DE2213624A1 - RASTER OPTICS AND EXAMPLES OF THEIR APPLICATION, IN PARTICULAR FOR PHOTOGRAPHIC AND KINEMATOGRAPHIC RECORDING AND / OR REPLAY OF 3-D IMAGES - Google Patents

Description

Raste rop tik and examples of their use, especially for the photographic and cinematographic recording and / or reproduction of 3-D images The flawless or at least largely flawless implementation, for example the cinematographic recording and reproduction of three-dimensional images, also known as stereo film, spatial film or 3-D film, is in the various Variations are known, however, none of the known methods has so far been used in be able to enforce in practice over the long term.

On the one hand, this should be due to the fact that viewing of 3-D images does not correspond to the normal visual process and, on the other hand, is the correct spatial effect of a stereo film strongly depends on the viewer's place depending, quite apart from the factors that damage the image, which are physiology the visual process are to be assigned.

Recently, spatial images that appear true to nature have been created using lasers and holography can be realized without any special aids, such as polarization glasses or the like, are to be considered. The inclusion of such images is - after that current state of the art - but still completely limited to stationary objects and, in addition, a large, three-dimensional projection of such holograms is available Time not yet possible. For example, in the Aufsata, it says, "Extended Basics the holography "" Electronics "1969, issue 9, page 284:" On the other hand, living Objects because of their temporal instability with C w lasers over = not holograph at all. "This difficulty was caused by the" combination of the conventional photography with holography "circumvented, as it is said. But obviously there are still great difficulties here, for example "the production and working with lens grids" relate to.

The combination of the lens window known as the "holocoder" with the conventional photography is also under the title: "Sight = lendung bei dense Nebel "in" Hobby "No. 15, pages 44 - 48, and there it says with reference a holocoder is now added to the image recording using the holocoder (page 48) Exposure developed positively and projected again through the facet lens, eo creates a three-dimensional image of the objects captured, namely in the same distance in front of the lens as the objects were. However, it is difficult to get this image properly visible as there is none to this day There is a three-dimensional screen, so it is more practical to use the holocoder To produce a hologram. "According to this state of the art, it appears necessary that a lenticular grid can be simple, light and yet be manufactured with high precision should make working with such a lens maker easier and more varied will. This also includes one for the projection of three-dimensional images suitable screen that can be produced in any size. Realizing this both requirements is the subject of the present invention.

For this purpose, it is assumed that two cylinder lenses with the same curvature arranged one behind the other and rotated by 90 ° to each other act like one spherical lens. This means that this lens arrangement from one thing point one the same image point and thus also good images.

If now two CYLINDER LENSES - LINE GRID, with cylindrical lenses from same curvature, rotated 90 ° against each other close to each other = lying and immovable are connected to one another, then this results in a lenticular grid with a multiplicity of individual lenses lying next to one another.

In contrast to the known lens grids, which are made of a variety of spherical lenses (fly's eye lens) or a variety If there are cylindrical lens lines running parallel to one another, the lens grid would be according to the invention with: CYLINDER LENS RASTER to be named.

With reference to lens grids, the one since 1908 is still assumed FAMOUS LENS GRID FILM. (see e.g. '2A B C,' der Optik ", Fig. 1, page 494 or @Farbenphotographie und Parbfilm "by Werner Schule, fig. 21, page 36 and fig. 22, page 37). This lenticular lens film has narrow cylindrical lenses (single width 0.03 mm § embossed lengthways into the riin on one side of the film.

Such CYLINDER LENSES - LINE GRID, which in transparent plastic films or - plates are embossed or rolled in, are also @@@@@ for image separation used for stereo images, (see also 3rd "A B C of optics" page 138, column 2, paragraph 3.) The subject of the invention is described below with reference to the drawing figures.

Fig. 1 a) shows a cylinder lens with a parallel beam concentrated to the picture line.

Fig. 1 b) with two cylindrical lenses offset from one another by 90 ° concentrated parallel beam to the image point.

Fig. 2 *) cylinder lens grid according to the invention with a view in direction I - I p) enlarged section sue @) d) enlarged section from @), whereby the two line grids crossed by 90 ° with the flat sides against each other lie.

D) Partial view, where the two crossed raster rolls between two mirror glass panes can be precisely leveled and held fixed in their position.

E) Partial view as D) with thinner mirror glass panes so that the The focal point of the cylindrical lenses is nusserhaib of the mirror glass panes.

Fig. 3 Schematic representation of a photo camera with cylindrical lens raster optics and a second cylindrical lens grid for pre-image alignment checking Recording

Fig. 4 Schematic representation of a cinema camera with cylindrical lens raster optics.

Fig. 5 Cylindrical lens grid screen for a large-scale display of the Camera Fig. 3 and 4 recorded 3-D pictures Fig. 6 Light raster screen with Fresnel lenses.

Fig. 7 Light raster screen with Zonan lenses.

Fig. 8 Summarized representation of the differences between lenses, Lens grids, cylindrical lenses, cylindrical lens line grids and a CYLINDER LENS GRID.

Fig. 1 a) shows a cylinder lens 1, which extends in the direction of arrow 2 # ray bundle 3, at the focal point of the lens one image line 4 combined. If, as FIG. 1 b) shows, two cylinder lenses 1 and 1 'are arranged one behind the other rotated by 90 °, then the # ray bundle 3 unites in the common focal point of these two lenses 1 and 1 'to form an image point 4'. The effect of such a cylinder lens system is the same as that of a spherical lens and consequently equally good images can be achieved with it. As far as necessary, cylindrical lenses can be corrected with reference to the beam path for a particularly good image just like spherical lenses and the same applies to the optics calculation as for spherical lenses, but it must be taken into account that always two identical cylindrical lenses - LINES - Haster belong together to a CYLINDER LENS grid.

Based on this, the new cylindrical lens grid, for example, preferably consists - and for the simple case - from two 90 ° crosses arranged one behind the other Cylinder lens LINES - grid 5 and 6, Fig. 2 4), as well as an enlarged section #) These cylinder lens plates or foils must be made for optical reasons be arranged largely flat to each other. For this reason, as shown in Fig. 2 D) shown in partial view, held between two mirror glass panes 7 and 8. Before that, of course, the line grids of 5 and 6 must be rotated against each other has been fixed exactly 90. The two glass panes, which are also plastic panes can be, are then on their edge all around by a putty ring 9 (two-component Glue) firmly connected to each other.

This means that the CYLINDER LENS GRID that lies in between is also against Ingress of moisture and / or dust completely protected.

Of course, measure all internal surfaces in front of the putty carefully cleaned and of any sticking Condensation skin be liberated.

In Fig.2} the thickness of the glass panes 7 and 8 is now chosen so that - as the parallel beam path lo shows - the focal points f of the cylindrical lens grid 5, are located within the glass = layer, while the outer glass surfaces 11 and 12 are interchangeable and represent the image plane 13. For certain application purposes It can be advantageous that the focal points of the optics are also outside the eJlasscheiben are located. For this skin, as shown in FIG. 2 E), the Glass panes 7 and 8 then selected correspondingly thinner. There is a third possibility in that the outer glass surface represents the image plane on one side, while the lens focal points F of the lenses are on the opposite side lie outside the glass pane, as indicated by 14 and 15 - FIG. 2 E) is.

From the above it should be apparent that the production of a "Holocoder" with cylindrical lenses is not as difficult as making one those with spherical lenses. But also the production of several identical ones CYLINDER LENS grid does not present any difficulties because two identical cylindrical lens LINE grid, simply rotated 90 ° against each other and placed next to each other, one CYLINDER LENS grid result. This, repeated any number of times, yields for always congruent CYLINDER LENS GRID.

The proposals result from experiments with this cylindrical lens grid to the example shown with Fig. 3 of a photo camera for the recording of 3-D images with the option of cropping the image before taking the picture look at and on To control image sharpness follows that with Fig. 4 Darge = presented exemplary embodiment of a cinema camera for recording 3-D films and the embodiment of a projection screen, FIG. 5 via which both the 3-D images of the still camera, FIG. 3, as well as the 3-D films of the film camera , Fig. 4, can be viewed as 3-D images enlarged as desired.

An essential feature here is of particular importance that as a confirmation, the images of the recordings made with the CYLINDER LENS GRID heart do not have to be converted into a hologram, as is the case, for example, with the well-known "Holocoder method" is required.

That this is so is due to a two identical CYLINDER-LENS- RASTER - in the Pig version. 2 a) and d) - the effect to be observed, which With FIGS. 3 and 3, as is to be described below.

The CYLINDER LENS GRID 16 and 17, for example, have dimensions tone 90 mm x 120 mm. The width of a cylinder lens line is 1mm, so each of the two cylindrical lens grids from ingge = together 90 x 120 = 10 800 individual lenses exists and each individual lens @@ testifies to the image object 18 to be recorded Real image in the image plane 19, Fig. 3 and Fig. 3 1, in complete image reversal. Groasen this multitude of 1 mm 2 large pictures within the 90 ml x 120 mm Image plane 19 are images of the image object 18 from just as many viewing directions benz. Viewing angles 21 and they can be used as images 22, for example, only by means of one magnifying glass 23 brought close to the image plane 19 can be recognized as such.

Otherwise, however, CYLINDER LENS GRIDS (and of course also lens grids) opaque for recognizing objects on the other side.

q Even so, the viewing is one for inclusion certain 3-D image section before recording in the embodiment shown in FIG. 3 schematically shown photo-wamere possible.

For this purpose a second CYLINDER LENS GRID 17, up to the dashed line Drawn location 24, brought close to the CYLINDER LENS GRID 16, so that the lenses of both grids are on the same axis, as is the case with Example from Figure 3 X can be seen.

At the same moment after this has occurred, the image is also = Item 18 is visible as a 3-D illustration in the frame of the CYLINDER LENS GRID 17. The 3-D image impression corresponds to that of a reconstructed image from one Hologram.

If, for example, there is now a photo plate 25 instead of the cylinder = Linsen-R-sters 17 with the layer side applied to the second cylindrical lens grid 16, then the previously observed image section can be fixed photographically on it. Of course, the cylindrical lens grid 16 and the are now located for this purpose Photo plate 25 in a light-tight housing and by means of a focal plane shutter 26, for example, for the exposure of the photo plate 25, the entire Surface of the cylindrical lens grid 16 released.

The photo plate 26, developed, gives a negative image a positive copy is peeled off and this is connected to the cylindrical lens grid 17 results in a 3-D image which, in the rain set, has a cylindrical lens line grid or holograms generated 3-D images, viewed from any direction can be recognized as a 3-t) image.

Such a 3-D image is produced as a slide by means of a Projecting a light image projector also on a large scale, but this is a special one D-D screen required.

Basically, this 3-D screen is nothing more than an in Large CYLINDER LENS GRID, as shown, for example, in Fig. 2 A),, , and E) is shown. Such a 3-D screen is also for demonstration of a 3-D cinema film recorded by means of CYLINDER LENS RAS = TER.

For the latter example, FIG. 4 shows a schematic of a 3-D film recording camera. This consists of the CYLINDER LENS GRID 28, whose image = plane 29 is the lens 30 on the movie 31 in the image window 32 is reduced in size, which means that the large number of the images generated by the cylindrical lens grid 28 are then recorded on the Fibm 31 are.

For the enlarged reproduction of the 3-D film recording, as with 5, the 3-D film shone through by means of the illumination optics 33 31 via the projection lens 34 in back projection onto the 3-D screen 35 projected. The decisive factor here is that the enlarged image grid of the film 31 'coincide with the raster lenses 36 of the screen 35 and thus nothing mild information is lost - the screen 35 should be the same number have as many lenticular lenses 36 as there are image raster on the film 31.

Now a cinema thcater requires a fairly large screen, which also has a large empty space behind the screen for rear projection Space presupposes. Such a 3-D screen in the version with CYLINDER LENS GRID has, in the minimum size of, for example, 3 x 4 meters / but a heavy weight.

Large 3-D screens are therefore useful - even this one Due to its weight - made of relatively thin, transparent plastic foils manufactured, in which the grid elements as Fresnel lenses of the appropriate size and focal length are embossed.

Or it will be on the plastic film - as another option - ZONE LENSES (on this: "Umschau" 1952, No. 2, page 46) printed or copied in by photo.

Such 3-D screens with grid elements from Freshel- 36 (Fig. 6) or zone lenses7 (Fig. 7) enable the 3-D images also in front-light projection to cheat. For this purpose, there is a reflective screen on the back 20 of the 3-D screen Area Y provided.

In the case of zone lenses, for example, this mirror surface2O is direct applied to one side of the film by vapor deposition or in a suitable manner or, in the case of Fresnel lenses, for example, it is also directly on one side of the film applied or as Spiegel2 @ at a defined distance behind the 3-D screen 35 'arranged.

In both cases, the reflective surface has the effect of projecting upwards the light image radiation coming from the projector 34 / from the 3-D screen, into the Viewing space is reflected, which at the same time the vial image recording of the film, After the photo radiation has passed through the optics of the screen, search for the 3-D image is reconstructed.

The applicability of the raster optics is not limited to those described above Examples are limited and it should be easy to see that the inventive Raster optics, because of the relatively low weight, in versions with the largest Maassen, for example, is also of particular importance for astronomical telescopes can be.

Claims (1)

P a t e n t a n t a n s p r u c h e 1. Raster optics, which do not indicate that they are is formed from cylindrical lenses. 2. Raster optics, characterized by the fact that they are made from Fresnel lenses is formed. 5. Raster optics, characterized in that they are formed from zone lenses is. 4. Raster optics according to claim 1, characterized in that at least two cylindrical lens line grids, preferably offset by 90 apart, next to each other lie. 5. raster optics according to claims 1, 2 and 3, characterized in that = They are used as films between flat (flat) glass or glass and / or plastic panes are held airtight and watertight. 6. Raster optics according to claim 5, characterized in that the outer surfaces the glass or plastic panes represent the image plane. 7. raster optics nich claim 2, characterized in that one A large number of Fresnel lenses are incorporated into a plastic film, for example by rolling in or pressing in. 8. raster optics according to claim 3, characterized in that a plurality of zone lenses photographic or photo = mechanical on a plastic film are applied by woping from a template. 9. Raster optics according to claims 1, 2, 3 and 5, characterized in = denotes, that they can be combined with one another and are interchangeable. 10. Photo camera and raster optics according to claims 1,2,3,5,6 and 9, d a d u r c h g e k e n n n n z e i c h n e t that two raster optics 16 and 19 - Fig. 3 - with congruent raster lenses are used to create a 3-D image in that a raster optics 16 with its lenticular lenses differentiate object images from various Viewing angles generated in the image plane 19 and the large number of object images through the other raster optics 17 is reconstructed to form a uniform 3-D image. 11. Photo camera and ROsteroptik according to claim lo, characterized in that instead of the raster optics 17 to Example, a photographic plate 25 @ is located in the image plane 19, on which, after exposure and development, the recorded 3-D image can be viewed via the raster optics 17. 12. Movie camera with raster optics according to claims 1, 2, 3, 5 and 6, characterized in that the image plane 29, the raster optics acting as a pre-lens 28 - FIG. 4 - reduced by the optics 30 on the movie 31 and fixed will. 13. 35mm camera with raster optics according to claim 12, characterized in that As in the case of the cinema camera - FIG. 4 - the small image on the film 31 via an optical system 30 is recorded. 14. Projection screen with raster optics according to claims 1, 2 or 3 and 4, 5, 7 and 8, characterized in that the projection screen 35 - Fig. 5 - compared to the multiple raster image to be projected thereon from a slide , a movie 31 or the like is much larger in relation to this, for example 1:50 or 1: 220, and that the raster optics 36 of the screen 35 are enlarged in the same or approximately the same ratio and in the same or approximately the same way = cher number and have the same geometrical arrangement as the image grid on the film 31, so that with the help of the projection optics 34 the image grid of the film 31 with the raster optics 36 # of the screen 35 are to be brought to cover. 15. Projection screen according to claim 14, characterized. draws that for a front projection the back of the screen 5 is mirrored or a mirror the size of the screen at a defined distance behind which = sem is arranged.