DE4040498A1 - Commercial masking for dodging when printing photographic negative or diapositive - scanning original and producing black=and=white negative mask of appropriate resolution to cover sensitivity grade of photographic paper used - Google Patents

Abstract

The resolution of the negative mask produced lies between 0.1 and 2 sets of lines per mm. The original is printed with the mask to cover the full range of the photographic paper. Each frame of a negative film strip (1) is secured at a first stage (2) pointwise by a light source (3), lens (4) and slit shutter (5). The light emerging from the film is collimated again by another lens (6) and separated into its colour components through a dichroitic mirror (7). Correspondingly sensitised measuring cells (R, G, B) register the basic prim. colour densities for storing in an image memory (8) with a resolution of approx. 500 to 1,000 pixels. An appropriate mask for the frame is generated in a selection logic (9). The density value for the mask is stored in another image memory (10). The resultant exposure density is calculated from both stored values and stored in a further image memory (11). AVANTAGE - Since mask covers whole area, dodged areas not detectable on final print. Quality of latter is not affected by sliding motion arising from continuous photo-finishing process as customary in commercial automatic machines.

Description

The invention relates to a method for masking photographic records according to the generic term of Claim 1.

For photographs taken in individual areas which contain large differences in brightness often the copies made in the light areas overexposed or in the darker areas un exposed. This will make details or finer Structures on the paper picture very bad or even no longer clearly shown.

In DE-OS 31 41 263 is a method for copying using color slides on reverse paper  described by masks for reducing contrast. The The slide is in direct contact with a phototro brought glass and this glass through the slide exposed with a UV lamp or similar. In the photo tropical glass, a black and white negative Mask of the original artwork. In the same position the combination of mask and slide is then made illuminated in the other direction and thereby the origi original with less contrast on the reverse paper pictured. In this process, the di direct contact of the mask glass with the slide in like a sharp mask, which then also sharp on the Reverse paper is shown. To get high quality copies lity must be ensured that mask and original artwork with exposure practically 100% are congruent. However, this is already through the different materials - film material and Glass - excluded. With the very intensive Be materials heat up proportionally strong and expand differently. Stand there then inferior prints where the chiaroscuro jumps in the mask that are not exactly with the Cover light-dark jumps of the original artwork, clear are recognizable. Should the procedure, as in the registration described in a large laboratory at an automa table-top copier, he says cause additional difficulties due to fast, jerky movements, which the composite of masked glass and original artwork between the individual stations is exposed. Shifts can be made here occur, which then become even stronger in quality of the deductions.

It is therefore the object of the invention to provide a method for masking photographic recordings the one with these slight relative shifts or various extensions in the quality of the Ab trains not noticeable.

The task is solved by the characteristic note paint one of claims 1 to 3. As a result you get a blurred image of the mask in all three cases on the photosensitive paper. The blur moves in an area that the sharp image of a Line of the original template in the area of the blurred image of the line of the mask is located. The Un The sharpness of the mask image on the paper is off depending on the respective magnification. You go for example from a commercially available 35mm film and an experimentally proven mask resolution of 0.7 line pairs / mm, the resolution of the Mask image in the negative plane with a template form mat of 0.8.1.1 cm approximately at the upper limit and at a template size of 20 x 25 cm approximately at the bottom limit of the specified range.

There are a number of ways to create a mask Possibilities. For example, the mask create intangible and pixel by pixel in an electro Store African data storage. The exposure of the Pa piers is then carried out point by point with the aid of a cathode beam tube or a laser. Here there is also the possibility that the original template in a data memory has been read in and the data of the Template with the data of the mask. The  Exposure then takes place without the template directly on the Paper. However, it is also possible through the Origi to expose the original and during the calculation of the exposure data, in addition to verifying the mask data turn. With both methods there is not only one con Trast reduction, but also a contrast increase possible. Intangible masks that only exist as a data set, continue to have the advantage on that these data records can still be edited as desired to let. For example, dark areas can be created on the mask a little, so that this light / dun kel transitions in any case within the dark Be areas of the deduction lie and are therefore more difficult to see are. This still allows the quality of the prints increase.

To create material masks, you can also phototropic glasses or foils, but also glasses with use phototropic coating. The exposure of the Paper then passes through the mask and the transpa pension original template through.

An intermediate stage between purely immaterial and ma serial masks forms an electronically controllable Mask matrix. Here is the advantage of the weary changeability of the mask since it is basically taken as a record exists. On the other hand, can but, as with material masks, the exposure in be carried out conventionally. A point wise exposure is not necessary. As examples of a transparent mask matrix are Liquid Cristal Displays and electronically controlled light valve  To name orders. Likewise, however, are already reflective ing, electro-optical components on the market, de Ren reflectivity can be changed in some areas can.

This means that even when masking, no significantly higher ones Luminosity or longer exposure times necessary it is advantageous to design the mask so that practically no darkening from its brightest point effect. A transmitted light mask should be on achieve maximum transparency at this point.

The inventive method can be advantageous ter also in large laboratories on printers with automa table exposure control. For the exposure control must use the density values the already masked original can be used (harmonized densities). In a preferred variant of the method, this can be done in purely arithmetical terms sieren. The original artwork is scanned ners measured and the individual density values are saved. From these values, according to spec algorithms calculate the mask. The copy light quantity is now made up of both values, namely the density values of the original and the density values of the Mask, calculated.

In addition to the purely arithmetic way to cash the Ko However, a second way can also be used stride. After scanning the original template created a mask and then the original template scanned again using the mask. The so  measured density values in turn give the basis to calculate the amount of copy light.

With both possibilities shown one can Realize fully automatic copying. With Hil For example, a decision logic can be used determine whether a mask based on the contrast range created and how the mask should be made. According to a method designed in this way, Generate high quality images fully automatically.

To the procedure for the far more demanding Field of professional photography suitable for ma Chen, it is necessary to have another way to measure influence by an operator create. Advantageously, the picture the original template and the already masked image each because Darge on a color or black and white monitor poses. This can be done on a single monitor, however happen on two separate monitors. The effect a correction of the degree of masking can be carried out the operator immediately on the monitor with the mas Check the displayed image. A correction of the density values sampled from the original template and the color values are visible on both monitors.

Further details and advantages of the invention Procedures result from the subclaims in Zu related to the description of the device play that explained in detail using the drawing will.

Show it:

Fig. 1 shows a device for carrying out the method to the invention it with purely computational exposure control,

Fig. 2 shows a device in which the exposure is controlled by measurement, and

Fig. 3 shows a device for the field of professional photography.

In Fig. 1, a negative film 1 is guided by a scan station 2 . Here, each individual image is scanned point by point via the light source 3 , the lens 4 and the slit blades 5 . The light beam passing through the film is again bundled by the lens 6 and zer zer into its color components by dichroic mirror 7 . The individual beams then strike correspondingly sensitized measuring cell rows R, G, B. The negative densities in the three primary colors are then stored in the image memory 8 with a resolution of approximately 500-1000 pixels. A mask suitable for the single image is then generated in the selection logic 9 . The density values of the mask are stored in the image memory 10 . The resulting density values are then calculated from the density values of the mask in the image memory 10 and the density values of the negative original in the image memory 8 and stored in the image memory 11 . In the density logic 12 , the copying density is calculated from the resulting density values in the memory 11 . In individual cases, it may also be useful to consult the density values of the negative from memory 8 . The calculation of the copy density on the basis of the resulting density values has the additional advantage that the "density scrap" of the printer can be reduced compared to unmasked copying. Since the density logic normally calculates the copy density due to the large area contrast, errors can easily occur when taking pictures with a very high contrast. Since when using the resulting density values, the large area densities are practically compressed, the calculated copy densities can be approximated better to the target copy densities. The shutter speed can then be calculated in step 13 from the copy density. The shutter speed and mask density values from the image memory 10 are then stored in the shift register 14 .

After the scanning station 2 , the film 1 is conveyed through the intermediate storage 15 into the copying station 16 . The corresponding values can now be called up from the shift register for each individual image passing through the copying station. A light source 18 is arranged above a condenser arrangement 17 with a color filter arrangement 19 , the function and control of which is not described further here. The copy light corrected in its color densities strikes the LCD matrix 20 located below the condenser arrangement 17 . This matrix is controlled with the aid of the values for the mask density taken from the shift register 14 , which are converted into control values in the converter 21 . The shutter 22 also receives its information about the opening time from the shift register 14 . The mask is imaged over the lens arrangement 23 on the diffusion plate 24 . About the lens assembly 25 , the image of the mask and the single image of the film 1 is then copied onto the photosensitive paper 26 .

In Fig. 2 parts of the same function are provided with the same reference numerals. Film 1 is supported here by a combined scanning and copying station. From the light source 18 , light passes through the condenser 17 , the mask matrix 20 and the lens arrangement 23 onto the diffusion plate 24 . The mirror 27 is pivoted out of the beam path in a manner not shown. The negative on the film 1 is therefore imaged out of focus by means of the mirror 28 on a black and white surface CCD 29 of the video camera 30 with the aid of optical means. With the aid of the CCD output signals, a mask is generated, converted into LCD control signals and stored in the memory 31 . The LCD matrix 20 is controlled with these values. Now the mirror 27 is pivoted into the beam path and the already masked image of the negative on the film 1 is imaged on the color area CCD 32 . In the density logic 12 connected to it, the resulting density values in the three basic colors are already available for calculating the copying density. The light mixing arrangement 19 can now be controlled with the aid of these values. The mirror arrangement 27 , 28 can serve as a closure. For this purpose, both mirrors are swung out of the beam path. The shutter speed also results in a manner not shown from the Ko pier density. The negative is now copied onto the paper 26 together with the mask via the lens arrangement 25 .

In Fig. 3, the negative on the film 1 through the initially transparent mask matrix 20 is illuminated and imaged on the swivel mirror 27 onto the color surface CCD 32 of the video camera 33 . The negative color image is stored in the image memory 34 . The image is reversed via the converter 35 and stored in the memory 36 as a positive color image. The color image is displayed on the monitor 37 . The negative color image from the memory 34 is simultaneously converted into a black and white image in the wall 38 and stored in the memory 39 . A negative black and white mask is calculated via the selection logic 9 and stored in the memory 10 . From the mask in memory 10 and the positive color image in memory 36 , a masked positive color image is now generated in memory 40 . This image is put on the monitor 41 . In converter 42 , a positive black and white mask is generated from the negative black and white mask from memory 10 and stored in memory 43 . In converter 21 , these values are in turn converted into control signals for the LCD matrix. An operator can now directly compare the unmasked original image on the monitor 37 and the image masked on the basis of mechanical specifications on the monitor 41 . A color correction on the three control buttons fen 44 immediately affects the Lichtmischvorrich device 19 and is therefore immediately visible on both monitors. A correction of the unsharp mask with the aid of the operating button 45 has an effect on the mask gradation in the selection logic 9 and is therefore immediately visible on the monitor 41 . A correction of the density via the control button 46 on the monitor 41 has an effect on the opening time of the closure 22 via the copy density calculation, not shown. If the operator appears the monitor image 41 optimally, the exposure process can be triggered. For this purpose, the mask mask 20 is first activated, the mirror 27 is pivoted out of the beam path and the shutter 22 is opened. The negative of the film 1 and the mask are copied to the paper 26 together via the lens arrangement 25 .

It is of course also possible to display only the masked positive image on the monitor 41 . In order to facilitate an optimal adjustment for the operator, however, it has proven to be advantageous if the masked image can be compared with the unmasked image.

Claims (20)

1. Process for masking photographic recordings, characterized by the combination of the following features:

• a) scanning the original,
• b) creating a black and white negative mask of the original template with a resolution between 0.1 and 2 line pairs per millimeter,
• c) Copy the original artwork onto the photosensitive material using a sharp image of the mask on the photosensitive material.

2. Method for masking photographic recordings, characterized by the combination of the following features:

• a) scanning the original,
• b) creating a sharp black and white negative mask of the original artwork,
• c) Copying the original template onto light-sensitive material using an image of the mask on the light-sensitive material with a resolution in the negative plane between 0.1 and 2 line pairs per mm.

3. Process for masking photographic recordings, characterized by the combination of the following features:

• a) scanning the original,
• b) creating a black and white negative mask of the original template with a resolution between 0.1 and 2 line pairs per mm,
• c) Copy onto photosensitive material using an image of the mask on the photosensitive material with a resolution in the negative plane between 0.1 and 2 lines pairs per mm.

4. The method according to any one of claims 1 to 3, because characterized in that the mask is electro niche created in a data store and that light-sensitive material point by point, esp special using a cathode ray tube or is exposed by means of a laser. 5. The method according to claim 4, characterized in net that the mask created in the data storage is processed so that areas of the mask with a certain brightness in reduced Scale on the photosensitive material be formed. 6. The method according to claim 4, characterized in net that copying on photosensitive  Material through a transparent original template ge through. 7. The method according to any one of claims 1 to 3, because characterized in that the mask with photo tropical material, especially glasses or fo lien is created and copied on light sensitive material through a transparent Original artwork and the mask is done through. 8. The method according to any one of claims 1 to 3, because characterized in that the mask with a electro-optical component or other control erbaren light valve arrangements, in particular a liquid crystal display or a plas ma-display is created and copied on photosensitive material through a trans Parente original template through. 9. The method according to any one of claims 1 to 3, because characterized in that the mask on a reflective part is generated. 10. The method according to any one of claims 1 to 3, because characterized in that when copying on photosensitive material of the brightest Place the mask only due to the material avoidable light-weakening effect. 11. The method according to one or more of the claims che 1 to 10, characterized in that in one with automatic exposure control  working printer for creating paper pictures of negative or positive films for the Calculation of copying light quantities density values who used the masked original the. 12. The method according to claim 11, characterized records that due to the of the original location sampled density values the density of a Calculates the mask and thus creates a mask and the amount of copy light from that of the Original template scanned density and for the mask calculated density is calculated. 13. The method according to claim 11, characterized records that due to the of the original the density of a mask calculated and thus a mask is generated and the amount of copy light by a second scan Original artwork using the Mask is determined. 14. The method according to claim 12 or 13, characterized ge indicates that because of the Origi automatically scanned density it is decided whether and to what extent the fo graphic recording is masked. 15. The method according to claim 14, characterized records that the image result due to the the original sample scanned density and a possible color correction with and without  Use the mask as a color or Black and white monitor image is shown and the image result from an operator can be checked and influenced. 16. The method according to claim 15, characterized records that by correcting the maskie the monitor image with the display the image result using the mask being affected. 17. The method according to claim 15, characterized records that by correcting the of the Original artwork derived the image signals Density and color values of both monitor images be influenced. 18. Device for carrying out the method according to claim 12, characterized in that a measuring station ( 2 ) for determining the density values in the three basic colors is arranged in a copying machine in the film running direction in front of the copying station ( 16 ), that a data processing unit ( 8- 13 ) is provided, in which the density values of the mask to be created and the shutter speed of the exposure control are calculated and that with the output signals in the subsequently arranged copying station ( 16 ) the shutter ( 22 ) of a light source ( 18 ) and an electrically controllable mask matrix ( 20 ) can be controlled. 19. The apparatus for performing the method according to claim 13, characterized in that in a copying machine in the copying beam path between the light source ( 18 ) and film ( 1 ) an electrically controllable mask matrix ( 20 ) and between film ( 1 ) and light-sensitive paper ( 26 ) one pivotable or partially permeable arrangement ( 27, 28, 29 and 30 ) is provided for determining the density values and that a logic circuit ( 31 ) calculates the density of the mask from the density values and controls the mask matrix ( 20 ) accordingly. 20. The apparatus of claim 18 and 19, characterized in that a color video camera ( 32, 33 ) for scanning the unmasked image, a first color monitor ( 37 ) for displaying the unmasked image and a second color monitor ( 41 ) for display of the calculated masked image is provided.