color unevenness. The image inspection mechanism 140 includes a mechanism for reading color information of an image such as a scanner, and a control mechanism for calculating the read color information. The scanner of the image inspection mechanism (color inspection mechanism) 140 reads the color information of the color adjustment image for automatic adjustment of color unevenness. The color information of the read image is arithmetically processed by either the control mechanism in the image inspection mechanism 140, the control unit in the printing system 1, or DFE2, which is a connected computer. The image inspection mechanism 140 can be used in-line, but may be used offline.

Next, the recording medium P passes through the reversing mechanism 150 that reverses the front and back sides, the printing mechanism 160 that prints the back side (second side), the drying mechanism 170 that dries the back side, and the image inspection mechanism 180.

The color unevenness on the back surface is adjusted by the image inspection mechanism 180 having the same function as the above-mentioned image inspection mechanism 140.

Finally, the recording medium P is wound by a winding device (rewinder) 190, which is an example of a post-processing device that processes the recording medium P after printing. Depending on the content of the post-processing process after printing, a unloading process including a cutting operation of cutting the paper using a cutter may be performed instead of the rewinder.

<Head configuration>
FIG. 3 is a bottom view showing an example in which the recording heads according to the embodiment of the present invention are arranged in a line head configuration. More specifically, it is a top view of the printing mechanisms 120 and 160 shown in FIG. 2 in which a plurality of recording heads are arranged in a staggered pattern as viewed from below.

The recording medium P is conveyed to the printing mechanisms 120 and 160 by a plurality of rollers in the direction of the arrow shown in FIG. Since the printing mechanisms 120 and 160 have almost the same configuration, the printing mechanism 120 will be described below. As shown in FIG. 3, the printing mechanism 120 is provided with a head unit 121 composed of a single-pass inkjet line head.

The head unit 121 ejects ink droplets of basic colors of, for example, black (K), cyan (C), magenta (M), and yellow (Y) to form an image on the recording medium P. Further, the head unit 121 may further be provided with a head that ejects orange or violet, which is a specific color (spot color), or droplets for overcoating that imparts gloss or other treatments.

Since the head unit 121 needs to have a size larger than the width of a recording medium capable of forming an image, it is configured by connecting a plurality of inkjet recording heads in which a large number of nozzle holes (nozzles) 122 for ejecting ink droplets are formed in a row. Has been done. In FIG. 3, the yellow head unit 121Y is composed of a plurality of heads (recording heads) H1Y to H7Y. The magenta head unit 121M, the cyan head unit 121C, and the black head unit 121K are also each composed of a plurality of heads.

The head unit 121 can be retracted (separated) from the path through which the recording medium P is conveyed, and in the retracted state, a maintenance operation for cleaning the nozzle surface and ejecting thickened ink is performed. ..

In each head unit 121, a plurality of inkjet recording heads are arranged on a flat plate-shaped base frame 123 in two rows in a direction orthogonal to the transport direction of the recording medium P, for a total of seven inkjet recording heads 17 in a staggered manner. Both ends of the are fixed to the base frame 123 with screws 124a and 124b.

Further, each inkjet recording head has three positioning surfaces 125a, 125b, 125c (indicated as black circles in this figure) in the main scanning direction (vertical to the recording medium transport direction) and the sub-scanning direction (recording medium transport direction). ) Has been determined.

In the present embodiment, as shown in FIG. 3, inkjet recording head units 121K, 121C, 121M, 121Y for four different colors, for example, K, C, M, and Y, are arranged along the transport direction of the recording medium P. , It is fixed to the main body frame (not shown) with screws.

Since these plurality of heads and nozzles have variations such as ejection characteristics, the printed result causes a color difference between the ejected heads and in the heads. Therefore, it is necessary to adjust the color unevenness to adjust the color unevenness.

Further, a plurality of heads (for example, heads H1Y, H1M, H1C, H1K) arranged side by side in the transport direction can form a secondary color or a tertiary color on a recording medium by ejecting different inks. For convenience, these rows in the transport direction are described as head row HC1, head row HC2, head row HC3, head row HC4, head row HC5, head row HC6, and head row HC7.

<Information processing device>
FIG. 4 is a hardware block diagram of the information processing device 3. As shown in FIG. 4, the information processing device 3 includes a CPU (Central Processing Unit) 31, an HDD (Hard Disk Drive) 32, a RAM (Random Access Memory) 33, a ROM (Read Only Memory) 34, a display device 35, and an input. A device 36, a CD-ROM driver 37, an external interface 38, a communication interface 39, and the like are provided, and each of them is connected to each other by a bus 30.

The CD-ROM driver 37, which is an example of the drive device, is an interface with the CD-ROM 4 which is a detachable recording medium. As a result, the information processing device 3 can read and / or write from a storage medium such as a CD-ROM 4 via the CD-ROM driver 37.

The color adjustment determination program according to the embodiment of the present invention is stored in a storage medium such as a CD-ROM 4 or a USB storage device, and can be read by the information processing device 3 via the CD-ROM driver 37 or the USB driver. Can be done. Alternatively, the color adjustment determination program may be installed on the HDD 32.

The HDD 32 is a non-volatile storage device that stores various programs and data. The stored programs and data include, for example, an information processing system that controls the entire information processing device 3 (for example, an OS (Operating System) that is basic software such as "Windows (registered trademark)" or "UNIX (registered trademark)". In addition, there are applications that provide various functions (for example, "document creation / table creation / editing functions") on an information processing system.

For example, the color adjustment determination program according to the embodiment of the present invention also uses a part of the application of the table creation function and the calculation function. Further, the HDD 32 manages the stored programs and data by a predetermined file system and / or DB (Data Base).

The input device 36 includes a keyboard, a mouse, and the like, and is used to input each operation signal to the information processing device 3.

The external interface 38 is an interface that connects to an external device by a wired connection, and is, for example, a USB driver. In the present embodiment, the external interface 38 can be connected to the colorimeter 5 via wiring (for example, a USB cable) 51. In this case, the color information measured by the colorimeter 5 is transferred to the information processing device 3 via the wiring 51. When the storage medium is USB, the color adjustment determination program may be executed via the external interface 38 which is a USB driver.

The display device 35 includes a display and the like, and includes a processing result (for example, “print result”) by the information processing device 3, a GUI (Graphical User Interface) (for example, “setting screen related to color conversion”), and FIGS. Color information such as color measurement values, values being calculated (KCMY density, hue angle), adjustment values, etc., such as 11, FIG. 15, and FIG. 16 are displayed.

The communication interface 39 is an interface that can be connected to the printing system 1 or DFE2 by wireless connection. The information processing apparatus 3 transfers the calculation result (adjustment target head and adjustment value) calculated based on the acquired color information to the printing system 1 or DFE2 via the communication interface 39.

The ROM 34 is a non-volatile semiconductor memory capable of holding internal data even when the power is turned off. The ROM 34 stores data such as a BIOS (Basic Input / Output System) that is executed when the information processing device 3 is started, system settings of the information processing device 3, and network-related settings.

The RAM 33 is a volatile semiconductor memory (storage device) that temporarily holds programs and data read from the various storage devices.

By executing the program read on the RAM 33, the CPU 31 realizes overall control of the information processing apparatus 3 and operation of various mounted functions.

With the above hardware configuration, the information processing device 3 can perform calculation / transmission processing of adjustment values for color adjustment by, for example, executing a program related to a printer driver or an application read from the HDD 32 onto the RAM 33 by the CPU 31. can.

FIG. 5 is a functional block diagram of the information processing device 3. FIG. 5 shows the functions that can be executed in the hardware configuration of FIG.

The information processing device 3 has, as functional units, a color measurement value acquisition unit 301, a color difference calculation unit 302, a primary color target color difference storage unit 303, a color difference / primary color target color difference comparison unit 304, a secondary color target color difference storage unit 305, and A color difference / secondary color target color difference comparison unit 306 is provided. The color difference / primary color target color difference comparison unit 304 and the color difference / secondary color target color difference comparison unit 306 function as an adjustment presence / absence determination unit that determines whether or not color adjustment is necessary based on the comparison result.

Further, the information processing device 3 includes a density value acquisition unit 311, a concentration average value calculation unit 312, a concentration difference calculation unit 313, an adjustment target head identification unit 314, and an adjustment value setting unit 315.

Further, the information processing device 3 includes a hue angle calculation unit 321, a hue angle average value calculation unit 322, a hue angle difference calculation unit 323, an adjustment target head row identification unit 324, and a head adjustment value setting unit 325.

The information processing device 3 is also provided with an output unit 331 that outputs data. Examples of output include at least display and may further include transmission. When executing the color adjustment determination method, the output unit 331 is realized by the display device 35 shown in FIG. 2 and the communication interface 39 that performs data communication.

Further, the information processing device 3 may be provided with an adjustment value storage unit 332 for storing the adjustment value.

In such an information processing device 3, the color measurement value acquisition unit 301 and the density value acquisition unit 311 are color information acquisition units that acquire color information from the colorimeter 5.

In FIG. 5, the functional units 31 to 315 related to the K, C, M, and Y densities (solid densities) are used for adjusting the primary color, and the functional units 321 to 325 related to the hue angle are used for the secondary color, the tertiary color, or the primary color. Applicable.

Here, the primary color is a single color generated on the recording medium by one kind of ink, and is, for example, yellow (Y), magenta (M), cyan (C), and black (K). On the other hand, the secondary color is a color generated on a recording medium by ejecting two or more types of ink from two or more types of heads, and is, for example, R (red), G (green), and B (blue). be. Of course, if the device is equipped with inks of colors such as R (red), G (green), and B (blue), R (red), G (green), B (blue), etc. are also primary colors. .. The secondary color is not a concept limited to a specific color, but refers to a color generated on a recording medium using two types of ink.

Hereinafter, the functions of the internal components will be described in detail together with FIGS. 6 to 11.

<Outline flow>
FIG. 6 shows a schematic flow to which the color adjustment determination method including the color measurement step of the present invention is applied. In the color adjustment step, as shown in FIG. 6, the automatic adjustment is first performed in step S1, and then the manual adjustment is performed in step S2 to end the color adjustment step (step S3).

Here, since the color difference between nozzles in the same head is relatively small, it is often possible to make adjustments by automatic adjustment. However, since the scanning sensitivity of the scanner to the gradation is not sufficient, even if the automatic adjustment shown in S1 is repeated, the color difference between the heads, which tends to increase the color difference, cannot be sufficiently read, and the adjustment value cannot be predicted accurately. , Difficult to adjust. Below, the color difference between images formed by a plurality of heads is described as a color difference between heads.

Therefore, in order to adjust the color unevenness between the heads remaining after the automatic adjustment in S1, the color difference between the heads is adjusted by manual adjustment in S2. Since the manual adjustment increases the burden on the operator, it is preferable to manually adjust the color difference after adjusting the unevenness in the head by automatic adjustment.

In this way, automatic adjustment mainly performs color adjustment within the same head, and manual adjustment performs color adjustment between different heads.

In the conventional manual adjustment, the operator visually determines whether the color adjustment of the head should be performed. Therefore, the accuracy of adjustment depends on the skill of the operator, and it may not be possible to achieve the target color difference between heads. In addition, it may take a very long time to achieve the color difference between the target heads.

Therefore, in the color adjustment determination method according to the embodiment of the present invention, the information processing apparatus 3 executes a process of determining whether to perform color adjustment on the head in the manual adjustment process shown in S2. ..

<Example of image for color adjustment>
Here, in the detailed flow of FIGS. 8, 9, 13, and 14 described later in the automatic adjustment of S1 in FIG. 6 and the manual adjustment of S2, in the color information acquisition step (color measurement step, color density measurement step). The color adjustment image used will be described.

FIG. 7 shows an explanatory diagram of a color adjustment image in which a plurality of gradations are set for acquiring color information. In FIG. 7, (a) is gradation data for color adjustment, which is the original image data for printing in the printing system 1. (B) is a gradation image for color adjustment (color adjustment gradation chart) on a recording medium printed based on the gradation data. (C) is a gradation image for color confirmation (color confirmation gradation chart) on the recording medium after adjustment. A gradation image for color adjustment (gradation chart for color adjustment) is an example of an image for color adjustment. The color confirmation gradation image (color confirmation gradation chart) is an example of a color confirmation image.

Note that FIG. 3 shows an example in which seven heads H1 to H7 are arranged in each of the head units 121Y, 121M, 121C, and 121K, but in this example, the heads for each color are 5 of H1 to H5, respectively. One example will be described.

7 (a) to 7 (c) show gradations using, for example, black (K). In the gradation data shown in FIG. 7A, an example is shown in which the gradation data is filled with five levels (steps) of 20%, 40%, 60%, 80%, and 100% from the bottom.

Here, the KSMY density in the primary color which is a single color (single color) is also referred to as CMYK density, Tone, solid density, film thickness, ink thickness, and component density value. It expresses the shade of color according to the degree. As described above, the gradation data of the primary color is not limited to the four colors of CCMY. When inks such as R (red), G (green), and B (blue) are mounted, the gradation data of those colors is also used.

Then, for example, the black recording heads H1K to H5K output a gradation image for color adjustment (color adjustment gradation chart) based on the set five-step gradation data. At this time, as shown in FIG. 7B, the color (density) of the output image may be different for each head.

As shown in S2 of FIG. 6 described above, the color is adjusted by manual adjustment so as to reduce the variation between the heads. Specifically, as shown in FIG. 7B, the portion having a low density (for example, head H4K) in the color adjustment gradation chart is shifted to a higher gradation, and the portion having a low density (for example, head H2K) is more. The setting is changed in the printing system 1 so as to shift to a lower gradation.

By changing the above settings, the adjusted output chart (color confirmation gradation chart) is made to have substantially the same color as that of FIG. 7 (a) as shown in FIG. 7 (c).

Here, FIG. 7A shows an example of output from the black recording heads H1K to H5K, but C (cyan) and M are monochromatic ink colors for examining the primary color in the same layout. It also outputs (magenta) and Y (yellow) color adjustment gradation charts.

When investigating a secondary color in which two types of ink are mixed, for example, R (red), G (green), B (blue) are used based on the gradation data as shown in FIG. 7 (a). Outputs the gradation chart for color adjustment. As an example of the RGB chart, it is preferable that the pattern contains the primary colors constituting each in the same proportion.

Although FIG. 7 shows an example in which the gradation is in five stages, another example of the gradation chart for color adjustment is output based on the gradation data in which the interval of gradation 0% to 100% is set to every 10%. You may use the chart. It is possible to adjust color unevenness with high accuracy by outputting a gradation chart for color adjustment for 10 steps of 10%, 20%, ..., 100% and measuring all 10 steps. be.

On the contrary, as an example of the gradation chart for color adjustment, a chart in which the number of gradations to be output is further reduced can be mentioned. For example, in many cases, in a certain gradation section, the color change (gradation-density characteristic, etc.) with respect to the gradation is linear, so select several typical gradations and the rest are the same as the representative points. It is possible to reflect the adjustment value. For example, by dividing into three groups such as 10% to 50%, 60% to 80%, and 90% to 100%, and using the adjustment values obtained by 50%, 80%, and 100% as the adjustment values of the same group, It is possible to reduce the number of color measurement points.

Alternatively, color information may be obtained by outputting a chart of the number of steps of an arbitrary gradation as an image to be printed. For example, any gradation to be adjusted can be adjusted to the control adjustment point of DFE2 or the like, and can be adjusted in the optimum number of steps for the hardware.

Further, the gradation step setting of the image to be printed may be set in the gradation region where the gradation-color characteristic becomes linear.

Based on the gradation data (see FIG. 7A) in which the area is set in this way, the color adjustment gradation chart (see FIG. 7B) printed on the recording medium P is displayed on the colorimeter 5 Use to measure the color and get the color information. At this time, for example, in the case of K (black), the color measurement values of the portions (head units) formed by each of the plurality of heads H1K, H2K, H3K, H4K, and H5K are acquired. Each of the rows in FIG. 7B is a region formed by a plurality of heads H1K, H2K, H3K, H4K, and H5K having the same gradation information of the original image data having the same gradation.

As the color information for calculating the adjustment value, the color information acquired when measuring the color with the colorimeter 5 includes at least the color measurement value (L * a * b *) in the case of the primary color, and further accuracy. It is preferable to acquire various color information such as density and XYZ color system in order to improve the color.

On the other hand, in the case of a secondary color, it is sufficient to have a color measurement value (L * a * b *) as color information, and the hue angle is obtained from the color measurement value and used for calculating the adjustment value. Again, the color measurement values may be L * u * v * values or CIE XYZ values. Further, the hue angle may not be obtained from the colorimetric value, but the hue angle hab (CIE Lab hue angle) or huv (CIE Luv hue angle) may be obtained directly as color information.

Using the color information of the color adjustment image output on the recording medium as described above, the adjustment value used for manual adjustment is calculated in the information processing apparatus.

In FIG. 7, the measurement unit for acquiring the color information is an example of adjusting the head unit, but the adjustment unit can be any one. Further, in order to reduce the influence of variation in the measurement result depending on the printing position, it is more preferable to measure a plurality of points in the same head.

For example, it may be a nozzle unit or a block unit (interval unit) that divides a nozzle into blocks. As an example of the section unit, since the characteristics are different between both ends and the center of the head, as shown in FIG. Can be adjusted.

<Manual adjustment of primary color>
FIG. 8 shows a schematic flow of manual adjustment of the primary color according to the first embodiment (control example) of the present invention.

When the operator 6 gives an instruction to start adjustment in step S21, the printing system 1 obtains color information for each gradation and each head for each head and nozzle, so that FIG. 7A shows. Based on the gradation data as shown, a color adjustment image (color adjustment gradation chart) is printed (formation step).

In step S22, the color adjustment image (color adjustment gradation chart) printed in S21 as shown in FIG. 7B is measured by the colorimeter 5 to acquire color information.

In step S23, the information processing device 3 acquires the color information, and based on the color information, sets the adjustment value for the head that needs to be adjusted. Details of the adjustment value setting method will be described later together with FIG.

In step S24, the information processing apparatus 3 transfers the set adjustment value to the printing system 1 (or DFE2). Alternatively, the operator 6 manually inputs the adjustment value displayed on the information processing apparatus 3 into the input unit 101 or 201 of the printing system 1 (or DFE2).

In step S25, in the printing system 1 (or DFE2), the setting is changed so that the adjustment value of the head is reflected for the nozzle group of one head for the head to be adjusted. As an example of changing the setting, the head drive voltage at the head to be adjusted (the shape of the drive waveform applied to the piezoelectric element, which is the drive member that drives the ink ejection operation at the head) is changed from the other head drive voltage. , There is a method of controlling the dot diameter of the ink droplet. Alternatively, in order to control the dot diameter, the head may be moved up and down to change the flight distance in ejecting ink droplets. Alternatively, the gradation may be set for each head by image processing. Further, the gradation and density of the head may be adjusted by another adjustment method.

Then, in step S26, the printing system 1 prints a color confirmation image (color confirmation gradation chart) for grasping the color information for each gradation in the setting state in which the adjustment value is reflected.

In step S27, the color confirmation gradation chart that reflects the adjustment for each head, which was output in S26, is measured by the colorimeter 5, and the color information is acquired.

In step S28, the color difference between the heads in the color confirmation image (color confirmation gradation chart) measured by the information processing apparatus 3 in S27 is smaller than the target color difference (allowable target range of the color difference). Then (Yes in S28), the manual adjustment is completed. In this way, the obtained adjustment value is reflected, and it is determined from the adjusted image whether or not readjustment is necessary.

If the color difference between the heads is larger than the target color difference and readjustment is necessary (No in S28), the process returns to the step of setting the adjustment value (S23), and the adjustment is further repeated until Yes in S28. ..

In S28, the determination as to whether or not to repeat the adjustment was made based on a specific target color difference. However, the worker 6 printed, for example, the adjusted color confirmation image (color confirmation gradation chart). ) And the color adjustment image (color adjustment gradation chart) before adjustment may be visually judged.

Further, here, an example of outputting the color confirmation gradation chart again has been described. However, when the color difference between all the heads is smaller than the target color difference in S33 of FIG. 9, which will be described later, the manual adjustment value setting step of S23 of FIG. In, the flow may be terminated without setting a new adjustment value and outputting the color confirmation gradation chart as shown by the dotted line.

<Calculation of primary color adjustment value by information processing device>
FIG. 9 shows a detailed flow of manually adjusting the primary color in the information processing apparatus 3 executed in step S23 of FIG. FIG. 9 is a detailed flow of manually adjusting the primary color in the information processing apparatus 3 according to the first embodiment of the present invention.

Further, FIG. 10 shows a color measurement value acquisition table in a plurality of sections (positions) of the head displayed by the information processing apparatus 3 when the color adjustment target is the primary color. 11A and 11B are a primary color adjustment value calculation table displayed by the information processing apparatus 3, in which FIG. 11A is a color difference between heads, and FIG. The difference, (c), indicates the specified adjustment target head and the adjustment value of the set KCMY concentration.

Here, the color measurement value (L * a * b * value) reflects the apparent darkness in the L value (density) and the difference in hue in the a * and b * values. The primary colors K, C, M, and Y produced using one type of ink have the same hue (a * value, b * value) if the same ink is used, so adjust the density. You just have to.

Therefore, as shown in FIGS. 9 and 11, in the color adjustment determination method for determining which head is to be adjusted for the color adjustment of each of the primary color KCMY, the color measurement value (L * a * b * value) is used. It is efficient to determine the presence or absence of adjustment using the above and calculate the adjustment value using the KCMY concentration.

As shown in FIG. 10, in the step of acquiring the color measurement value, for each color head included in each head row, color information for each gradation is acquired for each of a plurality of sections of the image formed by each head. There is.

FIG. 11 shows an example in which an adjustment value is set by using a value for each head obtained by averaging each section as a desired target color for a specific gradation.

In the adjustment value calculation flow shown in FIG. 9, a case where the target color (target color), which is the target value to be approached at the time of adjustment, is used as the average color information (KCMY density) of all heads will be described as an example. ..

In step S31, the color measurement value acquisition unit 301 (see FIG. 5) of the information processing apparatus 3 acquires the color information detected by the colorimeter 5 for each gradation (color measurement value acquisition step, density acquisition step). .. When the information processing device 3 acquires color information, it is preferable that the value detected by the colorimeter 5 for the output color adjustment gradation chart is transferred and automatically taken into the information processing device 3. Alternatively, the operator 6 may manually input the measurement result of the colorimeter 5. Here, in S31, the color measurement value (L * a * b *) and the density (KCMY density) of each head KSMY of the plurality of heads are acquired as the color information. As described above, the density (KCMY density) may not be acquired and may be calculated from the color measurement value.

For example, in the information processing apparatus 3, the acquired values of each color (K, C, M, Y) transferred or manually input are displayed in a table as shown in FIG.

In step S32, the color difference calculation unit 302 of the information processing device 3 calculates the color difference between adjacent heads (pairs and two locations) from the color measurement value (color difference calculation step). Here, the adjacent heads are heads arranged in a direction orthogonal to the transport direction of the recording medium, such as H1Y and H2Y in FIG. For example, in the information processing apparatus 3, the calculated color difference between the heads is displayed in a table as shown in FIG. 11A. Here, for example, the color difference when the gradation shown in FIG. 10 is 60% is displayed.

Here, the color difference ΔE, which represents the color difference, is represented by the distance between two points in the L * a * b * color space.
The color difference is represented by ΔE (ΔE = [(ΔL *) 2+ (Δa *) 2+ (Δb *) 2] 1/2).

In this embodiment, ΔE is described by ΔE * ab based on L * a * b *, but ΔE is ΔE * uv (ΔE * uv ＝ [(ΔL *) 2+) consisting of L * u * v * values. It may be (Δu *) 2+ (Δv *) 2] 1/2).

In step S33, the color difference / primary color target color difference comparison unit 304 of the information processing device 3 compares the color difference between the heads with the target color difference (target range). For example, the target color difference stored in the primary color target color difference storage unit 303 of the information processing device 3 is 1.5. At this time, in the color difference between the heads shown in the table of FIG. 11A, the color difference between the heads H1Y and H2Y in Yellow (Y) shown by the underlined portion and the color difference between the heads H4C and H5C in Cyan (C). However, the target color difference is exceeded. Therefore, these head pairs (H1Y and H2Y in Y, H4C and H5C in C) become adjustment candidate head pairs for manual adjustment (two heads determined to require adjustment), and the subsequent manual adjustment step is performed. It will be implemented.

This S33 is a determination step for determining whether or not head adjustment is necessary using the color difference. If at least one of the calculated color differences between the heads is larger than the target color difference (Yes in S33), the process proceeds to step S34.

On the other hand, if all the obtained color differences between the heads are smaller than the target color difference (No in S33), the process proceeds to S3 in FIG. 6 without performing the subsequent manual adjustment, and the entire color adjustment process is completed. As a result, the adjustment time can be shortened. In addition, over-adjustment can be prevented.

In step S34, the information processing device 3 calculates the average color measurement value of all the heads. Specifically, the density value acquisition unit 311 acquires the CMYK densities in the color adjustment images (color adjustment gradation charts) created by the plurality of heads measured by the colorimeter 5, respectively, and calculates the density average value. Unit 312 calculates the average KCMY density of the KCMY densities of all the heads.

In step S35, the density difference calculation unit 313 of the information processing apparatus 3 calculates the density difference, which is the difference in the density of each head, from the average density of all the heads (concentration difference calculation step). For example, in FIG. 11B, the difference between the average KCMY density of all the print areas of all the heads (corresponding to the target color) and the KCMY density of each head is calculated in FIG. 11 (b) in the information processing apparatus 3. It is displayed in a table as in b).

Although FIG. 11B shows the difference between the KCMY density and the average KCMY density for all the heads, only the pair to be adjusted specified by the color difference between the heads of S34 has the average KCMY density. You may compare. Further, although the difference in the density of each head is calculated from the average density in the above, it may be calculated by using the difference between the color measurement values instead of the density.

In step S36, the adjustment target head specifying unit 314 of the information processing device 3 identifies the head having the larger difference as the adjustment target head (head determination step). Specifically, the difference between the average density (in this example, the average density of KSMY) and the density of the pair of heads to be adjusted (KSMY density) is obtained, and which head has the larger difference from the average density is compared. , Select the head to be adjusted to adjust the head with the larger difference from the average density. Further, as described above, the head to be adjusted may be selected by using the color measurement value.

For example, in FIG. 11B, when the values of the head H1Y and the head H2Y are compared in Yellow (Y), H2Y is farther from 0 (average KSMY concentration), and in Cyan (C), the heads H4C and H5C are separated. Comparing the values, H5C is farther apart. Therefore, the yellow (Y) head H1Y and the Cyan (C) head H5C, which are underlined, are specified as adjustment targets.

By adjusting the head having the larger difference so as to be closer to the target color, the target color can be achieved with a small number of repetitions.

In step S37, the adjustment value setting unit 315 of the information processing apparatus 3 sets the adjustment value so that the specified (selected) head approaches the average density.

Then, in step S38, on the display device 35 of the information processing device 3, as shown in FIG. 11C, the adjustment value is displayed so that the head to be adjusted, the color of the adjustment target, and the adjustment direction can be known on the table. Will be done. Here, the set adjustment value may be directly output to the printing system 1 or DFE2 by the output unit 331.

In step S39, the head adjustment value (KCMY density) is memorized, and the process ends.

In this way, the color difference between the heads and the color difference between the target heads are compared, and if it is smaller than the target, the adjustment is completed, and if it is larger, the adjustment value is recalculated and the readjustment process is repeated.

Further, in the flow of FIG. 9, an example of adjusting in units of heads is given at the time of adjustment, but the unit of adjustment can be arbitrary.

For example, when the average color measurement value of a plurality of sections is used as the color measurement value used for the judgment of adjustment, when the color difference is larger than an arbitrary target color difference (target color difference) when selecting the section to be adjusted. , Adjust only that section.

Here, in the examples of FIGS. 9 and 11, an example in which the KCMY density corresponding to the average color is used as the target color (desired target color) at the time of adjustment has been described. In this control, even if there is a color that is extremely far from the target color, it is possible to prevent an unadjustable section from occurring by adjusting toward the average value.

However, as the target color for adjustment when adjusting color unevenness, the maximum or minimum color measurement value (brightest point or darkest point) of the entire print area is calculated, and the KCMY density is used as the target value. May be good. This makes it possible to prevent the image from becoming too light or too dark when using lightness or density.

Further, it is also possible to specify a specific color as the target color for adjustment when adjusting the color unevenness. For example, if it is assumed that a specific color is printed continuously with a national flag, company name, catchphrase, etc., adjusting the KCMY density closer to the specific color will make the actual image more efficient. Color adjustment becomes easier when printing. In this case, the color is stored in advance, for example, in S34, the KCMY density of the specific color which is the target color is called, and in S35, the difference between the KCMY density of the specific color and the KCMY density of each head. Should be calculated.

In the primary color, it is preferable to use the relative density when approaching the density corresponding to the average color, the brightest maximum density, and the darkest minimum density, and to use the absolute density when approaching a specific color.

Further, although the adjustment is performed for a predetermined gradation in FIG. 11, it is preferable to determine whether the head adjustment is necessary for each of the plurality of gradations. However, instead of a gradation chart including images of a plurality of gradations, an image having only a predetermined gradation may be output, and the presence or absence of adjustment may be determined as an image for color adjustment.

In the above, the case of the primary color was explained, but in the case of the secondary color, it is impossible to adjust the density and brightness, so it is more difficult to deal with it only by the adjustment by the automatic inspection using the scanner, and the color tone is correct. There was a high need to rely on manual adjustments to make adjustments.

In addition, since it is necessary to determine which of the constituent colors should be adjusted and how much to adjust, there is a problem that the difficulty of manual adjustment is further increased as compared with the case of the primary color. Therefore, the following color adjustment of the secondary color is executed.

<Adjustment of secondary color (second embodiment)>
FIG. 12 shows a conceptual diagram of adjustment using the hue angle in the secondary color.

In the L * a * b * color space, the L * axis is the brightness axis that represents brightness, and when it is close to 0, it indicates black, and when it is close to 100, it indicates white. The a * axis represents green to red, minus indicates green, and plus indicates red. The b * axis represents blue to yellow, minus indicates blue, and plus indicates yellow. The larger the numerical value on both the a * axis and b * axis, the stronger the color (higher saturation).

As described above, the color difference ΔE, which represents the color difference, is represented by the distance between two points on a uniform color space such as the L * a * b * color space.

In the color adjustment of this embodiment, since a secondary color that does not use black is premised, the adjustment is performed using the hue angle difference ΔH, assuming that the lightness L is equal.

For example, in the case of CIE Lab, the hue angle is calculated by hab = tan-1 (b * / a *) [degree]. hab is the angle from the + a * axis of CIE Lab. FIG. 12 is a diagram showing a hue angle in CIE Lab.

In the case of CIE Luv, it is calculated by huv = tan-1 (v * / u *) [degree]. Huv is the angle from the + u * axis of CIE Luv.

Using this difference in hue angle, for example, in CIE Lab, the balance of the two colors of ink ejected on the recording medium P, which affects the values of a * and b *, is adjusted. Hereinafter, the description will be given based on the hue angle in CIE Lab.

<Manual adjustment flow of secondary color>
FIG. 13 shows a schematic flow of manual adjustment of the secondary color according to the second embodiment (control example) of the present invention.

The difference in this embodiment is that the color adjustment image (color adjustment gradation chart) to be adjusted is not the primary color (KCMY) but the secondary color (RGB). Therefore, the flow of FIG. 13 prints an image reflecting two types of adjustment value candidates when setting the adjustment value in steps S240 and S250 as compared with the flow of the primary color of FIG. 8, and step S271 The difference is that the adjustment value that has the smaller difference from the target color is selected. The differences will be described in detail with FIG.

The color adjustment image (color adjustment gradation chart) used in this embodiment has the same layout as that shown in FIG. 7 (a), and examples of secondary colors are R (red), G (green), and B. Outputs a (blue) three-color chart. It is assumed that this RGB is a pattern in which the primary colors constituting each of them are contained in the same proportion. Even in the case of the secondary color, the traversal of FIG. 7B has the same gradation information of the original image data. Further, the column of FIG. 7B is formed by the respective head rows HC, and the regions formed by the head rows HC1, HC2, HC3, HC4, and HC5 are arranged in the horizontal direction.

Here, the outline of the calculation of the two types of adjustment values to be output will be described by returning to FIG. Which of the adjustment value of the first color and the adjustment value of the second color constituting the secondary color is set to + can be obtained from the relationship between the hue angle before adjustment and the target hue angle.

In FIG. 12, Red, which is a secondary color generated on a recording medium by the inks of the primary color Yellow and the primary color Magenta, will be described as an example. For example, suppose that the hue of Red before adjustment is closer to the Yellow side than the target hue. That is, it is assumed that the hue angle is larger than the target hue angle.

In this case, we want to make the adjusted hue closer to Magenta, so when adjusting the adjustment value, we set Magenta to + (plus) (increase) the gradation chart for color confirmation and Yellow to- (minus) ( (Reduce) Outputs a gradation chart for color confirmation.

When using a secondary color, even if the direction for changing the angle can be calculated, it is often difficult to determine which of the two colors should be adjusted. Therefore, if you want to get closer to a predetermined color, you can adjust it more accurately by trying both the adjustment value of that one color adjusted to + (plus) and the value adjusted to the other color to- (minus). The value can be calculated.

Further, here, an example in which the gradation chart for color confirmation is output again has been described in S240 and later in FIG. 13, but when the color difference between all the heads is smaller than the target color difference in S43 in FIG. 14, which will be described later, FIG. The flow may be terminated without setting a new adjustment value in the manual adjustment value setting step of S23 and without outputting the color confirmation gradation chart as shown by the dotted line.

In addition, which of the adjustment value of the first color and the adjustment value of the second color constituting the secondary color should be set to + has the hue angle of the single color ink as information, and the target hue angle is before the adjustment. The proportion of ink closer to the hue angle may be set to be larger. However, in the case of Red, for example, if the hue angle is larger than the target value, it is known in advance that it should be closer to Magenta, so it is decided to change the ink ratio without using the hue angle information of the single color ink. You may.

Further, a description of the adjustment of Green shown in FIG. 12 will be described later together with FIG.

<Calculation of secondary color adjustment value by information processing device>
FIG. 14 shows a detailed flow of calculating the manual adjustment value of the secondary color in the information processing apparatus 3 according to the second embodiment of the present invention.

FIG. 15 shows a color measurement value acquisition table in a plurality of sections of the head displayed by the information processing apparatus 3 when the color adjustment target is a secondary color. 16A and 16B are a secondary color adjustment value calculation table displayed by the information processing apparatus 3, in which FIG. 16A shows the difference in hue angles between head rows, and FIG. 16B shows the average value of hue angles of all head rows. The difference between (c) and (c) indicates the specified adjustment target head row and the set adjustment value.

As shown in FIG. 15, in the step of acquiring the color measurement value, the color information for each gradation is acquired for each of a plurality of sections of the image formed by each head row. As an example, as shown in FIG. 16, an example is shown in which an adjustment value is set using a value for each head row obtained by averaging each section for a specific gradation.

In step S41 of FIG. 14, the color measurement value acquisition unit 301 (see FIG. 5) of the information processing apparatus 3 uses the color measurement value (L * a * b *) as the color information detected by the colorimeter 5. Acquire (acquisition step). For example, in the information processing apparatus 3, the color measurement value (L * a * b *) and the CMYK density, which are the acquired values of each secondary color (R, G, B) transferred or manually input, are It is displayed in a table as shown in FIG. In this embodiment, the CMYK density information does not have to be acquired, but it may be used for color adjustment at the time of adjustment in step S48 described later.

In step S42, the color difference calculation unit 302 of the information processing device 3 calculates the color difference between adjacent head rows (between two locations) (color difference calculation step). Here, the adjacent head rows are head rows arranged in a direction orthogonal to the transport direction of the recording medium, such as HC1 and HC2 in FIG. For example, in the information processing apparatus 3, the color difference ΔE between the head rows in the secondary color in the printing system 1 including the five head rows HC1 to HC5 is displayed in a table as shown in FIG. 16A.

The secondary color is formed by ejection from a plurality of heads in a row in the transport direction. Therefore, when determining the adjustment based on the secondary color, the color difference used for the determination is the color difference between the images formed by the head row. The color difference between images formed by a plurality of head rows is described as the color difference between head rows.

In step S43, the color difference / secondary color target color difference comparison unit 306 of the information processing device 3 compares the color difference between the head rows with the target color difference.

In FIG. 16A, for example, the target of the color difference between the head rows in the secondary color stored in the secondary color target color difference storage unit 305 is ΔE <2.5. In this case, the color difference between the head rows HC3 and HC4 and the color difference between the head rows HC4 and HC5, which are the underlined portions, is a combination of head rows larger than the target ΔE (two types of “two head rows”). These head row pairs (HC3 and HC4, HC4 and HC5) are adjustment candidate head row pairs for manual adjustment.

This S43 is a determination step for determining whether or not adjustment of the head row is necessary using the color difference. If at least one of the calculated color differences between the head rows is larger than the target (YES in S43), that is, if there is a pair of head rows to be manually adjusted, the process proceeds to step S44. move on.

On the other hand, if the color difference between the head rows is smaller than the target color difference (No in S43), the subsequent manual color adjustment is not performed, the process proceeds to S3 of FIG. 6, and the entire color adjustment process is completed.

In the case of Yes in S43, in step S44, the hue angle calculation unit 321 of the information processing apparatus 3 calculates the hue angle of the secondary color formed by using the inks of a plurality of colors for each of the head rows HC1 to HC5 ( Hue angle acquisition step).

Then, in step S45, the hue angle average value calculation unit 322 calculates the average hue angle of a predetermined secondary color formed by all the head rows.

Subsequently, in step S46, the hue angle difference calculation unit 323 obtains the difference between the average hue angle and the hue angle of each head (hue angle difference calculation step). For example, the hue angle difference which is the result of calculating the difference between the secondary color average hue angle (corresponding to the target color) formed in all the head rows and the hue angle of the secondary color formed in each head row. ΔH is displayed in a table in the information processing apparatus 3 as shown in FIG. 16 (b).

In step S47, the adjustment target head row specifying unit 324 selects the head row having the larger difference in hue angle from the average value of the hue angle in the pair of head rows for which the color difference has been calculated as the head row to be adjusted. (Identify) (Head row determination step).

For example, in the table shown in FIG. 16B, when the hue angles for Green (G) are compared, the difference between the head row HC3 and the head row HC4 is larger in HC4 from the average hue angle, and the head rows HC4 and HC5 However, HC4 has a larger difference from the average hue angle. Therefore, a plurality of heads forming Green in the underlined head row HC4 are to be adjusted.

Here, the value of the hue angle of the image formed by the head row HC4 is smaller than the average hue angle. In other words, it is close to yellow. Therefore, in FIG. 16C, the adjustment value (adjustment direction) is such that the formation result of Green in the predetermined plurality of heads of the head row HC4 is in the direction approaching the average hue angle (direction in which the hue angle is increased). Enter "+" for Green as. Since "+" means that the angle from the + a * axis is increased, the proportion of cyan ink in the ink forming Green is increased.

In step S47, a plurality of heads in the head row to be adjusted and the direction of adjustment are determined.

Based on the setting of the adjustment value setting unit 325 in step S48, in steps S240 to S260 of FIG. 13, the color confirmation in which the adjustment value of the head that ejects the first color ink constituting the secondary color is set to + (plus). A gradation chart for color confirmation and a gradation chart for color confirmation in which the adjustment value of the head for ejecting the second color ink is set to − (minus) are output.

For example, as shown in FIG. 16C, in order to increase (make +) the hue angle of the secondary color Green formed by the head row HC4, the adjustment value of Cyan's ink is adjusted as shown in FIG. Set it to + (plus) or set the adjustment value of Yellow ink to- (minus). For example, in the hue angle corresponding to the target color (Green (target)) and the hue angle before adjustment (Green (before adjustment)), the head that ejects the ink closer to the hue angle corresponding to the target color (first). The head) is the head H4C of the first color (Cyan), and the head (second head) that ejects ink closer to the hue angle corresponding to the color before adjustment is the head H4Y of the second color (Yellow).

At this time, as the color confirmation image, an image for increasing the discharge amount of the head H4C of the first color (Cyan) (image for the first color confirmation) and an image for decreasing the discharge amount of the head H4Y of the second color (Yellow) (first image). Both of the color confirmation images of 2) are output. For this purpose, the setting in which the adjustment value of the head of the first color is set to + (plus) and the setting in which the adjustment value of the head of the second color is set to − (minus) are output. The degree of change for the head that ejects ink of each color is arbitrary, but it is preferable to change based on the magnitude of the difference. Further, the change may be made with the smallest change amount.

Then, returning to S240 in FIG. 13, the adjustment values of the above two types of color confirmation gradation charts are transferred or input to the printing system, and the settings are changed so that the adjustment values are adjusted according to the two types of candidates in S250. , S260 prints two types of gradation charts for color confirmation, respectively (color confirmation image forming step).

Then, in S270, two types of color confirmation gradation charts are measured to obtain the color difference between the head rows.

Here, the worker 6 or the information processing apparatus 3 selects the candidate having the smaller color difference between the head rows (the one with the better balance).

Then, in step S28, the color difference between the head rows and the color difference between the target head rows are compared, and if it is smaller than the target, the adjustment is completed. S270, S271, and S280 of FIG. 13 adjust either the first head (Cyan's head H4C in FIG. 16) or the second head (Yellow's head H4Y in FIG. 16) in a predetermined head row. It is a secondary color adjustment head determination step to determine whether or not to use.

In this way, the color difference between the head rows and the color difference between the target head rows are compared, and if it is smaller than the target, the adjustment is completed, and if it is larger, the adjustment value is recalculated and the readjustment process is repeated.

In this way, when it is difficult to determine which color should be adjusted for the head that discharges, it is possible to obtain the adjustment value more accurately by printing and trying both adjustment values. Further, in the case of a secondary color, a more visually uniform image can be obtained by determining the adjustment value using the hue angle as a determination standard.

If the color confirmation gradation chart is set for the first printing, whichever has a better balance, the adjustment value setting in the printing system 1 is returned to the first setting in S29 to end the process.

As described above, in the case of the secondary color, it is difficult to correctly grasp the difference in the density, so it is preferable to use the hue angle. The amount of adjustment for adjusting to the target color may be obtained from a calibration curve in which the color characteristics for each gradation are linearly interpolated, or may be adjusted in any gradation step.

In FIG. 14, an example is shown in which the target color is used as the average hue angle and adjusted so as to approach the average value, but the maximum value or the minimum value of the color measurement values in the entire region may be used.

Alternatively, the target color may be set to a hue angle corresponding to a specific color. In this case, a specific color and its hue angle are stored in advance, for example, in S45, the hue angle of the specific color that is the target color is called, and in S46, the hue angle of the specific color and the hue angle of each head are used. The difference from the hue angle may be calculated.

Also, in order to keep the gray balance constant regardless of the gradation, select the target hue angle from the combination that is closest to a * = b * = 0, or match it with the target shade of gray. Is preferable.

Further, although adjustments have been made for predetermined gradations in FIG. 16, it is preferable to determine whether or not adjustment of the head row is necessary for each of the plurality of gradations. However, instead of a gradation chart including a plurality of gradation images, an image having only a predetermined gradation may be output, and the presence or absence of adjustment may be determined as an image for color adjustment.

When adjusting the secondary color in this way, by using the hue angle as the color information, it is possible to adjust the hue that cannot be adjusted by the density and the lightness.

Further, instead of the hue angle difference, the adjustment may be performed using the distance between two points on the a * b * plane or the u * v * plane.

Here, the case of adjusting the secondary color is taken as an example, but the primary color and the tertiary color can also be adjusted by the method using the hue angle.

<Adjustment with tertiary color>
Further, it is also possible to use an arbitrary hue angle as an adjustment color target when adjusting a tertiary color in which three colors of ink are mixed. It is possible to apply the adjustment determination method shown in the second embodiment to the adjustment of the tertiary color (for example, composite black). Composite black can be adjusted by L * or density, but it is also possible to calculate and set the adjustment value by the hue angle in the same way as the secondary color.

As a result, it is possible to adjust the color of the tertiary color or higher while adjusting the gray balance.

<Incorporation of colorimeter into printing system>
In the above, the method of obtaining the adjustment value for manual adjustment has been described, but if a colorimeter capable of measuring the color measurement value (L * a * b *) and the density of a single color can be provided in the printing system, it will be automatic. At the time of adjustment, it is also possible to obtain the adjustment value inside the printing system and reflect the color adjustment with high accuracy.

<Utilization of multi-stage scanner in printing system>
As shown in the flow of FIG. 6 described above, in the color information acquisition step for automatic adjustment in step S1, at the time of color unevenness adjustment, scanning is performed in nozzle units or block units, and density unevenness in the head and nozzle omission are performed. Must be detected and must be scanned at high resolution.

Therefore, the adjustment between the heads has a large color difference, so that manual adjustment is required. However, instead of the manual adjustment, the color adjustment between the heads is performed by the control unit of the printing system 1 or DFE2 by acquiring the hue angle with the scanner itself included in the image inspection mechanisms 140 and 180 (see FIG. 2). You may.

In this case, if the automatic adjustment shown in S1 of FIG. 6 and the manual adjustment shown in S2 are to be executed at the same time, it is necessary to satisfy the requirements for the two scanned images at the same time and to process the entire width of the print area. Requires memory.

Therefore, with one scanner that can measure colors, the settings are changed in two steps to perform high-resolution / low-bit adjustments such as nozzle omission, and then low-resolution / multi-bit adjustments such as tint. By implementing the above, it is possible to make adjustments including the tint of the secondary color even with the scanner.

FIG. 17 shows a schematic flow of a color adjustment method in a printing system when the scanner is provided with color measurement performance.

In step S81, adjustment of high resolution and low bit such as nozzle removal in the head is performed first. That is, when adjusting the color unevenness (adjusting the streaks) in a small section, the color information is read with a high resolution. The adjustment at high resolution of S81 is adjusted centering on the nozzle omission in the head by the same method as the conventional automatic color unevenness adjustment.

In step S82, the adjustment value for performing the color adjustment between the heads or between the head rows is calculated by performing the low resolution / multi-bit adjustment for adjusting the color tone (for example, the secondary color). This multi-bit adjustment is performed centering on the tint by the same adjustment method as in FIGS. 14 to 16 in the case of the above-mentioned secondary color using a colorimeter.

By adjusting the color tone with the scanner whose settings have been changed in this way, it is possible to make adjustments in consideration of the color tone even with a scanner that is cheaper than the colorimeter.

<Other variants>
In the present embodiment, a line head inkjet device in which a recording medium is conveyed and a plurality of heads are arranged in a direction orthogonal to the conveying direction is described, but it is a serial inkjet device in which the head moves with respect to the recording medium. However, the present invention is applicable as long as a plurality of heads are arranged in a direction orthogonal to the moving direction of the heads. That is, the present invention can be applied as long as a plurality of heads are arranged in a direction orthogonal to the relative moving direction of the recording medium and the head.

Although the preferred embodiment of the present invention has been described in detail above, the present invention is not limited to the specific embodiment, and is within the scope of the gist of the embodiment of the present invention described in the claims. Various modifications and changes are possible.

1 printing system 2 DFE
3 Information processing device 4 CD-ROM (storage medium)
5 Colorimeter 121 (121Y, 121M, 121C, 121K) Head unit 122 Nozzle 301 Color measurement value acquisition unit 302 Color difference calculation unit 304 Color difference / primary color target color difference comparison unit (adjustment presence / absence judgment unit)
306 Color difference / secondary color target color difference comparison unit (adjustment presence / absence judgment unit)
H1Y, H2Y, H3Y, H4Y, H5Y, H6Y, H7Y Recording heads (head, yellowhead)
H1M recording head (head, magenta head)
H1C, H4C, H5C recording heads (head, cyan head)
H1K, H2K, H3K, H4K, H5K recording heads (head, black head)
HC1, HC2, HC3, HC4, HC5, HC6, HC7 Head row P Recording medium

Japanese Unexamined Patent Publication No. 2011-199409

Claims (12)

The plurality of heads in which the plurality of nozzles for discharging the liquid are arranged and the recording medium are relatively moved, and the liquid is discharged from the plurality of heads arranged in a direction orthogonal to the relative moving direction. And the formation step of forming an image for color adjustment on the recording medium,
In the color adjustment image, an acquisition step of acquiring a color measurement value of a portion formed by each of a plurality of heads arranged at different positions in the orthogonal direction, and an acquisition step.
A color difference calculation step for calculating a color difference between at least two locations from the color measurement value for each location, and
A determination step for determining whether or not adjustment of the head that discharges the liquid is necessary using the color difference, and
A plurality of head rows in which the heads are arranged in the relative moving direction are arranged to form a plurality of head rows, and the plurality of head rows are arranged so as to be arranged in a direction orthogonal to the relative moving direction.
Liquids of different colors are discharged from the plurality of heads included in each head row, and images of colors composed of the liquids of different colors are formed on the recording medium.
In the formation step, liquids of different colors are discharged from at least a plurality of heads for each head row to form the color adjustment image on a recording medium.
In the color difference calculation step, the color difference between two locations formed by the plurality of head rows arranged at different positions in the orthogonal direction in the color adjustment image is calculated.
For the color difference, the allowable color difference is stored and stored.
In the determination step, only when the color difference between the predetermined two locations is larger than the allowable color difference among the color differences between the one or a plurality of the two locations, the two images forming the predetermined two locations are formed. Judging that it is necessary to adjust one of the head rows,
The step of acquiring the hue angle of the color adjustment image and
The hue angle corresponding to the desired target color, and the hue angle of a portion of the color adjustment image formed by a plurality of heads included in each head row of the two head rows determined to require the adjustment. The hue angle difference calculation step for calculating the hue angle difference, which is the difference between, and
A head row determination step for determining which of the two head rows to adjust the head based on the hue angle difference, and
Color adjustment judgment method having. For the color difference, the allowable color difference is stored and stored.
In the determination step, only when the color difference between the predetermined two locations is larger than the allowable color difference among the color differences between the one or the plurality of the two locations, the two images forming the predetermined two locations are formed. The color adjustment determination method according to claim 1, wherein it is determined that adjustment of any of the heads is necessary. The density acquisition step for acquiring the density information of the color adjustment image, and
Density difference which is a difference between the density information corresponding to a desired target color and the density information of the predetermined two images formed by the two heads of the color adjustment image for which the adjustment is determined to be necessary. And the concentration difference calculation step to calculate
The color adjustment determination method according to claim 2, further comprising a head determination step for determining which of the two heads to adjust based on the density difference. The color adjustment determination method according to claim 3, wherein in the head determination step, the head having a large density difference is determined to be the head to be adjusted. The density information corresponding to the desired target color is characterized in that the gradation information of the original image data is the same in the color adjustment image and is the average value of the density information of the region formed by the plurality of heads. The color adjustment determination method according to claim 3. The color adjustment determination method according to claim 1 , wherein in the head row determination step, the head of the head array in which the portion having a large hue angle difference is formed is determined to be the head to be adjusted. In a head row including a plurality of heads forming a portion having a large difference in hue angle.
Assuming that the plurality of heads forming the color adjustment image and discharging liquids of different colors are the first head and the second head,
Based on the hue angle, there are two, a first color confirmation image in which the ejection amount of the first head is increased and a second color confirmation image in which the ejection amount of the second head is decreased. The color adjustment determination method according to claim 6 , further comprising a color confirmation image forming step of forming an image on a recording medium. Based on the first color confirmation image and the second color confirmation image, the color difference is calculated to determine which of the first head and the second head is to be adjusted. The color adjustment determination method according to claim 7 , further comprising a secondary color adjustment head determination step. The hue angle corresponding to the desired target color is the average value of the hue angles of the regions of the color adjustment image in which the gradation information of the original image data is the same and is formed by a plurality of head rows. The color adjustment determination method according to claim 1, which is a feature. The plurality of heads in which the plurality of nozzles for discharging the liquid are arranged and the recording medium are relatively moved, and the liquid is discharged from the plurality of heads arranged in a direction orthogonal to the relative moving direction. Of the color adjustment images formed on the recording medium, the acquisition step of acquiring the color measurement values of the portions formed by the plurality of heads arranged at different positions in the orthogonal directions, and the acquisition step.
A color difference calculation step for calculating a color difference between at least two locations from the color measurement value for each location, and
A determination step for determining whether or not adjustment of the head that discharges the liquid is necessary using the color difference, and
A plurality of head rows in which the heads are arranged in the relative moving direction are arranged to form a plurality of head rows, and the plurality of head rows are arranged so as to be arranged in a direction orthogonal to the relative moving direction.
Liquids of different colors are discharged from the plurality of heads included in each head row, and images of colors composed of the liquids of different colors are formed on the recording medium.
In the formation step, liquids of different colors are discharged from at least a plurality of heads for each head row to form the color adjustment image on a recording medium.
In the color difference calculation step, the color difference between two locations formed by the plurality of head rows arranged at different positions in the orthogonal direction in the color adjustment image is calculated.
For the color difference, the allowable color difference is stored and stored.
In the determination step, only when the color difference between the predetermined two locations is larger than the allowable color difference among the color differences between the one or a plurality of the two locations, the two images forming the predetermined two locations are formed. Judging that it is necessary to adjust one of the head rows,
The step of acquiring the hue angle of the color adjustment image and
The hue angle corresponding to the desired target color, and the hue angle of a portion of the color adjustment image formed by a plurality of heads included in each head row of the two head rows determined to require the adjustment. The hue angle difference calculation step for calculating the hue angle difference, which is the difference between, and
A head row determination step for determining which of the two head rows to adjust the head based on the hue angle difference, and
Color adjustment judgment method having. On the computer
A color adjustment determination program, characterized in that the color adjustment determination method according to any one of claims 1 to 10 is executed. The plurality of heads in which the plurality of nozzles for discharging the liquid are arranged and the recording medium are relatively moved, and the liquid is discharged from the plurality of heads arranged in a direction orthogonal to the relative moving direction. Among the color adjustment images formed on the recording medium, the color measurement value acquisition unit for acquiring the color measurement values of the portions formed by the plurality of heads arranged at different positions in the orthogonal directions. ,
A color difference calculation unit that calculates a color difference between at least two locations from the color measurement value for each location,
Using the color difference, an adjustment presence / absence determination unit that determines whether or not adjustment of the head that discharges the liquid is necessary, and an adjustment presence / absence determination unit.
A plurality of head rows in which the heads are arranged in the relative moving direction are arranged to form a plurality of head rows, and the plurality of head rows are arranged in a direction orthogonal to the relative moving direction.
Liquids of different colors are discharged from the plurality of heads included in each head row, and images of colors composed of the liquids of different colors are formed on the recording medium.
Liquids of different colors are discharged from at least a plurality of heads for each head row to form the color adjustment image on a recording medium.
The color difference calculation unit calculates the color difference between two locations formed by the plurality of head rows arranged at different positions in the orthogonal direction in the color adjustment image.
For the color difference, the allowable color difference is stored and stored.
The adjustment presence / absence determination unit formed an image of the predetermined two locations only when the color difference between the predetermined two locations is larger than the allowable color difference among the color differences between the one or a plurality of the two locations. Judging that it is necessary to adjust one of the two head rows,
A hue angle calculation unit for acquiring the hue angle of the color adjustment image, and
The hue angle corresponding to the desired target color, and the hue angle of a portion of the color adjustment image formed by a plurality of heads included in each head row of the two head rows determined to require the adjustment. The hue angle difference calculation unit that calculates the hue angle difference, which is the difference between
An adjustment target head row specifying portion for determining which of the two head rows to adjust the head based on the hue angle difference, and
Information processing device with.

Images