WO1993003574A1 - Process and printing device for producing screen angles in the digital printing process - Google Patents

Abstract

Digitally coded signal value (SWY, SWM, SWC, SWK) separated according to the colour intensities (IY, IM, IC, IK) of colour pixels of a pattern (V) are converted by the process and device by means of sets (k) of conversion matrices (KMY, KMM, KMC, KMK). The converted signal values (SWY, SWM, SWC, SWK) are then arranged in lines and columns with the aid of a modulo calculation for a colour print (Y, M, C, K) in a graphic format (GFY, GFM, GFC, GFK) in such a way that a screen angle for the colour print (Y, M, C, K) concerned is set in line and column-overlapping combination of the converted signal values (SWY, SWM, SWC, SWK).

Description

Method and printing device for generating screen angles in digital color printing

The invention relates to a method and a printing device for generating screen angles in digital color printing according to the preamble of claims 1 and 3, respectively.

Halftone processes are methods known in printing technology for controlling the output of shaded image areas via the size of the image pixels to be reproduced. Larger pixels produce darker areas, while small pixels result in lighter areas. The resolution of an image is determined either by the number of pixels per inch or, if the pixels are combined in image lines, by the number of image lines per inch used. The latter is called the screen frequency and is measured in lines per inch (lpi). The halftone process, originally used in analog printing technology, is also used in a modified form in digital printing technology, e.g. B. applicable in printing devices such as ink, matrix and laser printers and in laser imagesetters, for the output of monochrome and colored image areas. In contrast to the conventional halftone process in analog printing technology, where the size of a pixel can be varied, only pixels of constant size, so-called "dots", can be printed in digital printing technology. The resolution that can be achieved with such digital output devices is therefore also given in dpi (dots per inch). Since a digital output device cannot vary the size of the dots and therefore there is no real halftone process, one is forced to emulate the halftone process. In this pseudo-halftone process, groups of dots are combined into larger dots. The geometry of these groups of dots results in a larger area considered, again the typical line pattern known from the real halftone process from analog printing technology. From the thickness of these lines, the resolution of an image in lpi (lines per inch) can then be specified.

The conventional halftone process used in analogue printing technology is even more complex for the digital printing technique in the reproduction if shaded color areas and the finest differences in color nuance (different gray values) are to be printed. The gray value of a color is the intensity of a color, e.g. For example, a red with a low gray value appears as pale pink, a red with a high gray value as a full, rich color. For color images, each subtractive basic color (cyan, magenta and yellow) has its own basic pattern for the arrangement of the pixels. The term subtractive basic color means that if white light (mixture of the additive basic colors red, green and blue (RGB colors)) is reflected on the subtractive basic color, then each of these subtractive basic colors absorbs at least one color of the additive Primary colors. The whole picture is created by printing the subtractive basic colors and additionally the color black successively (according to the overlay principle). The subtractive basic colors (cyan, gastric ta, yellow) and the color black are referred to below as basic colors (C, M, Y, K. for cyan, magenta, yellow and black). The printing of the color black is necessary because, due to color impurities in the subtractive primary colors, the additive mixture of these three subtractive primary colors does not produce a pure black tone. In the conventional halftone process in analog printing technology, a so-called screen angle is used for each of the primary colors C, M, Y, K. The screen angle is the angle at which the image lines of the basic color C, M, Y, K are rotated with respect to the horizontal. Both in analog and digital printing technology Screen angles used for the individual primary colors C, M, Y, K are, for example, screen angles of 0 ° or 90 °, 15 °, 45 ", 75" in the order mentioned for the colors yellow, magenta, black and cyan. The screen angle of 90 ° for the color yellow means only a rotation of the screen by 90 ° with respect to the 0 ° screen, without changing anything for the print image to be created.

There are two main reasons for using these screen angles.

On the one hand would without a screen angle in the, for. B. with printing plates in analog printing technology to print the basic colors even with the smallest adjustment errors of the printing plates so-called Moirέ effects arise. Because of these Moirέ effects, interference patterns disturb the overall impression of the image in the intersection of the four primary colors C, M, Y, K.

On the other hand, the basic colors C, M, Y, K used in analog printing technology are not really transparent for cost reasons, so that the image pixels of the individual basic colors C, M, Y, K have to be offset from one another in order to Avoid false colors due to extensive color overlaps.

Both reasons are decisive for both analog and digital color printing. In the case of digital color printing, however, it is made more difficult that digital output devices have to emulate the halftone process by combining groups of dots into larger dots. This is done, for example, by forming base or halftone cells. The basic or halftone cell is a square matrix of dots and its size corresponds approximately to the pixels in the conventional analog printing process. The square matrix is a dither matrix generated according to the dither method known to the person skilled in the art. Thus, the dither method is spielsweise in the publication "Digital Halftoning for Monochrome and Color Printing" a Tutorial Presented March 20, 1988 at SPSE's 4th International C ^'ongress on Advances in Non-I pact Printing Technologies, News Orleans, Louisiana by Mr. G. Thompson and Mr. G. Goetzel. The number of color gradations that can be represented with such a square matrix or halftone cell is identical to the number of replaceable matrix or cell elements plus an additional color gradation (color tone white) if no matrix or cell element is set. How well the halftone process can be reproduced in digital color printing essentially depends on four parameters:

(i) the size of the dot,

(ii) the size of the square matrix or the semitone cell, (iii) the degree of filling of the square matrix or semitone cell,

(iv) the screen angle.

Running z. B. to achieve a 50 Ipi (lines per inch) image resolution, a 6x6 halftone cell with 36 cell elements is required in a 300 dpi printer. The degree of filling of this halftone cell indicates how many cell elements (dots) are set. If, for example, nine cell elements are set in the 6x6 halftone cell, this corresponds to a degree of filling of 25%. If these halftone cells are strung together in rows and columns over larger areas, they appear as rows, the raster angle indicating the angle of these rows to the horizontal or vertical.

The purpose for which the matrix or halftone cells are designed is decisive. For example, If a color separation is to be carried out, care must be taken that the screen angle and the screen filling of the matrix or halftone cell are optimized such that, if possible, no moiré patterns are produced. If you still want to print out a color, e.g. B. create with a thermal transfer printer, the matrix or halftone cell must also be designed so that the cleanest possible and rich colors. For this, it is advantageous if the number of matrix or cell elements is as small as possible, since this increases the image resolution.

For this purpose, many graphics and DTP (desk top publishing programs) used in digital printing technology today offer the possibility of directly specifying the values for the screen frequency and the screen angles of the primary colors. The optimal setting depends on the digital output device used in each case. Many of the color printers on the market today use the standard Postscript interpreter from Adobe. This defines a 6x6 matrix or halftone cell, which is equivalent to a printer resolution of 300 dpi and an image resolution of 50 lpi. The Postscript interpreter is designed to support a large number of different digital output devices from monochrome printers to high-resolution laser imagesetters. The Post-Script interpreter uses color angles based on the usual screen angles of the halftone method, so-called default angles.

Another possibility of avoiding moiré patterns due to the smallest adjustment deviations is to design the mechanics of a digital output device for extremely precise adjustment of the recording medium to be printed on the device.

From WO 90/05423 is a device and a Process known with which or with which shaded color areas and the finest differences in color shade are printed according to the halftone method. In order to avoid occurring moiré patterns, a screen angle is introduced for each color printout. To generate these screen angles, dither matrices produced according to the dither method are rotated with respect to their coordinates by a 3x3 transformation matrix. For the coordinate rotation of the dither matrix, such a large computing effort is required that this z. B. with a requirement to print 20 pages (A4) per minute with a maximum of 80 color expressions for a four-color printer, even with the fastest microprocessors currently available cannot be handled in time.

It is therefore the object of the invention to provide a method for generating color angles in digital color printing, in which the color angles are generated in a simple manner without great computation effort.

It is also an object of the invention to provide a printing device for generating color angles in digital color printing, in which the color angles are generated in a simple manner without great computation effort.

These objects are achieved the features indicated in the characterizing part of claims 1 and 3 by _^.

With the method according to the invention and with the printing device according to the invention, in digital color printing with the aid of a modulo calculation, screen angles are generated from a set of conversion matrices (dither matrices) without the printing throughput (number of printed recording media) per minute) because of too long computing times in the generation of the screen angles. With the method according to the invention, with larger print throughputs (e.g. 20 pages per minute). The method also offers the advantage that no additional software expenditure is required for the modulo calculation for programming a central unit (microprocessor) which converts digitally coded, color-separated signal values. The modulo calculation rule is implemented in many known microprocessors.

Advantageous developments of the invention are specified in the subclaims.

An embodiment of the invention is explained with reference to the drawings of Figure 1 to Figure 10. Show it:

FIG. 1 shows a flow diagram for digital color printing in block diagram representation,

FIG. 2 shows a microcomputer system of a printing device for carrying out the flow chart shown in FIG. 1,

3a to 3d a set of 4x4 conversion matrices for the basic color cyan, each with a degree of filling of 25%,

4a to 4d a set of 4x4 conversion matrices for the basic color magenta, each with a degree of filling of 50%,

Figure 5 is a cross-line, a screen angle of 75 ^*-generating arrangement of the Konversionsmatrizen for the color cyan in accordance with Figures 3a to 3d,

FIG. 6 shows a cross-column arrangement of the conversion matrices for the basic color magenta according to FIGS. 4a to 4d, producing a screen angle of 15 °,

FIG. 7 shows a 4x4 conversion matrix for the basic color yellow with a degree of filling of 50%, FIG. 8 shows a 4x4 conversion matrix for the basic color black with a degree of filling of 25%,

FIG. 9 shows an arrangement of the conversion matrix for the basic color yellow according to FIG. 7 spanning rows or columns and producing a screen angle of 90 ″,

FIG. 10 shows an arrangement of the conversion matrix for the basic color black according to FIG. 8 that spans rows or columns and generates a raster angle of 45 ^* .

Figure 1 shows a block diagram of a flow chart for digital color printouts, z. B. in ink, thermal transfer and laser printers. However, the sequence diagram can also be used in the combination of laser imagesetter and analog printing technology. The sequence shown begins with the fact that color pixels of a template V contain the basic colors Y, M, C, K (yellow, magenta, cyan and black) in digitally coded color intensities IY, IM, IC, IK of the color pixels Signal values SWY, SWM, SWC, SWK can be separated. This process, known as color separation, is known to the person skilled in the art. B. known from the publication "Digital Halftoning for Monochrome and Color Printing" and WO 90/05423. The color intensities IY, IM, IC, IK determined in the color separation are, for example, for the basic color yellow Y with IY = 50%, for the basic color Magenta M with IM = 50%, for the basic color cyan C with IC = 25 % and for the basic color black K with IK = 25%. For the subsequent conversion of the separated, digitally coded signal values SWY, SWM, SWC, SWK there is a set k of conversion matrices KMY, KMM, KMC, KMK for the corresponding color intensities for each basic color Y, M, C, K. IY, IM, IC, IK available. Based on the color intensity values given in FIG. 1, this means that there is a set of conversion matrices KMY for the basic color yellow Y with a degree of filling of 50%, a set of conversion matrices KMM for the basic color Magenta M with a degree of filling of 25% etc. Dither matrices are preferably used as conversion matrices KMY, KMM, KMC, KMK, but these can also be replaced by any other conversion matrices. The dither matrices and the dither method are known to the person skilled in the art from the publication "Digital Halftoning for Monochrome and Color Printing" and WO 90/05423. A detailed description in the context of this exemplary embodiment is therefore omitted.

The set k of conversion matrices KMY, KMM, KMC, KMK is freely selectable in terms of the number k of its conversion matrices. So z. For example, the set k of conversion matrices consists of k = 4 conversion matrices KMY, KMM, KMC, KMK. Instead of four matrices, two, three or any number of matrices can also be contained in the set k (k = 1 ... N, where N is a natural number). It is only important for the set k of conversion matrices KMY, KMM, KMC, KMK that each individual conversion matrix KMY, KMM, KMC, KMK does not differ from the others with regard to the color intensity IY, IM, IC, IK to be reproduced.

In the present exemplary embodiment (for k = 4: FIGS. 3a to 3d and FIGS. 4a to 4d; for k = 1: FIG. 7 and FIG. 8), where e.g. B. 4x4 conversion matrices each with 16 matrix elements ME are used, this means that the number of matrix elements ME set in the set k of conversion matrices KMY, KMM, KMC, KMK is the same for all matrices . In order to convert the individual signal values SWY, SWM, SWC, SWK and then to arrange them in graphic formats GFY, GFM, GFC, GFK in rows or columns for color printouts of the basic colors Y, M, C, K to be successively produced on a recording medium AT , the conversion matrices KMY, KMM, KMC, KMK are used for the arrangement across rows or columns in the graphic format GFY, GFM, GFC, GFK from the set k of conversion matrices KMY, KMM, KMC, KMK for each basic color Y, M, C, K using the calculation formulas: n = line of the graphic format od k (1) or n = column of the graphic format mod k (2) selected, where n is the current conversion matrix KMY, KMM, KMC, KMK to be arranged in the row or column of the graphic format GFY, GFM, GFC, GFK for the signal values SWY, SWM, SWC, SWK and k is the number of conversion matrices KMY, KMM, KMC, KMK in the respective set k. The value n can assume the numerical values n = 0, n = 1, n = 2 and n = 3 for k = 4 and at the beginning with the row or column "0". Depending on whether the graphic format GFY, GFM, GFC, GFK is generated in rows or columns, for the selection of the conversion matrix KMY, KMM, KMC, KMK from the set k of conversion matrices either the calculation formula (1) or the calculation formula (2 ) be used.

FIG. 2 shows a microcomputer system 1 of a printing device 2, which is connected to a mainframe 3 (HOST) (double arrow in FIG. 2). The printing device 2 is designed, for example, as a single-pass printer. In contrast to the multi-pass printer, in the case of such a type of printer, a recording medium to be printed for the individual color printouts is guided past several color print heads in succession. However, this also increases the risk that register errors will occur. These register errors are then the cause of the moiré pattern mentioned at the beginning. The color-separated signal values SWY, SWM, SWC, SWK of the template V according to FIG. 1 are transferred from the mainframe computer 3 to the microcomputer system 1 sequentially for conversion. For this purpose, the microcomputer system 1 has a SCSI interface module 10, which is connected via a common bus 11 for a microprocessor 12, a working memory 13 (RAM), a mass memory 14, e.g. B. egg ne hard disk memory, and four FIFO modules 15 ... 18 (FIFO = First In First Out) known to those skilled in the art are connected to them. In the working memory 13 of the Mikrocom¬ computer system 1, the various sets are k of convergence sionsmatrizen KMY, KMM, KMC, KMK for the ^'basic colors Y, M, C, K with the different color intensities IY, IM, IC, IK stored. With the transfer of the separated signal values SWY, SWM, SWC, SWK from the mainframe 3 via the interface module 10 to the microprocessor 12, the microprocessor 13 accesses the data in the converter for converting the separated signal values SWY, SWM, SWC, SWK Working memory 13 stored sets k of conversion matrices KMY, KMM, KMC, KMK. Access is based on the formula (1) and (2). The modulo calculation carried out in this calculation form can be carried out in a simple manner without great computation effort, since the calculation steps necessary for this calculation can be carried out without additional programming with the microprocessor 12. However, in order to be able to carry out the modulo calculation according to the calculation formulas (1) and (2), either the row or the column of the graphic formats GFY, GFM, GFC, GFK buffered in the mass memory 14 must be used for the converted signal values SWY, SWM, SWC , SWK be known. This can also be achieved by means of a memory management for the mass storage 14 carried out by the microprocessor 12. If all of the signal values SWY, SWM, SWC, SWK converted in the graphic format GFY, GFM, GFC, GFK are temporarily stored in the mass memory 14 by the dither method, the stored values can be accessed by the microprocessor 12 in the mass memory 14 by means of specifically controlled accesses Via the FIFO modules 15 ... 18 in the order in which they were saved, they can also be output again to print modules 4 ... 7 for the primary colors Y, M, C, K. By activating the printing modules 4 ... 7 of the printing device 2, the color printouts are then made in accordance with the template V 1 printed successively on the record carrier AT.

In order for the color pixels of the original V to be printed out on the recording medium without a moiré pattern, the individual color prints must be applied to the recording medium AT with a different screen angle. How these screen angles are generated for the individual color printouts is described below.

3a to 3d show four (set k with k = 4) conversion matrices KMC, each with 16 matrix elements ME for the basic color cyan. Each of these four conversion matrices KMC has four set matrix elements ME (black rectangles in FIGS. 3a to 3d). The number of matrix elements ME set corresponds exactly to the degree of filling of the respective conversion matrix KMC. With four set matrix elements ME of 16 possible, this corresponds to a degree of filling of 25%. This degree of filling corresponds exactly to the color intensity IC of the separated signal value SWC according to FIG. 1. The four set matrix elements ME of the four conversion matrices KMC are not selected arbitrarily, but rather in a targeted manner for generating a raster angle for the basic color cyan C. From the analog printing technology, for the basic color cyan z. For example, a screen angle of 75 "to the horizontal is shown to be optimal. When emulating the halftone process for digital printing technology, efforts are therefore made to maintain this screen angle. The four conversion matrices KMC thus result in the figures 3a to 3d Arrangement shown in which the set matrix elements ME of the conversion matrices KMC are arranged in columns, each in different micro-columns MSP, for the creation of the graphic format GFC with 12 lines (lines 0 to 11) and 12 columns (columns 0 to 11) ) according to FIG. 5, the conversion matrices KMC according to FIGS. 3a to 3d arranged row by row in order to generate the required screen angle of 75 "for the column elements ME arranged in columns, in the different microgaps MSP. In this case, if the calculation formula (1) for rows" 0 "to" 11 "at k = 4 calculated value n assumes the numerical value n = 0, n = 1, n = 2 and n = 3, which corresponds to the conversion matrix KMC corresponding to these numerical values according to FIGS. 3a to 3d in the respective line" 0 "to" 11 "arranged.

4a to 4c show four (set k with k = 4) 4x4 conversion matrices KMM for the basic color magenta M. Corresponding to the color intensity IM of the separated signal value SWM of 50% according to FIG. 1, all conversion matrices KMM also have one Filling level of 50%. This in turn means that half of the 16 matrix elements ME are set by each conversion matrix KMM. The setting of the individual matrix elements ME is again not arbitrary, but is based on a screen angle of 15 ^* to the horizontal that is optimally highlighted for the basic color Magenta M in analog printing technology. When this raster angle and the degree of filling are taken into account, z. For example, the arrangement set in FIGS. 4a to 4d, in which the set matrix elements ME of the conversion matrices KMM are arranged line by line, in each case in different micro-lines MZE. For the creation of the graphic format GFM with again 12 rows (rows 0 to 11) and 12 columns (columns 0 to 11) according to FIG. 6, the conversion matrices KMM in FIGS. 4a to 4d are arranged column by column by the required screen angle of 15 ^* for the matrix elements ME arranged line by line in the micro-lines MZE different in pairs. Here, if the value n calculated with the calculation formula (2) for the columns "0" to "11" at k = 4 assumes the numerical value n = 0, n = 1, n = 2 and n = 3, that of the latter Numerical values 4a to 4d, the corresponding conversion matrix KMM was arranged in the respective column "0" to "11".

FIG. 5 shows the graphic format GFC created from the four conversion matrices KMC in accordance with FIGS. 3a to 3d, as it is temporarily stored in the mass memory 14 according to FIG. 2 for the color expression of the basic color cyan C. The graphic format GFC is structured line by line, i. H. The individual conversion matrices KMC according to FIGS. 3a to 3d are arranged line by line with the aid of the calculation formula (1). In the inter-line interaction, the areal arrangement of the conversion matrices KMC shown in FIG. 5 shown in FIGS. 3a to 3d results from this. FIG. 5 shows that the grid angle of 75 ° automatically results for the conversion matrices KMC arranged in the manner described.

FIG. 6 shows the graphic format GFM created from the four conversion matrices KMC according to FIGS. 4a to 4d, as it is temporarily stored in the mass memory 14 according to FIG. 2 for the color printout of the primary color magenta M. The graphic format GFM is structured in columns, ie the individual conversion matrices KMC according to FIGS. 4a to 4d are arranged in columns using the calculation formula (2). In the inter-column interplay, this results in the areal arrangement of the conversion matrices KMM shown in FIG. 6 according to FIGS. 4a to 4d. FIG. 6 shows that for the conversion atrices KMM arranged in the described manner, the screen angle of 15 ^* automatically results.

FIG. 7 shows a (set k with k = l) 4x4 conversion matrix

KMY for the basic color yellow Y. According to the color intensity IY of the separated signal value SWY of 50%

FIG. 1 also shows the conversion matrix KMY degree of efficiency of 50%. This in turn is equivalent to the fact that half of the 16 matrix elements ME of the conversion matrix KMY are set. The setting of the individual matrix elements ME is again not arbitrary, but is based on an angle of 90 ° to the horizontal that is optimally emphasized in the analog printing technology for the basic color yellow Y. Likewise, the screen angle could also have been 0 °, without this having changed anything in the printed image. If the grid angle of 90 ° and the degree of filling are taken into account, B. the arrangement set in FIG. 7, in which the set matrix elements ME of the conversion matrix KMY are arranged in two microgaps MSP. The creation of the graphic format GFY with again 12 rows (rows 0 to 11) and 12 columns (columns 0 to 11) according to FIG. 9 does not actually need the calculation formula for the basic color yellow Y with the separated color intensity IY of 50% (1) or (2), because the calculated numerical value n will always be n = 0. The calculated numerical value n = 0 means that in the graphic format GFY, each column / row field is occupied with the conversion matrix KMY indicated in FIG.

FIG. 8 shows a (set k with k = l) 4x4 conversion matrix KMK for the basic color black K. According to the color intensity IK of the separated signal value SWK of 25% according to FIG. 1, the conversion matrix KMK also has a degree of filling of 25%. on. This in turn means that half of the 16 matrix elements ME of the conversion matrix KMK are set. The setting of the individual matrix elements ME is again not arbitrary, but is based on an angle of 45 ° to the horizontal that is optimally emphasized in the analog printing technology for the basic color black K. If the grid angle of 45 ° and the degree of filling are taken into account, B. the arrangement shown in FIG. 8, in which the set matrix elements ME of the conversion matrix KMK are arranged diagonally. The creation of the GRP graphic format with again 12 rows (rows 0 to 11) and 12 columns (columns 0 to 11) according to FIG. 10 does not actually need for the basic color black K with the separated color intensity IK of 25% using the calculation formula (1 ) or (2), because the calculated numerical value n will always be n = 0. The calculated numerical value n = 0 means that in the graphic format GFK each column / row field is occupied with the conversion matrix KMK indicated in FIG.

FIG. 9 shows the graphic format GFY created from the conversion matrix KMY according to FIG. 7, as it is temporarily stored in the mass memory 14 according to FIG. 2 for the color expression of the basic color yellow. The GFY graphics format is structured in columns or rows, i.e. H. the conversion matrix KMY according to FIG. 7 is arranged in rows or columns using the calculation formula (1) or (2). In the interplay between columns or rows, the areal arrangement of the conversion matrix KMY shown in FIG. 9 shown in FIG. 9 results from this. FIG. 9 shows that for the conversion matrix KMY arranged in the manner described, the screen angle of 90 automatically results ° results.

FIG. 10 shows the graphic format GFK created from the conversion matrix KMK according to FIG. 8, as it is temporarily stored in the mass memory 14 according to FIG. 2 for the color expression of the basic color black. The GRP graphics format is in turn structured in columns or rows, i.e. H. the conversion matrix KMK according to FIG. 8 is arranged row-wise or column-wise with the aid of the calculation formula (1) or (2).

The result is the interplay between columns or rows from this the areal arrangement of the conversion matrix KMK shown in FIG. 8 shown in FIG. 10 is shown. FIG. 10 shows that for the conversion matrix KMK arranged in the manner described, the screen angle of 45 ° results automatically.

Claims

Claims 1. A method for generating screen angles in digital color printing, in which color pixels of an original (V) are separated into signal values (SWY, SWM, SWC, SWK) containing digitally coded color intensities (IY, IM, IC, IK) of the color pixels , in which the signal values (SWY, SWM, SWC, SWK) for color printouts (Y, M, C, K) are converted using conversion matrices (KMY, KMM, KMC, KMK), in which each signal value (SWY, SWM, SWC, SWK) several matrix elements (ME) are assigned to the conversion matrix (KMY, KMM, KMC, KMK) and in which the converted signal values (SWY, SWM, SWC, SWK) in graphic format (GFY, GFM, GFC, GFK) are temporarily stored for color printing, characterized in that a) a set (k) of conversion matrices (KMY, KMM, KMC, KMK) for converting the individual signal value (SWY, SWM, SWC, SWK) for color printing (Y, M, C , K) is used, each conversion matrix (KMY, KMM, KMC, KMK) of the set (k) having an equal number of matrix elements (ME) b it that can be assigned to the signal value (SWY, SWM, SWC, SWK) for the conversion, b) the matrix elements (ME) for each conversion matrix (KMY, KMM, KMC, KMK) of the set (k) are arranged such that in the interline and column interplay of the converted signal values (SWY, SWM, SWC, SWK) temporarily stored in the graphic format (GFY, GFM, GFC, GFK) for the color printout (Y, M, C, K) with the arrangement of the matrix elements ( ME) sets a predeterminable screen angle, c) to generate the screen angle in graphic format (GFY, GFM, GFC, GFK) the signal values (SWY.) Converted using the set (k) of conversion matrices (KMY, KMM, KMC, KMK) , SWM, SWC, SWK) according to the calculation form: n = row of the graphic format mod k and / or n = column of the graphic format mod k are arranged in rows or columns in the graphic format, where n is the current, in the row or column of the graphic format (GFY, GFM, GFC , GFK) to be assigned conversion matrix (KMY, KMM, KMC, KMK) for the signal values (SWY, SWM, SWC, SWC) and k the number of conversion matrices (KMY, KMM, KMC, KMK) in the respective set ( k) is. 2. The method of claim 1, d a d u r c h g e k e n n z e i c h n e t that the conversion matrices (KMY, KMM, KMC, KMK) are dither matrices. 3. Printing device for generating screen angles in digital color printing, with a central unit (12) of a microcomputer system (1), which is digitally coded, according to color intensities (IY, IM, IC, IK) of color pixels of a template (V ) separated signal values (SWY, SWM, SWC, SWK) with the aid of conversion matrices (KMY, KMM, KMC, KMK) stored in a working memory (13) of the microcomputer system (1), in which each signal value (SWY, SWM, SWC, SWK) several matrix elements (ME) of the conversion matrix (KMY, KMM, KMC, KMK) are assigned and with a fixed value memory (14) of the microcomputer system (1) in which the converted signal values (SWY, SWM, SWC, SWK) in the Graphic format (GFY, GFM, GFC, GFK) for output to print modules (4 ... 7) are temporarily stored by the central unit (12), characterized in that a) a sentence is stored in the working memory (13) of the microcomputer system (1) (k) of conversion matrices (KMY, KMM, KMC, KMK) for converting the individual sig nal values (SWY, SWM, SWC, SWK) for color printing (Y, M, C, K) is saved, each conversion matrix (KMY, KMM, KMC, KMK) of the set (k) having the same number of matrix elements (ME) that can be assigned to the signal value (SWY, SWM, SWC, SWK) for the conversion, b) the matrix elements (ME) for each ^' conversion matrix (KMY, KMM, KMC, KMK) of the set (k) are arranged in such a way that the interplay between the rows and columns in the graphic format (GFY, GFM, GFC, GFK) in the Read-only memory (13) of the temporarily stored converted signal values (SWY, SWM, SWC, SWK) for the color printout (Y, M, C, K) sets a screen angle that can be predetermined with the arrangement of the matrix elements (ME), c) for generating the Screen angles in graphic format (GFY, GFM, GFC, GFK) the signal values (SWY, SWM, SWC, SWK) converted with the aid of the set of conversion templates (KMY, KMM, KMC, KMK) from the central unit (12) according to the calculation formulas: n = row of the graphic format mod k or n = column of the graphic format mod k row or column w else in the graphic format (GFY, GFM, GFC, GFK), where n is the current conversion matrix (KMY, KMM, KMC, KMK) to be arranged in the row or column of the graphic format (GFY, GFM, GFC, GFK) is the signal values (SWY, SWM, SWC, SWK) and k is the number of conversion matrices (KMY, KMM, KMC, KMK) in the set (k). 4. Printing device according to claim 3, d a d u r c h g e k e n n z e i c h n e t that the conversion matrices (KMY, KMM, KMC, KMK) are dither matrices.