DE2445465A1 - Production of transparency copies - gradation controlled by raster device between original and copy - Google Patents

Abstract

A system for the production of coloured copies of transparencies in which a photographic copying machine forms the transparency on the copying material by means of colour filtration and finally develops the copying material in a copy material development device has the gradation of the copy controlled by means of a raster (GR) which is positioned in the copier light output pathway. Before exposure, the contrast range of the transparency is photoelectrically measured and the signal so produced used to control the raster operation.

Description

Method and apparatus for making colored copies of Slides The invention relates to a method and a device for production of colored copies of slides, being in a photographic copier the slide is mapped onto the copy material with color filtering and then the copier is developed in a material / developing machine.

Because of the development of the copy material in continuous processing machines the contrast of the copy may not be during the development process or by individual Material selection can be controlled. It is the same with color copies as opposed to black and white copies practically impossible to bend the gradation by pre-exposure.

The gradation of the material intended for copying slides is set so that a slide with a medium, not too large contrast range results in optimal copies. In many cases, however is the range of contrast of slides so large that he cannot cope with the usual types of copy material can be.

It is the object of the invention to provide a method for copying such To create "hard" transparencies on common copier material that can be used for variable purposes Adaptation of the copying gradation to the contrast range of the slide is suitable, that a good copy can be made even in problematic cases, the apparatus for performing this method being in conventional copier designs should be able to be integrated without great effort.

According to the invention this is achieved in that the gradation of Copies is controlled by means of a grid located in the copy beam path. The contrast range of the slide to be copied is advantageous before the exposure determined photoelectrically and entered by means of an electronic evaluation device The electrical signal proportional to the contrast range is obtained and with the signal by a servomotor the grid in the range between the single and the double autotypical distance from the copy material moved and optionally by means of a further The servomotor controlled by the electronic evaluation device refocuses the lens.

A glass engraving line grid, a glass engraving cross grid, a cylindrical lens grid or a spherical lens grid can be used.

In principle, a contact grid can also be used, which through the servomotor between the distance zero and a distance to the copy material is set, each grid point being spread over a grid cell will.

The proposed method of gradation control is very demanding little effort, is compatible with conventional woping devices and can be done without Automate difficulties.

Appropriate devices for carrying out the method according to the invention emerge from the further subclaims and the description in which based the invention is explained in more detail in the drawing. They show: FIG. 1 a basic illustration for changing the gradation by means of a glass engraving grid, FIG. 2 shows a basic illustration for changing the gradation using the lens grid 3 schematically a representation of a copier according to the invention, Fig. 3a schematically a Variant of a contrast measuring device proposed according to FIG. 3.

It is known from printing technology that by means of rasterized exposure an original on hard copy material achieves a balanced tonal value reproduction can be. Little is known, however, that even with the comparatively flat gradations of some color copy materials in this way the contrast range of the original is possible.

Be it. in this context it should be noted that doing so, of course there is no real rasterization in the reprotechnical sense because of the discrimination Mngsstep with conversion of continuous tonal values into exactly defined point sizes is missing.

Fig. 1 shows schematically an arrangement for changing the gradation by means of a glass engraving grid, which can be a line or a cross grid and Fig. 2 such an arrangement with a cylinder or spherical lens grid.

A light source (not shown) is thereby used. illuminated Slide D by means of an objective in an image plane B directly in front of the engraving grid GR or the lenticular grid LR shown.

Behind the grid GR or LR is the at a certain distance a Copy material KM arranged.

The glass engraving grid according to Fig. 1 consists of a grid with alternating opaque and translucent strips; Cross grids consist of the combination two such plates. The permeable spaces can be used as pinhole cameras be viewed, which is a multiple image of the diaphragm plane of the magnifying lens Cause 0 in the plane of the recording material.

For the autotypical distance a between the grid and the copy material For f-stops up to li: a = N (V + I) / 2R, where R is the screen frequency in lines per millimeter, N is the f-number and V is the magnification.

If the distance cLI is increased, the latching action is reduced and disappears at the amount of about 2a; one then receives again about the initial gradation.

In principle, there are further options for grading the grid effect the variations in the screen frequency or the duty cycle and variations the permeability of the grid lines. Furthermore, there is still double exposure in the repro technique With and without grid common, lens grids according to Fig. 2.

They are used in the same way as engraving grids, but are essential light stronger. Because of their small size, they provide something that is diffractive Image of the aperture, so that in general an effect like the glass engraved grid Fig. L arises. In practice, the resulting point profile is superimposed still a constant light component, that of imperfect, optically ineffective transitions originates between the lenticular lenses. The fact that it is analog and rasterized Blending exposure results in lenticular screens less than engraved screens cause pronounced effects. If you want to avoid this interfering light, the lenticular grid must be used can be combined with a precisely fitting aperture mask.

Commercially available lens grids are not always suitable for the one suggested here Purpose suitable. However, lens grids have proven to be very suitable that according to the teaching of DT-OS l 772 567 and at a spatial frequency of 10 L / mm for the and cylindrical lens grid of 7 L / mm for the spherical lens grid have a focal length of about 1.3 mm.

On the other hand, commercially available glass engraving grids are proposed for the Gradation control with a spatial frequency of about 5-10 L / mm and a duty cycle from 1: 1 to 1: 2 well suited.

Fi.g 3 shows schematically an arrangement for carrying out the invention Procedure with a roll copier.

In a copier with a lamp housing L and a lens 0 becomes a slide, which is in the picture stage, on the roll-shaped copy material KM pictured. The image B is in the immediate vicinity of the grid R, which through a servomotor M1 between the position R2a and the position shown in dashed lines R is movable.

a As explained above, the gradation flattening is in position Ra maximum; it is hardly present in position @ 2a.

A pivotable mirror S is provided in the beam path the slide D before exposure through an objective 0 'onto a matrix of photosensitive Elements M throws; which are used in a known manner for contrast measurement. Over a electronic device, the contrast is 28, i.e. the difference between the maximum transparency t max and the minimum transparency imin of the matrix M determined transparency distribution Q '(x, y). In the simplest case it will directly generates a signal that is proportional to the required displacement 2 a of the grid and controls the servomotor M 1 directly. In general, however, the control is required according to a specified characteristic, which is via a mechanical control cam or via a permanently programmed small computer, either analog-electronic or can be done digitally via a stepper motor.

This control device, which regulates the displacement a a, can also if necessary, the lens O by means of a second servomotor M2 around the paths refocus. Because of the exposure time control in the lens O under certain circumstances built-in shutter V a shift of the entire lens problematic can be, the minimum adjustment can be of the objective O - so far it is necessary at all - by adjusting a link of the objective O take place.

FIG. 3a shows a variant of the contrast measuring device according to FIG. 3. The matrix M is arranged in a station separate from the exposure. Since slides are generally not as strips, but individually in the copier are entered, the separate arrangement presents no problem.

The invention is not limited to the described embodiment of the Copier limited. For example, the grid R could remain stationary and the copy carrier KM can be adjusted by the motor by the amount yes or the contrast brass in another known way, e.g. by means of a NipRow disk or a cathode ray tube take place.

Claims (11)

Expectations Process for the production of colored copies of transparencies, whereby in a photographic copier the slide with color filtering on the Imaged copy material and then the copy material in a developing machine is developed, characterized in that by means of one in the copying beam path located raster (GR, LR) the gradation of the copy is controlled. 2. The method according to claim l, characterized in that before the Exposure of the contrast range of the slide to be copied (D) photoelectrically is determined and by means of an electronic evaluation device one of the contrast range dependent electrical signal obtained and with the signal by a servomotor (M1) the grid in the area between the single (a) and double (2a) automatic Distance from the copy material (KM) is moved. 3. The method according to claim l, characterized in that before the Exposure of the contrast range of the slide to be copied (D) photoelectrically is determined and by means of an electronic evaluation device one of the contrast range dependent electrical signal obtained and with the signal by a servomotor (M1) a contact grid in the area between zero and the distance from the copy material (KtI) is moved, in which each grid point is just scattered over a grid cell will. 4. The method according to claim 2 or 3, characterized in that means another servomotor controlled by the electronic evaluation device (M) the lens (0) is refocused 2. 5. The method according to any one of claims 1 or 2, characterized in that that a glass engraving line grid is used as the grid. 6. The method according to any one of claims l or 2, characterized in that that a glass engraved cross grid is used as the grid (GR). 7. The method according to any one of claims 1 or 2, characterized in that that a cylindrical lens grid is used as the grid (R). 8. The method according to any one of claims 1 or 2, characterized in that that a spherical lens grid is used as the grid (LR). 9. Photographic copier for making colored copies of transparencies, characterized in that in the beam path for gradation control one along the optical axis in the range between single (a) and double (2a) autotypical distance from the copy material (KM) adjustable grid (LR, GR) is provided. 10. A photographic copier according to claim 8, characterized in that that for photographic contrast measurement of the slide (D) with a measuring station a matrix (M) of photosensitive elements, an electronic device to determine the maximum image contrast and to obtain one proportional to it electrical signal and that to control the distance of the grid (GR, LR) from Kopiermatieral (KM) an electromotive which can be actuated by the electronic device Adjusting device (Ml) is provided. 11. Photographic copier according to claim 9, characterized in that that for refocusing the image (B) a controllable by the electronic device Servomotor (M2) is provided for adjusting the lens (O). Blank page