DE1163670B - Mosaic Photography Process - Google Patents

Description

Mosaic Photography Process The invention relates to a process for mosaic cinematography and mosaic projection, in which moving images from neighboring Parts of the scene recorded directly or indirectly on several negative film strips so that the images are on the longitudinal edges of adjacent parts of the scene overlap and in the areas of overlap when shooting with the help of vignetting organs a first partial vignette is generated.

In mosaic photography, parts of one become a wide angle of view Comprehensive scene recorded simultaneously with the help of multiple cameras, each one are arranged so that they can capture a specific part of the scene. Man has already suggested avoiding parallax by viewing the scene optically at the light entry opening of a single camera with the help of mirrors centered, these mirrors are arranged so that only one camera is directly on the part of the scene to be recorded by them is set, while the other Camera or each additional camera the associated partial image of the scene under mediation through a reflective mirror. After developing the films of the different cameras and after making the copies it becomes the original Scene then made visible by means of simultaneous projection.

In such a recording process, it is important that at the connection points no discontinuities between the parts of the scene recorded by the separate cameras appear. The cameras are preferably set up so that they are along the edge each film forms a transition zone in which the relevant parts of the Scene can be recorded twice on the films of neighboring cameras. At the demonstration if the images appearing in these transition zones are superimposed, see above that you get a seamless projected scene. The width of the transition zones on the films depends on the opening size of the camera, i. i.e., its width decreases when the aperture is made smaller. If the transition zones have a Getting too narrow a width makes it difficult to get the correct overlap during to ensure the projection. So that the intensity of the light during the performance did not vary in the overlap zones, measured the density of the films over the whole The width of the overlap zones vary. In practice, however, it has been shown that the width of the zone within which the density varies is less than that Width of the transition zone. This creates bright stripes on the screen Width corresponds to the parts of the transition zones having a uniform density. In order to avoid this disadvantage, it is already known in the overlapping zones to generate a first partial vignette when recording vignetting recordings. It is also known; photographic vignetting strips on the Copy unexposed positive film before transferring the negative images onto it will.

It is the object of the invention to vignetting the overlap zones to improve.

This is achieved according to the invention in that for correction of the first partial vignette with regard to width and intensity gradation a second partial vignette is applied in the overlap zones of the positive or negative films.

In an arrangement for mosaic photography with three separate cameras the width and intensity of the vignetted area changes with change the aperture and depending on. the intensity of the scene to be recorded coming light, especially if the light-dark contrast of the scene is relatively strong is. Furthermore, this first vignetting does not have a linear course.

Due to the additional vignetting rank according to the invention, firstly the aforementioned variations in the width and intensity of the first vignetting corrected and at the same time the total width of the vignetted zones to the The width of the overlapping zones is increased and the intensity gradation is evened out will. A first partial vignette will be within the transition zone then generated when adjacent scene parts of the motion picture on the different Negative film strips are applied. When the motion picture is recorded outdoors is, the cameras used here are provided with vignetting devices, z. B. with the thin masks described below, by means of which the gradation of the Intensity of the light is regulated, which is the transition zone between neighboring Reached parts of the scene, creating the first partial vignette in the transition zone will. If, on the other hand, there is an existing motion picture film that is not based on the mosaic cinematography is to be split into two or more separate film strips, the first partial vignette generated in the laboratory at the point in time at which adjacent parts of the scene applied to the negatives for use in mosaic cinematography will. This can be done in a similar way to the cameras used outdoors, d. H. with the help of a suitable vignetting device to regulate the intensity of the Light that reaches the transition zone of the mosaic negative, while the relevant Part of the scene is applied to this negative.

In both cases, the first partial vignette is effective in the transition zone The negative film strip has a gradation in the intensity of the light that passes through the transition zone of the positive film is reached during copying, and as a result, the first Partial vignette in the transition zone to the transition zone of the projection using positive film applied.

The additional vignette according to the invention is preferably dimensioned in such a way that that the area of the total vignetting compared to that of the first vignetting is enlarged.

The additional vignette according to the invention can be used in the overlapping zones before copying the developed negative film onto the positive film by exposure of the unexposed positive film with light that is graded in its intensity will.

Alternatively, the additional vignette according to the invention can be used during of the copying process are generated before the positive film is developed, namely by introducing an additional regulated gradation of the intensity of the light rays, which reach the overlap zones of the positive film beyond the light, by means of which the vignette was created on the negative film.

The additional vignette according to the invention can also be generated in this way be that you have the exposed negative film before your development in its overlap zones exposed to light, the intensity of which is regulated, so the additional Generate vignette in the transition zone.

According to the invention, the additional vignette can also be applied before the exposure of the negative film.

The invention is described below with reference to schematic drawings explained in more detail using several exemplary embodiments.

F i g. 1 is a diagram for explaining a for the mosaic photography suitable arrangement of cameras, and it shows in plan three separate cameras; F i g. Fig. 2 schematically illustrates an image obtained with the aid of of films is projected, which with the help of the camera arrangement according to FIG. 1 under Interposition of development and copying processes have been established; F i g. 3 shows one another in a partial representation drawn on a larger scale adjacent edge sections of uncorrected films, such as those made with the help of two the cameras according to FIG. 1, with the films being developed are; F i g. Fig. 4 is a diagram used to explain the invention; F i g. FIG. 5 shows a piece of negative film serving as a mask produced according to a Embodiment of the invention has been made with the aid of a mask; F i G. 6 schematically illustrates the use of the negative serving as a mask according to FIG. 5; F i g. 7 illustrates the obfuscation method of the present invention of positive film; F i g. 8 shows the application of the method according to the invention when obscuring an unexposed negative film.

In Fig. 1 shows the general arrangement of three cameras for the Mosiak photography method according to the patent cited above: According to FIG. 1, three cameras A, B and C are arranged in an enclosure 2 which has an opening 4 through which the relevant scene is photographed. The light inlet opening of camera A is indicated schematically at 6, that of camera B at 8 and that of camera C at 10; the films assigned to the three cameras are labeled 12, 14 and 16, respectively. The light inlet opening 8 of the camera B forms the optical center of the system. Two walls 18 and 20, which according to FIG. 1 are arranged in parallel, but this need not necessarily be the case, are arranged so that only those light rays reach the light inlet opening 8 of the camera B which fall through the opening 4 within the mean angle β. Those light rays which fall through the opening 4 within the angle α strike a surface of the wall 18 which is mirrored in order to reflect these light rays to the light entry opening 6 of the camera A. Correspondingly, the light rays passing through the opening 4 within the angle hit the wall 20 and are reflected to the light inlet opening 10 of the camera C. The inner surfaces of the walls 18 and 20 do not reflect any light and only serve to reflect those within the angle f3 to the camera B. As described in the cited patent, thin masks 22 and 24 are arranged at the ends of the walls 18 and 20 facing away from the cameras, each in the plane of the boundary rays entering the camera B, in order to prevent direct light rays reach the side cameras from the part of the scene to be recorded by camera B. If all parallax is to be eliminated, theoretically the optimal position of cameras A and C in relation to camera B and the reflective surfaces of walls 18 and 20 results in a position in which the light inlet opening 8 is the mirror image of the light inlet openings of the two side cameras forms.

In practice it has been shown that better results are achieved leave when you consider the reflective surfaces compared to the theoretical position for one precise optical centering around a small angle in one adjusted in such a direction that the transition zones on the fins widen. By adjusting the z. B. is only 0.06 °, the width of the transition zone Enlarged enough to avoid loss of artwork when zoomed out to avoid the aperture. This slight angle adjustment of the No noticeable parallax is caused in the mirror.

Along both edges of the film 14 and along one edge of each of the fins 12 and 16, vignetted stripes extend which arise when the film is exposed and whose width should correspond to the width of the transition zone. In practice, the width of the vignettes has so far been smaller than the width of the transition zones, and when the images projected with the help of the transition zones are superimposed to connect the parts of the scene, too much light will appear at the edges of the mosaic parts the screen. For a film whose width between the perforations z. B. is around 25.4 mm, the theoretical width of the vignette should be around 1.4 mm on both sides of the film used in camera B; it turns out, however, that the vignette of such a film is only about 0.7 mm wide at medium exposure (aperture 8).

In Fig. 2 is a projected image of an elongated object O shown schematically. The lines 26 and 28 denote the edges of the scene parts, which are projected using films that are copies of films acts, which with the help of the camera arrangement according to F i, g. 1 were recorded. at optimal overlap and vignetting would be lines 26 and 28 on the screen does not appear, and the image of the object O would not appear on the connecting lines be interrupted.

Lines 26 and 28 appear as relatively light, narrow stripes, when the vignetted zones are narrower than the transition zones. This can be done more clearly from Fig. 3 shows where, on a greatly enlarged scale, an edge of an uncorrected th positive or negative film 30 is shown with the camera A after F i g. 1 was recorded; . furthermore, FIG. 3 an edge on the same scale of an uncorrected positive or negative film 32, which by the camera B after F i g. 1 was recorded. In Fig. 4 gives the curve drawn as a solid line 42 the transmittance of the film 32; again. The transition zone on the film 30 is shown in FIG. 3 denoted by 34, while the transition zone of the film 32 at 36 is indicated. The vignetted zone of film 30 where the light transmission curve 42 is drawn in at 38 for the film 30 and at 40 for the film 32. When projecting the films 30 and 32 one must arrange the projectors so that the projected images of the transition zones 34 and 36 of the two films are superimposed. The light passes through the non-vignetted parts with its full intensity the transition zone of each film, and there is just as much light in these zones transmitted as in the main picture area, so that on the screen according to FIG. 2 light stripes appear on lines 26 and 28.

According to the invention, the positive or negative films are treated so that the already mentioned partial vignette is supplemented in such a way that the light permeability drops evenly over the entire width of the transition zone, as shown in FIG. 4th is indicated by the dashed line 42 a. As a result, arise at the connecting lines of the mosaic parts do not have any discontinuities in illuminance. In the case of the in FIG. The arrangement shown schematically in FIGS. 5 and 6 is a negative film 44 produced by means of a suitable mask in such a way that the central part 46, which that part of a. Feature film that lies between the transition zones, is opaque, while the zones 48 on both sides of the central zone assuming the negative film 44 for correcting a production negative the camera B is to serve, between the area of the perforations 50 and the edges of the central zone 46 are progressively veiled. One can use F i, g. 5 too take it as a representation of the mask that is used to prepare the negative film. In this case the central zone 46 would be transparent, and the edge strips 48 would become progressively denser from the central zone 46 to the outer edges will. For different apertures and distance settings of the cameras one prepares a set of negative masking films in which one or two Strips 48 are present, the density of which is graded in the manner described, to allow adaptation to the film in question. The ones used as masks Negatives 44 are then shown in FIG. 6 placed on an exposed production negative, and the production negative is exposed by means of a light source 52 before it is passed on to the development institute.

Another arrangement for generating a vignette of the desired Width is in FIG. 7 shown schematically. In this arrangement there is a mask 54 arranged with a slit 56 over a positive film 58, and the light a Light source 60 passes through a suitable neutral filter 62 and a color filter 64, a lens 66 and the slit 56 on the positive film. The lens 66 is arranged so that they can be pivoted to produce the varying lighting that is desired is to achieve the graduated exposure of the vignette; further is the lens 66 vertically adjustable so that the width of the vignette can be varied.

Another modified arrangement is shown in FIG. 8 shows where an unexposed negative film is exposed on its way to the camera along one or both edges with a light source 68 and through a light wedge 70 ; the wedge 70 can be moved toward and away from the film to vary the width of the resulting vignette. Those skilled in the art will find further arrangements which fall within the scope of the invention and which make it possible to gradually reduce the light transmittance of the edge zones of a film in order to produce vignettes of suitable width.

Claims (6)

Claims: 1. Method for mosaic cinematography and mosaic projection, in the case of the motion pictures of adjacent parts of the scene on several negative film strips be recorded directly or indirectly, so that the images are on the longitudinal edges adjacent parts of the scene overlap and in the overlap zones a first partial vignette is generated during the recording with the help of vignetting devices is, d a -characterized that for the correction of the first partial vignette with respect to Width and intensity gradation a second partial vignette in the overlapping zones the positive or negative films is applied. 2. The method according to claim 1, characterized characterized in that the additional vignette is dimensioned so that the area of the Overall vignetting is increased compared to that of the first vignetting. 3. The method according to claim 1 or 2, characterized in that the additional Vignette in the overlapping zones before copying the developed negative film onto the positive film by exposing the unexposed positive film with in its Intensity graded light is generated. 4. The method according to claim 1 or 2, characterized in that the additional vignette during the copying process is generated before the positive film is developed by inserting a additional regulated gradation of the intensity of the light rays, which the overlap zones of the positive film beyond the light by means of which the vignette was generated on the negative film. 5. The method according to claim 1 or 2, characterized characterized in that the additional vignette is generated by the fact that the exposed Negative film exposed to light in its overlapping zones before developing, whose intensity gradation is regulated, so does the additional vignette in the to generate transition zone. 6. The method according to claim 1, characterized in that that the additional vignette is generated before the exposure of the negative film. In Publications considered: German Auslegeschrift No. 1052 801; British U.S. Patent No. 826,422; USA: Patent Nos. 2,544,116, 2,844,070.