This application is based upon and claims the benefit of priority from Patent Application No. 2008-283503 filed on Nov. 4, 2008, in the Japan Patent Office, of which the contents are incorporated herein by reference.
1. Field of the Invention
The present invention relates to a method of and an apparatus for converting colors to produce a print of desired designated densities using a printing machine that has been set to standard density conditions.
2. Description of the Related Art
Prints are produced by generating original film plates in various colors including cyan (C), magenta (M), yellow (Y), and black (K), for example, producing PS plates (presensitized plates) from the original film plates by exposure and development, mounting the PS plates on a printing press such as a rotary press or the like, and adjusting printing conditions including the ink film thickness, the dampening water, the temperature, etc.
Therefore, complex steps are involved in producing prints. In order to produce a print in desired colors, it has been customary prior to the production of the print to generate a proof using a simple output device such as a monitor, a color printer or the like, and adjust printing conditions in order for the proof to have the desired colors of the print to be produced.
Japanese Laid-Open Patent Publication No. 2007-208492, for example, discloses a method of confirming the colors of a print before the print is produced by a printing press. According to the disclosed method, if the colors of a proof fall in an allowable range with respect to the colors of the print, then the print is produced by the printing press without changing platemaking data for generating PS plates and target densities to be set as printing conditions in the printing press. On the other hand, if the colors of the proof deviate from the allowable range with respect to the colors of the print, then the platemaking data are changed or a target mixed-color halftone density or a target halftone dot area ratio which is related to the target density as the printing condition, and thereafter a proof is produced again, the process being repeated until the print having the desired colors is produced.
The colors of a print are normally adjusted by the operator who adjusts the ink keys to change the densities of the inks. The process of changing the densities of the proof by changing the target mixed-color halftone density or the target halftone dot area ratio, and the process of changing the densities of the print using the ink keys tend to cause the operator who makes adjustments to develop different sensations about the colors. Therefore, it is highly difficult to produce a print having desired colors which match the proof. Standard densities for prints that are desired by users may differ from user to user. For changing standard densities, it is necessary to adjust the ink keys and then print a color chart again to generate an ICC profile again.
However, such a process is highly time-consuming because a color chart made up of many color patches has to be printed depending on the new standard densities and measure the colorimetric values of the color chart. In addition, the operator needs to be highly experienced for changing standard densities using the ink keys or the like.
When the standard densities of a printing press are changed using ink keys, the standard densities are set uniformly with respect to one ink key. For example, it is assumed that, as shown in
It is an object of the present invention to provide a method of and an apparatus for converting colors to produce a print of desired densities easily without the need for adjusting a printing press, so that the above problems of the related art will be solved.
According to an aspect of the present invention, there is provided a method of converting colors of image data capable of producing a print of standard densities with a printing press set to standard density conditions and generating a print of desired designated densities with the printing press set to the standard density conditions, comprising the steps of generating a standard density print profile capable of producing the print of the standard densities with the printing press set to the standard density conditions, generating a designated density print profile capable of producing the print of the designated densities with the printing press when the printing press is set to designated density conditions, and converting the colors of the image data using the standard density print profile and the designated density print profile.
According to another aspect of the present invention, there is provided an apparatus for converting colors of image data capable of producing a print of standard densities with a printing press set to standard density conditions and generating a print of desired designated densities with the printing press set to the standard density conditions, comprising a color converter for converting the colors of the image data using a standard density print profile capable of producing the print of the standard densities with the printing press set to the standard density conditions, and a designated density print profile capable of producing the print of the designated densities with the printing press when the printing press is set to designated density conditions.
With the method and the apparatus according to the present invention, it is easy to produce a print of desired designated densities with the printing press set to the standard density conditions without the need for adjustments of the printing press, using a designated density print profile which is capable of producing a print of designated densities with the printing press that is set to designated density conditions, and a standard density print profile which is capable of producing a print of standard densities with the printing press that is set to standard density conditions.
The above and other objects, features, and advantages of the present invention will become more apparent from the following description when taken in conjunction with the accompanying drawings in which preferred embodiments of the present invention are shown by way of illustrative example.
Like or corresponding parts are denoted by like or corresponding reference characters throughout views.
The editing device 12 comprises a designated density print color conversion table generator 26 for generating a designated density print color conversion table using the designated density print profile 20 generated by the profile generator 24 and a standard density print profile to be described later, and a print color converter 28 for converting the image data C, M, Y, K into the image data C1, M1, Y1, K1 based on which a print P1 of designated densities can be produced, using the designated density print color conversion table.
The designated density print profile 20 is a profile representative of the relationship between device-independent colorimetric values of the print P1 produced when the settings of the printing press 14 are set to designated density conditions for making the densities of the print P1 generated by the printing press 14 equal to designated densities, e.g., colorimetric values X, Y, Z or colorimetric values L*, a*, b* of the print P1, and the image data C, M, Y, K. The designated density print profile 20 is generated by the profile generator 24 based on existing image data C, Y, M, K and measured values of a color chart C1 that is produced from the image data C, M, Y, K by the printing press 14.
The printer profile (proof profile) 22 is a profile for converting device-independent colorimetric values, e.g., colorimetric values X, Y, Z or colorimetric values L*, a*, b*, into image data C, M, Y, K depending on the output characteristics of the printer 18 as a device. The printer profile 22 is generated by the profile generator 24 based on existing image data C, M, Y, K and measured values of a color chart C2 that is produced from the image data C, M, Y, K by the printer 18.
Each of the color charts C1, C2 may comprise a number of color patches of primary (monochromatic) through quaternary colors produced with inks (color materials) C, M, Y, K according to halftone dot percentages set at intervals in the range from 0% to 100%.
The standard density conditions refer to conditions for adjusting printing conditions such as ink film thicknesses, etc. of the printing press 14 such that when the printing press 14 produces the color chart C1 with halftone dot % set to prescribed values for the inks C, M, Y, K, the densities of the inks of the color chart C1 will become the standard densities defined by the user which may be a printing company or the like. The changing density conditions refer to conditions for individually changing the densities of the inks C, M, Y, K from the standard densities by respective given amounts, and securing the densities of other inks than the inks to be changed to standard densities.
The print color predicting system 10 according to the present embodiment is basically constructed as described above. A color converting method carried out by the print color predicting system 10 will be described below with reference to a flowchart shown in
First, known image data C, M, Y, K are supplied to the printing press 14, which is set to the standard density conditions which make the monochromatic densities of color patches equal to standard densities Dstd and prints a color chart C1 (standard density color chart) (step S1). The color chart C1 comprises a plurality of color patches printed in respective halftone dot % of the image data C, M, Y, K at predetermined intervals in the range from 0% to 100%.
The color chart C1 generated by the printing press 14 that has been set to the standard density conditions is measured for standard density spectral reflectances Rstd by the measuring unit 34 (step S2). The measured standard density spectral reflectances Rstd are stored in the measured value storage unit 36.
The print profile generator 50 calculates colorimetric values X, Y, Z or colorimetric values L*, a*, b* from the standard density spectral reflectances Rstd, and generates a standard density print profile representative of the relationship between the image data C, M, Y, K and the colorimetric values X, Y, Z or colorimetric values L*, a*, b* (step S3).
Then, the standard density conditions of the printing press 14 are changed to changing density conditions for obtaining given changing densities, and the printing press 14 prints color charts C1 (changed density color charts) using the same image data C, M, Y, K at predetermined intervals in the range from 0% to 100% as those for printing the color chart C1 under the standard density conditions (step S4).
The changing density conditions are conditions for individually changing the standard densities Dstd of the color patches produced with the inks C, M, Y, K by given density changes for the respective inks, and securing the densities of those inks other than the changed inks to the standard densities Dstd, so that the densities are −0.2, −0.1, +0.1, and +0.2, for example, smaller or greater than the standard densities Dstd in terms of optical densities. Accordingly, there are 16 color charts C1 generated under the changing density conditions with the densities of the colors C, M, Y, K being set to the standard density Dstd−0.2, the standard density Dstd−0.1, the standard density Dstd+0.1, and the standard density Dstd+0.2, respectively.
The color charts C1 generated by the printing press 14 under the changing density conditions are measured for changed density spectral reflectances R1 by the measuring unit 34 (step S5). The measured changed density spectral reflectances R1 are stored in the measured value storage unit 36.
It is assumed, for example, that the standard density spectral reflectance Rstd under the standard density conditions of a monochromatic density patch of only C is represented by RC(std), the spectral reflectance under the standard density conditions of a monochromatic density patch of only M by RM(std), the changed density spectral reflectance R1 under changing density conditions for changing the density of the monochromatic density patch of only C by a given density change by (RC(std)+ΔRC), and the changed density spectral reflectance under changing density conditions for changing the density of the monochromatic density patch of only M by a given density change by (RM(std)+ΔRM). Then, the spectral reflectance RCM under the changing density conditions for changing the density of color patches of C and M by the same given density change is ideally expressed as follows:
If the fourth term on the right side of the equation (1) is small enough to be regarded as 0, then the first term on the right side represents a standard density spectral reflectance Rstd produced when the color patches of C and M are generated under the standard density conditions, the second term on the right side represents the difference of a changed density spectral reflectance R1 produced by changing the density of only C of the color patches of C and M, from the standard density spectral reflectance Rstd, and the third term on the right side represents the difference of a changed density spectral reflectance R1 produced by changing the density of only M of the color patches of halftone dot percentages of C and M, from the standard density spectral reflectance Rstd.
Therefore, the changed density spectral reflectance RCM caused when the densities of both the colors C, M are changed can be determined by adding each spectral reflectance difference produced when one of the densities of the colors C, M is fixed and the other changed, to the standard spectral reflectance RC(std)·RM(std) under the standard density conditions.
The changed density spectral reflectance RCM(ALL−0.1) is approximately determined according to the equation:
and the changed density spectral reflectance RCM(ALL+0.1) is approximately determined according to the equation:
From the above results, a designated density spectral reflectance R, which is a spectral reflectance at the time C, M, M, K are changed to an arbitrary density under desired changing density conditions, is determined according to the following equation:
R=R
std
+R
ΔC
+R
ΔM
+R
ΔY
+R
ΔK (2)
based on the above equation (1), where Rstd represents a standard density spectral reflectance, RΔC a spectral reflectance difference at the time the density of only C is changed, RΔM a spectral reflectance difference at the time the density of only M is changed, RΔY a spectral reflectance difference at the time the density of only Y is changed, and RΔK a spectral reflectance difference at the time the density of only K is changed.
The difference calculator 38 calculates the spectral reflectance differences RΔC, RΔM, RΔY, RΔK for the corresponding color patches between the standard density spectral reflectances Rstd measured in step S2 and the changed density spectral reflectances R1 measured in step S5 (step S6), and stores the calculated spectral reflectance differences RΔC, RΔM, RΔY, RΔK in the difference storage unit 40.
Then, designated densities for the print P1 to be generated by the printing press 14 are designated by the designated density setting unit 42 (step S7). The print profile generator 50 calculates a designated density spectral reflectance R according to the equation (2), using the standard density spectral reflectances Rstd stored in the measured value storage unit 36 and the spectral reflectance differences RΔC, RΔM, RΔY, RΔK corresponding to the designated densities stored in the difference storage unit 40.
The spectral reflectance differences RΔC, RΔM, RΔY, RΔK stored in the difference storage unit 40 are generated based on the density changes adjusted such that they are −0.2, −0.1, +0.1, and +0.2, for example, smaller or greater than the standard densities Dstd in terms of optical densities. If there are no data corresponding to the density changes which represent the differences between the standard densities and the designated densities, then the spectral reflectance differences RΔC, RΔM, RΔY, RΔK can be determined by interpolating the spectral reflectance differences RΔC, RΔM, RΔY, RΔK in the vicinity thereof. The spectral reflectance differences may be interpolated by a known process such as linear interpolation, spline interpolation, polynomial approximation, or the like.
The spectral reflectance differences RΔC, RΔM, RΔY, RΔK thus calculated are added to the standard density spectral reflectance Rstd in the equation (2) to calculate a designated density spectral reflectance R for the designated density.
If only the standard density Dstd of C is to be adjusted, then a designated density spectral reflectance R is calculated by using only the spectral reflectance difference RΔC of C and setting the other spectral reflectance differences RΔM, RΔY, RΔK to 0. If the standard densities Dstd of C and M are to be adjusted, then a designated density spectral reflectance R is calculated by using the spectral reflectance differences RΔC, RΔM of C and M and setting the other spectral reflectance differences RΔY, RΔK to 0.
When the standard densities Dstd of all the four colors C, M, Y, K are adjusted to respective designated densities, a designated density spectral reflectance R can be calculated according to the equation (2). However, in the event that the color patches to be processed for calculating a designated density spectral reflectance R are in three colors C, M, Y, the spectral reflectance density RΔK should ideally be 0 irrespective of density changes of K. Actually, the spectral reflectance density RΔK (may not be 0 due to printing and measuring variations.
Consequently, when the standard densities Dstd of all the four colors C, M, Y, K are adjusted to respective designated densities, in the event that the color patches to be processed for calculating a designated density spectral reflectance R are in three colors C, M, Y, it is desirable to calculate a designated density spectral reflectance R with the spectral reflectance difference RΔK being set to 0. Similarly, in the event that the color patches to be processed for calculating a designated density spectral reflectance R are in two colors C, M, it is desirable to calculate a designated density spectral reflectance R with the spectral reflectance differences RΔY, RΔK being set to 0.
The print profile generator 50 calculates colorimetric values X, Y, Z or colorimetric values L*, a*, b*, for example, from the designated density spectral reflectance R, and generates a designated density print profile 20 which represents the relationship between the colorimetric values X, Y, Z or colorimetric values L*, a*, b* and the image data C, M, Y, K (step S8). The designated density print profile 20 thus generated is set in the color converter 16.
Known image data C, M, Y, K are supplied to the printer 18, which outputs a color chart C2 made up of a plurality of color patches onto a recording medium (step S9) in the same manner as the color chart C1 is printed (step S1).
The color patches on the output color chart C2 are measured for colorimetric values, e.g., colorimetric values X, Y, Z or colorimetric values L*, a*, b*, by the colorimeter 52 (step S10). The printer profile generator 54 generates a printer profile 22 which represents the relationship between the measured colorimetric values X, Y, Z or colorimetric values L*, a*, b* and the image data C, M, Y, K used to generate the color chart C2 (step 511). The generated printer profile 22 is set in the color converter 16. Since the printer profile 22 does not depend on the changing density conditions, the printer profile 22 may be generated only once unless the conditions of the printer 18 are changed.
After the designated density print profile 20 and the printer profile 22 have been set in the color converter 16 as described above, desired image data C, M, Y, K are supplied to the color converter 16 for color conversion, and the printer 18 generates a proof P2 (step S12).
The color converter 16 converts the image data C, M, Y, K into colorimetric values X, Y, Z using the designated density print profile 20, for example, and thereafter converts the colorimetric values X, Y, Z into image data C2, M2, Y2, K2 using the printer profile 22. If the designated density print profile 20 has been determined with high accuracy, then the colors of the proof P2 generated by the printer 18 agree highly accurately with the colors of a color sample generated from the image data C, M, Y, K.
The user then visually compares the proof P2 and the color sample with each other or measures the proof P2 colorimetrically for comparison. If the desired colors are not reproduced on the proof P2 (step S13), then the designated densities are corrected, and the process of generating the designated density print profile 20 with the print profile generator 50 is repeated (step S14). When a proof P2 of desired colors is produced, the designated density print profile 20 that has been used is determined as a desired designated density print profile 20.
When the designated density print profile 20 is determined, the designated density print color conversion table generator 26 of the editing device 12 acquires the determined designated density print profile 20 and the standard density print profile generated in step S3 from the profile generator 24, and generates a designated density print color conversion table using these profiles (step S15). The generated designated density print color conversion table is set in the print color converter 28.
The editing device 12 converts desired image data C, M, Y, K into image data C1, M1, Y1, K1 using the designated density print color conversion table set in the print color converter 28 (step S16), and supplies the image data C1, M1, Y1, K1 to the printing press 14 which has been set to the standard density conditions. A designated density print color conversion table, which is designated by 56 in
The printing press 14 produces a print P1 based on the converted image data C1, M1, Y1, K1. Though the printing press 14 has been set to the standard density conditions, it can produce a print P1 of designated densities without the need for changing its printing conditions to designated density conditions because the image data have been converted into the image data C1, M1, Y1, K1 by the designated density print profile 20 in order to produce a print P1 of designated densities. Therefore, the operator who handles the printing press 14 is not required to perform a process, which is complex and needs a lot of experience, for setting the printing press 14 to designated density conditions for achieving designated densities.
As shown in
Specifically, the designated density print color conversion table 60 includes the designated density print profile 20 which converts image data C, M, Y, K into colorimetric values X, Y, Z and a K-separation gradation converter 62 for converting the image data K into desired image data K1. The designated density print color conversion table 60 also includes the standard density print profile 58 which converts the colorimetric values X, Y, Z into image data C1, M1, Y1 based on the relationship between the colorimetric values X, Y, Z with fixed image data K1 and the image data C1, M1, Y1. The designated density print color conversion table 60 supplies the image data C1, M1, Y1, K1 to the printing press 14, which generates a print P1 wherein the desired black color is reproduced.
In the above description, the designated density print profile 20 is generated using the spectral reflectances of the color chart C1. However, the measuring unit 34 may comprise a spectral densitometer for measuring the spectral densities of the color chart C1, and a designated density print profile 20 may be generated from the spectral densities measured by the spectral densitometer.
Specifically, it is assumed, for example, that the spectral density under the standard density conditions of a color chart C1 of only C is represented by DC(std), the spectral density under the standard density conditions of a color chart C1 of only M by DM(std), the spectral density under given changing density conditions of a color chart C1 of only C by (DC(std)+ΔDC), and the spectral density under the given changing density conditions of a color chart C1 of only M by (DM(std)+ΔDM). Then, the spectral density DCM under the given changing density conditions of a color chart of C and M is expressed as follows:
The first term on the right side of the equation (3) represents a standard spectral density produced when a color chart C1 of C and M is generated under the standard density conditions, the second term on the right side represents the difference of a spectral density produced by changing the density of only C of the color chart C1 of C and M to given changing density conditions, from the standard density conditions, and the third term on the right side represents the difference of a spectral density produced by changing the density of only M of the color chart C1 of C and M to given changing density conditions, from the standard density conditions.
Therefore, the spectral density DCM caused when the densities of both the colors C, M are changed can be determined by adding the difference produced when one of the densities of the colors C, M is fixed and the other changed, to the standard spectral density (DC(std)+DM(std)) under the standard density conditions, as with the spectral reflectance RCM. Unlike the equation (1) for determining the spectral reflectance RCM, the spectral density DCM can be determined with high accuracy as the equation (3) is free of the term representing the error ΔRC·ΔRM.
As a result, in the profile generator 24, a target spectral density D at the time C, M, M, K are changed to an arbitrary density under desired changing density conditions is determined according to the following equation:
D=Dstd+D
ΔC
+D
ΔM
+D
ΔY
+D
ΔK (4)
like the above equation (2), where Dstd represents a standard spectral density, DΔC a spectral density difference at the time the density of only C is changed, DΔM a spectral density difference at the time the density of only M is changed, DΔY a spectral density difference at the time the density of only Y is changed, and DΔK a spectral density difference at the time the density of only K is changed. In the equation (4), the spectral density differences DΔC, DΔM, DΔY, DΔK are calculated according to the equation (2), thereby determining a designated density print profile 20 with respect to density changes from the standard densities Dstd.
In the event that the color patches to be processed for calculating the target spectral density D are in three colors C, M, Y, it is desirable to calculate the target spectral density D with the spectral density difference DΔK being set to 0. Similarly, in the event that the color patches to be processed for calculating the target spectral density D are in two colors C, M, it is desirable to calculate the target spectral density D with the spectral density differences DΔY, DΔK being set to 0.
A designated density print profile 20 may be generated using colorimetric densities or colorimetric values rather than the spectral reflectances or spectral densities.
In the above description, a designated density print profile 20 corresponding to density changes from the standard densities Dstd is determined. However, intermediate densities between the maximum and minimum densities of C, M, Y, K that can be printed by the printing press 14 may be set as standard densities, and a designated density print profile 20 may be generated based on a standard density color chart and a changed density color chart which have been generated according to the intermediate densities. The intermediate densities may be set as average values of the maximum and minimum densities or arbitrary values between the maximum and minimum densities.
Since the colors of the print P1 generated by the printing press 14 vary depending on the sheet of paper used for printing and the printing conditions including the inks, the dot gain, etc., the color converter 16 should desirably convert the image data in view of changes of such printing conditions.
The present invention is not limited to the illustrated embodiments, but may freely be changed or modified within the scope thereof.
Specifically, any image data C, M, Y, K supplied to the editing device 12 are converted by the print color converter 28 into image data C1, M1, Y1, K1 for producing a print P1 of designated densities, and the image data C1, M1, Y1, K1 are supplied to the color converter 72. In the color converter 72, the standard density print profile 58 converts the image data C1, M1, Y1, K1 into colorimetric values X, Y, Z, which are converted into image data C2, M2, Y2, K2 by the printer profile 22. The image data C2, M2, Y2, K2 from the printer profile 22 are supplied to the printer 18, which generates the proof P2.
The user then visually compares the proof P2 and the color sample with each other. If the desired colors are not reproduced on the proof P2, then the designated densities are corrected, and the process of correcting the designated density print color conversion table to set in the print color converter 28 is repeated until a proof P2 of desired colors is obtained. When a proof P2 of desired colors is obtained, a designated density print color conversion table is determined.
For example, the print color predicting system 10 employs the printer 18 to generate the color chart C2 and the proof P2. However, the print color predicting system 10 may employ a color monitor, for example, to display the color chart C2 and the proof P2. In this case, the profile generator 24 colorimetrically measures the color chart C2 displayed on the color monitor, generates the designated density print profile 20 and a monitor profile based on the measured colorimetric values, and sets the designated density print profile 20 and the monitor profile in the color converter 16.
The designated density print profile 20 may be generated with respect to an arbitrary number of colors, e.g., two or more colors, rather than the four colors C, M, Y, K.
The color materials for use on the print P1 are not limited to inks, but may be toners, for example.
Although certain preferred embodiments of the present invention have been shown and described in detail, it should be understood that various changes and modifications may be made therein without departing from the scope of the appended claims.
Number | Date | Country | Kind |
---|---|---|---|
2008-283503 | Nov 2008 | JP | national |