WO1982000903A1 - Process and circuit for the partial electronic correction in colour image reproduction - Google Patents

Abstract

In the method for improving the drawing in colour image reproduction by partial electronic retouching, the trichromatic sampling of a colour component of the colour image provides the trichromatic components which are subjected to an analog/digital conversion and stored in the memory (1). With a coordinate probe (50, 51, 52), a retoucher will proceed in the same way as with a retouching brush. By means of the probe, the coordinates of a moving area on the image (surface of the brush) of a trichromatic component to be retouched as well as the number of correction steps by image point will be searched. For the marked correction area the corrections will be calculated point by point. The trichromatic components of the coloured image or of a coloured printing will be read in the memory (1) and modified to obtain the retouching effect under the control of a monitor (2). The individual values of the corrections for each correction step may be freely selected. By previously determining the modifications so that they decrease from the center towards the edges of the image (for example according to the Gauss distribution), there will be provided in the retouching area a retouching degree which increases or decreases progressively.

Description

 Method and circuit arrangement for partial electronic retouching in color image production

description

Method and circuit arrangement for partial electronic retouching in color image reproduction.

Technical field

The invention relates to electronic reproduction technology, in particular to the production of corrected and retouched color extracts using an electronic image processing system (retouching station).

Underlying state of the art

In electronic color reproduction, three primary color measurement signals are obtained in a color scanner by optoelectronic scanning of an original, which represent the color components red, green and blue of the scanned pixels. A color correction computer corrects the color measurement signals and uses them to produce the color separation signals required for producing the color separations, which are a measure of the quantities of printing ink required in later printing.

The color separation signals are digitized and stored as digital color values pixel by pixel in a storage medium. In an image processing tation system, the stored color values of various individual templates can be combined according to a layout plan to form the data volume of an entire page and / or subsequent partial retouching (color and / or tonal value corrections) can be carried out by changing the color values. Partial retouching, ie limited to selectable, locally limited image areas, is necessary to optimize the correction made in the color calculator or to take editorial changes and customer requests into account afterwards. These retouches are, for example, the application of highlights by lightening, the working out of shadow areas by darkening or the improvement of the drawing by lightening and darkening, often with a gradual (progressive) effect, ie a gradually increasing or decreasing effect, should be achieved.

To record the retouched color separations, the changed color values are read out from the storage medium, converted back into analog color separation signals and fed to a color scanner in which the framed or non-rastered color separations "yellow", "cyan", "magenta" and "black" are exposed to produce printing forms become.

In German patent application P 29 20 058.6 (international patent application PCT / DE 80/00070) a method for partial electronic retouching has already been proposed, in which the digital color values are partially and pixel-wise under visual control on a monitor corresponding to the desired retouching effect in the color image or in the color separation can be changed by pixel-dependent correction values. The image point coordinates of the color values to be retouched and the desired retouching strength are determined by the retoucher by guiding the coordinate pen of a coordinate detection device like a retouching brush over the image part to be retouched, the coordinate pen touching the corresponding image points, and out of

Number of touches the retouching strength is derived for the individual pixels. In order to retouch larger parts of the image more quickly, the correction area and thus the number of image points captured and retouched with each touch of the coordinate pen is enlarged, which corresponds to an enlargement of the "brush surface".

This method of working with the coordinate pen as an "electronic retouching brush" specified in the German patent application P 29 20 058.6 allows achieving any kind of gradients, but requires a great deal of care and is particularly time-consuming if the gradients are to be smooth with no recognizable gradation .

Disclosure of the invention

The object of the present invention is therefore to provide a method and a circuit arrangement for partial electronic retouching in color image reproduction, which improves the proposed method in that gradual retouching changes and color gradients are easier and can be carried out in a shorter time.

This object is achieved in the present invention in that the individual amounts by which the correction values (Y _R , M _R , C _R , K _R ) of the

Correction range can be changed per correction step, can be freely selected.

The same amounts of change are advantageously specified for all correction values (Y _R , M _R , C _R , K _R ) of the correction area, as a result of which a uniform retouching strength is achieved within the correction area.

The correction values (Y _R , M _R , C _R , K _R ) are preferably given decreasing amounts of change from the center of the correction area to the edge thereof, as a result of which a gradual (running) retouching strength is achieved within the correction area. The amounts of change can be specified according to a selectable function, in particular according to a Gaussian function.

The correction values (Y _R , M _R , C _R , K _R ) are added to the pixel values (Y, M, C, K) assigned to the image point (positive retouching) or subtracted from these (negative retouching).

In an advantageous embodiment it is proposed that a) color increments (Y, M, C, K) are specified for the individual color components, which are the smallest amounts of change for the correction values (γ _R, M _R , C _R , K _R ), b) the pixel coordinate pairs (x, y) of the correction area are determined, c) for each determined pixel coordinate pair (x, y) per correction step

Retouching factor (r) determining the retouch strength, which determines the correction value

(Y _R , M _R , C _R , K _R ) indicates the number of color increments to be added, and d) pixel-related retouching factors (r) and color increments (ΔY, ΔM, ΔC, ΔK) are multiplied together to give the respective correction values ( Y _R , M _R , C _R , K _R ).

It is provided that a) at least one pixel coordinate pair (x ₀ , y ₀ ) of the correction area is detected by marking using a marking device of a coordinate detection device (50, 51, 52), in particular using a coordinate pen (51), and b ) the remaining pixel coordinate pairs

(x, y) of the correction area depending on the marked pixel-coordinate pair (x ₀ , y ₀ ) can be calculated.

By selecting the pixel coordinate pairs to be calculated (x, y) around the marked pixel coordinate pair (X ₀ , y ₀ ), the shape and size of the correction area are determined.

An advantageous further development provides that a) each point contact with the marking device (51) of the coordinate detection device (50, 51, 52) corresponds to a correction step, and b) each retouching factor (r) for a pixel coordinate pair of the correction area is calculated from the number of point touches (n) and an evaluation factor (w) predetermined for the pixel coordinate pair in question, which indicates the amount of change in the correction value concerned (Y _R , M _R , C _R , K _R ) per point contact as a multiple of the color increments (ΔY, ΔM, ΔC, ΔK), the coordinate pen (51) like a retouching brush over the one to be retouched Part of the image is guided to move the correction area (brush surface).

It is proposed that the same evaluation factors (w) be specified for all correction values of the correction range, as a result of which a uniform retouching strength is achieved within the correction range. Alternatively, it is proposed to specify decreasing evaluation factors (w) for the correction values from the center of the correction area to its edge, as a result of which a gradual (running) retouching is achieved within the correction area.

The digital color values (Y, M, C, K) are preferably read from the storage medium (1), changed by the correction values (Y _R , M _R , C _R , K _R ) and the corrected color values (Y ', M ', C, K') after retouching is again stored on the storage medium (1).

An advantageous improvement is that the unretouched or retouched color image (original) or an unretouched or retouched color separation for visual inspection on a monitor (2) is shown that a movable light mark (31) is faded into a screen (3) and that the movement of the light mark (31) with the movement of the coordinate pin (51 ) of the coordinate data acquisition device (50, 51, 52) is synchronized.

It is envisaged that the digital color values (Y, M, C, K) of the individual color separations from the storage medium (1) are loaded into an image repetition memory (7) and that the image repetition memory (7) for point-by-point recording on the monitor (2) cyclically is read out.

The determined retouching factors (r) are preferably overwritten pixel by pixel in a retouching memory (49), and the retouching memory (49) is used for the pixel-based assignment of color values (Y, M, C, K) and correction values

(Y _R , M _R , C _R , K _R ) read out synchronously with the refresh memory (7).

The retouching factors changed by the correction process are each overwritten into a blanking interval in the image recording in the retouching memory (49).

An advantageous further development is that the pixel coordinate pairs (x, y) of the marked points are stored in the order of their detection, and that the pixel coordinate pairs (x, y) in reverse order are called up and the corresponding retouching factors (r) in the retouching memory (49) are changed in order to undo the retouching that occurred when the points were previously touched.

In a further preferred development, the entire correction is canceled by deleting the retouching memory (49).

The brush surface is advantageously indicated by a correspondingly enlarged light mark (31).

The part of the image to be retouched is advantageously limited by an electronically generated mask.

An advantageous arrangement for carrying out the method consists of a color sensor (38) for forming the color increments (ΔY, ΔM, ΔC, ΔK), a retouching sensor (39 *) for forming the retouching factors (r) for the color values to be corrected (Y, M, C, K), a correction value transmitter (40) connected to the color sensor (38) and the retouching sensor (39 *) to form the correction values (Y _R , M _R , C _R , K _R ) and from the image repetition memory (7) downstream link levels (15,16,17,18) in the color channels for changing the color values by the correction values.

The retouching transmitter (39 *) is preferably from a coordinate detection device (50, 51, 52) for determining the pixel coordinates (x, y) the color values to be corrected, from an evaluation circuit (48 *) connected to the coordinate detection device (50, 51, 52) to form the retouching factors (r) for each pair of coordinates detected, and from one with the evaluation circuit (48 * ) connected retouching memory (49).

Brief description of the drawings

The invention is explained in more detail below with reference to FIGS. 1 to 9. Show it:

Figure 1 shows a circuit arrangement for partial electronic retouching in color image reproduction;

Figure 2 is a flow chart;

Figure 3 different shapes of brush surfaces; Figure 4 shows a path of movement of the brush surface; Figure 5 is a graphic representation; FIG. 6 shows a further graphic representation;

Figure 7 is a graphical representation for coordinate determination; FIG. 8 shows an exemplary embodiment for a retouching device; Figure 9 is a flow chart.

Best way to carry out the invention

Figure 1 shows the basic structure of a circuit arrangement for partial electronic retouching (retouching place) in color image reproduction and Figure 2 shows a flow chart to explain the process flow. The circuit arrangement is correct except for the retouching transmitter were in accordance with the arrangement shown in Figure 1 of the aforementioned German patent application P 29 20 058.6 (international patent application PCT / DE 80/00070). For this reason, a detailed description of identical modules that have the same reference numbers can be dispensed with.

A storage medium 1 (magnetic tape; magnetic disk) contains the digital color values already corrected in a color scanner for the color separations "yellow" (Y), "magenta" (M), "cyan" (C) and "black" (K) one to be reproduced Color image. The color image is to be visually checked on the screen 3 of a color monitor 2 of a partial retouch with a gradual (ongoing) effect, i. H. gradually increasing or decreasing strength.

The color values required for displaying the color image or a corresponding image section are selected or calculated from the entire data inventory of the storage medium 1 by means of a process computer 4 and transferred to an image repetition memory 7 via data buses 5 and 6.

To generate a still image on the color monitor 2, a memory control unit 8 cyclically calls up the X / Y addresses of the image repetition memory 7 via an address bus 9. The stored color values F [Y, M, C, K] are read out and supplied to digital adder stages 15, 16, 17 and 18 via data lines 11, 12, 13 and 14. In the adding stages 15, 16, 17 and 18, digital correction values F _R [γ _R , M _R , C _R , K _R ] are added (positive retouching) or subtracted from these (negative retouching) in order to obtain the retouched color values F in accordance with the desired retouching effect '[Y', M ', C, K']. The retouched color values F 'arrive via a data bus 20 and a light mark generator 21 on a D / A converter 22 which generates four analog color separation signals.

A downstream print simulation computer 23 converts the four color separation signals into the control signals r, g and b for the color monitor 2 in such a way that the color image shown conveys the same color impression as the subsequent multi-color printing itself. A clock generator 24 synchronized by the memory control unit 8 controls the color image recording.

The correction values F _R are obtained in a correction circuit 19, which is modified from an input stage 37 with a number of function keys 37 ', 37''and37''', from a color transmitter 38, from one compared to the aforementioned German patent application Retouching sensor 39 * and consists of a correction value sensor 40.

The location-dependent correction value F _R (x, y) for each pixel with the coordinates x and y is given by the general equation:

F _R (X, Y) = ΔF.r (x, y) (1) or for the individual color separations using the equations:

Y _R (X, Y) = ΔF.r (x, y)

M _R (x, y) = Δ Mr (x, y) (2)

C _R (x, y) = ΔC-r (x, y)

K _R (x, y) = ΔK.r (x, y)

given.

In equations (1) and (2), ΔF [ΔY, ΔM, ΔC, ΔK] are location-independent color increments which represent the smallest amounts of change for the color values. The color increments are calculated in the color transmitter 38 from the color values of an initial color and a target color for the retouching.

A measure of the retouching strength is the retouching factor r, which specifies the number of color increments F to be added for each pixel in order to obtain the relevant correction value F _R.

By increasing the number of color increments an increase in retouching and by decreasing the number is a corresponding decrease in

Retouching achieved. The retouching factors r are obtained in the retouching sensor 39 *.

The retouching sensor 39 *, the structure and mode of operation of which is described in more detail in FIG. 8, essentially consists of a coordinate detection device with digitizing tablet 50, coordinate pin 51 and measuring stage 52, and a modified evaluation circuit 48 * for calculation the retouching factors and from a retouching memory 49.

By means of the coordinate pen 51, the correction area is shifted over the part of the image to be retouched, and the respective number of correction steps is determined as the number of pixel touches. While the coordinate pen 51 marks only one pixel each, the evaluation circuit 48 * des

Retouching sensor 39 * simultaneously determines the retouching factors of several selectable pixels in the vicinity of the marked pixel. These pixels form the correction area. The simultaneous determination of the retouching factors of the correction area corresponds to an enlargement of the effective area of the coordinate pen 51 or the brush surface, as a result of which larger areas can be retouched more quickly.

The freely selectable number and the position of the simultaneously addressed image points in relation to the marked image point determine the size and shape of the correction area or the brush surface, which is moved with the coordinate pen 51 over the image part to be retouched.

Some forms of brush surfaces are shown in FIG. 3 for explanation. FIG. 3a shows a square brush surface with 5 × 5 pixels 71, FIG. 3b shows a rectangular brush surface with 3 × 7 pixels 71 and FIG. 3c shows a brush surface approximating the circular shape. The pixels touched with the coordinate pin 51, in execution Example, the center points of the brush surface are highlighted in the figures by thick lines.

FIG. 4 shows the displacement of a square brush surface 72, which consists of 3 × 3 pixels, over an image part to be retouched. The path of movement of the coordinate pen 51 is indicated by a dashed line 73.

Back to Figure 1.

According to the invention, the amounts by which the correction values F _R can be changed within the brush area per correction step can be freely selected. The corresponding retouching factors r are calculated in accordance with equation (3) in the evaluation circuit 48 *.

r (x, y) = n (x, y) .w (x, y) (3)

In equation (3), "n" means the desired number of correction steps or point contacts with the coordinate pen 51 and "w" is a freely selectable evaluation factor, which for each pixel indicates the amount of change per correction step as a multiple of the color increments ΔF.

In the case of a uniform retouching strength within the brush surface, as z. B. is desired for opaque retouching, the retouching factors of all the pixels located within the brush area are each changed by the same amount. The weighting factors w are constant, for example "1". With each touch by the coordinate pin 51, the retouching factors r are then increased by "1" (reinforcement of the retouching) or decreased by "1" (withdrawal of the retouching).

In the case of a running retouching strength, the retouching factors r of the pixels lying within the brush area are changed by different amounts in accordance with the selected evaluation factors w, as a result of which the retouching strength advantageously progresses gradually or progressively within the brush area, ie. H. is gradually increasing and / or decreasing.

For example, the evaluation factors w can be selected such that a retouching strength that decreases from the center of the brush surface to its edge is achieved. The retouching strength can change within the brush area according to the Gauss curve or another function. The possibilities are not limited to the examples given. Any evaluation factors can be distributed within the brush area.

The formation of the retouching factors is explained on the basis of graphic representations in FIGS. 5 and 6, the retouching factors determined after a certain number of correction steps (touches) being entered in the brush area.

FIG. 5 shows the conditions for a brush surface with a uniform retouching strength. The evaluation scheme is shown in FIG. 5a. All Pixels of the brush surface are rated w = 1. After touching (n = 1) according to FIG. 5b, all retouching factors are "1" and the correction values according to equation (1) F _R = ΔF. After, for example, three correction steps (n = 3), corresponding to FIG. 5c, all retouching factors have increased to "3" and the correction values are F _R = 3 ΔF.

FIG. 6 shows the conditions for a brush surface with retouching strength. FIG. 6a again shows an evaluation scheme according to which a decreasing retouching strength is achieved depending on the distance from the center of the brush surface. The retouching factors after a correction step (n = 1) are shown in FIG. 6b and after three correction steps (n = 3) in FIG. 6c. By evaluating the image point 71 with w = 1 and the image point 71 'with w = 2, for example after three correction steps, the correction value F = 3 ΔF and for the image point 71' the double correction value, namely F _R =, already results 6 ΔF. The retouching factors outside the brush area are zero. At the same time, the profiles of the retouching strength through the center of the brush surface are indicated schematically in the figures for the individual cases.

Back to Figure 1.

The retouching factors r ascertained in the evaluation circuit 48 * of the retouching sensor 39 * become open during the blanking interval of the image recording the color monitor 2 overwritten in the retouch memory 49 via a data bus 55. The corresponding addresses of the retouching memory 49 are selected via an address bus 54.

The blanking interval of the image recording is signaled by the memory control unit 8 to the evaluation circuit 48 * via a line 56, the addresses of the image repetition memory 7 and the retouching memory 49 are called cyclically and synchronously via address buses 9 and 9 ', which means that pixels are called assigned digital color values F and retouching factors r can be read out simultaneously. The retouching factors read out from the retouching memory 49 are passed to the correction value transmitter 40 via a data bus 57, in which they are multiplied by the correction values Δ F calculated in the color transmitter 38 by the color increments Δ F calculated in the color transmitter 38 To get F _R. The correction values F _R are over

Data lines 58, 59, 60 and 61 transmitted to the digital adders 15, 16, 17 and 18 in the individual color channels.

In order to make the image point marked by the coordinate pen 51 (center point, the brush surface) or the entire brush surface visible, a light mark 31 is faded into the screen 3 of the color monitor 2, which is generated in the light mark generator 21. The movement of the coordinate pin 51 is synchronized with the movement of the light mark 31. For this purpose, the pixel coordinates or addresses determined in the evaluation circuit 48 * are sent via an address bus 53 ' the memory control unit 8 transmits and compares it there with the cyclically called addresses of the image repetition memory 7. If the address is the same, a command “light mark” is generated on a line 34, and the light mark generator 21 generates the movable light mark 31 on the screen 3.

The invention is not limited to the determination of the retouching factors from the number of pixel touches. Rather, it lies in the

Within the scope of the invention, the retouching factors also result from the mechanical pressure with which the coordinate pin 51 is pressed onto the digitizing tablet 50, or from the dwell time of the coordinate pin 51 on the corresponding one

To determine points of the digitizing tablet 50.

The determination of the retouching factors and the structure of the retouching transmitter 39 * are described in more detail below.

The calculation of the pixel coordinates x and y within the brush area is first explained with reference to FIG. 7. A detail from the digitizing tablet 50 of the coordinate detection device or from the image to be retouched is shown with two positions I and II of the brush surface 72 in the X / Y coordinate system 74. In position I the brush surface 72 has the center point coordinates x ₀₁ and y ₀₂ and in position II the center point coordinates x ₀₂ and y ₀₂ , the points P ₁ and P _{2 being} the points marked with the coordinate pen 51. The position II was through the movement of the coordinate pin 51 is reached along a dashed line 75.

The brush surface 72 is assigned an X '/ Y "auxiliary coordinate system 76, which runs through the center P. In the X" / Y' auxiliary coordinate system 76, the auxiliary coordinates x 'and y' of those pixels that are fixed on the Forming a brush surface in terms of shape and size are involved. The corresponding pixel coordinates x and y each result for the individual current positions of the brush surface in the X / Y coordinate system 74:

x = x ₀ + x '

(4) y = y ₀ + y '

FIG. 8 shows a detailed exemplary embodiment for the retouching transmitter 39 *, in particular for the evaluation circuit 48 *. The retouching sensor 39 * performs the functions: detection of the center point coordinates (a), calculation of the pixel coordinates (b) and determination of the retouching factors (c).

(a) Detection of the center point coordinates (x ₀ ; y ₀ )

The center points P of the brush surface 72 (FIG. 7) are marked with the coordinate pen 51 on the digitizing tablet 50 of the coordinate detection device, and the measuring stage 52 transmits the detected pixel coordinates x ₀ and y ₀ via the data bus 53, a comparison stage 77 and over a further data bus 78 to an adder 79 in the evaluation circuit 48 *.

Coordinate detection devices of this type are commercially available (for example from Summagraphics, 35 Brentwood Ave., Fairfield USA) and are known to the person skilled in the art, so that a detailed description is not necessary. In the coordinate detection device of the exemplary embodiment, the coordinates are first determined with a much higher resolution than the resolution of the stored and displayed image from 512 x 512 pixels, which achieves a high measurement accuracy. The measured coordinates are then in the measuring stage 52 to the possible

512 x 512 coordinates x ₀ and y ₀ or addresses converted and output.

(b) Calculation of the pixel coordinates (x; y)

In the comparison stage 77, successive pairs of center point coordinates x ₀ and y ₀ are continuously compared with one another. In the event of a change of coordinates which occurs when the coordinate pin 51 is displaced, the comparison stage 77 supplies a "change of coordinates" command on a line 80 to an address counter 81. The address counter 81, each started by the "change of coordinates" command, calls all possible cycles and lines Coordinates of the X '/ Y' auxiliary coordinate system 76, which are fed via a data 3us 32 to a coordinate computer 83 for determining the auxiliary coordinates x 'and y'. The coordinate calculator 83 is Programmed via a programming input 84 with the parameters of the desired brush surface according to one of FIGS. 3a to 3c. In the exemplary embodiment, a circular brush surface may be desired, the size of which is predetermined by the radius R.

The coordinates called up by the address counter 81 are examined in the coordinate computer 83 to determine whether they satisfy the circular equation x ' ² + y' ² = R ² for the brush surface. The coordinates satisfying the circular equation are the auxiliary coordinates x 'and y' of the brush surface. The auxiliary coordinates x 'and y' are given via a data bus 85 to the adder 79, in which the pixel coordinates x and y are formed in accordance with equation (4).

The calculation sequence in the coordinate calculator 83 for the example of a circular brush surface with the radius R illustrates a flow diagram in FIG. 9.

In an alternative exemplary embodiment, the coordinate computer 83 can also contain a mask memory which can be addressed by the called coordinates and into which the desired brush surface is programmed. The mask information controls a gate for the called coordinates in such a way that only those in the

Coordinate values falling on the brush surface can be passed as auxiliary coordinates x 'and y'. This alternative embodiment is advantageously used with brush surfaces of any shape. (c) Determination of the retouching factors

First, the evaluation factors w for the pixels of the brush surface are determined. For this purpose, the auxiliary coordinates x 'and y * address an evaluation memory 87 via an address bus 86, into which the desired evaluation factors w of the brush surface according to the evaluation topic of FIGS. 5 and 6 have previously been entered via a programming input 88. The evaluation memory 87 has a capacity which corresponds at least to the number of pixels which are allotted to the largest brush surface.

The evaluation factors w are overwritten from the evaluation memory 87 via a data bus 89 into a process computer 90. The pixel coordinates x and y of the brush surface calculated in the adding stage 79 address a working memory 92 via an address bus 91 for the intermediate storage of the retouching factors. The retouching factors stored under the selected addresses of the working memory 92 are read into the process computer 90 via a data bus 93, changed according to the correction steps and evaluation factors and written back into the working memory 92. This process is repeated with each command "change of coordinates", which is reported to the process computer 90 by the comparison stage 72 via a line 94, all the evaluation factors of the brush surface being read out cyclically from the evaluation memory 87 and associated with the current positions of the brush surface Retouching factors in the working memory 92 to be changed accordingly. If the "change of coordinates" command, as described above, is given each time the center point coordinates are changed, the brush surfaces overlap when the coordinate pen 51 is moved. If there is no overlap, the "change of coordinates" command is delayed in comparison stage 77 until until the new center coordinates of the circular ones

Brush surface at least the distance R from the old ones.

Corresponding to the assumed 512 x 512 pixels of the color image to be retouched, the working memory 92 and the retouch memory 49 have a capacity of 512 x 512 x 8 bits, so that a retouch factor up to the value 255 can be stored per pixel (address).

In this way, a scheme of the current, local distribution of the desired retouching strength in the color image is created in the working memory 92 in the form of the stored retouching factors r, r in the image part to be retouched

0 and outside this part of the picture r = 0.

As already described, the retouching factors during the blanking interval of the image recording, by the command "blanking interval" on the

Line 10 signals, transferred to the retouching memory 49 by means of the process computer 90 via the data bus 55. Commercial usability

The invention is advantageously used in the entire field of electronic reproduction technology, in particular in the field of color image reproduction, by means of electronic color scanners and image processing systems for the production of retouched and corrected printing forms in the form of color separations or printing cylinders.

Claims

Subject of the invention

Claims

1. Method for partial electronic retouching in color image reproduction, in which the color signals of the individual color components obtained by pixel-by-point and trichromatic original scanning are digitized and stored as color values on a storage medium, in each of which a number of color values can be shifted within an image that can be retouched Correction area marked at the same time and for these color values assigned correction values that can be changed step by step are determined and in which the. marked color values are changed by the correction values under visual control in order to obtain the retouched color values, characterized in that the individual amounts by which the correction values (Y _R , M _R , C _R , K _R ) within the correction range (72) per Correction step can be changed, freely selectable.

2. The method according to claim 1, characterized in that for all correction values (Y _R , M _R , _CR , K _R ) of the correction area (72) the same amounts of change are specified, whereby a uniform retouching strength is achieved within the correction area.

3. The method according to claim 1, characterized in that for the correction values (Y _R , M _R , C _R , K _R ) From the center of the correction area (72) to the edge decreasing amounts of change are specified, whereby a gradual (running) retouching strength is achieved within the correction area.

4. The method according to claim 3, characterized in that the amounts of change are specified according to a selectable function, in particular according to a Gaussian function.

5. A method according to any one of claims 1-4, characterized in that the correction values (Y _R, M _R, C _R, K _R) to the image primarily associated color values (Y, M, C, K) is added (positive retouching) or be subtracted from them (negative retouching).

6. The method according to any one of claims 1-5, characterized in that a) color increments (ΔY, ΔM, ΔC, ΔK) are specified for the individual color components, which are the smallest amounts of change for the correction values (Y _R , M _R , C _R , K _R ), b) the pixel coordinate pairs (x, y) of the color values (Y, M, C, K) of the correction area (72) are determined, c) pro for each pixel coordinate pair (x, y) found Correction step a retouching factor determining the retouching strength

(r) is determined, which is the correction value (Y _R , M _R , C _R , K _R ) as the number of to be added

Indicates color increments, and d) pixel-related retouching factors

are multiplied to obtain the respective correction values (Y _R , M _R , C _R , K _R ).

7. The method according to any one of claims 1-6, characterized in that a) at least one pixel coordinate pair (X ₀ , Y ₀ ) of the correction area (72) by marking by means of a marking device of a coordinate detection device (50,51,52) , in particular by means of a coordinate pen (51), and b) the remaining pixel coordinate pairs (x, y) of the correction area (72) are calculated as a function of the marked pixel coordinate pair (X ₀ , y ₀ ).

8. The method according to claim 7, characterized in that by selecting the to be calculated

Pixel coordinate pairs (x, y) around the marked pixel coordinate pair (x ₀ , y ₀ ) shape and size of the correction area (72) can be determined.

9. The method according to any one of claims 1-8, characterized in that a) each point contact with the marking device (51) of the coordinate detection device (50, 51, 52) corresponds to a correction step, and b) each retouching factor (r ) for a pixel coordinate pair (x, y) of the correction area (72) from the number of point touches (n) and an evaluation factor (w) predefined for the respective pixel-coordinate pair which calculates the change amount of the relevant correction value (Y _R , M _R , C _R , K _R ) per point contact as a multiple of the color increments (ΔY, ΔM, ΔC, ΔK) indicates, the coordinate pen (51) being guided like a retouching brush over the part of the image to be retouched in order to shift the correction area (brush surface).

10. The method according to claim 9, characterized in that for all correction values (Y _R , M _R , C _R , K _R ) of the correction area (72) the same evaluation factors (w) are predetermined, whereby a uniform retouching strength is achieved within the correction area .

11. The method according to claim 9, characterized in that for the correction values (Y _R , M _R , C _R , K _R ) from the center of the correction area (72) to the edge decreasing evaluation factors (w) are specified, whereby a within the correction area gradual (ongoing) retouching is achieved.

12. The method according to any one of claims 1-11, characterized in that the digital color values (Y, M, C, K) are read out from the storage medium (1) by the correction values (Y _R , M _R , C _R , K _R ) changed and the corrected color values (Y ', M', C ', K') after retouching again stored on the storage medium (1) become .

13. The method according to any one of claims 1-12, characterized in that the unretouched or retouched

Color image (original) or an unretouched or retouched color separation for visual inspection on a monitor (2) is shown that a ver movable light mark (31) is shown in a screen (3), and that the movement of the light mark (31) with the Movement of the coordinate pin (51) of the coordinate detection device (50,51,52) is synchronized.

14. The method according to any one of claims 1-13, characterized in that the digital color values (Y, M, C, K) of the individual color separations from the storage medium (1) are loaded into a frame buffer (7), and that the frame buffer ( 7) is read out cyclically for point-by-point recording on the monitor (2).

15. The method according to any one of claims 1-14, characterized in that the determined retouching factors (r) are overwritten point by point in a retouching memory (49), and that the retouching memory (49) for the punctual assignment of color values (Y, M, C, K) and correction values (Y _R , M _R , C _R , K _R ) synchronously with the image repetition Memory (7) is read out.

16. The method according to claim 15, characterized in that the changed by the correction process

Retouching factors (r) are each overwritten in a blanking interval of the image recording in the retouching memory (49).

17. The method according to any one of claims 1-16, characterized in that the pixel coordinate pairs (x, y) of the marked points are stored in the order of their detection in a list, and that the pixel coordinate pairs (x, y) in reverse order called up and the corresponding retouching factors (r) in the retouching memory (49) are changed in order to undo the retouching which occurred when the points were previously touched with contours.

18. The method according to any one of claims 1-17, characterized in that the entire correction is canceled by deleting the retouching memory (49).

19. The method according to any one of claims 1-18, characterized in that the brush surface is indicated by a correspondingly enlarged light mark (31).

20. The method according to any one of claims 1-19, characterized in that the retouched rende Bildteil is limited by an electronically generated mask.

21. Arrangement for carrying out the method according to claim 1, consisting of a storage medium for the color values of the individual color separations, a downstream image repetition memory and a monitor connected to the image repetition memory for visual inspection, characterized by a color sensor (38) for forming the color increments (ΔY, ΔM, ΔC, ΔK), a retouching sensor (39) for forming the retouching factors (r) for the color values (Y, M, C, K) to be corrected, one with the color sensor (38) and the Retouching transmitter (39 *) connected correction value transmitter (40) to form the correction values (Y _R , M _R , C _R , K _R ), and by means of the image repetition memory (7) after switching logic levels (15, 16, 17, 18 ) in the color channels to change the color values through the correction values.

22. The arrangement according to claim 21, characterized in that the retouching sensor (39 *) from a coordinate detection device (50, 51, 52) for determining the pixel coordinates (x, y) of the color values to be corrected, from a evaluation circuit (48 *) connected to the coordinate detection device (50, 51, 52) for forming the retentive factors (r) for each pair of coordinates detected and from a retouching memory (49) connected to the evaluation circuit (48 *) consists. Reference numbers 80/545 - "ongoing retouching" 1 storage medium 2 color monitor 3 screen 4 Prezebrecnner

5 data bus

6 data bus

7 refresh memory

8 memory controller

9 address bus

10 line

11 data line

12 data line

13 data line

14 data line

15 adding stage 16 adding stage

17th level of adder

18 adding stage

19 correction circuit

20 data bus

21 light mark generator

22 D / A converter

23 Print simulation calculator

24 clock generator

25 line

26 line

27 line

28 line 29 line

30 line

31 light mark

32 coordinate control levers

33 address line

34 line

35 measured value memory

36 write input

37 input level

38 colourants

39 * Retouchers

40 correction value transmitter

41 line

42 Data bus

43 Data bus

44 data line

45. Data line 46 Data line 47 Data line

48 * evaluation circuit

49 retouching memory

50 digitizing tablet Reference numbers 80/545

Coordinate pin measuring stage address bus address bus line data bus data line data line data line data line line line line - - - line line data bus pixel brush area line coordinate system line auxiliary coordinate system comparison stage data bus addition stage line address counter data bus coordinate computer programming input data bus Address bus Evaluation memory Programming input Data bus. Process computer address bus memory data bus line