JP6776139B2 - Print color evaluation system and print color evaluation method - Google Patents

Description

The present invention relates to a print color evaluation system and a print color evaluation method for evaluating the print color of ink printed on paper.

Conventionally, when the same printed matter is continuously printed, it is evaluated whether or not the printed print color has stable quality every time the printed matter is printed (see, for example, Patent Document 1).
For example, in the newspaper industry, in order to manage the print color of the newspaper surface to be printed, a management patch laid out at a predetermined position on the newspaper surface is used. This management patch is composed of print colors printed with inks of multiple colors, measures the print colors with a dedicated measuring device, and manages fluctuations in the print colors on the newspaper surface with multiple control items (density, density, This is done by observing dot gain, trapping, etc.).

Japanese Unexamined Patent Publication No. 2004-106523

However, in general, including the above-mentioned Patent Document 1, in order to maintain a stable print color, it is necessary to measure the print color of the management patch on a daily basis, and it is necessary to install a dedicated measuring device for each printing factory. Yes, the management cost will be high.
In addition, when the dedicated measuring equipment used is discontinued, the standards and accuracy of the measured control item information differ, and it becomes impossible to compare the newly measured control item with the control item as history information. , The control of fluctuation is interrupted and the stable quality of print color cannot be maintained.

The present invention has been made in view of the above points, and the print color printed on the printed matter is evaluated by evaluating each of the printed colors in the management patch printed on the printed matter with the captured image without using a dedicated measuring device. An object of the present invention is to provide a print color evaluation system and a print color evaluation method capable of stable management.

The present invention has been made to solve the above-mentioned problems, and the print color evaluation system of the present invention is composed of a plurality of print color color patches provided at predetermined positions of an object of color management. An RGB value extraction unit that extracts RGB values for each of the plurality of print colors from an captured image captured by a management patch, and tristimulus value conversion that converts the RGB values for each print color into target tristimulus values. Using a predetermined formula with the ratio of the target tristimulus value to the tristimulus value of ambient light as a variable, the target ink tilt coefficient for each print color and the ratio of the preset reference tristimulus value to the tristimulus value. The target specific color tone value and the reference specific color tone value are determined from each of the target ink tilt coefficient and the reference ink tilt coefficient from the ink tilt coefficient calculation unit that calculates each of the reference ink tilt coefficients by a predetermined function with Using the specific color tone calculation unit, the target specific color tone value, the reference specific color tone value, and the specific color tone value of the printed paper, the printing color of each of the color patches is calculated according to the above formula. It is characterized by including a print color density calculation unit for calculating the density by a predetermined formula.

The print color evaluation system of the present invention converts the three target stimulus values into a spatial color perception model conversion unit that converts the parameters of the spatial color perception model of CIECAM02, and a spatial color perception model that converts the spatial color perception model into a Lab color space. It further includes a Lab color space conversion unit and a modified tristimulus value conversion unit that converts the Lab color space into a pseudo tristimulus value, and when the ink tilt coefficient calculation unit obtains the target ink tilt coefficient, the pseudo tristimulus value Is characterized by using.

In the print color evaluation system of the present invention, for each of the print colors, the ink tilt coefficient calculation unit obtains the target tristimulus values and the reference tristimulus values obtained by measuring the pre-printed print colors. The target ink tilt coefficient and the reference ink tilt coefficient of the above are obtained, and the specific color tone calculation unit obtains the target specific color tone value and the reference specific color tone value using each of the target ink tilt coefficient and the reference ink tilt coefficient. , The print color density calculation unit uses the ratio of the target specific color tone value to the reference specific color tone value and the measured density obtained by measuring the printing of the pre-printed print color, respectively, for each of the print colors. It is characterized in that the concentration of is obtained.

The print color evaluation system of the present invention is characterized by further including a history management unit that records the density of the print color for each printing device and manages fluctuations in the density of the print color.

In the print color evaluation method of the present invention, the RGB value extraction unit is provided at a predetermined position on an object for color management, and is obtained from an image captured by a management patch composed of color patches of a plurality of print colors. , An RGB value extraction process for extracting RGB values in each of the plurality of print colors, and a tristimulus value conversion process in which the tristimulus value conversion unit converts the RGB values for each print color into target tristimulus values. The ink tilt coefficient calculation unit uses a predetermined formula with the ratio of the target tristimulus values to the tristimulus values of ambient light as a variable to obtain the target ink tilt coefficient for each print color and a preset reference 3 for the tristimulus values. The ink tilt coefficient calculation process, which calculates each of the reference ink tilt coefficients by a predetermined function with the ratio of the stimulus values as a variable, and the specific color tone calculation unit perform the target ratio from each of the target ink tilt coefficient and the reference ink tilt coefficient. The color tone calculation process for calculating the color tone value and the reference color tone value by a predetermined formula, and the print color density calculation unit determines the target color tone value, the reference color tone value, and the printed paper. It is characterized by including a print color density calculation process unit for calculating the print color density of each of the color patches by a predetermined formula using the specific color tone value of.

According to the present invention, a print color evaluation capable of stably managing the print color printed on the printed matter by evaluating each of the printed colors in the management patch printed on the printed matter by the captured image without using a dedicated measuring device. A system and a print color evaluation method can be provided.

It is a schematic block diagram which shows the structural example of the print color evaluation system by 1st Embodiment of this invention. It is a figure which shows the configuration example of the captured image table in the print color history database 111. It is a figure which shows an example of the management patch provided in the printed matter to which the print color is managed. It is a figure which shows the configuration example of the print evaluation table in the print color history database 111. It is a figure which shows the configuration example of the reference evaluation table in the reference print color database 110. It is a flowchart which shows the operation example of the process of obtaining the target print color density and the target print color evaluation value of each patch of the management patch of the print color evaluation system 100 by this embodiment. It is a figure which shows the operation screen of the print color evaluation system 100 by this Embodiment on the display screen of the mobile terminal device such as a smartphone. It is a schematic block diagram which shows the structural example of the print color evaluation system by 2nd Embodiment of this invention. It is a figure which shows the structural example of the print evaluation table in the print color history database 111A.

<First Embodiment>
Hereinafter, the print color evaluation system according to the first embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a schematic block diagram showing a configuration example of a print color evaluation system according to the first embodiment of the present invention.
In FIG. 1, the print color evaluation system 10 includes an evaluation control unit 101, a color profile creation unit 102, an RGB value extraction unit 103, a tristimulus value conversion unit 104, an ink tilt coefficient calculation unit 105, a specific color tone calculation unit 106, and printing. Each of the density calculation unit 107, the evaluation value calculation unit 108, the image storage unit 109, the reference print color database 110, and the print color history database 111 is provided. The print color evaluation system 10 is, for example, a functional unit configured on the memory of a smartphone when a program of an application installed on the smartphone is activated.

The evaluation control unit 101 reads the data of the captured image of the management patch, attaches the captured image identification information, writes it to the captured image table in the print color history database 111, and stores it. Further, the evaluation control unit 101 controls each unit in the print color evaluation system 10.
The color profile creation unit 102 creates a color profile of an image imaging device that captures an captured image on the print color evaluation system 10 based on the captured color checker. This color profile is, for example, an ICC (International Color Consortium) profile, and is used to convert RGB values supplied by an image capturing apparatus into absolute reference tristimulus values (X, Y, Z). Further, the color profile creation unit 102 writes and stores the obtained color profile in the reference print color database 110.

FIG. 2 is a diagram showing a configuration example of a captured image table in the print color history database 111. Each record of the captured image table is provided with columns for a captured image data index, target printing device identification information, and a captured date and time, corresponding to columns for captured image identification information.
The captured image identification information is identification information for identifying each of the captured images. The captured image data index is information indicating the address of the area in which the captured image data is written in the print color history database 111. The target printing device identification information is identification information that identifies each of the target printing devices that manages the fluctuation of the print color by printing the management patch captured on the captured image. The imaging date and time is information indicating the date and time when the captured image indicated by the captured image identification information was captured.

That is, the evaluation control unit 101 is supplied with the captured image data from the imaging device together with the target printing device identification information to be managed and the imaging date and time (date and time of imaging in the case of a newspaper), which is the date and time of imaging. Data is written in a predetermined area of the print color history database 111. Then, the evaluation control unit 101 corresponds to the captured image identification information, and has the captured image data index which is the address of the area of the print color history database 111 in which the captured image data is written, the target printing device identification information, and the imaging date and time, respectively. Is written in the captured image data table and stored.

FIG. 3 is a diagram showing an example of a management patch provided on a printed matter whose print color is to be managed. In the present embodiment, the management patch of FIG. 3 manages, for example, fluctuations in the print color of newspaper as a printed matter. The management patch 500 of FIG. 3 is composed of print color patches on which a plurality of different colors are printed. For example, the management patch has a halftone dot area ratio of 50% cyan (Cyan 50%) printed area, a halftone dot area ratio of 100% cyan (Cyan 100%) printed area, and a halftone dot area ratio of. Area where 100% Magenta is printed on 100% (100% Cyan), 100% yellow (100% Yellow) is printed on Cyan (100% Cyan) with 100% halftone dot area ratio. Area printed with black (Black 50%) with halftone dot area ratio of 50%, area printed with magenta (Magenta 50%) with halftone dot area ratio of 50%, halftone dot area ratio of 100% Area where magenta (100% Magenta) is printed, area where 100% yellow (Yello 100%) is printed on magenta (100% halftone dot area) with 100% halftone dot area ratio, black with 100% halftone dot area ratio Area where (Black 100%) is printed, area where 40% Magenta (40% Magenta) is printed on (Cyan 50%) with 50% halftone dot area ratio, and 40% yellow (Yello 40%) is printed on it. , The area where halftone dot area ratio of 50% yellow (Yello 50%) is printed, the area where halftone dot area ratio of yellow (Yello 100%) is printed, that is, each printing color patch is composed. .. Further, the region of the paper itself, which is the medium on which the print color is printed, that is, the region where the halftone dot area ratio of each of cyan, magenta, yellow, and black printing is 0% is also used as the Paper region in the following description. ..

Returning to FIG. 1, the RGB value extraction unit 103 extracts the RGB values of the print colors of each print color patch from the captured image of the management patch 500, and makes them correspond to the target print color identification information for identifying each print color. It is written and stored in the print color history table in the print color history database 111. This print color history table is provided for each imaging date and time and the target printing device in the print color history database 111.
For example, the RGB value extraction unit 103 extracts the RGB value of the region in which the cyan (100%) having a halftone dot area ratio of 100% is printed in the captured image. Then, the RGB value extraction unit 103 corresponds to the target print color identification information for identifying cyan having a halftone dot area ratio of 100%, which is the print color of this region, and writes the extracted RGB values to the print color history table. Remember with.

Further, the RGB value extraction unit 103 extracts RGB values in the image area outside the management patch 500, that is, in the Paper area in the captured image (extraction of the RGB values of the paper itself on which the management patch 500 is printed). ) Is also performed, and the print color history table is written and stored in correspondence with the predetermined target print color identification information. When extracting the RGB values, the RGB value extraction unit 103 performs noise removal processing in the captured images, for example, using five captured images of the same management patch 500. The RGB value extraction unit 103 obtains a histogram of the RGB values of each of the print color patches in the management patch 500 for each captured image, and adds the histograms for five captured images to generate a comprehensive histogram. This histogram is created for each RGB value, and the horizontal axis shows the gradation degree, and the vertical axis shows the number of pixels of each gradation degree. Then, the RGB value extraction unit 103 extracts the RGB value of each print color region of the management patch 500 in the captured image after removing the gradation degree equal to or less than the preset numerical value (number of pixels) as noise.

FIG. 4 is a diagram showing a configuration example of a print evaluation table in the print color history database 111. In each record of the print evaluation table, the target RGB value, the target tristimulus value, the target ink tilt coefficient, the target specific color tone value, the target print color density, and the target print color density, correspond to the target print color identification information column. Each column with the target print color evaluation value is provided.
The target print color identification information is identification information for identifying the print color (such as cyan (Cyan 100%) having a halftone dot area ratio of 100%) in each print color patch of the management patch 500. The target tristimulus values (X2, Y2, X2) are obtained by converting the RGB values (R, G, B) of the print color of each color patch in the management patch 500 captured in the captured image by using a color profile. These are the obtained tristimulus values. The target ink inclination coefficient (Lx2, Ly2, Lz2) is a coefficient obtained by converting the target tristimulus values by a predetermined relational expression.

The target colorimetric tone value is CTV (Colorimetric Tone Value), and is obtained by a predetermined relational expression using the target ink inclination coefficient. In addition, the target colorimetric tone value may be indicated as PrintColorValue corresponding to the target tristimulus values. The target print color density is the density of the print color patch in the management patch 500 obtained by a predetermined relational expression using the target specific color tone value. The target print color evaluation value is each of the dot gain of the print color patch and the trapping of the secondary color in the management patch 500, which are obtained by a predetermined relational expression using the density of the print color patch. Each numerical value obtained by a predetermined relational expression in the above-mentioned printing evaluation table will be described later.

FIG. 5 is a diagram showing a configuration example of a reference evaluation table in the reference print color database 110. In each record of the evaluation table for printing, the print color density, the reference tristimulus value, the measurement light source, the reference ink inclination coefficient, and the reference specific color tone value are each corresponding to the reference print color identification information column. Is provided.
The reference print color identification information is used as a standard value when managing fluctuations in the print color of the management patch 500, and is used as a standard value for each print color corresponding to each print color of the management patch 500 printed on paper for reference (for example,). , Cyan (Cyan100%) having a halftone dot area ratio of 100%, etc.). The print color density is a density value measured by a densitometer for each of the above-mentioned actually printed print colors. The reference tristimulus values (X1, Y1, Z1) are, for example, tristimulus values obtained by extracting the reflected light from the printed portion of each printed color according to the spectral sensitivity. The measurement light source indicates the light source environment when the print color density and the reference tristimulus values are measured. For example, in this embodiment, the light source of D50 is used.

The target ink inclination coefficient (Lx1, Ly1, Lz1) is a coefficient obtained by converting the reference tristimulus values (X1, Y1, Z1) by a predetermined relational expression. The target colorimetric tone value is CTV (Colorimetric Tone Value), and is obtained by a predetermined relational expression using the target ink inclination coefficient. In addition, the target colorimetric tone value may be indicated as RefColorValue corresponding to the reference tristimulus value. This reference evaluation table is created once at the stage of starting management, and will not be newly created unless the evaluation criteria are changed. In addition, for each of the reference concentration and the reference tristimulus value, the numerical values of only the paper as the medium are also measured.

Returning to FIG. 1, the tristimulus value conversion unit 104 reads the color profile from the reference print color database 110. Then, the tristimulus value conversion unit 104 sequentially converts the target RGB values read from the print evaluation table of the print color history database 111 into the target tristimulus values by using the read color profile, and obtains the target tristimulus. The values are written and stored in the print evaluation table in correspondence with the target RGB values.
The ink tilt coefficient calculation unit 105 uses the following equation (1) to obtain the target ink tilt coefficient (X1, Y1, Z1) from each of the target tristimulus values (X2, Y2, Z2) and the reference tristimulus values (X1, Y1, Z1). Lx2, Ly2, Lz2) and the reference ink inclination coefficient (Lx1, Ly1, Lz1) are calculated respectively. That is, the ink inclination coefficient calculation unit 105 sets each of the target tristimulus values (X2, Y2, Z2) and the reference tristimulus values (X1, Y1, Z1) with respect to the variables X, Y, Z in the equation (1). By substituting with, the target ink inclination coefficient (Lx2, Ly2, Lz2) and the reference ink inclination coefficient (Lx1, Ly1, Lz1) are calculated respectively. For equation (1), refer to "A Regression-Based Model of Colorimetric Tone Reproduction for Use in Print Standards, WB Birkett, C Spontelli -TAGA Proceedings, 2005".

Then, the ink inclination coefficient calculation unit 105 prints the print color history database 111 by associating the calculated target ink inclination coefficient (Lx2, Ly2, Lz2) with the target tristimulus values (X2, Y2, Z2) used. Write and store in the evaluation table. Further, the ink tilt coefficient calculation unit 105 prints the reference print color database 110 by associating the calculated reference ink tilt coefficient (Lx1, Ly1, Lz1) with the reference tristimulus values (X1, Y1, Z1) used. Write to the evaluation table and store it. The ink inclination coefficient is a numerical value corresponding to the ratio of the target tristimulus values (X2, Y2, Z2) to the tristimulus values (refX, refY, refZ) of ambient light.

The colorimetric tone calculation unit 106 calculates PrintColorValue as the target colorimetric tone value using the following equation (2). That is, the colorimetric tone calculation unit 106 calculates the target colorimetric tone value PrintColorValue by substituting the target ink inclination coefficient (Lx2, Ly2, Lz2) into the equation (2). Then, the specific color tone calculation unit 106 makes the calculated target specific color tone value PrintColorValue correspond to the target ink inclination coefficient (Lx2, Ly2, Lz2) used, and refers to the print evaluation table of the print color history database 111. Write and memorize. In the following equation (2), each of Lxpaper, Lypaper, and Lzpaper is the target inclination coefficient of the paper itself, which is the print medium in the captured image.

Similarly, the colorimetric tone calculation unit 106 calculates the reference colorimetric tone value RefColorValue by substituting the reference ink inclination coefficient (Lx1, Ly1, Lz1) for the equation (3). Then, the specific color tone calculation unit 106 makes the calculated reference specific color tone value RefColorValue correspond to the reference ink inclination coefficient (Lx1, Ly1, Lz1) used, and refers to the reference evaluation table of the reference print color database 110. Write and memorize. In the following equation (3), each of LxRefpaper, LyRefpaper, and LzRefpaper is the target inclination coefficient of the paper itself on which the print color is printed for reference.

The print density calculation unit 107 calculates Density as the target print color density by substituting each of the target colorimetric tone value PrintColorValue and the reference colorimetric tone value RefColorValue using the following equation (4). In the equation (4), RefDensity is the print color density in the print evaluation table of the reference print color database 110, which is obtained by measuring the print color printed on the paper for reference. That is, the target print color density Density is calculated based on the result of multiplying the ratio of the target specific color tone value PrintColorValue to the reference specific color tone value RefColorValue by the print color density RefDensity.

The target print color density Density described above is calculated for all the print colors (of the paper itself) in the management patch 500 shown in FIG. Then, the print density calculation unit 107 corresponds to the target print color identification information, and writes and stores the calculated target print color density Density in the print evaluation table of the print color history database 111.

The evaluation value calculation unit 108 obtains the target halftone dot area ratio ToneValueA by using the following equation (5).

In the above equation (5), Density _50% is the target print color density of the print color having a halftone dot area ratio of 50%, and Density _100% is the target print color density of the print color having a halftone dot area ratio of 100%. , Density _paper is the target print color density of the paper itself. Further, the formula (5) is a formula for calculating the concentration defined in ISO (International Organization for Standardization) 1267-1. For example, when the halftone dot area ratio with respect to cyan is obtained, the target print color densities of cyan having a halftone dot area ratio of 50% and cyan having a halftone dot area ratio of 100% are substituted into Eq. (5). When the target halftone dot area ratio ToneValueA is obtained as 60%, the evaluation value calculation unit 108 uses 60% (target halftone dot area ratio obtained from the captured image) -50% (control value when printing). Halftone dot area ratio) = 10%, and the dot gain of cyan is calculated as 10.

Further, the evaluation value calculation unit 108 obtains the trapping value T by using the following equation (6).

In the above equation (6), Density _{1 + 2} is the target print color density of the patch in which two print colors are overcoated, and Density ₁ is the target print color density of the print color printed underneath in the overcoat, and Density ₂ is the target print color density of the print color printed on the upper part of the print of the target print color density Density ₁ . Generally, in the order of overcoating, black is printed first, then cyan, and then magenta and yellow are printed. For example, the case where the evaluation value calculation unit 108 calculates the trapping value T in the patch in which the print color in FIG. 3 is 100% magenta and 100% yellow is described.

In this case, the evaluation value calculation unit 108 uses the target print color density of the overcoating patch of 100% magenta and 100% yellow as Density _{1 + 2} in the equation (6), and sets the Density ₁ of the 100% magenta patch. Using the target print color density and using the target print color density of the 100% yellow patch as Density ₂ , the trapping value T in the overcoated patch of 100% magenta and 100% yellow is calculated. Then, the evaluation value calculation unit 108 writes and stores each of the calculated dot gain and trapping value as the target print color evaluation value in the print evaluation table of the print color history database 111 in correspondence with the target print color identification information. ..

FIG. 6 is a flowchart showing an operation example of a process for obtaining the target print color density and the target print color evaluation value of each patch of the management patch of the print color evaluation system 100 according to the present embodiment. FIG. 7 is a diagram showing an operation screen of the print color evaluation system 100 according to the present embodiment on the display screen of a mobile terminal device such as a smartphone. Hereinafter, the operation of the print color evaluation system 100 according to the present embodiment will be described with reference to FIGS. 6 and 7.

The operator operates the icon of the smartphone to start the application of the print color evaluation system 100.
Step S101:
By the above activation operation, the evaluation control unit 101 displays the operation screen shown in FIG. 7A on the display screen of the mobile terminal device.
When the operator operates (for example, touches) the icon 701 on the operation screen, the evaluation control unit 101 operates the camera function (image imaging device) of the mobile terminal device, as shown in FIG. 7 (b). On the display screen 700, while confirming the color checker to be imaged, the captured image of the color checker is captured. At this time, the captured image (FIG. 7 (c)) captured by the operator is confirmed on the display screen 700, and the captured image is completely included in the image of the color checker or is out of focus. It makes a judgment such as. As a result of the confirmation, if the captured image does not completely include the image of the color checker or is out of focus, the image is taken again.

Step S102:
The color profile creation unit 102 creates a color profile of an image imaging device that captures an captured image on the print color evaluation system 10 based on the captured color checker. Then, the color profile creation unit 102 writes and stores the obtained color profile in the reference print color database 110.

Step S103:
The color profile creating unit 102 determines whether or not the accuracy of the created color profile is sufficient by determining the smoothness of gradation reproduction, the continuity at the position where the hue changes, and the like. At this time, if the color profile creation unit 102 determines that the accuracy of the color profile is sufficient, the process proceeds to step S104. On the other hand, when the color profile creation unit 102 determines that the accuracy of the color profile is not sufficient, the process returns to step S101, the operation screen of FIG. 7A is displayed on the display screen 700, and re-shooting is urged.

Step S104:
When the operator takes an image of the management patch 500 printed at a predetermined position on the newspaper, for example, in the operation screen of FIG. 7D, the target printing device identification information entry field is displayed on the operation screen of the display screen 700. For 702, the target printing device identification information of the printing device in which the management patch 500 to be evaluated is printed on the newspaper is input. Further, the worker inputs the date and time when the management patch 500 to be evaluated is printed on the newspaper in the print date entry field 703.

The evaluation control unit 101 prompts the operator to image the management patch 500 on the newspaper by inputting the target printing device identification information and the date.
As a result, as shown in FIG. 7E, the operator can refer to the area 704 on which the management patch 500 is printed on the display screen 700, and the management patch 500 on the newspaper is printed. Take an image of the area of. The evaluation control unit 101 temporarily writes and stores the captured image of the management patch 500 captured in the image storage unit 109. At this time, the captured image (FIG. 7 (f)) captured by the operator is confirmed on the display screen 700, and the captured image is completely included in the image of the management patch 500 or is in focus. Judgment such as whether or not there is. As a result of the confirmation, if the captured image does not completely include the image of the management patch 500 or is out of focus, the image is taken again.

Step S105:
The operator operates an icon (not shown) for starting the evaluation process of the management patch 500 on the operation screen.
The evaluation control unit 101 reads the captured image from the image storage unit 109 by operating the icon for starting the evaluation process, writes it in the print color history database 111, stores it, and identifies the captured image given to the captured image. Along with the information, each of the captured image data index, the target printing device identification information, and the imaging date and time is written and stored in the captured image table.

Further, the evaluation control unit 101 causes each unit of the print color evaluation system 100 to control to start the print color evaluation process using the captured image captured by the management patch 500.
The RGB value extraction unit 103 reads the captured image of the management patch 500 from the print color history database 111, and obtains the RGB value of the print color of each patch in the imaged region of the management patch 500 of the read captured image. Then, the RGB value extraction unit 103 writes and stores the extracted RGB values in the print evaluation table of the print color history database 111.

Step S106:
The tristimulus value conversion unit 104 reads the target RGB value, which is the RGB value of the print color of each patch extracted by the RGB value extraction unit 103, from the print evaluation table of the print color history database 111. Then, the tristimulus value conversion unit 104 converts the read target RGB value into the target tristimulus values (X2, Y2, Z2). The tristimulus value conversion unit 104 writes and stores the converted target tristimulus values (X2, Y2, Z2) in the print evaluation table of the print color history database 111.

Step S107:
The ink inclination coefficient calculation unit 105 reads out the target tristimulus values (X2, Y2, Z2) of the target print color of each patch converted by the tristimulus value conversion unit 104 from the print evaluation table of the print color history database 111. Then, the ink inclination coefficient calculation unit 105 converts the read target tristimulus values (X2, Y2, Z2) into the target ink inclination coefficient (Lx2, Ly2, Lz2) using the equation (1). The ink inclination coefficient calculation unit 105 writes and stores the converted target tristimulus values (X2, Y2, Z2) in the print evaluation table of the print color history database 111.

Further, the ink inclination coefficient calculation unit 105 reads out each of the reference tristimulus values (X1, Y1, Z1) corresponding to each of the target print colors of the management patch 500 from the reference evaluation table of the reference print color database 110.
Then, the ink inclination coefficient calculation unit 105 converts the reference tristimulus values (X1, Y1, Z1) of the reference print color into the reference ink inclination coefficient (Lx1, Ly1, Lz1) using the equation (1). The ink inclination coefficient calculation unit 105 writes and stores the converted reference ink inclination coefficient (Lx1, Ly1, Lz1) in the reference evaluation table of the reference print color database 110.

Step S108:
The colorimetric tone calculation unit 106 reads out the target ink inclination coefficient (Lx2, Ly2, Lz2) of the target print color of each patch converted by the ink inclination coefficient calculation unit 105 from the print evaluation table of the print color history database 111. Then, the colorimetric tone calculation unit 106 converts the read target ink inclination coefficient (Lx2, Ly2, Lz2) into the target colorimetric tone value PrintColorValue using the equation (2). The specific color tone calculation unit 106 writes and stores the converted target specific color tone value PrintColorValue in the print evaluation table of the print color history database 111.

Further, the specific color tone calculation unit 106 reads out the reference ink inclination coefficient (Lx1, Ly1, Lz1) of each reference print color converted by the ink inclination coefficient calculation unit 105 from the reference evaluation table of the reference print color database 110. Then, the colorimetric tone calculation unit 106 converts the read reference ink inclination coefficient (Lx1, Ly1, Lz1) into the reference colorimetric tone value RefColorValue using the equation (3). The specific color tone calculation unit 106 writes and stores the converted reference specific color tone value RefColorValue in the reference evaluation table of the reference print color database 110.

Step S109:
The print density calculation unit 107 reads the target specific color tone value PrintColorValue of the target print color of each patch converted by the specific color tone calculation unit 106 from the print evaluation table of the print color history database 111. Further, the print density calculation unit 107 reads the reference specific color tone value RefColorValue of each reference print color converted by the specific color tone calculation unit 106 from the reference evaluation table of the reference print color database 110.
Then, the print density calculation unit 107 substitutes each of the read target specific color tone value PrintColorValue and the reference specific color tone value RefColorValue into the equation (4), and the target printing of each target printing color of the patch in the management patch 500. Find the color density Density.

Step S110:
The evaluation value calculation unit 108 calculates the dot gain and the trapping value T by each of the equations (5) and (6) using the target print color density Density of each target print color of the patch in the management patch 500. To do.
Then, the evaluation value calculation unit 108 writes and stores each of the dot gain and the trapping value T as the target print color evaluation value in the print evaluation table of the print color history database 111.
Further, the evaluation control unit 101 displays the print density, dot gain, trapping value, etc. of each patch of the management patch 500 on the display screen 700.

As described above, in the present embodiment, each print color of the patch of the management patch 500 printed on the newspaper by the print color evaluation system which is an application (program) installed in the mobile terminal device of each worker. Each of the print color density and the target print color evaluation value is obtained. It is possible to manage the history of each of the print color density and the target print color evaluation value, and manage the fluctuation of the print color printed on the newspaper (history management unit (not shown).
In addition, the print color density and target print color evaluation of each print color of the patch of the management patch 500 are sent from each mobile terminal device to a management server such as a technical center that centrally manages each of the printing devices in each printing factory. The value may be transmitted and centrally managed by this management server.

As described above, according to the present embodiment, the print color density of the print color printed in advance is referred to as a reference, and from the captured image of the print color management patch on the newspaper or the like to be evaluated, the patch in the management patch is used. In order to obtain the target print color density of the print color printed on each of the above, the print color density in the printing of the print color on each printing machine is not required in each of the printing factories where each printing machine is located. Can be easily managed according to the target print color density obtained by imaging the management patch.

<Second embodiment>
Hereinafter, the print color evaluation system according to the second embodiment of the present invention will be described with reference to the drawings. FIG. 8 is a schematic block diagram showing a configuration example of a print color evaluation system according to a second embodiment of the present invention.
In FIG. 8, the print color evaluation system 10A includes an evaluation control unit 101, a color profile creation unit 102, an RGB value extraction unit 103, a tristimulus value conversion unit 104, an ink tilt coefficient calculation unit 105, a specific color tone calculation unit 106, and printing. Density calculation unit 107, evaluation value calculation unit 108, image storage unit 109, reference print color database 110, print color history database 111A, spatial color perception model conversion unit 112, Lab color space conversion unit 113, and modified tristimulus value conversion unit. Each of 114 is provided. In the configuration of the second embodiment of FIG. 8, the same reference numerals are given to the same configurations as those of the first embodiment. Hereinafter, each of the configurations and operations different from those of the first embodiment will be described with respect to the second embodiment.

The spatial color perception model conversion unit 112 converts each of the reference tristimulus values (X1, Y1, Z1) and the target tristimulus values (X2, Y2, Z2) into the table tristimulus values by a general predetermined conversion formula. It is converted into the parameter of CIECAM02 which is a color system (spatial color perception model) different from the above. Then, the spatial color perception model conversion unit 112 writes and stores the obtained CMYKAM02 parameters in the print evaluation table of the print color history database 111A.

Here, the parameters of CIECAM02 are Q (brightness), J (brightness), H (hue component), h (hue angle) M (colorfulness), C (chroma), and saturation s. In the first embodiment, the ink inclination coefficient was obtained directly from the tristimulus values, but in the second embodiment, the ink inclination coefficient is obtained after conversion to CIECAM02. By obtaining a pseudo Lab from the parameters of CIECAM 02 and converting the pseudo Lab into a pseudo tristimulus value, it is possible to correct the color expression to be close to the human sense.
However, in the color system of CIE1976L ^* a ^* b ^* , there is a difference between the numerical value that accurately represents the color and the color that the human sense actually perceives. For this reason, in recent years, CIECAM02, which expresses a color closer to the human sense than CIE1976L ^* a ^* b ^* , that is, a color closer to the color seen and perceived by humans, is used.

The Lab color space conversion unit 113 converts the parameters of CIECAM02 into the parameters of the color system of the pseudo CIELab using the following equation (7).

In the above equation (7), J is the brightness of the parameter of CIECAM02, C is the chroma of the parameter of CIECAM02, and h is the hue angle of the parameter of CIECAM02. The parameters of L02, a02, and b02, which are the pseudo-Lab values calculated in the equation (7), are different from the parameters L ^* , a ^*, and b ^* of CIE1976L ^* a ^* b ^* , and the parameters L of the Lab. , A, and b are the parameters obtained in a pseudo manner corresponding to each of the above. This conversion from CIECAM02 to a pseudo-Lab color system is performed in order to finally obtain the tristimulus value. Then, the Lab color space conversion unit 113 writes and stores the obtained pseudo Lab value in the print evaluation table of the print color history database 111A.

The modified tristimulus value conversion unit 114 uses a general conversion formula to obtain pseudo tristimulus values (X02, Y02, Z02), which are pseudo tristimulus values, from the respective parameters of the pseudo Lab values L02, a02, and b02. Ask for. Then, the modified tristimulus value conversion unit 114 writes and stores the obtained pseudo tristimulus values (X02, Y02, Z02) in the print evaluation table of the print color history database 111A.
Then, the ink tilt coefficient calculation unit 105 replaces the target tristimulus values (X2, Y2, Z2) in the equation (1) with pseudo tristimulus values (X02, Y02, Z02), and the ink tilt coefficient (Lx2, Ly2). , Lz2) is calculated.
Since the subsequent processing is the same as that of the first embodiment, the description thereof will be omitted.

FIG. 9 is a diagram showing a configuration example of a print evaluation table in the print color history database 111A. In FIG. 9, in each record of the print evaluation table, the target RGB value, the target tristimulus value, the CMYKAM02 parameter, the pseudo Lab value, and the pseudo tristimulus correspond to the target print color identification information column. Each column of a value, a target ink inclination coefficient, a target specific color tone value, a target print color density, and a target print color evaluation value is provided.
For each of the target print color identification information, the target RGB value, the target tristimulus value, the target ink tilt coefficient, the target specific color tone value, the target print color density, and the target print color evaluation value, the first This is the same as the configuration of the print evaluation table in the print color history database 111 of FIG. 4 in the embodiment. The CIECAM02 parameters are Q (brightness), J (brightness), H (hue component), h (hue angle) M (colorfulness), C (chroma), and saturation s, which have already been described. The pseudo Lab values are L02, a02, and b02, respectively. Pseudo tristimulus values (X02, Y02, Z02).

According to the present embodiment, as in the first embodiment, the print color density of the print color printed in advance is referred to as a reference, and management is performed from the captured image of the print color management patch on the newspaper or the like to be evaluated. In order to obtain the target print color density of the print color printed on each of the patches in the patch, printing of the print color on each printing machine without using a dedicated measuring device at each printing factory where each printing machine is located. The print color density in the above can be easily managed by the target print color density obtained by imaging the management patch.
Further, according to the present embodiment, since the target print color density is calculated after being converted to CIECAM02, which can express a color close to the human sense, it is compared with the first embodiment. Therefore, since it is possible to manage the fluctuation of the print color by using the numerical value of the color closer to the human sense, it is possible to manage the fluctuation of the print color as the human see. it can.

Further, a program for realizing the respective functions of the print color evaluation system 10 in FIG. 1 and the print color evaluation system 10A in FIG. 8 is recorded on a computer-readable recording medium, and the program recorded on the recording medium. May be read into the computer system and executed to perform the print color evaluation process. The term "computer system" as used herein includes hardware such as an OS and peripheral devices.

In addition, the "computer system" includes the homepage providing environment (or display environment) if the WWW system is used.
Further, the "computer-readable recording medium" refers to a portable medium such as a flexible disk, a magneto-optical disk, a ROM, or a CD-ROM, or a storage device such as a hard disk built in a computer system. Further, a "computer-readable recording medium" is a communication line for transmitting a program via a network such as the Internet or a communication line such as a telephone line, and dynamically holds the program for a short period of time. In that case, it also includes the one that holds the program for a certain period of time, such as the volatile memory inside the computer system that becomes the server or client. Further, the above-mentioned program may be for realizing a part of the above-mentioned functions, and may further realize the above-mentioned functions in combination with a program already recorded in the computer system.

Although the embodiment of the present invention has been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment, and the design and the like within a range not deviating from the gist of the present invention are also included.

10, 10A ... Print color evaluation system 101 ... Evaluation control unit 102 ... Color profile creation unit 103 ... RGB value extraction unit 104 ... Tristimulus value conversion unit 105 ... Ink tilt coefficient calculation unit 106 ... Color ratio tone calculation unit 107 ... Print density Calculation unit 108 ... Evaluation value calculation unit 109 ... Image storage unit 110 ... Reference print color database 111, 111A ... Print color history database 112 ... Spatial color perception model conversion unit 113 ... Lab color space conversion unit 114 ... Modified tristimulus value conversion Department

Claims (5)

RGB that extracts RGB values for each of the plurality of print colors from an image captured by a management patch composed of color patches of a plurality of print colors provided at a predetermined location of a color management object. Value extractor and
A tristimulus value conversion unit that converts the RGB values for each print color into target tristimulus values, and
The ratio of the target tristimulus value to the tristimulus value of ambient light is used as a variable, and the target ink inclination coefficient for each print color and the ratio of the reference tristimulus value set in advance to the tristimulus value are used as variables according to a predetermined formula. An ink tilt coefficient calculation unit that calculates each of the reference ink tilt coefficients by a predetermined function,
A specific color tone calculation unit that calculates a target specific color tone value and a reference specific color tone value from each of the target ink inclination coefficient and the reference ink inclination coefficient by a predetermined formula.
A print color density calculation for calculating the print color density of each of the color patches by a predetermined formula using the target color tone value, the reference color tone value, and the color color tone value of the printed paper. A print color evaluation system characterized by having a part. A spatial color perception model conversion unit that converts the three target stimulus values into parameters of the spatial color perception model of CIECAM02, and
A Lab color space conversion unit that converts the spatial color perception model into a Lab color space,
It is further equipped with a modified tristimulus value conversion unit that converts the Lab color space into a pseudo tristimulus value.
The print color evaluation system according to claim 1, wherein the ink inclination coefficient calculation unit uses the pseudo tristimulus value when obtaining the target ink inclination coefficient. From each of the target tristimulus value and the reference tristimulus value obtained by measuring the print color printed in advance by the ink tilt coefficient calculation unit, the target ink tilt coefficient and the reference ink tilt for each print color are obtained. Find each coefficient
The specific color tone calculation unit uses each of the target ink inclination coefficient and the reference ink inclination coefficient to obtain the target specific color tone value and the reference specific color tone value, respectively.
The print color density calculation unit uses the ratio of the specific color tone value to the reference specific color tone value and the measured density obtained by measuring the printing of the pre-printed print color to obtain the respective densities of the print colors. The print color evaluation system according to claim 1 or 2, wherein the printing color evaluation system is obtained. The invention according to any one of claims 1 to 3, further comprising a history management unit that records the density of the print color for each printing device and manages the fluctuation of the density of the print color. Print color evaluation system. From the captured image in which the management patch composed of the color patches of a plurality of print colors is captured, the RGB value extraction unit is provided at a predetermined position of the object of color management, and the RGB value extraction unit is used for each of the plurality of print colors. RGB value extraction process to extract RGB values and
A tristimulus value conversion process in which the tristimulus value conversion unit converts the RGB value for each print color into a target tristimulus value, and
The ink tilt coefficient calculation unit uses a predetermined formula with the ratio of the target tristimulus values to the tristimulus values of ambient light as a variable to obtain the target ink tilt coefficient for each print color and a preset reference 3 for the tristimulus values. The process of calculating the reference ink slope coefficient using a predetermined function with the ratio of the stimulus values as a variable, and the process of calculating the ink slope coefficient.
A specific color tone calculation process in which the specific color tone calculation unit calculates a target specific color tone value and a reference specific color tone value from each of the target ink inclination coefficient and the reference ink inclination coefficient by a predetermined formula.
The print color density calculation unit uses the target color tone value, the reference color tone value, and the color tone value of the printed paper to determine the print color density of each of the color patches by a predetermined formula. A print color evaluation method characterized by including a print color density calculation process unit calculated by.