DE19639014C2 - Measuring field group and method for recording optical printing parameters in multi-color edition printing - Google Patents

Description

The invention relates to a measurement field group and a method for the detection of optically Printing-related sizes in multi-color edition printing according to claims 1, 14 and 15.

For recording optical printing parameters - hereinafter referred to as quality data - are in multi-color print runs, especially commercial and newspaper known numerous solutions. The quality data acquisition, for example of color, Ink layer thickness, register, shift, duplication values, area coverage and the same, is used to monitor and control the coloring in multi-color printing.

Statements about the color perception can be made by printing and colorimetric analysis measure from combination measuring fields can be obtained, as is known from DE 44 02 784 A1 is known, from which the invention is based. By using the described there  The measuring field group becomes the space required for the printed product to be checked printed measuring field or the measuring field group significantly reduced. However allowed this measuring field or the measuring field group known from it does not yet record Measured values for the register and not for the determination of processing problems, such as Slide and duplicate.

A procedure for determining registration errors and measuring suitable Passermar Ken is known for example from DE 27 31 842 C3. Such registration marks should be in addition to the color marks printed on the printed product to be checked and with an appropriate measuring device. There must be at least two different measuring devices are mastered and used.

DE 40 05 558 A1 also describes a method for recording remissions of Solid and grid fields for the creation of diagnoses of changes in Process parameters such as dampening solution metering, machine temperature and duplication, known. There are remissions of the solid and halftone during printing fields recorded. This is done in such a way that of at least two printed copies the remissions of solid and screen areas from at least two fields or compared by at least two grid areas of different area coverings will. This process is based on the fact that within a color zone over a print run seen the remissions of the grid areas can change, although the remissions of the solid areas remain constant.

The invention has set itself the task of collecting quality data in Multi-color print run, preferably in offset printing and not only for Commercial offset printing, but also to improve newspaper offset printing. Here the space required for the measurement required to determine quality data elements or measuring field groups compared to known solutions and the measuring equipment expenditure can be kept low.  

This object is achieved by the formation of a measuring field group according to claim 1 and achieved by means of a method according to claims 14 and 15.

The invention is based on a measurement field group which has a plurality of measurement fields, the for obtaining color values. Color densities or surface coverings or a combination nation from it, are suitable. Suitable here means that the measuring fields are large are enough to use the measurement techniques available to determine these values to be able to measure, d. H. the measuring fields must have color measuring areas of sufficient size exhibit. The definition of the minimum dimension as required dictates that each measuring field is at least large enough to cover an area could, if the measuring field were printed in a raster tone.

According to the invention, the measuring fields each have at least one assigned strip, the measuring field and this at least one assigned strip in the same color print printed, the strip is narrow in relation to the dimensions of the measuring field and in a predetermined, also small in relation to the dimensions of the measuring field lateral distance to the edge of the measuring field. The color-free in the same print The remaining target area between the edge of the measuring field and the adjacent strip is included comparable to the corresponding actual area. The target surface is the surface which with ideal, sliding and duplication-free pressure in the respective pressure of the measuring field and the strip remains colorless; the actual area is the area that is actually free in printing.

The entirety of the measuring field and assigned strip is referred to below as a measurement called element.

With a single touch, each of the measuring fields according to the invention can also be used orderly quarreling in addition to a color value, the color density and / or the area coverage in the measuring field, by measuring the zone or area between the measuring field and its lateral color stripe a shift and duplication value for the one in question Printing unit can be determined.  

It is particularly advantageous if the color strip and the measuring field of the individual measurement elements are separated from each other by a color-free zone, since the measurement in this Trap is most optimal; However, this is not absolutely necessary.

Since the at slide and duplication-free print at least that in the print in question unprinted area between the measuring fields and their colored stripes on the side the border on both sides, through the edge of the measuring field on the one hand and the color strip on the other hand, the shift and duplication values can be determined.

By a predetermined edge of the zone to be measured by an edge of a Measuring field is formed, the combined measurement of color and sliding / duplicating space-saving possible on the same measuring element.

In a preferred development, the measuring fields each have at least two of these lateral ones Color strips for determining the sliding and duplication in circumferential and in sides direction up. The zones between the measuring fields and are very particularly preferably their lateral color stripes in the circumferential and lateral directions; two like that on one Zones formed in individual measurement fields therefore run at right angles to one another.

In this case, the relative positions of the measurement are used to determine the register values elements, preferably the lateral color stripes of the individual measuring fields, to each other certainly. Because of the inventive design of the individual measuring elements in this case, too, no additional registration marks are printed. Because the zones between the measuring fields and their lateral color stripes when printing the relevant one If the measuring element is not printed, the register values can be changed on the inventive Measuring elements are determined.

The measuring elements are preferably at least single-color full tones fields in the respective primary colors, generally cyan, magenta and yellow for the 4- Color printing, or corresponding single-color grids, in which the basic colors  are printed with their nominal area coverage. If both Solid densities as well as area coverings are to be determined individually solid color fields and single color grid fields printed in the primary colors. Des a solid color field in black and also a halftone field in which the color black is printed with its nominal area coverage be.

In an even more preferred embodiment, additional combination measurements are also provided fields are provided, in each of which at least two basic colors with their nominal areas degrees of coverage are printed on top of each other, so that meaningful values with regard to of the ink acceptance behavior can be determined.

Finally, in a very particularly preferred further embodiment, an additional one Combination measuring field printed, in which the basic colors with their nominal Coverage levels are printed one above the other.

The above-mentioned measuring elements or a selection thereof are made after a first one Embodiment variant of the invention printed individually in the picture. In a second before drafted variant, they are, provided exact register, in the form of a compact measuring field blocks arranged and printed, so that the neighboring Measuring elements with their lateral color strips butt against each other or the color stripes a small distance apart. Furthermore, there are also mixed forms of these two variants possible, in which several measuring elements to such Arranged measuring field blocks and possibly several such measuring field blocks, each with different measuring elements are provided; Individual elements can be next to it also be printed in the picture. When using a single compact measuring field block can, provided that a suitable measuring device is used, by means of a single Probing all values influencing the quality of the printed product, namely the Register values, shift and duplication values as well as color density, color acceptance and color balance values, color values, area coverings and the like can be determined.

A particularly preferred measuring device has a sensor, preferably a photoelek  trical sensor, with spectral or at least 3-area and two-dimensional spatial resolution. A CCD color camera is preferably used which points to a Microscope is mounted.

If the measuring elements are arranged individually and in suitable measuring field blocks Subcombinations are printed on the image, they can be interested still determine the quality data using a single measuring device. The measuring device in this case is arranged to be movable over the continuous printed product. From the Prepress are the traversing control of the measuring device, the locations of the probed Measuring elements or measuring field blocks communicated.

A preferred embodiment of a measuring element and a compact measuring field blocks and two processes for optimizing color reproduction in multicolor Edition printing is described below with reference to figures. Show it:

Fig. 1 shows a measuring element,

Fig. 2 shows a compact measurement field block with juxtaposed measuring elements according to Fig. 1,

Fig. 2.1 Generalization of the measurement field block of Fig. 2,

Fig. 2.2 a compact measurement field block for the 8-color printing,

Fig. 2.3 two juxtaposed measuring elements of a measurement field block,

Fig. 3 shows a decision tree for optimizing the color rendering in a single edition and

Fig. 4 shows a decision tree for optimizing the color rendering over several editions.

The measuring element shown in FIG. 1 comprises a measuring field F with associated lateral color strips S. In the exemplary embodiment, measuring field F has the shape of a square. One of the narrow, rectangular color strips S runs parallel to the edges of each of the four square sides. A color-free zone Z, that is to say a zone Z which remains color-free at least in the printing of the measuring element, is formed between the edges of the measuring field F on the one hand and the lateral color strips S on the other hand. whose width and thus area is exactly specified with ideal printing. By comparing this ideal area of zone Z, ie the target area of zone Z, with the measured partial area of zone Z, which is not printed in the actual pressure, ie the actual area of zone Z, the shifting and duplicating values of this pressure can be determined. It would be sufficient to determine the sliding and duplication in the circumferential and lateral directions to provide two differently colored stripes S to each other. The two other color strips S then only amplify the measurement signal in an advantageous manner.

The minimum size of the area of the measuring field F is determined by the grid width of the Printing process, d. H. the grid point size considering the available came resolution or the spatial resolution of the sensor and a sufficiently meaningful given statistics.

The square area of the measuring field F in the exemplary embodiment can be within the straight line plugged frame basically only rectangular and basically even arbitrary, but predetermined in a defined manner. The color stripes S do not necessarily have to run parallel to the edge, but the color-free zones Z must likewise, provided that the ideal pressure is present, it must be defined by its borders. However, the illustrated shape of the measuring element with the assigned strips makes it easier an analysis of the measurement results following the actual probing of the measuring field nits. Furthermore, this form is particularly suitable for the summary several such measuring elements to a compact measuring field block.

Such a compact measuring field block is shown in FIG. 2. In the exemplary embodiment, it consists of twelve measuring elements, which are combined to form a 3 × 4 checkerboard-like measuring field block. The individual measuring fields with assigned strips, ie the individual measuring elements, are designated A1 to D3.

The compact measuring field block for multi-color printing in general, ie for any number of primary colors, is shown in Fig. 2.1. An exemplary measuring field block for 8-color printing is finally shown in FIG. 2.2. In the following, reference will always be made to the measuring field block of FIG. 2 for 4-color printing only by way of example.

In the compact measuring field block, two adjacent measuring elements A1 to D3 butt each other with their lateral color strips S or with a predetermined distance of the size of "a" if, ideally, no register deviations occur in the print. Two measuring fields, which are printed next to one another in such a way that their color stripes S facing each other are at a small distance a from one another, are shown in FIG. 2.3.

In the measuring field block of FIG. 2, measuring element A1 is formed by a solid tone field in black. The measuring element A2 is a grid in which the color black is printed with its nominal area coverage. The measuring element B1 is a combination measuring element in which the three basic colors cyan, magenta and yellow are printed one above the other with their nominal area coverage. The measuring elements A3, B2 and C1 are formed by single-color grid elements with nominal areas of coverage in the three primary colors. In the measuring elements B3, C2 and D1, the three primary colors are printed individually in full tone. The remaining measuring elements C3, D2 and D3 are finally further combination measuring elements, in which two of the basic colors with nominal area coverage are printed one above the other.

In newspaper printing as a preferred example of use, the measuring elements A1 to D3 each have an extent of approximately 1.65 × 1.65 mm ² and the compact measuring field block with twelve such measuring elements has an extent of 6.6 × 5 mm ² . The miniaturized measuring elements formed in this way are also printed in selected image areas or, as shown, as a compact measuring field block on a printed product to be checked and then recorded inline, online or offline using a CCD color camera mounted on a microscope. The picture could also be taken at one or more image points using a photoelectric sensor with spectral and two-dimensional spatial resolution.

The captured images are digitized and then software using of a feature-specific algorithm evaluated directly. The data can also be saved in the individual colors separated and the binary image thus generated with a corresponding note paint-specific mathematical algorithm can be evaluated. A combination of both Procedure is also possible.

In the exemplary embodiment, the color strips S of the measuring elements B3, C2, D1 and A1 are used determining the registration of cyan, magenta, yellow and black in circumferential and in Side direction. The relative positions are based on the cyan measuring element B3 of the measuring elements C2, D1 and A1 for magenta, yellow and black and thus any Register deviations determined. Pushing and duplicating is determined by the fact that the unprinted zone Z between the surface of each measuring field F and the color strip S is measured.

The areas of the measuring fields F of the same measuring elements B3, C2, D1, A1 are used for Determination of the solid color densities of the corresponding colors.

With the help of measuring elements A2, C1, B2 and A3, the area coverage of Black, yellow, magenta and cyan determined. The register and shift as well as duplication values could also be determined using these single color grid elements.

The measuring elements C3, D3 and D2, in each of which two of the three basic colors in a grid tone are printed on top of each other and the measuring element B1, in which all three basic colors in Screen tones printed one above the other serve to determine the color values and the Color acceptance in two and three-color overprint.  

A preferred image processing comprises a photoelectric sensor with spectral and two-dimensional spatial resolution and image analysis hardware and software that in principle, however, can also be formed by hard-wired hardware, and a digital computer, preferably a personal computer. For the recorded Signals from the sensor become the relevant image points of the compact by means of image analysis Measurement blocks selected and the recorded signals, for example using Matri z operations in XYZ values and subsequently in LAB values and density values trans formed.

For the determination of the surface coverings and the register, those are recorded Signals separated into binary images and then using a feature-specific algo rhythm evaluated.

By also printing the compact measuring field block according to FIG. 2, by using the image analysis for evaluating the measurement data or the recorded image by means of a single probing operation in a small space in the type area, the features on the printed product which are necessary for product qualification and possibly for diagnosis can be determined . This means that an extraordinarily large number of quality features can be obtained in the shortest possible time.

In the example shown for four-color printing, the compact can be touched per touch Measuring field blocks six register values, four full tone density values, four dot gain values, three ink acceptance values for the basic colors, four shift and duplication values and four Color locus vectors and four color distances of the secondary and tertiary chromatic colors, in total that is, 29 measured or characteristic values can be determined.

FIGS. 3 and 4 show decision trees, which is created following a diagnosis based on the obtained quality information. Using these decision trees, it is also possible to optimize color rendering in multi-color production printing. The decision trees shown can be further refined by including further quality data, such as the color values of the primary colors, data on ink and water flow on the printing press, temperature of the ink material, air temperature and humidity or image data of the printed subject.

In general, it should be noted that color deviations caused by adjusting the color and / or Dampening solution guidance on the printing press can be corrected. Alternatively or In addition, it is possible to selectively produce the color separations in prepress Make corrections to the area coverage (tonal value compensation). While the adjustment of the printing press also to compensate for short-term swans offers color rendering, tonal value compensation is suitable in printing preliminary stage for the correction of systematic or long-term fluctuating color deviations gene.

When generating a diagnosis based on the quality data collected, a distinction should therefore be made between these two strategies. These are two decision-making situations, namely on the one hand the optimization of the color reproduction in a single edition and on the other hand the optimization of the color reproduction over several editions. Fig. 3 accordingly shows a decision tree for the printing of a support and Fig. 4 shows a decision tree for the printing of several runs.

The branches each represent random points. With each branch, it is decided on the basis of the determined quality data, on which path to continue to the right. There are both exclusive branches, in which only one continuation path is to be followed, as well as non-exclusive branches, in which progress is possible on more than one continuation path. When optimizing the color reproduction over several editions ( FIG. 4), it can happen that a color deviation is caused by a disturbance in the tone value increase and a trapping disturbance. In this case, both the rheology problem causing the color deviation and the trapping disorder can be remedied, ie it is a non-exclusive branch at the random point.

In the event of a fault, each path in the decision tree ends with a on the right Recommended action. Depending on the situation, there is a correction of the color and moisture middle guidance or a combination of both corrections, the correction of a color material drawn rheology problem, the correction of a trapping disorder, the correction of shooting ben or duplication, the recalibration of the printing characteristics of the individual colors or the Recalibration of the color profile in terms of color management in question.

The decision trees according to FIGS. 3 and 4 are read in the pseudocode as follows:

A further differentiation of the recommendations for action is also possible. So can for example, the request to fix pushing or duplicating with an indication of possible causes, e.g. B. on the web tension, paper properties or the properties of rubber blankets.

Both decision trees shown as examples show how effective and Meaningful data compression automatically a quality assessment and, in the case too large deviations, a diagnosis combined with a recommendation for action is generated becomes. It is not satisfied with this, for example the known ed gene-related statistical parameters such as minimum, maximum, mean and scatter to be calculated and output automatically.

By using measuring fields according to the invention with assigned strips or compact measuring field blocks or a combination thereof in combination with image analysis and ent divorce tree it is possible to derive those based on densitometry and colorimetry conventional tools of optimizing color rendering with the new tools of color management to unite into an overall system.

If the quality data is very noisy, i.e. H. practically only random deviations contain a recommendation for action can no longer be clearly derived. In In this case, measurements are continued or additional quality data are used. An example is the situation where there are color fluctuations over several editions occur in multicolored overprinting that are not reproducible. It will then further editions printed and measured.

As an alternative to the decision tree, you can use it to derive the diagnosis and the Recommendations for action also include neural networks or unsharp logic algorithms (Fuzzy logic) or a combination thereof. Especially the neurona len networks have the advantage that they can be trained using test patterns nen.  

If the correct recommendations for action are known for each set of quality data, can provide such a network with the expert knowledge necessary to create a diagnosis are conveyed without sharp setpoints or tolerances in the must be determined in advance. Such an approach comes very close to the fact contrary to the fact that numerical expert knowledge is more blurred than in sharp form is present.

Claims (20)

1.Measuring field group with optically scanned measuring fields of a predetermined structure printed on a multicolored printed product with a printing press, wherein at least one measuring field edge per measuring field has a certain course relative to the printing direction and each measuring field has a minimum dimension for determining at least one optically printing technical variable, which is in terms of area is large enough that it is also possible to measure area coverage, characterized in that the measuring fields (F) are each assigned at least one narrow strip (S) at the same pressure, which runs at a short distance from the edge of the measuring field, the color being free in the same pressure remaining target area between the measuring field edge and the strip (S) of the corresponding actual area is comparable. 2. measuring field group according to claim 1, characterized in that the measuring fields (F) at least two strips (S) that are at an angle to each other are assigned. 3. Measuring field group according to claim 1 or 2, characterized in that the measuring field (F) and the assigned strip (S) in a target pressure by a perfect unprinted zone (Z) are separated from each other. 4. measuring field group according to one of claims 1 to 3, characterized in that the Quarrel (S) runs in a straight line parallel to the measuring field edge of the measuring field (F). 5. measuring field group according to one of the preceding claims, characterized in that that the measuring fields (F) and the strips (S) are rectangular. 6. measuring field group according to one of the preceding claims, characterized in that the measuring fields (F) have a strip (S) near each of their edges. 7. measuring field group according to one of the preceding claims, characterized in that that several measuring fields (F) in a target pressure with their assigned strips (S) abutting one another or having a predetermined small distance (a) form a compact measuring field block. 8. measuring field group according to one of the preceding claims, characterized in that that single-color full-tone fields (B3, C2, D1) are provided in the primary colors. 9. measuring field group according to one of the preceding claims, characterized in that that single-color grids (A3, B2, C1) are provided. 10. Measuring field group according to claim 8 or 9, characterized in that a solid tone field (A1) is provided in black.   11. Measuring field group according to one of claims 8 to 10, characterized in that a screen tone field (A2) in the color black is provided. 12. Measuring field group according to one of claims 8 to 11, characterized in that Grid combination measuring fields (C3, D2, D3) are provided, in each of which at least two basic colors are printed on top of each other. 13. Measuring field group according to one of claims 8 to 12, characterized in that a grid combination measuring field (B1) is provided, in which all primary colors are printed on top of each other. 14. Process for the detection of optical printing parameters in multi-color print, in which

• a) individual color measuring fields (B3, C2, D1) according to one of claims 1 to 13 are printed in the basic colors on a multicolored printed product,
• b) the individual color measuring fields (B3, C2, D1) are optically scanned,
• c) the remitted light is evaluated and for each of the individual color measuring fields (B3, C2, D1) one or more optical printing parameters are or are determined and
• d) shift and duplication values are determined for each individual color measuring field (B3, C2, D1) by comparing the target area and the actual area between the measuring field edge and the strip, which is recorded with a single touch and remains color-free in the printing of the single color measuring field (B3, C2, D1) ( S).

15. A method for the detection of optical printing parameters in multicolour print, in which

• a) individual color measuring fields (B3, C2, D1) according to one of claims 1 to 13 are printed in the basic colors on a multicolored printed product,
• b) the individual color measuring fields (B3, C2, D1) are optically scanned,
• c) the remitted light is evaluated and for each of the individual color measuring fields (B3, C2, D1) one or more optical printing parameters are or are determined and
• d) Register values are obtained by measuring the relative metric positions of strips (S) or measuring fields (F) in different basic colors.

16. The method according to claim 14 or 15, characterized in that image points of the Print product serve as measuring fields (F) with assigned strips (S). 17. The method according to the preceding claim, characterized in that the Measuring fields (F) with assigned strips (S) image analysis using an image ver work process are recognized. 18. The method according to the preceding claim, characterized in that the Image processing a color separation, the generation of a binary image and a feature-specific mathematical algorithm for determining the optical includes print sizes. 19. The method according to any one of claims 14 to 18, characterized in that the Scanning using a photoelectric sensor with spectral or at least 3- Area and two-dimensional spatial resolution takes place. 20. The method according to the preceding claim, characterized in that the Scanned using a CCD color camera.