CH640956A5 - METHOD FOR THE RECOVERY AND USE OF COLOR CORRECTION DATA FOR THE COLOR IMAGE RECORDING. - Google Patents

Description

The invention relates to a method for obtaining and utilizing color correction data for color image recording according to the preamble of claim 1.

A method and a device for electronic color correction are already known from CH-PS 396 021, a memory being used for color correction, which outputs a corresponding number of corrected image recording signals as output values for a large number of different scanning signal values as input values. Such a color correction has the advantage that the color correction can be standardized by changing the correction data within the memory depending on the desired color correction. For example, a library of standard correction data is available, which provides optimized basic or selective corrections for certain template classes and printing conditions.

DE-AS 2 621 008 describes a method and a device for reproducing colored images or slides, in which

1. Nonlinearities between the behavior of the filters and the ink, i.e. the mismatch of filters and inks,

2. non-linearities due to the different thickness of the application of printing inks with the same spot size during reproduction,

3. Nonlinearities by covering different ink stains and

4. Nonlinearities are to be compensated for by photomechanical processes for producing the printing plates.

5 For this purpose, a large number (approximately 500) of selected sets of colors are produced, in which each set is composed of arbitrarily selected values of the respective proportions of the printing inks ge, mg, cy, sw. A printing plate is produced from each individual set and then an impression with the color used for the reproduction process. These sets contain color spots, i.e. Spots of the order of 6.5 mm to 12.7 mm, which are arranged in a matrix in the form of rows and columns. This matrix is scanned point by point with a fineness i5 of 3100 points / cm2.

Numerous independent measurements are thus carried out, which are averaged in terms of numbers, as a result of which an average value R, G, B is obtained for each ge, mg, cy, sw set. These are stored in a memory at predetermined 20 points and are used to calculate 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.

25 The color conversion equations are derived from quadratic equations based on a lecture entitled "A Proposed Engineering Approach To Color Reproduction", which was held at the 14th annual meeting of the Technical Association of the Graphic Arts, in Minneapolis, Minnesota, 30th USA on June 1962 by Irving Pobbaravsky was held to decline. Approximation equations are derived from these equations by a Taylor series expansion, of which only the first two linear terms are used as an approximation for the correction process. 35 During the recording process, starting from the samples, R, G, B of the original, the correction data, or rather the data for recording the color separations, are calculated for each pixel using these equations and coefficients. 40 Apart from the fact that this procedure is tedious due to the fact that the large number of color sets has to be produced, the exact correctness of the equations on which the starting point is based is questionable (there are also other systems of equations which deviate therefrom, e.g. the Neugebauer equations ) and from the fact that an approximation approach is assumed, this correction is imprecise and has the decisive disadvantage that it is aimed only at reproducing the original as accurately as possible, i.e. inadequacies of the original or deliberate changes can be caused by them Correction will not be considered. Errors such as color casts or other color errors must be eliminated in a separate correction process.

To prevent this, it has been proposed in DE-AS 2 621 008 to obtain and use data 55 for filling the addressable correction memory, as described in CH-PS 369 021, by

that a color correction unit set to a desired property is acted upon by a sequence of image scanning signal combinations that occur at all, and the respective corrected output signal combinations, which are associated in each case, are entered into the memory after digitization at the address associated with the image scanning signal combination. This method works with an adjustable electronic color correction unit, and any color corrections can optionally be set under visual control and the set color correction parameters can be obtained and saved for the subsequent reproduction process that follows.

3,640,956

However, it can also occur that the drum revolution is requested to remove this circumferential or line pulse.

the parameters of a color correction that gives for any one. With the help of the sampling clock sequence and the line pulse

Color correction process were obtained, for reproduction the entire scan image signal combinations of the individual scan points of the original image are evaluated by means of an addressable correction memory over a multiple

So far, no usable solution has been offered. s line 23 in a working memory 24, which then

The object of the present invention is therefore to determine the total image content of the original according to color components.

reasons, a method for the extraction and recycling of separates in the order of sampling point and line

To provide data for filling a correction memory that contains wisely ordered. The order of the image scan data regardless of the selected color correction method, the memory 24 is carried out via a control unit 25, the

Determination of the color correction parameters for the later reio the incoming digitized image signals using the

Production allowed. Pixel clock and line clock according to a scheme

The invention accomplishes this by sorting in the characterizing that is shown in FIG. 2.

Part of claim 1 specified features. After the original has been scanned, the

Embodiments of the invention are made in the following desired color correction on the original. For that described in more detail with reference to the drawings. These show: 15 available methods are irrelevant according to which corrective

Fig. 1 shows a basic arrangement for carrying out this correction procedure, be it a mans embodiment of the method according to the present or with the aid of known color correction devices such as those used in the invention, e.g. have been described in CH-PS 505'409. Required

2 shows an example of how the scanning data of the original and loaned is for the further process that color separations from the corrected color separations within a working memory are also sorted in a known manner, and provides the desired separations Corrections included.

3 shows an example for the storage of the correction. corrected a blue, green or red cast,

data in an addressable correction memory. Shades of pink, such as skin tones, improved, or shades of brown, such as

Fig. 1 shows an arrangement by means of which Ausfü- furniture colors are corrected. These corrections are e.g.

Example of the method according to the present invention — typical corrections as can be carried out for certain template classes. A colored template that is required, e.g. in the production of advertising catalogs

presentative for a series of templates with the same character, company advertisements etc., which is why this procedure is particularly

Teristic color corrections to be reproduced, it is suitable for standardizing the correction.

optically-electrically scanned, whereby in a known manner, in the further course of carrying out the present color measurement value signals R, G, B, which processes are these color separations individually optically-electrically

after a suitable transformation, digitized and saved using the previously described device

be saved. The scanning can be carried out by means of so-called stet, the scanning data of the individual color separations (ge,

Drum scanner, flatbed scanner or also a flying mg, cy, sw) also in the order of their scanning in

Spot scanners are carried out, but basic memory 24 is given.

any scanning device is suitable, the color image 35. FIG. 2 shows an example of how this data, within the points and lines, is scanned and the known pri-working memory 24 is arranged according to address, in the individual trichromatic color measurement signals R, G, B nen memory cells can be stored. Others are created. Possibilities of sorting the R-, G-, B-signal combinations- These scanning signals are possible according to a given option or the color separation signal combinations, the number of tone value levels is digitized and as digital scanning data- 40 however, it must be ensured that these address-specific signal combinations (R, G , B) for each pixel in which can be easily found in the memory. The order of their scanning is saved. The left column of FIG. 2 indicates the address A, under which the Daim present case is a drum scanner in the memory. In the right-hand column, the selection is made with a drum 1 on which an original 2 which data is stored in the corresponding memory cell is clamped and by means of an optoelectronic scanner. At addresses 0, 1 and 2, the scanning unit 3, which is guided axially past the drum 2, is the combined image signal combination Rb Gi, B] and is tested under the following. The drum 1 is driven by a motor 4, then the scanning data of the individual color samples. The output signals R, G, B of the scanning unit are moved in the sequence ge ,, mg ,, cy ,, sw! filed. Logarithmized at this in separate stages 5, 6, 7 and on A / D wall, the scanning image signal combiners 8, 9, 10 follow. 50 ions R2, G2, B2 of the next pixel and again the so-called raster disk 12, a color separation data of this pixel, ge2, mg2, cy2, sw2 etc. is arranged on a shaft 11, which with the aid of a light barrier which gives out the R, B, G signals, the filter signals from the front light source 13 and a photoreceptor 14 exist, image originals again and the signals ge, mg, cy sw emit the ent pulses which are transmitted via an amplifier 15 to clock stages 16 speaking corrected density values of the color separations. Given in ei and 17, in which these impulses are formed and, 55 nem storage area is therefore necessary for this type of organization case, are highly multiplied. The output signal in each case the filter signals and the density values of the excerpts clock of stage 16 should be the pixel clock and will be that of a pixel together. This facilitates the later analog-to-digital converter 8, 9, 10. The clock frequency process of finding the actual correction signals for determines the spacing and number of pixels within the filling of a color correction memory 26. The storage of a scan line. This cycle continues after the R, G, B signals have been passed through in such a way that for the first fen a slight delay at three registers 20, 21 and pixel, the digital value of the R signal at address 0, 22 which take over the scanning image provided by the digitizers for the second pixel the digital value of the R signal under signal combinations R, G, B. of the address 7 and for the third pixel the digital value In addition, in stage 17 by counting the clock series supplied by the R signal at the address 14 etc., the clock generator 15 receives a line clock, i.e. 1 65 The G signals of the successive pixels are derived impulses per line beginning. Instead, a B signal can be provided under addresses 1, 8, 15, etc. under the second pulse generator (not shown), which stores addresses 2, 9, 16, etc.

is connected to the drum or shaft and with each The signals of the yellow separation are below the address

640 956

sen 3,10,17 etc., that of the magenta extract mg under the addresses 4,11,18 etc., the signals of the cyan extract cy under the addresses 5,12,19 etc. and the signals of the black extract sw under the addresses 6,13,20 etc. The required storage space results from the number of lines in the image, the number of pixels per line and the data resulting per pixel, ie the R, G, B signals and the color separation signals. mg, cy, sw.

The subsequent determination of the correction data is carried out as follows:

The R, G, B values of the pixels that were obtained during the original scanning are stored under consecutive addresses in the image memory 24 and the ge, mg, cy, sw values of the individual pixels of the color separations are also under consecutive ones Addresses. Since the addresses of each pixel of the original and color separation sample correspond to one another in both cases because of the use of the same scanner and the same scanning grid, the R, G, B sample value and for the same pixel are only required for the address of one pixel Find the associated ge, mg, cy, sw values from the memory under the corresponding address and assign them to one another. A functional connection between the individual R, G, B values and the ge, mg, cy, sw values of the color separations has thus been established from the assignment of the individual pixels resulting from the scanning. This new assignment is then given in the correction memory 26 of FIG. 1, with which all the correction parameters are then present during the actual image reproduction from the original and the correction takes place exactly according to the previously selected arbitrary correction method. This sorting process can be carried out by means of a computer, which is why a more detailed description is not given here.

In the preceding case, it is necessary that the correction memory 26 is designed for all R, G, B combinations. In order to save storage space, it is also possible not to have a correction value ready for each sample tone value, but only to provide a limited number of correction values which, as a so-called support structure, represent the representative points of the color space. This makes it possible to use a much smaller correction memory. However, this procedure requires that during the actual correction process for the sample values for which no direct correction value is stored, the correction value is calculated. There are several ways to do this; On the one hand, the correction value can be determined by interpolation from the neighboring points of the scaffolding, whereby either only the next points or also points in a larger area are taken into account in the interpolation, or the supporting scaffold is chosen so closely that it is sufficient, only the next supporting point as Correction value.

Interpolation is possible in principle, but requires a series of arithmetic steps between two scanning processes.

The latter option has the advantage that a correction value is immediately available through a simple decision, but the error is negligible if the number of support points is sufficient. '

The following describes how the template values R, G, B with the associated extract values ge, mg, cy, sw are extracted from the stored data store, the values that are selected from the support points being selected for filling the correction memory 26 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 transformer” is also used in the following instead of the term “correction memory”.

The total color space may be represented by 16 x 16 x 16 nodes, which leads to 4096 nodes for which the color transformer has to be designed. Each coordinate therefore has 16 values, which are opposed by the 256 tone values according to which the scanning was carried out. These 16 red, green and blue values of the color transformer are denoted by r, g and b.

An ordering principle is initially specified, according to which the correction data are ultimately assigned to the addresses of the color transformer. Such a scheme is shown in Figure 3.

The addresses of the correction values result for the values r = 0, g = 0, b = 0:

ge has the address AAFT = AFT mg has the address AAFT +1 = AFT cy has the address AAFT + 2 = AFT sw has the address AAFT + 3 = AFT

For the combination r = 0, g = 0, b = 0, the following results:

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,

the following applies:

AAFT = start address of the color transformer AFT = current address of the color transformer.

This classification scheme can be represented by the following equation:

SZAFT = [SZAAFT] + 4 (256 [SZr] +16 [SZG] + [SZb])

Here mean:

SZ = memory cell, [] = content of the memory cell.

The factor 4 results from the fact that each 4 address value difference between the correction values ge, mg, cy, sw is successive r, g, b coordinates.

The lower part of FIG. 3 additionally shows r = 15, g = 15, b = 14 r = 15, g = 15, b = 15 for the r, g, b combinations

the addresses that result from the classification scheme. It can be seen that 4096 addresses are required four times, which also results from the fact that four correction values are stored per reference point.

In order to determine the correction values which result from the scanning and which have the smallest distance from the interpolation point in the color space, a comparison is made for all the scanning values with the largest possible maximum distance MAX from the interpolation point, and whenever a value is found, which is less than the largest possible distance, this value replaces the value MAX and the comparison is continued with the smaller value and this is replaced again by a smaller value resulting from the further comparison, etc., until the smallest value is found. This value is 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 using an electronic computer, e.g. by appropriate expansion of the unit 25 of FIG. 1, and is not a problem for a person skilled in the data processing, since the access of the scanning 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)

640 956 PATENT CLAIMS 1. A method for obtaining and utilizing color correction data for color image recording, the data being used to fill at least one addressable memory which outputs a corresponding number of corrected image recording signals as output values for a large number of different image scanning signals, characterized in that a) Corrected color separations are produced based on an original image using a color correction process, b) the original and the color separations are each optically and electrically scanned separately and the image scanning signals obtained are digitized after a predetermined number of tonal value levels, with each pixel of the original corresponding to an image scanning signal combination (R, G, B) and each pixel Color separations each correspond to a single sample (mg, cy, ge, sw), c) the image scanning signal combinations (R, G, B) and the sampling values of the color separations are sorted in the order in which they are sampled according to addresses, with each pixel being assigned an address, stored in a working memory (24) and in a calculation process within the The memory of the image scanning signal combinations (R, G, B) is assigned the sample values of the color separations (mg, cy, ge, sw) belonging to the corresponding pixels and are entered into the correction memory (26) under this assignment. 2. The method 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 (26). 3. The method according to claim 2, characterized in that the correction memory (26) for only some of the signal combinations red, green, blue, hereinafter referred to as R, G, B, is formed, whose tonal value spacing is a framework in the R- , G-, B-color space, which is representative of the detection of the color space, and that the assignment is made so that the values are accepted into the memory, whose image scanning signal combinations R, G, B have the smallest distance in the R- , G, B color space to the support points of the scaffold.