DE19617016A1 - Procedure for controlling colour rendering of offset printer - Google Patents

Abstract

A procedure for controlling the colour rendering of an offset printing machine in the three basic colour channels: cyano-blue, magenta and yellow employs a combination sensor for measuring the colour densities and spectra of the printed output at preselected points over its surface. The fast response feature of the sensor system enables signals quantifying observed colour deviations wrt. a previously established ideal obtained either by direct spectral analysis or from pre-run data to be continuously monitored. Differences are converted into corrective changes to the thickness of the respective colour deposits as a result of corresponding regulation of the colour metering controls.

Description

In offset printing, the desired colors of the reproductions are printed on the print fabric by overprinting a small number of basic colors, e.g. B. 4 made. Of the The main thing is that the color tone depends on the color of the substrate Layer thickness and the degree of screening of the primary colors used in the stack pressure, as well as from the so-called dot gain. The screening is in the prepress fe determines and sets the desired degree of weakening of the color impression of the rei a basic color at each point in the image. The increase in tonal value changes this originally desired weakening due to mechanical and optical we mechanisms by z. B. the halftone dots are flattened and thus a vi cause higher tonal value. However, this can be observed in prepress and be compensated so that the desired tonal value is produced again in the print. Problema The trend or random fluctuations in the tone of the print appearing in the table increase in value. Trendy deviations due to mechanical properties can only be selected by changing the layer thicknesses of the basic colors according to one th quality criterion. There are short-term random deviations no remedy, they are the equivalent of noise in electronic amplifiers and must be taken into account when defining tolerances.

The layer thicknesses of the primary colors serve for the screening of the individual colors in the print preamp as a constant parameter, so they usually have to be in specific To tolerance ranges remain. For the reasons explained above, later printing a constant deviation of the solid color density may be necessary in order to to achieve softening in the subject.

The layer thicknesses of the pure primary colors are measured on so-called full-tone Control areas by densitometers in the wavelengths defined by a DIN standard areas determine the ratio of incident light to reflected light. Interes Only the independent channels for CYAN (C), MAGENTA (M) and YELLOW (Y) are relevant. Of the Density value for BLACK (K) is usually calculated mathematically from the three independent Density values calculated. However, in the case of a measurement, it also provides its own Black channel is not usable information because there is no specific spectral range for "black" (apart from near infrared), and the black filter in principle Broadband filter is. The C, M and Y densities used in the text therefore represent a triple or also a vector of density values without a value for black.  

Color measuring devices with 3 are used to measure the color tones, especially in combination printing Filter channels (tristimulus) based on the eye sensitivity curves. Modern Messge Councils also use spectrophotometers with more than 30 channels, which can be action of the measured values in the channels simulate eye sensitivity.

A method is known from the patent specification DD 2 27 094 which is based on test prints of all occurring primary and mixed colors, the absolute proportions of these colors in the target and actual sheet determined and the comparison of these proportions to control the coloring uses. A disadvantage of this method is u. a. the effort to create the test prints and the use of the absolute proportions to control the coloring because this way colors that are based on different printing processes can never be compared ren.

A method is known from DE 43 11 132 A1 in which complete spectra at the actual and target measuring points as a linear combination of the spectra of the individual color involved in the printing ben are shown. The difference of the coefficients of the linear combination of the actual spec and the coefficient of the linear combination of the target spectrum is used to control the Coloring exploited. This saves the printing of all possible combinations of colors, but has the disadvantage that only prints of the same production technology, but z. B. no offset prints can be compared with target values from a proofing device.

From DE 43 43 905 A1 a method is known in which the spectral differences opti times broken down into weighted portions of the existing basic spectra. This method also allows the processing of spectral deviations between actual spectra and with another spectra produced target spectra, but has the disadvantage that always the entire spectrum must be won. Even with newer spectrometers, measurements last solutions much longer than with a simple densitometer, so that z. B. not with required speed in a control strip or in a continuous image range can be measured.

Starting from the prior art, the object of the present invention is an accurate but quick statement about the size and direction of the layer thickness to make changes to the basic colors involved, without the disadvantages of the above deletion to accept solutions.

This problem is solved by the characterizing features of claim 1 The inventions result from the subclaims.  

According to the invention, the density values in the channels for C, M and Y and the complete spectra of the colors involved in the printing at locations on the printing sheet measured on which the color prints as a pure solid. Alternatively, the values from ei taken from a database.

Then the measuring points are defined: This is done either in the preliminary stage hand the image information available there or with a teachin system, e.g. B. a La ser pointer, which is mounted on a positioning system.

C, M and Y setpoints can be obtained in the simplest form by measuring a sample be. If setpoints are only available in digital form in prepress, C, M and Y density values are determined by transformation rules, as they are in everyone today Image processing software are implemented. The decisive factor in the transformation is Black is not used as a co-printing color, since black does not contribute an independent part the density values.

The measurement is now preferably carried out with an automatic measuring system on all ge wanted parts of the picture. A combined measuring head is used for the measurement of spectra with more than 30 channels and density values from 3 channels. For the one-off determination of the Color spectra at the measuring locations require complete spectra. The knowledge the color composition, i.e. the proportions of the printing colors, is a prerequisite for Treatment of colors which, unlike the Euro colors C, M and Y, are not characteristic Main density, but like the printing ink black in more than one density channel have significant density values. During the time-critical process measurements only density values from the densitometer part of the combination measuring head are used.

The C, M, and Y density values obtained during the measurement are processed unit collected. The data is then differentiated from the measured data or calculated target C, M and Y density values. If one of the differences is exceeded The quality criterion formed is divided into the C, M and Y differences Measuring point involved in printing individual colors z. B. according to the principle of the smallest deviation squares. The differences are component by component as sums of product coefficients with C, M and Y values of the individual printing inks, with area coverage values and empirical weighting factors are presented in the form of a system of equations. After solving the system of equations, the coefficients result from themselves knew calculation methods. The coefficients are then correlated using characteristic curves in full tone density changes and then converted into slider changes. There in particular, there are an infinite number of different solutions to the system of equations possible if one or more printing inks have high density values in all spectral ranges  have. The division that corresponds to an expanded Gü is then selected Leaving the optimal layer thickness of offset printing the least. An Aussa ge over the current full tone layer thickness can be measured by direct measurement of full tone fields on Edge of the sheet or from other measuring surfaces in a zone. Alternatively, the treasure takes place increase of the solid color densities by color separation at measuring points with high area coverage divide in the color of interest.

When dividing the density differences, current or known information about the trapping behavior or z. B. include spectral non-linearities. It is Z. B. be knows that the reprinting colors with their main and secondary densities are not simply for Density of the first printing color can be added. The reason is not ideal Remission behavior of the real colors. This becomes very clear when printing opaque white in last inking unit. Opaque white outshines all pre-printing colors. That kind of glare The effects of compensation can be compensated for the behavior around the working point be described empirically.

Several measuring points within a color zone can be combined in one the quality function are taken into account, whereby for the various measuring points according to ih other weighting factors can be selected.

An example should illustrate the procedure:
Select a measuring point on a template and ensure that this measuring point is approached with sufficient accuracy by the automatic measuring system during the later process measurement. The density measurement on the template gives density values in channels C, M and Y to (c1, m1, y1). The information from the preliminary stage or the described spectral decomposition state that the colors C, M, Y, and K print in the inking units with proportions of (cfd%, mfd%, yfd%, kfd%) solid color density. The printing ink black is therefore noticeably involved in collective printing. From a mathematical point of view, there are an infinite number of decomposition options. It is therefore important to limit the variety of solutions to the system of equations by means of boundary conditions and to select a solution. The procedure is as follows:
The pure colors have the following CMYK density vectors:
C: (c100c, c100m, c100y)
M: (m100c, m100m, m100y)
Y: (y100c, y100m, y100y)
K: (k100c, k100m, k100y).

The measurement on the printed product during production gives the density values (c2, m2, y2) and thus the deviations from the setpoint (delta c, delta m, delta y). The rejection Quality criterion "Root of the individual squares of deviation" lies above a selected one th value, and so there is a need for countermeasures. Measuring the full tone density in the zone in question gives the values (C, M, Y, K) for CMYK. The color black (K) is in the example at the lower edge of the optimal range (Kmin, Kmax), therefore should the process increases the black layer thickness.

The following system of equations can be solved in the simplest case. If there are more than 4 basic printing colors, additional summands would be added.
(delta c, delta m, delta y)
=
Kc _* Gc _* Fc _* (c100c, c100m, c100y)
+ Km _* Gm _* Fm _* (m100c, m100m, m100y)
+ Ky _* Gy _* Fy _* (y100c, y100m, y100y)
+ Kk _* Gk _* Fk _* (k100c, k100m, k100y)
+ f (Kc, Km, Ky, Kk).

The solution of the system of equations gives numerical values of the factors Kc, Km, Ky, Kk. These factors become apparent to the printer after multiplying by the zonal solid densities shown so that he can implement them in changes to the zone control elements. Alternatively, you can also a direct implementation in slider changes take place, known or current learned characteristics can be used, the relationship between full tone Describe the change in density and slide change specifically for this zone.

Reference list

C CYAN
M MAGENTA
Y YELLOW
K BLACK
delta c cyan - component of the differential density vector to be adjusted
delta m magenta - component of the differential density vector to be adjusted
delta y Yellow - component of the differential density vector to be adjusted
c100c Cyan - component of the density vector of the basic color cyan
c100m Magenta - component of the density vector of the basic color cyan
c100y Yellow - component of the density vector of the basic color cyan
m100c Cyan - component of the density vector of the base color magenta
m100m Magenta - component of the density vector of the basic color magenta
m100y Yellow - component of the density vector of the base color magenta
y100c Cyan - component of the density vector of the basic color yellow
y100m Magenta - component of the density vector of the basic color yellow
y100y Yellow - component of the density vector of the basic color Yellow
k100c Cyan - component of the density vector of the basic color black
k100m Magenta - component of the density vector of the basic color black
k100y Yellow - component of the density vector of the basic color black

Gc empirical weighting factor of the density vector of the basic color cyan for Trapping, color drop etc.

Gm empirical weighting factor of the density vector of the basic color magenta for Trapping, color drop etc.

Gy empirical weighting factor of the density vector of the basic color Yellow for Trapping, color drop etc.

Gk empirical weighting factor of the density vector of the basic color black for Trapping, color drop etc.

Fc area coverage factor of the basic color cyan at the measurement location
Fm area coverage factor of the primary color magenta at the measuring location
Fy area coverage factor of the basic color yellow at the measuring location
Fk area coverage factor of the basic color black at the measuring location
Kc Share of the weighted basic color cyan in the cyan component of the differential density vector to be controlled
Km portion of the weighted base color magenta in the magenta component of the differential density vector to be adjusted
Ky Share of the weighted basic color yellow in the yellow component of the differential density vector to be adjusted
Kk Share of the weighted basic color black in the black component of the differential density vector to be adjusted
f (Kc, Km, Ky, Kk) function with the arguments Kc, Kin, Ky and Kk for modeling the boundary conditions in the search, e.g. B. Restriction of the search area

Claims (5)

1. A method for controlling the coloring of a printing press by density measurements in the channels C, M, and Y on the entire printing surface, characterized in that

• - the printing area coverage parts a) from each measuring location on the printing sheet are determined a) by spectral color decomposition of the current spectrum into parts of the individual spectra or b) by transferring the data from the digital prepress,
• - Once the setpoints in channels C, M and Y using an optimal synthesis z. B. can be simulated using the least squares method from spectral components of the primary colors actually printing if no measurements on a Sollbo gene or a comparable pattern are possible,
• the target-actual differences in the channels C, M, Y are printed out as a weighted sum of products of the determined printing area coverage components with the basic color-specific C, M, Y values and empirical coefficients,
• - The variety of possible solutions for the weighting factors of the sum components are limited by boundary conditions that take into account a distance of the current layer thickness from the optimal area in the quality criterion of the optimization process,
• the density differences determined in this way are converted into full tone changes in accordance with the grid density / solid density characteristic curves known or continuously monitored and adapted from preliminary tests, using the printing area portions determined in the first method step,
• - the full tone changes determined in this way are converted into changes in the actuators using methods known per se,
• - Regular checks of the layer thicknesses of the process colors are carried out using printed control fields and the direction of the deviation from the optimal range is included in the calculation of the next control step in such a way that there is always a reduction of these impermissible deviations or at least an error message.

2. The method according to claim 1, characterized in that empirically or analytically determined weighting factors of printing influences (trapping, ink drop) for each channel C, M and Y are taken into account in the system of equations, whereby these a reduced or increased effectiveness of the reprinting colors and thus accompanying non-linearity in the additive superposition of the density values of the Reflect primary colors.   3. The method according to claim 1 and 2, characterized in that in addition to today's übli narrowband density values, broadband density values can also be used. 4. The method according to claim 1 to 3, characterized in that for calculating the Control data also densities in the infrared range for determining layer thicknesses strong opaque process colors can be used. 5. The method according to claim 1 to 4, characterized in that several measuring points per Zone with individual or uniform weighting together in the division related.