RU2604691C2 - Three-dimensional image raster plate - Google Patents

Abstract

FIELD: information technology.

SUBSTANCE: invention relates to three dimensional still image reproducing means and can be used as organizations signages, advertising banners, window displays decoration, buildings decoration, offices and apartments design elements, as well as souvenir articles. Disclosed three-dimensional image raster plate is made in form of transparent material plate with refraction index of more than one, wherein on one of plate large faces or inside plate spot light sources in periodic order are arranged, and on plate opposite face set of spot light filters is arranged, coloring light from spot light sources in each direction in certain colour. In case of spot light sources arrangement inside plate, light filters can be arranged on both sides of plate, forming two independent three dimensional images on each side from plate. Besides, three dimensional image raster plate can be semitransparent, and three-dimensional image will be kind of floating between real objects. Besides, on plate opposite large faces two mutual independent three-dimensional images can be formed.

EFFECT: technical result is simplification and reduced thickness of three-dimensional image plate design, increase of three-dimensional image viewing angle to 180 degrees, higher image brightness, reduced power consumption, as well as reduction of computers computational power required for image creation.

15 cl, 4 dwg

Description

The technical solution relates to means for reproducing a volumetric static image and can be used as signage for organizations, advertising banners, window dressing, decoration of building facades, design elements of offices and apartments, as well as souvenir products.

A device for the formation and observation of dynamic and static three-dimensional images such as holograms. The device contains a laser radiation source, a fiber and holographic optical elements located on the surface of the fiber. The device further comprises a spatial light modulator configured to form a digital hologram, and a device combining a digital electronic control circuit of the spatial light modulator and an interface unit. The elements of the device are located along the optical axis of the device in the direction from the radiation source to the holographic optical element at the output of the device so that the spatial light modulator is located on the optical fiber after the holographic optical element configured to introduce radiation into the optical fiber and to the holographic optical element configured to output radiation from the fiber. The technical result is to ensure the restoration of a three-dimensional image of an object synthesized using software and hardware, the observation of which with the eye should be identical to the observation of real volumetric objects (see patent RU 2525317 C1, IPC G03H 1/10).

A device for reproducing a volumetric image, comprising a matrix light source, consisting of regularly located on the plane of point light sources, and an optically associated information panel consisting of sections with the possibility of each of them forming one of the fragments of the volumetric image. The matrix light source and the information panel are located in planes parallel to each other and fixed in space relative to each other. Between the matrix light source and the information panel there is a light-absorbing grating consisting of volume cells made with the possibility of light from one point source, respectively, only on one section of the information panel. The technical result consists in expanding the observation zone of a three-dimensional image, eliminating its distortions and making it possible to look around it (see patent RU 2304295 C2, IPC G02B 27/22).

Known optical Golenko transformer for converting a single two-dimensional mono-angle image into a three-dimensional image. Optical lens rasters are used, which are used for capturing, printing and reproducing rasterized stereo and / or multi-angle images, with the aperture ratio of cylindrical lenses of the specified lens raster or with the diameter of centrally symmetric lenses of the specified lens raster, comparable with the pixel size of the mono-angle image as an optical transformer converting a single two-dimensional mono-angle image into a three-dimensional image in order to simplify the design of the optical transform torus. (see patent RU 2385477 C2, IPC G02B 27/22).

The disadvantages of the known technical solutions are:

- The high complexity and cost of production of such systems due to the presence of technically complex structural elements.

- Narrow viewing angle of the volumetric image, not covering all possible positions of the viewer's eyes.

- The device in patent RU 2525317 C1, IPC G03H 1/10 requires large computer capacities to calculate the configuration of a computer hologram.

- The device in the patent RU 2385477 C2, IPC G02B 27/22 has a lens raster of centrally symmetric lenses in construction. Each of the lenses is thick and has a large set of distortions and aberrations, thus significantly limiting the image quality and viewing angle.

The technical result of the claimed technical solution is to simplify and reduce the thickness of the plate structure of the three-dimensional image, expand the viewing angle of the three-dimensional image to 180 degrees, increase the brightness of the image, reduce power consumption, as well as reduce the computing power required to create the image of computers. In addition, the raster plate of the three-dimensional image can be translucent, and the three-dimensional image will seem to hang between real objects. In addition, two mutually independent three-dimensional images can be formed on opposing large faces of the plate.

The technical result is achieved by the fact that:

1. In a raster plate of a three-dimensional image made in the form of a plate of a transparent material with a refractive index greater than unity, point objects emitting light or point objects reflecting or scattering light propagating inside the transparent material of the plate are placed periodically on one of the large faces of the plate due to the effect of total internal reflection, and on the opposite side of the plate there is a set of point light filters, with each individual point filter about paints a ray of light from a point object in its direction into a color corresponding to the element of the volumetric image displayed by this particular ray.

2. The plate is made of glass, or plexiglass, or polycarbonate, or acrylic, or crystal.

3. As light emitting point objects, small-sized LEDs are used.

4. Artificially created defects, or damage to the material of the transparent plate, or interspersed with foreign particles, scattering or reflecting the outside of the plate, the light propagating inside the transparent material of the plate due to the effect of total internal reflection, emitted by light sources located on the border of the transparent material are used as point objects. raster plate.

5. As a set of spot filters, a film attached to the plate with ink applied to it was used.

6. The developed film attached to the plate acts as a set of point light filters.

7. The ink applied to the surface of the plate acts as a set of optical filters.

8. In a raster plate of a three-dimensional image made in the form of a plate of a transparent material with a refractive index greater than unity, point objects emitting light or point objects reflecting or scattering light propagating inside the raster plate due to the effect of full internal reflection, and on the surface of the plate there is a set of point light filters, while each individual point light filter paints a ray of light from a point object in its direction in the color corresponding to the element of the volumetric image displayed by this particular beam.

9. The plate is made of glass, or plexiglass, or polycarbonate, or acrylic, or crystal.

10. As light emitting point objects, small-sized LEDs are used.

11. Artificial defects or damage to the material of the transparent plate or inclusions of foreign particles, scattering or reflecting the outside of the plate, the light propagating inside the plate due to the effect of total internal reflection, emitted by light sources located on the border of the transparent material of the raster plate are used as point objects.

12. As a set of spot filters, a film attached to the plate with ink applied to it was used.

13. The developed film attached to the plate acts as a set of point light filters.

14. The ink applied to the surface of the plate acts as a set of optical filters.

15. The set of optical filters is placed on both large faces of the plate, thus creating two volumetric images that are independent of one another on different sides of the plate.

In FIG. 1 shows a general diagram of a raster plate of a three-dimensional image specified in paragraph 1.

In FIG. 2 - the principle of forming a three-dimensional image with a raster plate specified in paragraphs 1-7.

In FIG. 3 - the principle of operation of the raster plate specified in paragraph 4.

In FIG. 4 - the principle of forming a three-dimensional image of the raster plate specified in paragraph 15.

The raster plate of the three-dimensional image in paragraphs 1-7 is shown in FIG. 1-3 and includes a plate of transparent material 1 with a refractive index greater than unity. Plate 1 is also a frame for attaching the remaining structural elements. On one of the large faces of the plate, point light sources 2 are placed in a periodic order. Light filters 3 are placed on the opposite side of the plate. Light filters can be placed either directly on the surface of the plate 1 or on a transparent film adhered to the plate 1. The filters themselves can be ink, or granules of film. In addition, filters can transmit light from point sources without changing its brightness and intensity. In this case, the beam of light in a given direction will remain white. In addition, filters can be black and completely block light rays from point sources in given directions.

In FIG. 2 shows the cross section of the plate of paragraph 1. The rays of light 4 from point sources 2 pass through filters 3, changing their intensity and color. Point light sources can in this case be ultra-small LEDs. Also, at the interface between the media of the plate 1 and the air, the rays 4 are refracted. The rays of light passing through the filters of the same color intersect at point 6, thus forming the imaginary point of the three-dimensional image hanging above the surface of the plate. The other part of the light rays passing through the filters of a different color, if they lay their way behind the transparent plate, intersect at point 5. Thus, at point 5, the actual point of the volumetric image located beyond the surface of the raster plate is formed. More complex volumetric images can be formed from a set of volumetric points. A ray of light 8 from a point source incident on the interface between the media at an angle greater than or equal to the angle of total internal reflection is reflected many times inside the plate and is lost at its ends. This effect does not allow light rays from different point light sources to pass through the same filters. Rays of light incident at an angle slightly less than the angle of total internal reflection are refracted at an angle close to 90 degrees. Thus, it provides an extension of the viewing angle of the volumetric image to 180 degrees.

The filters of the raster plate transmit light not only from the point sources of light of the plate itself, but also the light incident on the plate from the opposite side. Thus, objects located behind it will be partially visible through the plate. The plate will be translucent to the observer on both sides. The volumetric image will be superimposed on the existing background.

In FIG. 3 shows the raster plate indicated in paragraph 4. A white light source 9 is placed at the end of the transparent plate 1. Light from this source propagates inside the plate 1, as in a waveguide, without going beyond it, because he experiences complete internal reflection at the interfaces. Upon reaching artificially created scattering centers 2, light is scattered in all directions. The scattering centers are either artificially created by engraving defects in the transparent material of the plate, or artificially created inclusions of foreign material, on which light from the source 2 is reflected in all directions. Thus, scattering centers are passive point sources of light. The principle of forming a three-dimensional image is similar to the principle for paragraph 1.

In FIG. 4 shows the raster plate indicated in paragraph 15. Point light sources 2 are located inside the transparent plate 1. On both sides of the transparent plate 1 there are light filters. The rays of light 4, passing through the light filters on the upper side of the plate, form a three-dimensional image of points 5 and 6 for an observer looking at the plate from above the figure. The rays of light 4 passing through the lower filters form a three-dimensional image of point 7 for the observer located at the bottom of the figure. In this case, point 7 is not visible to the observer located above, and points 5 and 6 are not visible to the observer located below the figure. The volumetric image visible from below can also be placed both in front of and behind the plate, but in FIG. 4, the ray path for this case is not displayed due to bulkiness.

A raster plate of a volumetric image of a simple design, high brightness, wide viewing angle, low power consumption, small thickness, low required computational costs, with the ability to display two mutually independent volumetric images, with the possibility of transmitting light passing through the plate, will find industrial application.

Claims (15)

1. The raster plate of the three-dimensional image, made in the form of a plate of a transparent material with a refractive index greater than unity, characterized in that on one of the large faces of the plate periodically placed point objects that emit light, or point objects that reflect or scatter light propagating inside the transparent material of the plate due to the effect of total internal reflection, and on the opposite side of the plate there is a set of point light filters, each individual a light filter colors a ray of light from a point object in its direction in a color corresponding to a three-dimensional image element displayed by a given ray. 2. The raster plate of the three-dimensional image according to claim 1, characterized in that the plate is made of glass, or plexiglass, or polycarbonate, or acrylic, or crystal. 3. The raster plate of the three-dimensional image according to claim 1, characterized in that small-sized LEDs are used as light emitting point objects. 4. The raster plate of the three-dimensional image according to claim 1, characterized in that artificially created defects, or damage to the material of the transparent plate, or inclusions of foreign particles, scattering or reflecting the outside of the plate, light propagating inside the transparent material of the plate due to the effect, are used as point objects. total internal reflection emitted by light sources located on the border of the transparent material of the raster plate. 5. The raster plate of the three-dimensional image according to claim 1, characterized in that a film attached to the plate with ink applied to it is used as a set of spot filters. 6. The raster plate of the three-dimensional image according to claim 1, characterized in that a developed film attached to the plate acts as a set of point filters. 7. The raster plate of the three-dimensional image according to claim 1, characterized in that the ink deposited on the surface of the plate acts as a set of optical filters. 8. A raster plate of a three-dimensional image made in the form of a plate of a transparent material with a refractive index greater than unity, characterized in that point objects emitting light or point objects reflecting or scattering light propagating inside the raster plate periodically are placed inside the plate due to the effect of total internal reflection, and on the surface of the plate there is a set of point light filters, while each individual point light filter colors a light beam o point object in its direction in a color corresponding to the displayed data a particular voxel beam element. 9. The raster plate of the three-dimensional image according to claim 8, characterized in that the plate is made of glass, or plexiglass, or polycarbonate, or acrylic, or crystal. 10. The raster plate of the three-dimensional image according to claim 8, characterized in that small-sized LEDs are used as light emitting point objects. 11. The raster plate of the three-dimensional image according to claim 8, characterized in that artificially created defects, or damage to the material of the transparent plate, or interspersed with foreign particles, scattering or reflecting the outside of the plate, the light propagating inside the plate due to the effect of full internal reflections emitted by light sources located at the boundary of the transparent material of the raster plate. 12. The raster plate of the three-dimensional image according to claim 8, characterized in that a film attached to the plate with ink deposited on it is used as a set of spot filters. 13. The raster plate of the three-dimensional image according to claim 8, characterized in that a developed film attached to the plate acts as a set of point filters. 14. The raster plate of the three-dimensional image according to claim 8, characterized in that the ink deposited on the surface of the plate acts as a set of optical filters. 15. The raster plate of the three-dimensional image according to claim 8, characterized in that the set of optical filters is placed on both large faces of the plate, thus creating two independent three-dimensional images from different sides of the plate.

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