DE933664C - Device for edge adjustment and avoiding the perceptibility of the contact zones of the individual images of a mosaic image when projecting a film by means of several projectors on a screen using masks - Google Patents

Description

Device for adjusting the edge and avoiding the perceptibility of the Zones of contact between the individual images of a mosaic image when projecting a film using multiple projectors on one screen using masks The invention refers to the, mutual adjustment: the edges of separately projected Images. That are a mosaic image of individual images on the common screen without visible lines or zones in the transition areas between two adjacent individual images should result.

They are optical projection devices consisting of several Projectors for projecting .anei: juxtaposing individual images that are on assemble the screen to form a mosaic image, known in which the projectors are arranged in such a way to one another (that those thrown by them on the screen Individual images: overlap each other at their adjacent edges, for which ulberlap zones a mask is provided in each projector, which is in the overlap zone of each Single image causes a uniform light brightness gradation, which essentially complementary to that in the corresponding overlap zone of the immediately adjacent one Is single image, which causes the adjacent individual images to their intersecting edge zones without perceptible border lines in one another pass over.

Because by the fact that one goes through: the mask arrangement the fluoroscopy on the verge of one Gradually decrease the individual image towards the outside and the image transillumination in the overlapping edge zone of the adjacent individual image, can increase to a corresponding extent, the so coordinated add up in the projection Translucency of the two overlapping image edge zones into one Total fluoroscopic strength; those of the neighboring zones on the relevant Equates to single images.

While a (ago with the known projection devices for mosaic images this adjustment of the edges in: the transition areas of adjacent individual images Masks; causing oscillating movements along or against the edge of the image perform, masks are used according to the invention that relate to the to projecting images are immobile and have an edge zone, whose light permeability decreases towards the edge, the widths of these edge zones and the decrease in light transmission to the outside of all masks on the sides, where the partial images touch neighboring images of the mosaic during projection (, same and overlap or even out when projecting.

With the elimination of the complicated drive for the Massken achieved a considerable simplification of the projectors without this the quality of the edge adjustment for the individual images is impaired.

It also contains further advantageous refinements of the invention to see that the mask edge zones with decreasing light transmission from one Material that has the property of a light absorption wedge, and that the change in the light transmission in the mask edge zone with respect to a The line running approximately in the middle of the intersection zone is symmetrical.

In the drawing, Fig. I denotes a schematic representation that shows in general how images of fixed, common masks on one Screen are thrown on the mosaic images are to be generated, Fig. 2 is a diagram, dlas, the difference in light intensities across the intersecting border zones in the case of unsharp mask boundaries, FIG. 3 shows a diagram, Idas the gradation of the Shows light with the masks according to the present invention, Fig. 4 shows a plan view of a Piece of a mask according to the invention, FIG. 5 is a vertical partial section the mask according to 'Fig. 4, where the mask is in contact with the film to be projected, Fig. 6 the calculated curve of the curved inner edge surface of the light absorption wedge on the edge of the mask and that which is sufficient for the technical execution of the inner edge surface Curve of a circular cylinder surface, Fng. 7 is a plan view of a mask similar to that according to Fig. 4 and 5, but intended for the one Mld, next to, the other single images, lying on both sides in mosaic, Fig. 8 is a vertical partial section through the Mask according to FIG. 7, FIG. 9 is a plan view of a portion of a modified mask shape after, the invention; Fig. Ro shows a vertical partial section through the masike according to 'Fig. 9, FIG. 1 a view, similar to that of FIG. 9, showing a mask according to the invention of another modified form, Figure 12 shows a vertical section of the mask according to FIG. 11 and FIG. 13 a schematic view showing the gradation of the light transmittance .at the edges of the. Masks of Figures 4, 7 and i shows i.

Fig. I shows a mask 15 which is attached behind a film 16, an image of which is projected onto a curved screen 17 through a lens i8. In the case of a second projector, a mask 25 behind a film 26, whose image on the screen 17 through a lens 28. Touch films 16 and 26 preferably, the fronts of the masks 15 and: 25; in the case of the schematic representation the FinG. For the sake of clarity, masks and films are a little apart from one another shown. Because of the natural strength of the masks, it is not possible for them to be in the Bülddbene are in focus with the lenses 18 and 28.

Since the masks are not in the same plane as the filin, is the point on which the edges of masks 15 and 25 are focused, in front of or behind the surface of the screen 17, depending on whether, the masks are behind or in front of the films.

With the masks behind the film as shown, one edge of the mask 15 is sharply focused by the line 18 at a location indicated by the reference numeral -3o and the adjacent edge of the mask 25 becomes sharp at 31 accordingly pictured. On the surface of this screen 17, the somewhat blurred images of the masses 15 and 25 are scattered over a zone that extends from a vertical line 33 to. extends to a second perpendicular line 34. This overlapping zone contains alternating light and dark stripes.

Fig. 2 explains the reason for the emergence of this albwechselid light and dark stripes. Beyond line 33, the full light intensity is through Aden projector i8 thrown onto the screen, corresponding to the light value roo in the diagram. To the right of line 33 begins, the blurred image of the edge of mask 15, and the screen lighting by the projector 18 becomes progressively less, such as represented by line 37. Near the;. Edge of the projector 28 on the The screen projected image decreases the light intensity beyond the line 34 accordingly the change in light intensity according to line 38.

All of the umbrella lighting between lines 33 and 34 in the Zone where. yourself, the pictures the mask edges overlap corresponds to the sum of the luminous intensities., those at the intersecting edges of the touching Frames fall on the screen. The screen lighting; resulting from the projection of the respective individual images is shown here by the lines 37 and 38, and since the sum of the ordinates of lines 37 and 38 is not constant everywhere, there is also uneven illumination of the screen between the lines 33 and 34. As a result of the irregularities of the decrease in brightness, which here by lines 37 and 38 are shown, there is a light stripe in the middle between lines 33 and 34, while dark stripes in the immediately adjacent subsequent zones are visible. These @dark streaks can be toned down by letting the edge zones of the individual images overlap more; alber this is undesirable because it reduces the amount of light in the middle between, the lines 33 and 34 is reinforced and the joint between the individual images is even clearer than can be seen in the overall lighting according to FIG. 2, in which the light central stripe about the same as the screen lighting of the pictures outside, the overlapping tales is.

According to the invention allowed IThe edge zones of adjacent individual images intentionally overlap and used -dabei immovable masks with edge zones which ewirken a gradation of light intensity b, which is symmetrical about to that line, leave along their both projectors 50% of the amount of light ,. The gradation of the light from full screen illumination to zero or the lowest light transmittance of the mask is referred to below as the "transparency curve" of the mask edge.

3 shows the permeability curves for the purpose of explanation the desired effect, that of the known use of oscillating Masks is equivalent. In this figure, the light from the right projector takes place from approximately 100 per cent on line 33 'to zero on line 34'. These Change is made along a straight line with respect to the center line 40 of the zone is symmetrical in which the neighboring images on the screen overlap. In Figure 3, this permeability curve is a straight line, but it lies it is obvious that permeability curves of other shapes can be used, as long as the sum of the curves on both sides in the entire zone width of the intersection almost equal to the full light intensity on the screen in the neighboring zones everywhere which is single images. In order to achieve an even gradation of the passage of light as in To achieve Figure 3, a light absorbing wedge is used along the edge of the mask.

Figs. 4 and 5 show a shape of such a light absorption wedge. The arrangement according to these figures consists of a mask made of filter glass 42 is constructed having a curved inner edge L-surface 44 that becomes a Reduction in thickness of the filter glass up to. down to the sharp edge 45. To the To prevent accumulation of dirt on the edge of the mask and damage to the edge 45, a clear transparent glass filling 47 is inserted between the filter glass edges in such a way that that it adapts to the shape of the surface 44 and. she: touched. The filter glass 42 and the clear glass 47 are preferably an inseparable unit with one another tied together.

The film 16 moves across the face of the mask assembly and the light passing through it takes a value of 100 per cent left side of the edge 45 up to about zero at the point from "at which the filter glass 42 reaches its full absorption strength.

The exact curve of the interface 44 can be calculated from the known light transmittance of the filter glass 42 and is different for different types of such glass. The actual shape of this surface 44, calculated for the filter glass N-6 from Bausch & Lomb, is represented in FIG. 6 by the line 5o. In the practical implementation, this curve can approximately be reproduced by a circular cylinder surface, which is represented there by the line 51. . The cylinder surface 51 results in a mask edge "which transmits a bit too much light in some places and at other not enough, the deviations of the transmittance curves of the surface 51 relative to the theoretically perfect Durchläseigkeitsl-, curve, the --SiCH results for the surface 50, but are - imperceptible to a projected image, and therefore, when using the invention, for the sake of convenience and with a view to better monitoring the grinding during manufacture, cylindrical glass surfaces are preferably used.

Fig. 7 and. 8 show, on a smaller scale, a mask similar to that 4 and 5, but with light absorption wedges on both sides of the mask. Such a double-edged mask is used for a single image that is based on overlaps the screen with other images lengthways on two side edges. For those single images of a mosaic that are on one side of the screen and the other images only overlap on one side, it is clear that a light edge along just one overlap zone is sufficient.

Figures 9 and 10 show a modified form of the invention; being a Mask 55 made of a clear see-through. Glass body 57 with an opaque. Shield 58 is combined, which is applied to the front of the glass body 57 or is embedded in it. This opaque shield has a serrated or sawtooth-like edge ', as it is already in the known oscillating masks for Edge adjustment is used when projecting mosaic images, with the height of the prongs or the saw teeth 6o the width of the intersection zone of the Film images corresponds. When the saw teeth are 6o narrow enough and far enough away from the Are removed from the focal point of the screen, they cause a gradation of the Light intensity, which corresponds approximately to that of FIG.

Figures ii and 12 show another modified embodiment of the invention wherein a mask 65 is made from clear transparent glass 67 and provided with a light absorbing coating along its masking edge by applying a thin metal film 68 to one surface of the glass. Adene, metal film, can be applied in a known manner by evaporation of the metal onto the surface of the glass part 67 in such a way that the light permeability is graded and from 100% per year, corresponding to complete clarity of the glass, drops to a zero value where the metal film becomes smelly and uniform enough to prevent any passage of light. The metal film can be applied continuously to the glass 67 by moving the mask in a known manner at a correspondingly variable speed through an evaporation chamber, which is used to modify the mask 65.

FIG. 13 shows a transmission curve 70 for the masks shown in FIGS. This figure is similar to one side of FIG. 3 in that, being a straight line, it differs from it in that this curve never reaches the value zero. The filter glass of the thickness used for the masks! Allows some light to pass through even when it is at its greatest thickness. Tests have shown, however, that the passage of light is imperceptible if its brightness does not rise to more than about 2.5% of the full screen lighting. There is therefore no need to use filter glass of a thickness (which allows the passage of light to be reduced below this value, or to use completely opaque frames for those parts of the filter glass masks that are on the other side of the curved surfaces on which the thickness the light absorption changes evenly.

Claims (3)

PATENT CLAIMS: i. Device for edge adjustment and avoiding the perceptibility of the contact zones of the individual images of a mosaic image when projecting a film by means of several projectors on a screen using masks, which in each projector surround the part of the film image to be projected in such a way that the projected neighboring individual images overlap Edge zones are obtained in which they merge into one another without perceptible delimitation, characterized in that @ i the masks in relation to that to be projected; Original images are immobile and have an edge zone, the light transmission of which decreases towards the edge, the widths of these edge zones and the decrease in light transmission to the outside in all masks, on the sides where the partial images touch neighboring images of the mosaic during projection, are the same. and overlap or even out when projecting. 2. Apparatus according to claim i, characterized in that the Edge zones with decreasing, the light permeability of a material protrude, which has the property of a light absorption wedge. 3. Apparatus according to claim 2, characterized in that the change in the light transmittance in the edge zone of the mask is symmetrical with respect to a line running approximately in the center of the intersection zone. References: British Patent No. 670 11 1 .