DE1772568C3 - Methods and devices for producing carrier frequency modulated images - Google Patents

Description

7. Device for carrying out the process 45 According to the invention, this is achieved in that driving according to claim 1, characterized in that the image is represented by lying in the plane of the lens net that the filter pieces are arranged like a mosaic in such a way that color filters of different strip widths or wings are arranged are that in a star-shaped, angular position on a lenticular grid, which is the light for in each case a color-permeable strip (17, sensitive layer is placed in front of it) takes place.

18, 19), with the center field of the star 5 ° The area covered by the colored stripes must be very high for both types of lenticular raster. For this show is permeable. intended use are therefore suitable in addition to the

8. The device according to claim 7, characterized in that for known lenses embossed on plastics, that the color stripes (17, 18) of a 55 raster grid, which by exposure of an entersten and a second color mutually perpendicular sinoid stripe pattern on one

ί are right and the strip (19) in the third suitable substrate with the following

{ Color is twisted by 45 ° to these and around developing and re-halogenization or tanning

Factor Vl is wider. Development. Such grids show

ί 9. The device according to claim 7 or 8, da- 6 ° on the one hand an external molulation, but above all

! characterized in that the filter is characterized by a periodic change in the refractive index, the

Grid of spherical spheres arranged in a square form the effect of a cylindrical lens with

• j lenses (16) imaged on the substrate can result in a suitable intensity of the exposure.

will. The Lin-

10. Process for producing carrier frequency 65 sensor grid recordings can be removed after removing the

Develop modulated images on a black and white, light lenticular screen in a conventional manner

sensitive layer, characterized, and z. B. copy in the contact method without

that a noticeable loss of image quality occurs during recording with every image.

To reproduce such images, the recordings are made with a point-like light source as possible transilluminated, which is imaged by a condenser on an intermediate screen. One arranges If the layer support is immediately behind the condenser, there will be strong ones in the 31-end plane Diffraction orders occur that are filtered out at will or used to build the image can be.

Further details and advantages of the subject of the registration emerge from the subclaims in connection with the description of exemplary embodiments which are based on figures are explained in detail. It shows

F i g. 1 is a schematic diagram of an arrangement for color recording by means of different grid constants,

F i g. 2 the transparency of the color filters used in the method according to FIG. 1,

F i g. 3 shows an arrangement for color recording by means of elements arranged at different azimuth angles Filter strips,

F i g. 4 shows the arrangement of the filter strips in the diaphragm plane according to FIG. 3 and

F i g. 5 and 6 arrangements for reproduction according to FIG. 1 and 3 generated records.

In Fig. 1, 1 α and 1 b denotes an objective formed by two lenses, which creates a real image of an object, not shown, located above the lenses 1 on a layer carrier 2. The layer carrier 2 is a black and white film with a very high resolution or a very good modulation transfer function (MTF). In direct contact with the layer carrier 2 there is arranged a grid 3 formed by cylindrical lenses, the refractive power of which is designed so that it images color filter strips 4 arranged between the lenses 1 a, 1 b sharply onto the layer carrier 2. In the present example, the lens grid has 60 lenses per mm, that is to say a very fine grid that is directly reflected in the image quality.

In the plane between the two lenses 1 a, 1 b, the diaphragm plane of the objective, the filter strips 4 running parallel to the lens grid 3 are now arranged. On both sides of the plane of symmetry there is a strip 4 u for all three colors. This is followed by two very narrow Gelbfilierstreifen 4 b, which according to FIG. 2 in this region completely absorb blue. This is followed by red filter strips 4c on both sides. Since the yellow filter and the central area also allow red to pass unhindered, a continuous red stripe is imaged symmetrically to the axis of the cylinder lens by the cylinder lens 3 a, which is shown in the red extract 5. The two red filter stripes are followed by two blue filter stripes 4 t /, outer Width is such that the blue stripe adjoining the red stripe is only V ₃ the width of the red stripe. This is evident from the blue abstract 6. Finally, there are green filter strips 4e on both sides, the transmission of which is shown in FIG. 2 0.5 amounts. This transmission was chosen because, in the conditions shown, the green stripe imaged by the designated cylinder lens 3 <j is superimposed by a stripe of the same width from the adjacent lens 3 1> . Together, the two pictures result in a sufficient green intensity.

The same effect could also be achieved if the imaging geometry ensured that that each of the cylinder lenses only image a strip of half the width, but the full intensity would that these stripes butt against each other without gaps. In both cases there is a course of the Green excerpt, as indicated by the line 7 in FIG. 1 is shown.

When the film is exposed, the color grids are now given the brightness values of the film to be recorded

ίο item superimposed in the relevant colors, so that the stripe pattern of the grids is modulated accordingly.

After the exposure, the lens grid 3 can now be separated from the layer carrier 2. the Support 2 is then developed in a conventional manner so that a black and white image is formed on the Layer support shows. On the substrate there are now three superimposed in the same direction Stripe grid visible.

The reproduction of the three color information items with the associated color values can now be carried out in the already proposed Way (see DT-OS 16 22 865) as follows. In Fig. 5 with 8 is one possible denotes a small light source which is imaged onto an intermediate diaphragm 10 by a condenser 9 will. Immediately behind the condenser 9, the developed layer support 11 is arranged, which has a Objective 12 arranged as close as possible to diaphragm plane 10 is mapped onto a screen 13 will. In the diaphragm plane 10, the image of the lamp through the capacitor 9 is now in a corresponding manner Location designed. Outside the location of the direct image, which is also referred to as the zeroth diffraction order can only arise. depending on the fineness and direction of the grating during exposure different points of the diaphragm plane 10 light concentrations, the so-called higher diffraction orders. In the case of a strictly sinusoidal grid occurs only the first order of diffraction occurs, with harmonious gratings with higher orders also occur Higher order diffractions on. The radial deviation of the diffraction from the optical Axis through the fineness of the grating, the angular position of the diffraction brightness from the azimuthal position of the grid. By choosing the lattice constant and its angle, it can be determined where the corresponding order occurs in the diaphragm plane. One speaks therefore of a spatial frequency spectrum, wherein the grating in each case as a carrier frequency, the transmission of the image information causes.

If the diaphragm 10 now has the zeroth diffraction order, d. H. the direct imaging of the light source 8 in the plane 10, faded out and become the higher ones through corresponding openings in the diaphragm 10 Diffraction orders thrown through the lens 12 onto the screen 13, an image of the is created there on the layer support 11 imaged object, which, however, is only transmitted by diffraction phenomena will. Since the angle of deflection is now determined by the grid constant of the grid assigned to the individual colors from the optical axis or the radius of the center deviation is determined. Kt the position of the light concentration of each color and each diffraction order in the intermediate image plane, i.e. H. the Aperture level (also called "spatial frequency selection level"), fixed. It can now be done by arranging Color filters of the corresponding color at these points

len ensure that only the light associated with the relevant color separation enters the lens 12 and thus can reach the screen 13. A builds up on the screen 13 the composite image on the color separations.

Another arrangement of the grids consists in not designing the constants of the grids differently, but the azimuthal position of the grids. Such an arrangement is shown in FIGS. 3 and 4. In the case of a star-shaped arrangement of the strips 14 that are transparent to the primary colors in FIG Objective plane 15 is defined by a grid 16 of spherical lens elements in a suitable distance 7um Layer carrier a color grid extending over the entire layer carrier in each of the three basic colors pictured.

The arrangement of the color filters is shown in FIG. 4 again shown in detail. The filter arrangement results from the diagonal arrangement of a stripe 17 permeable to Giiin and a stripe 18 permeable to blue, on which a stripe 19 permeable to red at 45 ° is superimposed. The width of the red stripe is greater by a factor of I 1 than that of the other two stripes 17, 18. However, the pure colors only appear where several stripes do not overlap. In the fields where the red and blue stripes intersect, the filter color is purple, in the areas where green and red intersect, the filter color is yellow, and in the central square where all three stripes overlap, all colors are let through . An image of this mosaic-like filter arrangement with a square basic shape through spherical lenses in such a way that the squares meet without gaps in the image plane results in an overlay of three color-modulated line grids, which are inclined to one another at the same angles as the initial color strips 7, 18, 19.

The grid of square spherical ones required to map the color filters In addition to the plastic lens grids produced in a known manner, such as embossing, lenses can also have be photographic way produced grid, in which two to each other in the manner already described vertical systems of cylindrical lenses are applied. As experiments have shown The image quality of such photographically produced lens grids is sufficient for the present application completely off. These photographically produced grids are therefore of particular advantage, because the point size of the individual picture element matches the size of the lenticular lens, so that for To meet higher demands on the image quality, very fine lens grids must be used.

For the color reproduction of such after separation from the lenticular screen in the usual way

ίο black and white developed backing can be a Arrangement according to Fig. 5 can be used. In this case, as in FIG. 6 shown under various Angles in the diaphragm plane 10 successive brightness concentrations, each are assigned to one of the color separations. The angles between these brightness concentrations correspond the azimuthal angular position of the diffraction gratings to one another. On each of the brightness concentrations, from the inside to the outside, the colors blue in the first diffraction arrangement. Green and red with the familiar nuances on that repeat itself for the second order there is now the possibility in this To arrange a diaphragm, each for the level

Reproduction of the corresponding color separation lets the correct color through, but absorbs the other colors. In the plane of the screen 13, a three-color image is then built up by the lens 12. A particularly favorable possibility is to be seen in the fact that diaphragms with an adjustable size the opening or by means of light-weakening means such as gray filters and the like, the color components are matched to one another can be.

For playback in the manner according to the invention

produced, a color information containing black and white images can also other, from the holographic Playback technology known methods are used.

Instead of the three color separations of a color picture

You can also use the described method to successively print different monochrome images on one Layer support are exposed. For this purpose, a grid with changeable is used for each of the recordings Grid constant or different azimuthal angular position superimposed on the image. The separation the individual images during playback are then carried out in the manner described using apertures in the Aperture plane.

For this purpose 3 sheets of drawings

Claims (6)

Patent claims depicting the lens plane on the layer: lens grid arranged in the lens plane 1. Process for the production of carrier-frequency neter gap as a grid is passed over modulated images on a black and white, light-gap width or azimuthal angular position of sensitive layer, which changes 5 picture to picture. draws that the figure by in the ob- Color filters (4; 14) of different stripe widths or angular positions lying on the jective plane · -w _c u ju - t. on a lenticular grid (3; 16), which the light- The invention relates to a method and Vornchemens Layer (2) is upstream, takes place. «Services for the manufacture of carrier frequency modulators 2 device for carrying out the processing pictures on a black and white, light-sensitive driving according to claim 1, characterized marked layer. net that the filter strips (4) in the lens To produce carrier frequency modulated images symmetrical to one through the optical plane has already been proposed to lattice structures on the Axis running plane of symmetry are arranged. 15 to expose the film optically or in contact. the 3. Apparatus according to claim 2, characterized in that the grid must be very fine, on the one hand, to sufficiently identify that in the middle is a permeable strip (4 a) which is effective for all colors and on the other hand is no longer visible, to which two are located It is also known that in so-called lenses for a first basic color, preferably blue, non-raster color photography by means of its lenticular grid is connected to the transparent narrow stripe (4 b) , ao or color stripes located in the lens often have two next to it for a second basic color. and to use these in the correspondingly inverted, preferably red, transparent stripes (4c), beam path geometrically-optically to generate then two of a color projection image which are transparent to the first basic color. Stripes (4d) and finally two for a third. In the known geometrically and optically working basic color, preferably green, transparent lenticular lens methods of the type mentioned above are provided for stripes (4e ). 4. Device "according to claim 2 or 3, there are white Sdiichtträgers the difficulties characterized by the fact that the filter strips - especially that existing images because of the widths are dimensioned so that the widths of the cover can only be achieved with the greatest care Color stripes 30 of the lens grid imaged by the lenticular screen can hardly be copied without behave like 1 · 2 · 3 to produce undesirable moiré phenomena. It 5. Device according to one of claims 2, although numerous methods have been proposed, up to 4, characterized in that the lenticular lens raster recordings directly in contact, opraster (3) of cylindrical lenses (3a, 3b) formed table or to copy via an intermediate negative; it is whose axes run parallel to the filter strip 35 but has not yet been able to run reliably and (4). 'Develop economic process. 6. Device according to one of Ansrjrüche 2 It is the aim of the invention, a method and to 5, characterized in that the outermost devices for producing carrier frequency modulus filter strips (4d) have such a width, "" the first images to create Simplicity of the fact that their neighboring cylindrical lenses (3 α, 4 ° lenticular lens method when recording, because 3 b) offers images delivered with half transmission ^{that just overlap with} relatively coarse color elements to the filter or with full color coding, and in which the recording - Blocking effect of the filters without gaps, but they can be copied much more easily. than with the conventional lenticular process.