DE2810225A1 - ACQUISITION AND USE OF COLOR CORRECTION DATA FOR COLOR IMAGE RECORDING - Google Patents

Description

Dr.-Ing. Rudolf. Hell GmbH Kiel, February 22, 1978

Grenzstrasse 1-5. Lf / Hi

2300 Kiel 14 Q

Patent application no. 78/471

Password: Color Correction Data Acquisition · 2 8 1 Π

Acquisition and utilization of color correction data for color image recording

The present invention relates to the extraction and utilization of color correction data for color image recording according to the im The preamble of claim 1 referred to in Art.

There are already known from DT-PS 1053311 a method and a device for electronic color correction, wherein for Color correction, a memory is used which has a corresponding input value for a large number of different sample signal values Number of corrected image recording signals outputs as output values. Such a color correction has the advantage that the color correction can be standardized by, depending on the desired color correction, the correction data within the Memory changes. For example, there may be a library of standard correction data available for specific template classes and printing conditions provide already optimized basic or selective corrections.

There is still a procedure and a Facility ζψη reproducing colored pictures or slides has been described in which:

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1 . Non-linearities between the behavior of the filters and the printing ink, i.e. the mismatch between the filter and the printing inks,

2. Non-linearities due to the different thicknesses of the order of printing inks with the same spot size during reproduction,

3. Non-linearities due to the covering of different ink spots and

4. Non-linearities through photomechanical methods of manufacture the printing plates are to be compensated.

To do this, a large number (about 50O) of selected sets of colors are made, each of which is arbitrary selected values of the respective proportions of the printing inks ge, mg, cy, sw. A printing plate is made of every single sentence and then a proof is made with the color used for the reproduction process. These sets contain spots of color, i.e. spots of the order of 6.5 mm to 12.7 mm arranged in a matrix in the form of rows and columns.

This matrix becomes point by point with a fineness of 3100

Dots / cm scanned.

So there are numerous independent measurements carried out, which are numerically averaged, whereby for each ge, mg, cy, sw rate an average value for R, G, B is obtained. These will

stored in a memory at predetermined points and

are used to calculate "vori coefficients for a predetermined Set of color conversion equations. The coefficients of the color conversion equations are then stored in a computer memory at a predetermined location.

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The color conversion equations are derived from quadratic equations that are based on a lecture entitled "A Proposed Engineering Approach To Color Reproduction" presented at the 14th Annual Meeting of the Technical Association of the Graphic Arts, held in Minneapolis, Minnesota, USA on June 11, 1962 by Irving Pobbaravsky. Of these Equations are given by a Taylor's series expansion Approximation equations derived, of which only the first two linear terms are used as an approximation for the correction process will.

During the recording process, starting from the sample values, R, G, B of the original, for each pixel with these equations and coefficients via a computer Correction data, or rather the data for recording the color separations, is calculated.

Apart from the fact that this method is troublesome because of the large number of color sets to be produced, the exact overall one The correctness of the equations that are assumed is questionable (there are also other systems of equations that differ from this, e.g. the Neugebauer equations) and from the fact that an approximation approach is used, this correction is imprecise and has the decisive disadvantage that it is only aimed at reproducing the original as precisely as possible, i.e. Inadequacies of the original or deliberate changes can

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cannot be taken into account by this correction. Defects such as color casts or other color errors must be carried out in a separate correction process be eliminated.

To prevent this, it has been proposed in DT-OS 2018317 that data should be obtained and used to fill the addressable correction memory, as described in DT-PS 1053311, to achieve that one on one desired property set color correction unit with a sequence of ever occurring image scanning signal combinations is applied and the respective associated corrected output signal combinations after digitization below the address corresponding to the image scanning signal combination can be entered into the memory. This procedure works with a adjustable electronic color correction unit, and it can, if necessary, under visual inspection any arbitrary Color corrections set and the set color correction parameters for the subsequent subsequent reproduction process can be obtained and saved.

But it can also happen that it is required that the Color correction parameters obtained after any color correction process for reproduction by means of an addressable correction memory. For this No usable solution has been offered so far. The present invention is therefore based on the object of a method for Acquisition and utilization of data to fill a correction

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Memory, regardless of the selected color correction method the determination of the color correction parameters for later reproduction.

The invention achieves this through the in the characterizing part of claim 1 specified features.

Advantageous further developments of the invention are set out in the subclaims 2 and 3. The invention is described below described in more detail with reference to FIGS. 1 to 3. Show it:

Fig. 1 A basic arrangement for implementing the present Invention,

Fig. 2 shows an example of how the scan data of original and color separations are sorted by address within the arbext memory.

3 shows an example of the storage of the correction data in the addressable correction memory.

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1 shows an arrangement by means of which the present invention can be carried out. A colored template that representative of a series of templates with the same characteristic Color corrections are to be reproduced, is optically-electrically scanned, with primary in a known manner Color measurement signals R, G, B are obtained, which are digitized and stored after a suitable conversion. the Scanning can be carried out using a so-called drum scanner, flatbed scanner or a flying spot scanner are, but in principle any scanning device is suitable that scans the color image point by point and line by line and thereby the known primary trichromatic color measurement signals R, G, B generated.

These scanning signals are generated according to a predetermined number of tone value levels digitized and as digital sampling data signal combinations (R, G, B) for each pixel in the sequence of their sampling.

In the present case, a drum scanner is selected for this purpose been, on the drum 1 of the original 2 clamped and by means of an opto-electronic scanning unit 3, the axially is moved past the drum 2, is scanned. The drum 1 is driven by a motor 4. The output signals R, G, B of the scanning unit are in stages 5,

6, 7 logarithmized and given to A / D converter 8, 9, 10. • V »

A so-called raster disk 12 is arranged on the shaft 11, which, with the aid of a light barrier, comes from a light source and a photo receiver 14 is, emits pulses via a Amplifier 15 are given to clock stages 16 and 17 in which

these impulses are shaped and, if necessary, multiplied upwards. The output clock of stage 16 should be the pixel clock and is sent to the analog-to-digital converters 8, 9, 10. The clock frequency determines the spacing and number of pixels within a scan line. This clock continues to go to the registers 20, 21 after passing through a slight delay and 22 showing the scan image signal combinations provided by the digitizers Take over R, G, B.

In addition, in step 17, by counting the number of the Clock generator 15 supplied clock series a line clock, i.e. 1 pulse per line start, derived. Instead, it can be one that is not shown second pulse generator can be provided which is connected to the drum or shaft and this with each drum revolution Emits circumferential or line pulse. With the help of the sampling clock sequence and The entire scanning image signal combinations of the individual scanning points of the original image are connected to the line pulse via a multiple line 23 given into a working memory 24, which then contains the entire image content of the original according to color components contains separated in the order of the scanning arranged point by point and line by line. The order of the image sample data in memory is made via a control unit 25, which the incoming digitized image signals with the help of the pixel clock and of the line clock according to a scheme that is shown in FIG.

After the original has been scanned, the desired color correction is applied to the original. For the present According to the invention, it is irrelevant which correction method is used to make this correction, be it manually or with the aid

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known color correction devices, such as has been described in DT-OS 15 97, for example. But it is necessary for the further Sequence that color separations are also produced in a known manner from the corrected original, which the desired Corrections included. For example, a blue, green or red cast can be corrected, pink tones such as skin tones improved or brown tones how furniture colors are corrected. These corrections are, for example, typical corrections as required for certain template classes e.g. in the production of advertising catalogs, company advertisements, etc. ', which is why this process is particularly useful for standardization the correction is suitable.

In the further course of the implementation of the present invention, these color separations are individually optically-electrically used the device described above is scanned, the scanning data of the individual color separations (ge, mg, cy, sw) also in are given in the memory 24 in the order in which they are scanned.

Fig. 2 shows an example of how this data is stored within the working memory 24 sorted by address, can be stored in the individual memory cells. There are other ways of Sorting of the R, G, B signal combinations or the color separation signal combinations possible, but it must be ensured that the address is easily found in the memory can be. The left column of Fig. 2 indicates "the address. Ä., under which the data are stored in memory. The right column indicates which data is in the corresponding memory cell are filed. At the addresses 0,1 and 2 the scanning

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At

Image signal combinations R ₁ , G ₁ , B ₁ and under the pole addresses the scanning data of the individual color separations are then stored in the order ge ₁ , ItIg ₁ / Cy ₁ , SW ₁ . This is followed by turn, the scan image signal combinations R ", G", B the next pixel and in turn the color separation data this point, Ge, mg, ^c Yo ^'SW 2 ^etc · Hi ^he t> ^e i give the R, B -, G signals the filter signals of the original, and the signals ge, mg, cy, sw the corresponding corrected density values of the color separations. With this type of organization, the filter signals and the density values of the extracts of a pixel are therefore located in a memory area. This facilitates the later process of finding the actual correction signals for filling the color correction memory. The R, G, B signals are stored in such a way that for the first pixel the digital value of the R signal at address O, for the second pixel the digital value of the R signal at address 7 and for the third pixel the digital value of the R signal is stored under address 14, etc. The G signals of the successive pixels are stored under addresses 1, 8, 15 etc., the B signals under addresses 2, 9, 16 etc. The signals of the yellow separation ge are at addresses 4, 11, 18 etc., those of the magenta separation .mg at addresses 5, .12, 19. etc., the addresses of the cyan separation cy at addresses 6, 13, 20 etc., and the signals of the black separation sw at addresses 7, 14, 21 etc.

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The required memory requirement thus results from the number of lines in the image, the pixels per line and the number of pixels per pixel resulting data, i.e., the R, G, B signals and the color separation signals ge, mg, cy, sw.

The subsequent determination of the correction data takes place as follows:

The R, G, B values of the pixels obtained during the original scanning are stored under consecutive addresses in the image memory and the values of the individual pixels of the color separations are also stored under consecutive addresses. Since in both cases, because the same scanner and the same scanning raster are used, the addresses of each pixel of the original and color separation scan correspond to one another, the R, G, B sample value is only required for the address of a pixel and the R, G, B sample value for the same pixel below the to search for the corresponding ge, mg, cy, sw values from the memory and assign them to one another. From the assignment of the individual pixels resulting from the scanning, there is thus a functional relationship between the. individual R, G, B values and the ge, mg, cy, sw values. of the color separations produced. This new assignment is then given in ae be carried out by means of a computer, which is why it is condensed to a more detailed representation-.

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In the foregoing case, it is necessary that the correction memory is designed for all R, G, B combinations. To storage space To save, however, it is also possible not to have a correction value ready for each sample tone value, but only a limited one Number of correction values is provided which, as a so-called support structure, reproduce the representative points of the color space » This means that you can manage with a much smaller correction memory. Ο This procedure, however, requires that the actual Correction process for the sampled values for which no direct correction value is stored, the correction value is calculated = there is also various possibilities to determine the correction value once by interpolation from the monitorable points of the support structure, whereby either only the next points or points in a larger area are taken into account in the interpolation, or one chooses the support frame so narrow that it is sufficient to use only the next support point as a correction value.

Interpolation is basically possible, but requires between two scanning processes a series of calculation steps.

The latter option has the advantage that by a simple Decision, a correction value is available immediately, but the error is negligible if there is a sufficient number of interpolation points is = **

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Ιτα the following describes how the search for the template Vrarte R, G, B with the associated extract values ge, mg, cy, sw, from darr, stored data is done, whereby those values are selected for the filling of the IC correction memory, which are from the interpolation points have the smallest distance. Since the color correction by means of the correction memory represents a transformation of the color space in accordance with the correction carried out, the term “color information informator” is also used in the following instead of the term “correction memory”.

The overall color space should be represented by 16x16x16 grid points become, resulting in 4096 support points for which the color transformer is designed must be, leads. So each coordinate has 16 values, which facing the 256 tonal values after the sampling. Let these 16 red, green and blue values of the coloring transformer be included r, g and b.

First, a principle of order is given after the correction data are ultimately assigned to the addresses of the color transformer. Such a scheme is shown in FIG.

The addresses of the correction values result for the values r = O, g = 0, b = 0:
ge has the address AAFT = AFT

mg has the address AAFT + 1 - = AFT

cy has the address AFD + 2 = AFT
sw has the address AAFT + 3 = AFT

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211022:

For the combination r = 0, g = 0, d = 1 we get? ge has the address AAFT + 4 = AFT mg has the address AAFT + 5 = AFT cy has the address AAFT + 6 = AFT sw has the address AAFT + 7 = AFT,

where the following applies: AAFT = start address of the color transformer AFT = current address of the color transformer.

This Qr dmings scheme can be represented by the following equation

SZAFT = [sZAAFtJ + 4 (256 [_SZr] + 16 (_SZg] + [^ SZbJ) Significant here
SZ = memory cell, [_ J = content of the memory cell.

The factor 4 results from the fact that there is 4 address value difference between the correction values ge, mg, cy, sw of consecutive τ-f g- _s b coordinates.

The lower part of FIG. 3 also shows for the r, g, b combinations.

r = 15, g = 1S ₁ , b = 14 r = 15, g = 15, b = 15

the addresses that result from the classification scheme. One recognises, that four times 4096 addresses are required, which also results from the fact that four correction values are stored per interpolation point.

To determine the correction values that result from the scan and which have the smallest distance from the interpolation point in the color space, a comparison with a largest possible one is made for all samples Maximum distance MAX from the interpolation point, whereby whenever a value is found, the one below the greatest possible distance is, this value replaces the value MAX and the comparison with the smaller value is continued and this again by a the smaller value resulting from the further comparison is replaced, and so on, until the smallest value is found. This value will then assigned to the corresponding support point. Since the ordering scheme of the data according to FIG. 3 is available, this calculation can be carried out with an electronic computer, for example by corresponding expansion of the unit 25 of Fig. 1 and provides for a A person skilled in data processing poses no problem, since the access to the scan data from the original and from the color separations as well as the desired later organization of the data in the correction memory are given.

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Claims (3)

Dr: -Ing. Rudolf Hell GmbH Kiel, February 22nd, 1978 Grenzstrasse 1 - 5 Lf / Hi Kiel 14 Patent application No. 78/471 Password: Color correction data acquisition Patent claims Acquisition and utilization of data for filling at least one addressable memory which is used for a large number of different image scanning signals Emits input values a corresponding number of corrected image recording signals as output values, characterized in that 1) starting from an original image with any color correction process corrected color separations are produced, 2) the original and the color separations each separately optoelectrically are scanned and the image scanning signals obtained after a predetermined number of tone value levels are digitized, each pixel of the original corresponding to an image scanning signal combination (R, G, B) and a single sample (mg, cy, ge, sw) corresponds to each pixel of the color separations, 3) the image sample signal combinations (R, G, B) and the sample values of the color separations arranged in the order of their scanning according to addresses (each pixel 1 address), in. a working memory is stored that the image scanning signal combinations in a computing process within the working memory (R, G, B) the sample values of the color separations belonging to the corresponding pixels (mg, cy, ge, sw) 909837/0356 assigned and under this assignment in the. 2810225 Correction memory can be entered. 2. Utilization of data according to claim 1, characterized in that only a limited number of different image scanning signals are used as input values for the correction memory. 3. Extraction and utilization of data according to claim 2, characterized in that the correction memory is designed for only some of the signal combinations (R, G, B), the tone value spacings of which form a framework in the R, G, B color space , which is representative for the detection of the color space, and that the assignment is made in such a way that the values are transferred to the memory whose image scanning signal combinations (R, G, B) have the smallest distance in the R, G, B Have color space to the support points of the framework. . 909837/03