CH683568A5 - Method of masking photographic records. - Google Patents

Description

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description

The invention is based on a method for masking photographic recordings according to the preamble of claims 1 to 3.

In the case of photographic recordings which contain large differences in brightness in individual areas, the copies made are often overexposed in the bright areas or underexposed in the darker areas. As a result, details or finer structures on the paper image are reproduced very poorly or not at all.

DE-OS 3 141 263 describes a method for copying color slides onto reverse paper using masks for reducing contrast. The slide is brought into direct contact with a phototropic glass and this glass through the slide with a UV lamp or the like. exposed. A black and white negative mask of the original artwork is created in the phototropic glass. In the same position, the combination of mask and slide is illuminated from the other direction and the original image is thus depicted on the reverse paper with less contrast. In this method, the mask glass is in direct contact with the slide, creating a sharp mask, which is then sharply imaged on the reverse paper. In order to obtain high quality copies, it must be ensured that the mask and the original are practically 100% identical when exposed. However, this is already ruled out by the different materials - film material and glass. With the very intense exposure, the materials heat up relatively strongly and expand differently. Inferior prints are then created, in which the light-dark jumps in the mask, which do not exactly match the healing-dark jumps of the original, are clearly recognizable. If the method, as described in the application, is to be used in a large laboratory with an automatically working copier, additional difficulties result from rapid, jerky movements to which the combination of mask glass and original document between the individual stations is exposed. Here again shifts can occur, which then have an even greater impact on the quality of the prints.

It is therefore the object of the invention to find a method for masking photographic recordings in which these slight relative displacements or different expansions are not noticeable in the quality of the prints.

The object is achieved by methods having the characterizing features of claims 1 to 3. As a result, in all three cases, an unsharp image of the mask is obtained on the light-sensitive paper. The blurring moves in an area that the sharp image of a line of the original original is in any case in the area of the blurred image of the line of the mask. The blurring of the mask image on the paper depends on the respective magnification scale. If you assume, for example, 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 should be approximately at the upper limit and at a template size of 0.8 x 1.1 cm Original size of 20 x 25 cm are approximately at the lower limit of the specified range.

There are a number of ways to create a mask. For example, the mask can be created intangibly and stored pixel by pixel in an electronic data memory. The paper is then exposed point by point using a cathode ray tube or a laser. There is also the possibility that the original template was previously read into a data memory and the data of the template are offset against the data of the mask. The exposure then takes place directly on the paper without the original. However, it is also possible to expose through the original and to additionally use the mask data when calculating the exposure data. With both methods, not only a reduction in contrast, but also an increase in contrast is possible. Masks created intangible, which only exist as a data record, have the further advantage that these data records can still be edited as desired. For example, dark areas on the mask can be reduced somewhat so that these light / dark transitions are definitely within the dark areas of the print and are therefore more difficult to see. This can further increase the quality of the prints.

To create material masks, phototropic glasses or foils, but also glasses with a phototropic coating, can be used. The paper is then exposed through the mask and the transparent original.

An electronically controllable mask matrix forms an intermediate stage between purely immaterial and material masks. This offers the advantage that the mask can be changed later, since it basically exists as a data record. On the other hand, as with material masks, the exposure can be carried out in a conventional manner. Spot exposure is not necessary. Examples of a transparent mask matrix are liquid crystal displays and electronically controllable light valve arrangements. However, reflective, electro-optical components are already on the market, the reflectivity of which can be changed in certain areas.

It is advantageous to design the mask in such a way that there is practically no darkening effect from its brightest point, so that no significantly higher luminosities or longer exposure times are necessary even when masking. A transmitted light mask should achieve its maximum transparency at this point.

The method according to the invention can also advantageously be used in large laboratories on printers

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use with automatic exposure control. For the exposure control, the density values of the already masked original must be used (harmonized densities). In a preferred variant of the method, this can be achieved purely by calculation. The original template is measured using a scanner and the individual density values are saved. The mask can be calculated from these values using special algorithms. The amount of copy light is now calculated from both values, namely the density values of the original template and the density values of the mask.

In addition to the purely mathematical way of calculating the amount of copying light, a second way can also be followed. After the original template has been scanned, a mask is created and the original template is then scanned again using the mask. The density values measured in this way in turn provide the basis for calculating the amount of copying light.

A fully automatic copying process can be implemented with both of the options shown. A decision logic can be used, for example, to determine on the basis of the contrast range whether a mask is to be created and how the mask should be made. Using a process designed in this way, high-quality images can be generated fully automatically.

In order to make the process suitable for the far more demanding field of professional photography, it is necessary to create an option for manual manipulation by an operator. The image of the original template and the already masked image are each advantageously displayed on a color or black and white monitor. This can be done on a single monitor, but also on two separate monitors. The operator can immediately check the effect of a correction of the degree of masking on the monitor with the masked image display. A correction of the density values and the color values sampled from the original is visible on both monitors.

Further details and advantages of the method according to the invention result from the dependent claims in connection with the description of device examples, which are explained in detail with reference to the drawing.

Show it:

1 shows a device for carrying out the method according to the invention with purely arithmetic exposure control,

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

Fig. 3 shows a device for professional photography.

In Fig. 1, a negative film 1 is passed through a scanning station 2. Here, each individual image is scanned point by point via the light source 3, the lens 4 and the slit diaphragm 5. The light beam passing through the film is transmitted through the lens 6

bundled again and broken down into its color components by dichroic mirrors 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. Resulting density values are now 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 rejection» of the printer can be reduced compared to unmasked copying. Since the density logic normally calculates the copy density on the basis of the large area contrast, errors can easily occur when taking pictures with a very high contrast. Since the large area densities are practically compressed when using the resulting density values, the calculated copy densities can be approximated better to the target copy densities. The shutter speed can then be calculated from the copy density in step 13. 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 will not be described further here. The copied light, corrected in terms of 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 values 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 on the scatter plate 24 via the lens arrangement 23. The image of the mask and the individual image of the film 1 are then precisely copied onto the photosensitive paper 26 via the lens arrangement 25.

In Fig. 2 parts of the same function are given the same reference numerals. Film 1 is supported here by a combined scanning and copying station. Light passes from the light source 18 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 on the mirror 28 on a

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ner black and white surface CCD 29 of the video camera 30 imaged out of focus with the aid of optical means. A mask is generated with the aid of the CCD output signals, 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 primary 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 swiveled out of the copying beam path. The shutter speed also results from the copy density in a manner not shown. 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 is illuminated through the initially transparent mask matrix 20 and imaged on the color surface CCD 32 of the video camera 33 via the swivel mirror 27. 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 converter 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. A masked positive color image is now generated in memory 40 from the mask in memory 10 and the positive color image in memory 36. 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 the 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 masked image on the monitor 41 due to machine specifications. A color correction on the three control buttons 44 has an immediate effect on the light mixing device 19 and is therefore immediately visible on both monitors. A correction of the unsharp mask with the help 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 sees the monitor image 41 optimally, the exposure process can be triggered. For this purpose, the mask matrix 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 together onto the paper 26 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 comparison for the operator, however, it has proven to be advantageous if the masked image can be compared with the unmasked image.

Claims (1)

Claims 1. Method 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) Copying the original artwork onto photosensitive material using an 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 black and white negative mask of the original, c) Copy 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. Method 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 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. 4. The method according to any one of claims 1 to 3, characterized in that the mask is created electronically in a data memory and the light-sensitive material is exposed point by point, in particular by means of a cathode ray tube or by means of a laser. 5. The method according to claim 4, characterized in that the mask created in the data memory is processed so that areas of the mask with a certain brightness are imaged on a smaller scale on the light-sensitive material. 6. The method according to claim 4, characterized in that the copying onto light-sensitive material is carried out through a transparent original. 7. The method according to any one of claims 1 to 3, characterized in that the mask is made with phototropic material, in particular glasses or foils, and the copying onto light-sensitive material is carried out through a transparent original and the mask. 8. The method according to any one of claims 1 to 3, 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 4th 7 CH 683 568 A5 8th characterized in that the mask is created with an electro-optical component or other controllable light valve arrangements, in particular a liquid crystal display or a plasma display, and the copying onto light-sensitive material takes place through a transparent original. 9. The method according to any one of claims 1 to 3, characterized in that the mask is generated on a reflective part. 10. The method according to any one of claims 1 to 3, characterized in that when copying onto light-sensitive material from the brightest point of the mask only the material-related inevitable light-weakening effect. 11. The method according to any one of claims 1 to 10, characterized in that density values of the masked original document are used in a printer working with automatic exposure control to create paper images of negative or positive films for the calculation of the amounts of copied light. 12. The method according to claim 11, characterized in that on the basis of the density values scanned from the original template, the density of a mask is calculated and thus a mask is generated and the amount of copying light is calculated from the density scanned from the original template and the density calculated for the mask. 13. The method according to claim 11, characterized in that, based on the density scanned by the original, the density of a mask is calculated and thus a mask is generated and the amount of copying light is determined by a second scan of the original using the mask. 14. The method according to claim 12 or 13, characterized in that, based on the density sampled from the original, a decision is made automatically as to whether and to what extent the photographic recording is masked. 15. The method according to claim 14, characterized in that the image result is represented on the basis of the density sampled from the original template and a possible color correction with and without use of the mask in each case as a color or black and white monitor image and the image result is checked by an operator and can be influenced. 16. The method according to claim 15, characterized in that the monitor image is influenced by the correction of the degree of masking with the representation of the image result using the mask. 17. The method according to claim 15, characterized in that the density and color values of both monitor images are influenced by a correction of the image signals derived from the original. 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 primary 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) It is provided in which the density values of the mask to be created and the shutter time of the confection control are calculated and that the shutter (22) of a light source (18) and an electrically controllable mask matrix are used with the output signals in the subsequently arranged copying station (16) (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) a pivotable or partially permeable arrangement (27, 28, 29, 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 or 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) is provided to display the calculated masked image. 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 5