DE2600901C3 - Color correction device - Google Patents

Description

The invention relates to a color value correction device according to the preamble of patent claims 1 and 2.

To the production of color printing forms too simplify, it is known to use a television color monitor in such a way that a template, for example a colored original or a set of color separations by means of a raster scanner is sampled, whereupon the primary signals thus obtained by modifying and combining a Subjected to color correction and given for control on a television color monitor. The primary signals represent the color dosage values for represents the individual printing colors yellow, magenta and cyan and are by means of the color value correction device Corrected under visual control on the color monitor. If a set of color separations that have already been produced is used as a template, then one such color value correction device enables a check To what extent the present color separations will already deliver a usable print result or but to what extent certain revisions of the color separations are necessary. Generally included

to such test procedures in which a color monitor is used in the manner described finds the problem that the fluorescent substances in the television tube have the colors red, green and blue, while when printing the colors yellow, cyan and

is magenta. To despite these differently colored fluorescent materials on the television tube TV screen to create an image as it would be obtained if using the template Color separations a test print would be carried out is at a known color value correction device of of the generic type, which is used for the preliminary assessment of the necessary revision of color separations with With the help of a color television monitor, a: Transfoririationsmatrix provided, which the from the Sampling of the three color separations received primary signals transformed with one another in adaptation to the red-green-blue system, a correction matrix being connected upstream of this transformation matrix, which the individual primary signals in their gradation influenced In this known color value correction device, the primary signals are corrected Partial combination of yellow, cyan and magenta signals, however, the secondary and tertiary colors remain from Correction process unaffected. It has been shown that

by means of this known color value correction device no satisfactory adaptation of the television screen image to an analog print image can be effected.

The invention is therefore based on the object of providing a color value correction device of the generic type

Way of creating an improved match between the color television screen image and an analog print image is ensured

According to the invention, this object is achieved with a color value correction device of the generic type Type alternatively solved by the features listed in the characterizing part of claims 1 or 2 Particularly preferred embodiment of the invention: is the subject of claim 3. By the inventively provided secondary

w and tertiary color correction succeeds in making the television screen image a corresponding color print image so because to adjust that under visual inspection of the television screen the color dosage values for the individual Printing inks can be corrected properly.

So if the primary signals are obtained by scanning finished color separations, so that of each of the Signal groups obtained from color separations are temporarily stored and then processed simultaneously and then Color monitor are fed, so arises at Use of the color value correction device according to the invention on the color display monitor a television screen image which gives the same colored impression as the one with the corresponding color separations produced color print image would awaken. Satisfied:

the color impression of the television screen image does not affect the operator, the color dosage values become of the individual printing colors using the corresponding setting buttons on the control panel of the color value correction

tureinrichtung fit as long changed until the operating person fl has the impression that the television screen the '_._ requirements of the product to color ^printing; f5 image is sufficient. From the position of the % various setting knobs or the like, -,: can then be seen which corrections are still to be made to the ^:! existing color separations must be made ΐ in order to receive a satisfactory print product % . This makes the "■ '' necessity of once produced color separations in advantageously;. You having to establish the purpose of pre-assessment of the need to revise Probeandrucke avoided Of course, the color value || suitable correction device according to the invention not only fij to that described above Preliminary assessment of the necessary revision of color separations, but: '·; this can also be used, for example, to control the production of the color separations themselves, with a colored original then serving as a template for the derivation of the primary signals

Exemplary embodiments of the invention are explained in detail below with reference to the drawing It shows or shows:

1 to 5 including graphs of color image signals for explaining a first Embodiment of the invention, in which from the original primary signals corrected image signals of yellow, magenta and cyan, specifically:

F i g. 1 is a graphical representation of the primary signals, <o be obtained a set of color separations corresponding to one line of a color monitor view with the scanning of one line,

Fig. 2 is a graphical representation of the secondary J. and tertiary signals that preceded the primary signals. 3 $ F i g. 1 have been received,

3 shows a graphic representation of the inverted secondary and tertiary signals,

Fig. 4 is a graphic representation of the inverted : Secondary and tertiary signals after multiplication with correction factors and

F i g. Fig. 5 is a graph showing the corrected image signals of yellow, magenta and cyan;

F i g. 6 to 11 including graphic representations similar to FIGS. 1 to 5, which show the way in which corrected image signals of yellow, Magenta and cyan are obtained from the primary signals when using color bar signals, in detail:

F i g. 6 a color bar pattern with primary, secondary and tertiary signals,

F i g. 7 a graphic representation of the primary signals, which can be obtained from the color bar pattern in FIG. 6 receives,

Fig. 8 is a graphic representation of the secondary and tertiary signals obtained from the primary signals,

Fig. 9 is a graphic representation of the inversions Secondary and tertiary signals,

Fig. 10 is a graph of the inverted Secondary and tertiary signals after multiplication with correction factors as well

F i g. 11 is a graphical representation of the corrected Image signals of yellow, magenta and cyan,

F i g. 12 is a block diagram of a color value correction device according to the invention, by means of which the values based on FIGS. 1 to 11 explained correction can be carried out.
13 to 18 are graphic representations of the image signals for explaining a second exemplary embodiment of the invention, in detail:

13 shows a graphic representation of the primary signals, which one from the color bar musler of FIG. 6 receives,

F i g. 14 is a graphical representation of the secondary and tertiary signals obtained from the primary signals of FIG Fig. 13 receives,

Figure 15 is a graph of the inverted Secondary and tertiary signals,

16 shows a graphic representation of the secondary signals, in which the tertiary and secondary signals of F i g. 15 are added up,

Fig. 17 is a graph showing the signals shown in Fig. 17 being multiplied by Correction factors have been modified, as well as -

F i g. 18 is a graphical representation of the corrected Image signals of yellow, magenta and cyan,

19 shows a block diagram of an exemplary embodiment of the color value correction device according to the invention; by means of which the with reference to FIGS. 14 to 19 explained correction processes can be carried out,

Figure 20 is a more detailed block diagram of a color value correction device according to the invention, in which the control panel is reproduced,

Figure 21 is a detailed block diagram of an input controller 31 of the color value correction device of FIG. 20 and

Fig. 22 as an example the graphic representation of the Dynamic correction of a color separation.

If a color original, such as a color photograph, is to be printed, first color separations corresponding to the primary colors yellow (Y), magenta (M) and cyan (C) and optionally also black (B1), in which the printing is carried out, are produced accordingly the invention is explained in connection with the color separations of the three primary colors mentioned and black (printing inks). In the following, the term "secondary color" denotes a color that is produced by combining two primary or printing colors, the ratio of the combination being not fixed Yellow, magenta and cyan is produced, although here too the ratio of the combination is not fixed

In general, the invention is based on the knowledge that when, while scanning the Color separations generated on a television color monitor, a television screen image and thereby for color value correction the same the color dosage of the primary colors is fully increased, also the dosage of the secondary colors from mid-tone sections to dark sections is increased too close to saturation, as a result, the gradation becomes insufficient in these areas. To take this into account wear, in the invention, the secondary colors are compensated for by undercolor removal. The tertiary color components are also lowered by the tertiary color components in the primary colors by one certain factor can be reduced. This can be achieved that the television screen image in his Faru impression and in its quality a corresponding one corresponds to the printed color image.

A first exemplary embodiment of the color value correction device will now be described below with reference to FIGS explained according to the invention: A line of pri-

märsignellen obtained by scanning corresponding color separations is shown in FIG. 1 shown. The letters Y, Λ / and C denote primary signals which represent the negative values of yellow, magenta and cyan, ie they indicate the intensities of the complementary colors of the corresponding colors. For example, the optical density of yellow becomes small as the yellow value approaches 100%. On the other hand, when the yellowness value approaches zero percent, the optical density of yellow becomes large. Then ι ο the primary signals are combined in pairs, that is, yellow with magenta, magenta with cyan and cyan with yellow, the in FIG. 2 result in secondary signals shown.

These secondary signals consist of so-called NAM areas, which are created by non-additive mixing in the sense of a maximum selection of the primary signals. The NAM method is described, for example, in "Journal of SMPTE", Vol. 73, pages 658 to 660, or in US Pat. No. 3,371,160. The secondary signals are labeled YM, MC and CY. The secondary signals, which therefore consist of the NAM areas of two of the three primary signals, are scanned by scanning circuits. The amount of color at the 100% level of the respective signal is zero. The amount of paint or paint dosage is determined in the zero percent direction on the basis of this 100% level or level. Therefore, the amounts of paint or doses of paint can easily be added and subtracted by determining the level that corresponds to the zero value of the amount of paint. The secondary signals are inverted, whereupon the pulses corresponding to the 100% level (represented by "P" in FIG. 3) are added to each feedback period. In this way, one obtains the inverted composite secondary signals ( -YM, -MC and -CY) as shown in FIG. 3 shown.

The inverted secondary signals shown in FIG. 3 are then multiplied by correction factors *, β and γ , resulting in the corrected signals -YM-IX, -MC β and -CY-γ , as shown in FIG. 4 are shown. This multiplication of the inverted secondary signals by means of the correction factors ä, β and y takes place in compensation circuits. The correction factors α, β and γ differ according to the type of printing form, the printing inks, etc., but the values of the correction factors can be predetermined experimentally and arranged in tabular form. Furthermore, the values of the correction factors can be linear or non-linear. The corrected inverted secondary signals -YM · tx, -MC β and -CY · γ so are then added to the primary signals yellow Y, magenta M and cyan C , whereby corrected image signals Y'.M ' and C' are obtained

The television screen image is then generated by combining the aforementioned corrected image signals Y ', M' and C on the screen of the color monitor without darkening any of the secondary colors, namely red-blue-green in the television system. By appropriately setting the color metering parameters of the printing or primary colors on the control panel of the color value correction device, the quality of the television screen image can be optimized according to the subjective perception of the operator, whereupon the necessary corrections for the color separations result from the setting of the corresponding setting buttons. Overall, as a result of the secondary color correction described, the gradients of the various colors on the television screen of the color monitor correspond to those of a color printed image which would be obtained using the corresponding color separations, which means that excellent correction results can be achieved by means of the color value correction device according to the invention.

While the secondary color correction has been explained above, the NAM tertiary signal section (YMC in FIG. 2) results from the primary signals Y, M and C in a manner similar to that of the secondary signals, with an inversion taking place in the same way. The inverted tertiary signal is then corrected with a correction factor ό and added to the individual primary signals.

Overall, it can be seen that the color value correction device according to the invention with regard to scanning the color separations, the conversion of the electrical primary signals and the corrections of the secondary and tertiary signals works as follows before subsequent application to the color monitor:

The primary signals are labeled Y, M and C. The NAM section of Y and M is YM, the corresponding correction factor is «; the NAM portion of M and C is AiC the corresponding correction factor is β; the NAM portion of C and Y is CV, the corresponding correction factor is y; the NAM portion of Y, M and C is VMC the corresponding correction factor is 6; and the correction values are r, g, b and bl. The equations for these correction values are:

r = - YM ■ -v.
b = - MC ■ ,;.
g = -CY -: -

W = - YMC ■ λ.

Furthermore, the image signals corrected with regard to the secondary and tertiary color content are given by:

Y = γ + r + g + bl. M '= M + r + h + bl

C = C

As in Fig. 5, the correction carried out by means of the color value correction device according to the invention shifts the secondary and tertiary color sections of the corrected image signals Y ', M' and C to a certain extent from zero percent to 100%, thus correcting these sections in the direction of higher brightness values will.

The corrected image signals Y ', M' and C obtained in this way are then converted into the television signals of red, blue and green by a matrix circle, as is also used, for example, in the color value correction device according to US Pat TV screen of the color monitor an image which corresponds to the color print image to be produced

Another exemplary embodiment of the color value correction according to the invention will now be described below with reference to FIGS. 6 to 11, color bar patterns serving as the source of the primary signals. Fig. 6 shows such a color bar pattern. When this is converted into image signals, the primary signals Y, M and C are obtained as shown in FIG. 7 are shown. F i g. Fig. 8 shows the secondary signals YM, MC and CV and combination with the pulse P (Fig. 9).

The in F i g. The signals shown in FIG. 10 are obtained by correcting the signals of FIG. 9 with correction factors, β, γ and O. In FIG. 11 are the corrected image signals

r = γ + _r +

ti.

M '= M + r + b + W

Primary signals of yellow and magenta, magenta and cyan or cyan and yellow each combined in pairs will. As shown in Fig. 14, these secondary signals are composed of the NAM sections, respectively in pairs of the signals Y, mouth C In F i g. 14, these secondary signals are again denoted by YM, MC and CY . After the detection circuits have detected the NAM portions of the primary signals of yellow, magenta and cyan, the thus obtained become secondary signals YM, MC and CY in Fig . 14 inverted, whereby the signals -YM, - MCun d -C? of Fig. 15 result. The tertiary signal YMC of Fig. 14 obtained by a tertiary color detecting circuit becomes the inverted signals -YM, -MC and - CY of FIG. 15, that is, added accordingly in each case. In this way, the tertiary color contents in the secondary colors are eliminated, as a result of which the signals

shown. The primary signals become yellow, magenta and cyan in the image signals of FIG. 11 not corrected, while the secondary colors red, namely MY in Fig. 11, green, namely CY in pig. 11, blue, namely MC in Fig. 11, and the tertiary color gray, namely YMCm Fig. 11, are changed by the compensation factors, β, γ and δ , whereby they are shifted from zero percent to 100%, i.e. the Saturation values are reduced.

An exemplary embodiment of a block diagram of the color value correction device according to the invention is shown in FIG. The primary signals Y, mouth C of FIG. 1 are connected to ports Y, Mbzw. Y, M and C are connected to detector circuits 41, 40 and 41 ", respectively, for the secondary signals, whereby the secondary signals MY, MC and CY shown in FIG. 2 can be derived. Simultaneously, the primary signals is applied to another detection circuit 42 for the tertiary signal, whereby the tertiary signal VMC is obtained. The circuits 43-43 "'serve to invert the pulses represented by P in Fig. 12 and to carry out an addition operation such that each of the secondary signals YM , MC and CY as well as the tertiary signal YMC are inverted and added to the Jmpijls P , whereby the jn F i g. Signals YM, -CY -MQ and shown 3 - YMC includes the compensation circuits 44-44 'serve' to the Signaje -YM, -MQ -CTund - YMCmittels the correction factors Λ β, γ and δ to be corrected to give the Signals - YM · «, -MC · ß , -CY · γ and - YMC <ό from Fig. 4 received Finally, the signals Y, Af. C -YMoL, -MC.ß, -CY -y and -YMC -6 is applied to adding circuits 45 to 45 "and added there in each case, whereby the corrected image signals Y ', M' and C 'are obtained as the output

Another embodiment of the invention will now be explained. The Farbbalkenrmister from FJg. t is in the shown in F ig · 7 primary signals Ύ, M and C converted f ig 13 shows signals obtained by. Addition of pulses with corresponding 100 <) ii? Levels of the signals Y, M and C in Fig. 7 to each return period of the signals Y, M and C can be obtained. The width of the pulses to be added is consistent with that of the Rückfflhru, ngsperiode Qbepin, pie, let secondary signals "get Ptl by dje, - YM + YMQ MC-YMQ -CY + YMQ

shown in FIG. 16, result.

By removing the tertiary color content from the secondary signals, with the proportion of r that corresponds to Y and Min Fi g. 18 is added, is changed, the color value of the secondary color red can be changed. The color value of the tertiary color, however, is not affects the signals

(-YM-YMC) -a, (~ MC + YMC) d and (-CY + YMC) ■ e

from F i g. 17 is obtained by the signals

-YM + YMQ -MC + YMC and
-CY + YMC

of Fig. 16 can be multiplied by predetermined correction factors. The correction factors a, d and e are determined according to the type of printing form, the

Printing inks, of the paper to be printed, etc. varies, but the values of the correction factors can be determined experimentally in advance and summarized, for example, in tabular form. The correction signals shown in Fig. 17 become the primary signals Y, M and C are added by means of suitable linear or non-linear circles

The tertiary signal MIfC of FIG. 1 is obtained in a similar way to the secondary signals. 14 in that the NAM sections of the primary signals Y, mouth C

of Fig.7 are combined, from which after

Inverting the signal -YMC of Fig. 15 results This is multiplied by a correction factor /,

thus giving the signal -YMC · f of FIG

The above-described secondary and tertiary

color correction can be summarized as follows:

Pi? Primary signals are Y, mouth C; the NAM portion of Y and M is YM, the corresponding correction factor is a; the NAM section of mouth C if MC the corresponding correction factor is d; the

NAM section of Y and C'MCY, the corresponding one Correction factor is e; the NAM section of Y, M

■ and Cjst yMC; the corresponding correction factor is / j

and the correction values are r ', g', b ' and bl'. Then we get:

ι · '= (-YM + YMC) a

b = (-AiC + YMC) d

g '= (-CY + Y MC) e

br = - YMC ■ S-

The corrected image signals V, M ' and C result after the secondary and tertiary signal correction as follows:

= Y

= M + r '

+ bi

C = C + + g '+ b' + bl '.

10

20th

As shown by Y ', M' and C in Fig. 18, the values of YM, MC, CY and YMC are shifted from zero percent toward 100% in accordance with the correction factors. For example, none of the colors red, green or blue is darkened. The gradation of the tertiary color is also not reduced, so that the television screen image can be produced in excellent correspondence with the color print image, that is to say, the color value correction device according to the invention is very effective. Of course, when the correction factors a, d and e are changed, the portion of Fig . F i g corresponding to the YMC becomes. 6 is not affected in any way

The block diagram of the color value correction device according to the invention shown in FIG. 19 will now be explained in detail. The connections Y, M and C are connected to the connections shown in FIG. 7 applied to the primary signals shown. The reference numerals 71 to 71 ″ denote holding circuits and output amplifiers, by means of which the respective zero percent levels of the primary signals Y, M and C are kept at a constant DC voltage. Pulses with a corresponding 100% potential are added to the feedback periods of the primary signals Outputs of the hold and output amplifiers 71 to 71 ″ are connected to detector circuits 72 to 72 ″ for the secondary signals, so that the secondary signals YM, MC and CY are obtained from FIG Thus a tertiary signal is connected, which gives the signal - YMC . The circles 74 to 74 ″ remove the tertiary color components from the secondary signals, ie the outputs of the detector circuits 72 to 72 'for the secondary signals are connected to the output of the detector circuit 73 for the tertiary signal combined The combined signals are inverted, which results in the signals

(- YM + YMCX (-MC + YMC) \ ma (-CY + YMC)

result. The outputs Y, M and C of the hold and output amplifiers 71 to 71 ", the outputs

C- YM + YMCX (-MC + YMQ and (-CY + YMC)

60

65 of the circles 74 to 74 ″ for removing the tertiary color components from the secondary signals and the output - YMC of the detector circuit 73 for the tertiary signal are connected to summing circuits 75 to 75 ″. The signals are thus combined with the predetermined correction factors. Negative pulses at 100% level are added to the feedback periods of the signals, resulting in the corrected image signals Y ', wound C' as output.

Referring to FIG. 20 now becomes a practically implemented color value correction device explained in detail according to the invention. This color value correction device has a scanning part 10, a memory 20, a control part 30, a gradation compensation part 40, a matrix circle 50 and a Color vision monitor 60 on.

Each color separation 13, which is arranged on a film carrier 11, is imaged by means of a camera 14 Scanning part 10 scanned. The film carrier 11 consists of a plate made of polished glass and is illuminated from the underside by a suitable light source or also illuminated by multiple light sources. The film carrier 11 also has a movable one Pin bar 12, the pins 121 of which are inserted into perforations 131 of each color separation 13 to earth the relevant color separation 13 to hold in a certain position on the film carrier 11. The camera 14 is a conventional black and white television camera and has a zoom lens 141.

The primary signals obtained by scanning the color separations 13 one after another using the scanning part 10 are obtained into the input control part 31 of the control part 30, whereupon they are transferred to the Memory 20 transferred and held there. The input control part 31 controls the input primary signals according to the type of color separations, wherein this is done by a channel selector switch 341 on a control panel 34, to be explained below

The controlled by the input control part 31 primary signals are separately supplied to the corresponding magnetic recording tracks in the memory 20 by means of Farbwahldruckknöpien 342 at the Bcdienungsschalttafel 34 and stored there, if so, for example, a yellow color separation is sampled 13 Vdurch pressing of the value Y in the color selection push buttons 342, so that is to The next step is to scan a magenta color separation 13W by pressing M on the color selection pushbuttons 342, the corresponding magenta primary signal group being fed to the magenta track of the memory 20 'A'-Ir. Similarly, the above steps can be followed for other colors.

The primary signals Y, M, C and B], which are stored in the corresponding color tracks in the memory 20, are then read out and introduced into a setting part 33 by the channel selector switch 341. The setting part 33 has various control or control circuits for light control, dark control , Compression, contrast and background control for each channel. Control buttons 343 for the respective colors and types of controls for each channel are also provided on the control panel or control panel 34.

The input control part 31 is shown in the form of an exemplary embodiment in FIG Drawing is the primary signal at an input 3101

11th

created. The white and black levels of the primary signal are determined by a level controller 3102 and a Holding circuit 3103 set You are then connected to a linear circuit 3104 and a non-linear circuit 3105 created. Both outputs are connected to a dynamic equalization circuit 3106 (gamma equalization). In this way, the ratio of the linear component and the non-linear component are through Selecting or corresponding setting by means of the channel selector switch 341 of the control panel 34 varies A ι ο Ncgaposiveramplifier 3107 provides an input when it is positive and reverses the input when it is positive is negative, whereupon the pulse corresponding to the 100% level adds up during the feedback period and the result is finally given as an output. One such device is for reproducing a negative original known as a positive image in television cameras. The dynamic equalization of the color separation is shown by way of example in FIG Halftone positive signal 3111, a halftone negative signal 3112, a full tone positive signal 3113 and a full tone negative signal are provided. When the dynamic equalization of the halftone positive signal 3111 is linear, can represent the positive image by inverting the halftone negative signal 3112 and adding it to the 100% level generate corresponding impulse. Furthermore, the full tone positive signal 3113 becomes the same gradation reproduced like that of the halftone positive signal 311 by adding an exponential correction will. The same applies to the full tone negative signal 3114.

With color value correction devices according to the invention, the difficulties of a repetitive Proofreading is simplified, which increases the profitability of the color printing process and that can accelerate the entire process. It should be noted that the embodiments described, even as far as they are shown in the drawing, serve only illustrative purposes and the invention in no way limit. Furthermore, for further details of the color value correction device according to the invention, in particular with regard to the details of the electrical circuit arrangement, reference is made to the DE-OS 26 00 901 is referred to.

For this purpose 10 sheets of drawings

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55

60

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Claims (3)

Patent claims: 1. Color value correction device for setting the color value of a television color monitor image, in particular for pre-estimating the necessary. Revision of color extracts in which the three channels of the color monitor are supplied with the primary signals resulting from the scanning of an original after modification and combination, characterized in that the primary signals (Y, M, C) are combined in pairs in order to select the larger signal in each case and using the same as a secondary signal (YM, MC, CY), that all three primary signals (Y, M, C) are also combined in the sense of selecting the largest signal in each case and using it as a tertiary signal (YMC) ; and that two of the three secondary signals (YM, MC, CY) and the tertiary signal (YMC ) are added additively to the primary signals (Y, M, C) after multiplication by correction factors {ac, β, ybzv / .o). 2. Color value correction device for adjusting the color value of a television color monitor image, in particular for the preliminary assessment of the necessary revision of color separations, in which the primary signals resulting from scanning a template are fed to the three channels of the color monitor after modification and combination, characterized in that the primary signals (Y, M, C) are combined in pairs in order to select the larger signal and use it as a secondary signal (YM, MC, CY); that all three primary signals (Y, M, C) are also combined in the sense of selecting the largest signal in each case and using it as a tertiary signal (YMC) ; and that of each secondary signal (YM, MC, CY) the tertiary signal (YMC) is subtracted, and two of the resulting difference values by multiplication with correction factors (a, d, e) in each case with the addition of the likewise provided with a correction factor (F) Tertiary signal (YMC ) can be added to the primary signals (Y, M, C). 3. Color correction device according to claim 1 or 2, characterized in that the secondary signals (YM, MC, CY) and the tertiary signal (YMC) are inverted after their formation and before their further processing.