SU576561A1 - Method of producing cinematograph image - Google Patents

Description

one

The invention relates to the field of cinema technology, implemented using holographic methods, and can be used for recording and reproducing moving images in time continuous.

The known systems for recording and reproducing movies, including holographic cinema systems, are based on recording a sequence of static frames that are separated from each other in time 1.

The closest known technical solution to the present invention is a method of obtaining film images by recording a volume hologram on a carrier and restoring it. Its disadvantage is the impossibility of fixing all phases of the moving image (part of them drops out), which significantly degrades the quality of the image being restored then, since there appears abrupt movement of movements 2.

To obtain the possibility of continuous recording in time and reconstructing moving images using the proposed method, a reflection hologram is recorded, continuously moving the carrier relative to the feed of its own light beam. Not a set of frames separated from each other are recorded on the carrier of holograms, but a strip of images merging with each other, smoothly transforming into each other in a continuous carrier.

This makes it possible to eliminate the jump-like character of the reproducible movement and record all its phases. In this way, the quality of the film image is significantly improved in comparison with the existing systems of scientific cinema and cinematography.

The method consists in the fact that a volume reflection hologram is recorded on the section of the longitudinal carrier containing the recording layer.

The invention is illustrated in the drawing, which illustrates the simplest example of the method. Here 1 is the substrate, 2 is the mirror layer, 3 is the photo emulsion, 4 is the diaphragm, 5 is the light beam from the object, 6 is the object.

The light beam 5 from the object 6 is directed onto the carrier, in front of which a diaphragm 4 is placed. As a result, from the point of the object 6, the photoemulsion is given rays at a certain angle corresponding to this point. In the emulsion 3, as a result of reflection of the light flux from the mirror layer 2, the pattern of standing waves, the antinodes of which are parallel to the carrier surface, is recorded, the distance between them depends on the angle of incidence of the light beam, and the intensity on the intensity of this beam.

For different points of object 6, the distance between the antinodes of the interference pattern will be different, and thus the image of all points of the object, spaced but vertical, is recorded in the same area of the carrier. To record a moving image, the carrier is not moved relative to the diaphragm 4 and the light beam 5 in the vertical direction. In this case, the interference pattern, recorded on the next section of the carrier, smoothly matches the interference pattern of the previous section, and changes in the object in time are reflected by a change in the intensity of the interference planes vertically. This ensures that the moving image is continuously recorded.

In order to register the horizontal component of the image, the luminous flux from the object 6 is focused in the horizontal direction on the carrier. It is also possible to record in the horizontal direction a hologram to obtain a three-dimensional image and parallax.

To reproduce the recorded image, the specular layer is removed from the carrier and illuminates it through the diaphragm with a beam of light. The light beam reflected from the carrier, with horizontal focusing or without it, is directed to the reflecting in all or transmitting scattering screen in all directions or only vertically, and the carrier is moved in the vertical direction.

Due to the fact that the reflecting hologram has a high selectivity to wavelength, the carrier can be illuminated with white light during reproduction.

Reflective holograms formed with a mirror can be crawled in monochromatic light. Therefore, it is possible to significantly expand the class of registered objects, if using a light filter to monochromatize the incident light to the carrier. In this case, the object can be illuminated with white light, i.e., not only pavilion shooting with special lighting is possible, but also shooting in open nature.

A color filter can be used to record a color image, which selects three spectral frequency bands.

The mirror layer on the carrier can be

is located not only under the emulsion, but also from its outer side. In this case, the illumination of the photoemulsion should be carried out from the side of the transparent substrate. The mirror layer can also be an external element with respect to the carrier, and it can also be completely absent (when using a reference beam to obtain a reflection hologram.

The use of a mirror layer in a carrier removes the question of the influence of vibration of the apparatus on the hologram recording process, since the pattern of standing waves moves with the oscillating carrier, and the vibration does not affect the hologram recording process.

The positive effect of the application of the invention is that continuous recording and reproduction of moving images are carried out in time. This enhances the quality of the movie image and allows you to capture all its phases, which opens up new possibilities, for example, in scientific cinema, as well as in cinematography. In the invention, it is possible to carry out a more compact recording of information and reduce the speed of movement of the carrier, which will lead to its saving. On

A three-dimensional image in the horizontal direction can be fixed to the carrier, which allows to obtain the effect of volume and parallax during playback. Finally, with continuous movement of the carrier, its lifetime is naturally increased, which, as we know about jump-like movement, is known to be very small.

Claims (2)

1. US Patent No. 3627916, Cl. G 02B 27/00, cl. 350-3.5, publ. 1971. 2. US patent number 3625584, cl. G 02B 27/00, cl. 350-3.5, publ. 1971.