DE755039C - Process for generating images that appear three-dimensional - Google Patents

Description

Method for generating three-dimensional images The invention relates to a method for creating three-dimensional images and consists in that a image known per se is used, which separates and shifts the stereo images to each other, e.g. B. distributed like a checkerboard, contains, and that this picture by two arranged one behind the other, complementing each other according to the picture layout, composed of complementary colored and / or oppositely polarized elements set grid is considered.

In the known picture mentioned, the chessboard-like division takes place for the purpose of compensating for the error of the pseudoplasty. Through the checkerboard Division is achieved namely that the picture, no matter in which place the eyes are, one half stereoscopic, the other half pseudoscopic is seen. Each eye sees one half of the partial image assigned to it, on the other half, however, the partial image assigned to the other eye. Practically means this is a complete mixture with the result that the pseudoplasty is not canceled and orthoplastic viewing is not possible.

In the method according to the invention, however, the result is Contemplation when the eyes are in the right place, a perfectly orthoplastic image; every eye can see through when looking at it those arranged one behind the other, complementing each other according to the picture division Grid of complementary colored and / or oppositely polarized elements only the picture elements assigned to its sub-picture. It has of the two one behind the other Viewing grids one has the task of separating the partial images during the the task behind it falls to others, those belonging to each partial image Image elements alternately complementary coloring or opposite polarity with the result that practically every picture element of the right as well as the left stereo sub-image is composed, for example, of a red and a green component or composed of oppositely polarized components. According to this procedure it is thus also possible to see a three-dimensional image in color, a possibility the well-known ones, which in themselves serve a completely different purpose, are chessboard-like split picture completely absent.

The figures explain the invention using exemplary embodiments. It shows Fig. I the production of an image with spatial image effect, the grid and the emulsion are visible in section, FIG. 2 is a plan view of the grid arrangement, FIG. 3 shows a diagrammatic representation corresponding to FIG. 1, FIG. 4 another Embodiment to FIG. 3, FIG. 5 shows a special version for viewing through Polarizing filter, FIGS. 6, 7 and 8, three different embodiments of clichés for generating images with a spatial image effect.

Figures i, 2 and 3 are about the creation of an image with stereoscopic effect after two stereo partial images i and 2, each of which has a projection lens 3 and .4 listened to. A light-sensitive, panchromatic Layer 5 exposed (a reversal emulsion is expediently used here), and although the exposure takes place through grids 6 and 7, of which the grid 7 is in contact with the light-sensitive layer 5 lies, while the grid 6 is in a certain Distance from the grid 7 is located. The grids 6 and 7 are line grids; the Elements (Lines) 8 and 9 of the grid 6 close with the elements io and i i of the grid 7 an angle different from o °, in the example shown an angle of 9o '. If it is a question of the creation of three-dimensional black and white images, so the grid elements 8 and 9 or io and i i can alternate from covered and translucent lines. Since, however, image and light losses occur here it is advantageous for the grid elements 8 and 9 or io and i i to have a complementary color to train. such that, for example, the grid elements 8 and io made of red and the grid elements g and i i consist of green color. This execution is also necessary for the creation of three-dimensional, colored images.

The distances between the grid 6 and the projection lenses 3, d. on the one hand and to the grid 7 or the emulsion 5 on the other hand are dimensioned such that the Projection beam cones, which from the optics 3 and 4 coming through and the same grid element, e.g. B. 9 '(Fig. I) of the grid 6, go on the emulsion 5 two non-overlapping surface elements lying next to one another without a gap capture.

It is now assumed that the stereo sub-images i and 2 handle colored sub-images. Accordingly, a red part of the picture of one part of the positive can be i only through the red elements 8 of the grid 6 and also only through the red elements io of grid 7 can be seen. The same applies to the red parts of the picture of the partial diapositive q., and green parts of the image can likewise, they now like from the one or the other partial slide 3 or d. come just through the green elements 9 and i i of the grid 6 and 7 are mapped through. Look at hand of Fig. 3 z. B. the red element 8 'of the grid 6 and the green element 9' of the same grid. A projection beam cone passing through the red element 8 ' a of the projection lens 3 forms on the grid 7 a direction of the grid elements io and i i perpendicular stripes b. The red light of this cone of light However, b can only penetrate the grid 7 in the area of the red grid elements io. These elements are denoted by ro 'in FIG. 3. In the area of the fields iö becomes thus the emulsion 5 is exposed to red light.

The projection beam cone c of the projection objective q which passes through the same red raster element 8 '. generates a likewise red cone of light rays d, which, however, again only penetrates the grid 7 in the area of the red elements io. The fields in question are denoted by "io". In the area of these fields, the light-sensitive layer 5 is exposed to red light, which belongs to the image components of the stereo partial image 2 or the projection lens 4. The ratios for those caused by the green element are similar 'f previous projection cone of rays E and the projection cone of rays e generated behind the green element g.' g of the grid 6, a green light beam g which coincides with the red light beam d However, this green light passes through the grid 7 only in the area of the green element ii. the fields in question here are denoted by ii '. In the area of these fields ii', the emulsion 5 is exposed to green light that comes from the partial image i or the projection lens 3. The light beam cone f, which is emitted by the projection lens q. also goes through the element g 'of the grid, creates a green light cone h behind the green element g', the Lic ht penetrates the grid 7 in the area of the green elements ii; the fields in question here are denoted by ii ″. In the area of these fields, the light-sensitive layer 5 is exposed to green light, which originates from the stereo partial image 2 or the associated projection lens.

In this way, therefore, arises on the photosensitive layer 5 one projected together from the partial images i and 2. Picture in which the picture elements are offset and stored separately from each other in a checkerboard manner, in such a way that that diagonal rows of fields alternate one and the other part of the picture To belong.

The picture itself is not drawn separately in FIG. 3; it looks but in terms of its division exactly like the chessboard-like division into the fields iö, io ", i i ', i i". The diagonal rows of fields with the Index ', so the rows of fields io', i i 'etc. belong to the stereo sub-picture i, the Diagonal rows of fields with the index "on the other hand, ie the rows of fields i o "and i i" etc. belong to the stereo sub-picture 2.

The light-sensitive exposed in the manner indicated by the grids 6 and 7 Layer is developed and reversed or copied. The result is then a black and white picture that contains both the colors and the plastic, the plastic insofar as, as already said, the elements with the index 'the one partial picture i and the elements with the index "belong to the other partial image 2, the colors thereby, that, as explained, the emulsion by red light only in the area of the red color elements, was exposed by green light only in the area of the green color elements.

If you now bring the developed black and white image behind the grid 6 and 7 in exactly the same position that the emulsion had during exposure, and one looks at the image through the grids 6 and 7 with the eyes approximately assume the position that previously the projection lenses 3 and q. had taken so one sees the picture three-dimensionally and in color, namely one eye sees it, for example the eye standing at 3, only the image elements that originate in front of the stereo sub-image i, and the other eye, at 4. standing, only the picture elements which are from the partial picture 2 originate. This becomes readily apparent if, for example, one looks at the two again Considered cones of rays a and c, which in this case are now cones of sight rays. The cone of sight rays a sees through the red element 8 'only the red elements io', while the cone of sight c through the red element 8 'only the red image elements iö 'can see. It is the same with the green picture elements; the green Picture elements i i 'are only seen by the eye standing at 3, the green picture elements i i "only from the eye standing at q.

The arrangement described also allows without any change the creation or viewing of three-dimensional black and white images.

Of course, it is useful to use the picture, which is primarily a see-through picture It is possible to illuminate or to illuminate when viewed from behind.

They take their place when creating vivid black and white images of the color part images i and 2 (color part slides) black and white part negatives. In this The panchromatic emulsion on which the exposure takes place only becomes trap developed and dried, not the other way around.

The arrangement is intended in the example described and drawn for the reproduction of images that are already available in the form of partial stereo images. The whole thing can also be used to record spatial black and white or colored images can be used in the camera. In this case, the stereo sub-images are i and 2 can be imagined without them, and the two images must have reflective surfaces (Mirrors or prisms) are projected together on the light-sensitive layer.

For the production of the images, instead of complementary colored grids, polarization grids can of course also be used, the elements of which polarize the light in opposite directions. For example, let the elements 8 of the grid 6 polarize in the opposite direction to the elements g of the same grid and also the elements io polarize the opposite way to the elements ii of the grid 7 (FIG. Q). Opposite polarization is to be understood as meaning both oppositely linear and circular and elliptical polarization. First and foremost, linear polarization comes into consideration. For the production of three-dimensional black and white images, nothing changes compared to the above-described arrangement when using polarization grids instead of complementary colored grids. However, if color images are to be produced, then color filters must be used. For example (Fig. 4.) during part of the exposure a green filter L with a polarization filter is switched into the beam path, which allows either only right or left polarized light to pass through (right and left here mean the two possibilities of opposite polarization) . During the other part of the exposure, a red filter of opposite polarization is switched on.

The developed image is viewed in the same way as described above, d. H. through those composed of complementary colors Grids 6 and 7. Of course, the division of the must be taken into account when looking at The grid used must be the same as the pitch used when the image was taken polarization grid used. But it can also be viewed through a polarization grid take place; but then the source of illumination must be divided into two complementary colors and each of these two colors has a polarization opposite to the other obtain. This is shown in FIG. The eye locations are with A1 and Az, the light sources labeled L1 and L2. The elements 8 and 9 of the grid 6 are polarizing in opposite directions; likewise the elements io and i i of the grid 7. These have colored elements Grid not. A red color filter is located in the beam path of the light source L1 a polarizing filter o, e.g. B. a left polarizing filter. In the beam path the light source L2, however, is a green color filter p with a polarization filter q opposite polarization, i.e. a right polarizing filter. Naturally each color filter n or p with the associated polarization filters o or q be united.

The use of color filters is unnecessary when viewing in black and white or from light sources subdivided in complementary colors.

After all, you can at. the recording, d. H. in the preparation of of the image also proceed in such a way that one of the two grids, e.g. B. the Grid 6, as a polarization grid and the other of the two grids, e.g. B. the grid 7, designed as a combined color and polarization grid, the latter in the sense of that z. B. all red elements io on the right and all green elements i i are opposite, i.e. polarized to the left. In this case it is at the time of admission Color filters do not need to be switched on for colored stereo images.

Upon consideration, the arrangement shown in FIG. 3 is again used maintained by grids composed of complementary colors. One could but also for viewing one of the two grids through a polarization grid substitute. When viewing three-dimensional black and white images even both grids can be polarization grids.

Instead of taking the picture, two grids 6 and 7 in a suitable one Distance to use which grid then when viewing the image in the same Arrangement and equidistant again are required, one can for the recording also use clichés of the grid arrangement required for viewing. One such cliché for taking pictures of three-dimensional black and white images is shown in Fig.6. It consists of a transparent plate, e.g. B. a glass plate or a film, and has covered fields i and open fields k, namely in chessboard-like division. The size of these fields corresponds to that of the fields io ', io ", i i' and i i" * of the arrangement according to FIG Fig. i, 2 and 3 to imagine the grid 6 and 7 away; in their place comes the cliché 6, in contact with the emulsion 5, as in the case of the one previously described Embodiment the grid was in contact with the emulsion.

Now one of the two projection lenses is first used 3 or 4. the layer which is in contact under the cliché is exposed. The covered ones Places i don't let the light through. The exposure is therefore only in the area of vacancies h. In this situation of the cliché in the area of the open Places k correspond to places of the light-sensitive layer struck by light Parts of the picture which belong to the stereo part picture i. Is this exposure process ended, so the cliché, while the photosensitive layer remains unchanged remains, shifted to the left or right by the amount x of the division, and then the light-sensitive layer is exposed through the projection objective 4. It are here the previously exposed areas through the covered areas i of the cliché covered, and the now uncovered areas of the emulsion are accordingly the stereo sub-image 2 exposed. After developing it results an image that is broken down into elements in a checkerboard shape as in FIG. 3 shown, which however only allows a spatial black and white view. The contemplation takes place, as shown in FIGS developed picture occupies the same position as the layer in these figures 5.

If in the cliché according to FIG. 6 the fields i and k are designed so that the one fields absorb X-rays, z. B. from lead or bismuth compounds exist that let other X-rays through, so can with this cliché X-rays can be made by passing the emulsion over the Object exposed through this cliché with an X-ray tube, then the cliché shifted by the amount x and followed by a second exposure, at which the tube is approximately at eye distance from the position of the tube at the first Exposure is located. The spatial X-ray image obtained in this way is described in FIG Considered wise.

A cliché for creating a colored spatial image is shown in Fig. 7 reproduced. This cliché is in turn divided into muted ones like a grid Fields i and in permeable fields k. However, the latter are alternately complementary, z. B. colored red and green (the different coloring is indicated by different hatching indicated). This cliché is in contact with the photosensitive when recording Layer 5 brought. The grids 6 and 7 of Fig. 3 are to be imagined in the recording. The exposure process is the same as described for Fig. 6; d. H. it will be first from the one projection lens, e.g. B. 3, exposed from and then, after Shifting the cliché by the amount x of the division, from the other cliché ¢ off. The layer exposed in this way gives a checkerboard shape after exposure split image in which the image elements io ', zo "and ii', ii" are stored in exactly the same way are as shown in FIG.

The observation of this image takes place as shown in Fig. I to 3, by means of the spaced apart grids 6 and 7; the picture appears colored and plastic.

8 shows the embodiment of a cliché in which there is no displacement during the exposure process. This cliché is also divided into a chessboard pattern; the size of the fields is the same as in the clichés of FIGS. 6 and 7, ie the fields correspond to their size according to the fields io ', io "of FIG. 3. In the cliché of FIG. 8, covered fields are not present; All fields are translucent, namely the fields of each diagonal row are alternately colored in complementary colors, e.g. red and green (the different colors are indicated by different hatching). In addition, however, adjacent diagonal rows of fields are polarized in opposite directions; the opposite polarization is indicated by the letters R, L in several fields, where R should mean right and left polarizing L. The recording with this cliché takes place in such a way that the cliché is brought into contact with the light-sensitive layer (the grids 6 and 7 i, a and 3 are again to be imagined) and that the exposure then takes place, with a right-hand pole in the beam path of one projection lens Arising filter and a left polarising filter in the beam path of the other projection lens is to be thought. A shift of the cliché during the exposure process is not necessary here. The result, in turn, is a black and white image that has both the colors and the three-dimensional effect. This black-and-white image is viewed again through spaced-apart grids 6 and 7 according to the arrangement of FIGS. are to be thought of. The picture appears colored and three-dimensional.

As already mentioned, the image is x-rayed when viewed. For this fluoroscopy, it is advisable to use two in the complementary colors of the Light sources of variable light intensity held by grid elements. Through this it is possible to make color corrections. Are when considering polarization grid is used, the correction can be made by means of light sources of variable intensity and upstream polarization filter can be achieved, the filter of the one Light source polarized opposite to that of the other light source.

If you don't work with clichés when recording, but rather is the case with the grids themselves, which will be used later in the observation it is advisable to use optics whose focal lengths are known per se are changeable so that the spacing between the grids can be kept constant.

The following is a compilation of the. the recording and at possible arrangements are given for consideration: A. Recording I. Arrangement of the grids as in Fig. i. Both grids consist of complementary colors Elements. With this arrangement, images can be copied in black and white and in color.

The exposures of the stereo sub-images can be carried out at the same time will.

II. Arrangement of the grid as shown in FIG. the grids are however not from complementary colored, but from oppositely polarizing elements composed.

With this arrangement, images can be copied in black and white at simultaneous exposure of both partial images.

However, images can also be copied in color. Here is however, the upstream connection of color and polarization filters is required (Fig. q.). The exposures of the two partial images can also be done simultaneously in this case to be made; however, during one half of the exposure time, for example a red filter with one polarization and during the other half of the exposure time For example, a green filter with opposite polarization can be connected upstream.

III. The arrangement according to I can be produced directly in the camera of recordings in black and white or in color. be used.

The same applies to the arrangement according to II. IV. Using a Clichés according to FIG. 6 by shifting the cliché and alternating exposure of the partial images. In this way, enlargements and direct recordings can be made in the Camera for black and white images.

V. Use of a cliché according to FIG. 7 by shifting the cliché and alternating exposure of the two partial images. Again, you can use enlargements and direct recordings made in the camera for black and white images and color images will.

VI. Use of a cliché according to FIG. 8 without shifting the cliché, with simultaneous exposure of the two partial images. There can be enlargements and direct recordings made in the camera for black and white images and color images will. B. Consideration I. Arrangement as shown in FIG. The elements of both grids are held in complementary colors. Ordinary things can be used to view the spatial image Light (daylight) or lamplight can be used. For color correction in the Viewing can divide the exposure source into two colors (complementary colors) be. By changing the lighting intensity of the two partial colors the image colors are corrected during viewing. II. Arrangement as per Fig. I, but using grids consisting of elements of opposite Polarization exist. The ordinary can be used to view the spatial image in black and white Light or lamplight can be used. For viewing the spatial image in colors must be the source of illumination in two. Complementary colors are subdivided, with these colors receive opposite polarization (Fig. 5).

Regarding the color correction, what was said under I applies.

III. Arrangement of the grid as shown in FIG. I, but one of the two grids of elements of opposite polarization, the other grid from Complementary colored elements of opposite polarization consists. It can the spatial images are viewed in black and white and in colors. The sources of illumination are as provided in arrangement I; color correction can also be done as under I will be carried out. One could also make this correction by decomposing the Reach exposure source in two parts with opposite polarizations.

IV. Arrangement of the viewing grid according to FIG of the two grids made up of elements of opposite polarization and the other grid is composed of complementary colored elements. Here, spatial images viewed in black and white and in color. The lighting source will be like arranged in case II. With regard to the color correction, what was said about arrangement I applies; however, the illumination polarization can also be varied.

Claims (7)

PATENT CLAIMS: i. A method for generating three-dimensional images, characterized in that a known photographically produced image is used, which separates the partial stereo images and offset from one another, z. B. distributed in a chessboard-like manner, and that this image is recorded and viewed by two raster arranged one behind the other, complementing each other according to the image division, composed of complementary colored and / or oppositely polarizing elements. 2. The method according to claim i, characterized in that for Consider at least two held in the complementary colors of the grid elements Light sources of variable light intensity are used. 3. Method of manufacture one Image for performing the method according to claim i, characterized characterized in that a light-sensitive layer behind grids of the arrangement, as required, exposed and developed for viewing according to claim i. 4. A method of manufacture according to claim 3, characterized in that the photosensitive Layer behind clichés with the grid arrangement required for viewing exposed and developed. 5. The method of claim 4 for producing a Image for black and white viewing, characterized by using one of the image splits accordingly, e.g. B. chessboard-like divided clichés with alternately covered and rows of translucent fields through which the photosensitive layer first from one of the two stereo optics and then after moving the Clichés about the amount of division that is exposed from the other stereo optics. 6. The method according to claim 4 for producing an X-ray image, characterized by using a z. B. chessboard-like divided clichés with alternating Series of fields that absorb X-rays and are permeable to these rays, through which the X-ray sensitive layer is first removed from an X-ray tube from and on, after shifting the cliché by the amount of the division, from an X-ray tube arranged approximately at eye distance from the first position is exposed. 7. The method according to claims 4 and 5 for producing an image for black and white or color viewing, characterized by using a Clichés in which the fields of the translucent field rows alternate are complementary colored. B. The method of claim 4 for producing an image for black and white or color viewing, characterized by using a clichés divided up according to the image division with alternating opposites polarizing, each consisting of complementary colored fields, where during the exposure in the beam path of one stereo sub-image a right-polarizing one a left-polarizing filter in the beam path of the other stereo sub-image is switched. G. Photographic image to create a spatial and at the same time colored image effect for the method according to claim i, characterized in that that it shifts the picture elements of two stereo sub-images and separates them from one another, z. B. in a manner known per se dissolved in a checkerboard manner and that the alternately complementary colors or image elements belonging to each partial image include opposite polarization directions. To delimit the subject matter of the invention From the state of the art, the following publication is to be considered in the granting procedure drawn: British Patent No. 514426.