RU2091841C1 - Raster device for viewing of patterns - Google Patents

Abstract

FIELD: optical systems for visual examination of stereoscopic pictures. SUBSTANCE: the device uses a raster screen having a face surface and a working surface with a raster relief made of lens elements, and on the external contour made in the form of a contour of the preset pattern, reflecting layer applied either onto the working surface of the raster relief, or located behind it at a distance providing for creation of patterns of the respective lens elements over its face surface. The raster screen may be made in the form of sections representing the elements of the present pattern installed for movement relative to one another; the reflecting layer may be made on the external contour in the form of a contour of the preset pattern; at least part of the layer reflecting surface corresponding at least to one element of the preset pattern or at least to one section may have a color differing from the color of the rest of the layer reflecting surface. At least one section of the raster screen may have a spacing or/and focus of its lens elements differing from the spacing and/or focus of the lens elements of the other screen sections, at least part of which may be made of color-carrying transparent coating with a color differing from the color of the raster screen material. EFFECT: enhanced convenience in use. 9 cl, 3 dwg

Description

 The invention relates to the field of instrumentation and printing, in particular, to optical systems for visual observation of volumetric images, namely: systems for displaying volumetric variable color images reproduced on a raster screen, and can be used to obtain a variety of printing products, for example, postcards, slides, business cards, advertising booklets and other advertising and printing products with three-dimensional images created above their surface, as well as for obtaining various x multicolor mosaic structures.

A raster device for acquiring images is known, comprising two lenses mounted one after the other for constructing and projecting an image onto a reflective raster screen mounted rotatably at an angle to the plane of the screen, in front of which the lens collective is mounted, and a magnifying glass whose optical axis is inclined relative to the common axis screen and team [1]
However, the known raster device does not provide volumetric color changing images, as if "soaring" above the front surface of the raster screen, and created both in the presence of a real image of the object, and without it. In addition, the known raster device is structurally complex due to the presence of a drive mechanism for rotating the raster screen and a multi-element optical system, moreover, viewing the image in the known raster device is possible only at a certain angle and in the presence of a light source of the actual object.

The closest technical solution is a raster device for obtaining an image containing a raster screen having a front surface and a working surface with a raster relief made of lens elements, with a reflective layer deposited on the raster relief, two lenses mounted in series for imaging on a reflective working relief the surface of the raster screen at an angle to the plane of the screen, in front of which there is a lens collective assembled from a positive bicomplete and a negative plane-concave lens, the flat surface of which is facing the screen, and a magnifying glass whose optical axis is inclined at the common axis of the screen and the collective, the curvature of the adjacent lens surfaces is different, while the raster screen has a front surface and a working surface with a raster relief made from lens elements [2]
However, the known raster device does not provide volumetric color changing images, as if "soaring" above the front surface of the raster screen, and created both in the presence of a real image of the object, and without it. In addition, the known raster device is structurally complex due to the presence of a drive mechanism for rotating the raster screen and a multi-element optical system, moreover, viewing the image in the known raster device is possible only at a certain angle and in the presence of a light source of the actual object.

 A technical positive result of the invention is the expansion of the functionality of the raster device when receiving color three-dimensional changing images above the front surface of the screen.

 The technical result is achieved in that in a raster device for obtaining an image containing a raster screen and a reflective layer, while the raster screen has a front surface and a working surface with a raster relief made of lens elements, the raster screen along the outer contour is made in the form of a predetermined image , and the reflective layer is deposited either on the surface of the raster relief, or is located behind it at a distance that provides images of the corresponding elements above its front surface.

 The reflective layer may be arranged to move from the surface of the raster relief in a vertical plane.

 The reflective layer can be made along the outer contour in the form of a contour of a given image.

 The raster screen can be made of at least two sections in the form of elements of a given image, installed with the possibility of movement relative to each other.

 At least one section of the raster screen can be performed with a step with the focus of its lens elements different from the step and / or focus of the lens elements of the remaining sections of the screen.

 At least one lens element of at least one section of the raster screen can be made with a focus different from the focus of the other lens elements of the corresponding section.

 At least a portion of the reflective surface of the layer corresponding to at least one element of a given image or at least one section may be made with a color different from the color of the rest of the surface of the reflective layer.

 At least a portion of the raster screen may be made of a color-bearing transparent material.

 At least a part of the front surface of the raster screen can be coated with a color-bearing transparent coating with a color different from the color of the material of the raster screen.

 In FIG. 1.2 shows a raster screen in the form of sections; in FIG. 3 is a raster screen in the form of sections with lens elements with different pitch and focus; schematic diagrams of a raster device for image acquisition are presented.

 The raster device for obtaining an image comprises a raster screen 1 having a front surface 5 and a working surface with a raster relief 4 made of lens elements 10, and along the outer contour made in the form of a contour of a given image 8, displaying a layer 3 located behind the working surface of the raster relief 4 at a distance that provides the image 2 of the corresponding lens elements 10 above its front surface 5 (Fig. 1).

 The raster screen 1 can be made in the form of sections 6, which are elements 9 of a given image 8, mounted with the possibility of movement relative to each other, while the reflective layer 3 can be made on the outer contour in the form of a contour of a given image 8, and at least part the reflective surface of the layer 3, corresponding to at least one element 9 of the specified image 8 or at least one section 6, can be made with a color different from the color of the rest of the surface of the reflective layer 3 (Fig. 1,2).

At least one section 6 of the raster screen 1 can be performed with a step i ⁱ or / and focus f ^{i of} its lens elements 10 different from the step L or / and focus F of the lens elements 10 of the remaining sections 6 of screen 1, at least part of which can be made of a color-bearing transparent material 11, while at least part of the front surface 5 of the raster screen 1 can be applied color-bearing transparent coating 12 with a color different from the color of the material of the raster screen 1 (Fig. 3).

 A raster device for receiving images works as follows.

The supplying rays, for example, from the ambient directional or scattered light, are refracted on the front surface 5 of the corresponding lens elements 10 of the raster screens 1, and light beams converted accordingly, depending on the type of raster screen 1 used, after passing through the lens elements 10 of the working surface of the raster relief 4 are multiplied by each icon of the corresponding lens elements 10 into a plurality of beams that interact with the reflective layer 3 deposited on the working surface of the raster relief 4, are reflected from it and, again passing through the lens elements 10 and refracting on the front surface 5 of the corresponding raster screen 1, create a three-dimensional mirror image 2 of the corresponding lens elements 10 of the raster screen 1 in front of its front surface 5 from the side of the incident beam on the distance provided by the focus f ⁱ (F) of the respective lens elements 10 (Fig. 1-3).

 At the same time, the observer sees as a created image a three-dimensional image 8 of the composition of the lens elements 10 of the raster screen 1, for example, in the form of an image of a butterfly “floating” in the air above the front surface 5 of the raster screen 1 and in a color corresponding to the color of the reflecting surface 3, light-transmitting coating 12 (if any) or the color of the material 11 of the raster screen 1 (Fig. 2,3).

 Raster screens 1 can be made in the form of a disk, rectangle, square, regular triangle or hexagon or other geometric shape with a reflective layer 3 applied to the working surface of their raster relief 4. Moreover, the shape attached to the raster screen 1 can correspond to an image, for example, a butterfly ( Fig. 1,2).

 The execution of the raster screen 1 of sections 6, including in the form of image elements 9, makes it possible to obtain a given image 8 with a multi-level arrangement above the front surface 5 of the raster screen 1 of individual elements 9 of a given image 8 by moving sections 6 in horizontal or / and vertical planes without their mutual overlapping. Moreover, when the sections 6 are moved relative to each other, the created predetermined image 8 is created, for example, a butterfly, soaring above the front surface 5, flaps its wings, and, for example, the crocodile collapses its mouth, and so on. friend can be performed according to a given program, for example, computer.

 The preparation of the raster screen 1 is carried out by giving it a given geometric shape, for example, in the form of a given image 8, by molding or corresponding cutting of the edges. After that, the raster screen 1 is divided into separate sections 6, while the latter can be in the form of geometric shapes (if the raster screen 1 is divided, for example, into squares, polygons, ellipses, etc.) or the shape of individual elements 9 of a given image 8, for example, the torso, wings, and the like parts of the butterfly. In the operating position, sections 6 are docked, restoring the original raster screen 1, operating in the same way as described above. After the operation of the raster device sections 6 can be stacked on top of each other, occupying a smaller volume than in working condition, thereby ensuring the compactness of the raster screen 1.

 If the sections 6 are located in the same plane, they are assembled into a single raster screen 1, for example, by gluing or fitting into a single frame.

 As the raster screen 1, a lens raster can be used, for example, with spherical lens elements 10 having a period (pitch), for example 0.2 mm, and made by, for example, casting, pressing, etc. of a transparent material such as glass , quartz, polystyrene polymer material, polymethylmethacrite, and the like. including color-bearing transparent material 11, in accordance with the coloring of the created volumetric predetermined image 8.

The size and distance from the front surface 5 of the raster screen 1 of the created volumetric set image 8 depends on the focal length f ⁱ , F of its lens elements 10. Moreover, individual sections 6 of a single raster screen 1 can be performed with different steps i ⁱ (L) and / or focus f ⁱ (F) of its lens elements (Fig. 3). Moreover, the steps of the lens elements 10, for example, two sections 6, can be performed in a certain ratio, for example 2: 1, which ensures the formation of two different interference patterns, thereby ensuring the creation of a more complex and more aesthetically colorful structure of the generated volumetric predetermined image 8 above the front surface 5 of the corresponding raster screen 1. And the difference in the foci (f ⁱ and F) of the lens elements 10 of the different sections 6 of the raster screen 1 allows you to form a given image 8 above it the target surface 5 multi-level individual elements 9. That is the individual parts of any element 9 of the given image 8 can be at different heights in accordance with the foci f ⁱ , F of individual or groups of lens elements 10 above the front surface 5 of the corresponding section 6 of the raster screen 1. Thus, the elements 9 of the specified image 8, for example, butterflies (trunk, antennae, wings, etc.) can be at different heights relative to the front surface 5 of the corresponding section 6 of the raster screen 1, depending on the foci f ⁱ , F of the lens elements 10.

The manufacture of sections 6 of the raster screen 1 with different foci f ⁱ , F of the lens elements 10 is carried out by manufacturing an appropriate matrix for one or a group of such lens elements 5 using several tools, for example five, forming corresponding recesses in the matrix according to a given program in the matrix of the corresponding lens elements 10. After that, the raster screen 1 is obtained by pouring the finished matrix with a polymerizing transparent varnish, for example, Metafon varnish manufactured by the LIT enterprise in Pereyaslavl-Hall Yes, and its subsequent removal after the polymerization of varnish.

The size and distance from the surface of the three-dimensional image 1 of the raster screen 1 created above the front surface 5 of the 2 corresponding elements 10 with the focal length f ⁱ , F varies depending on the distance at which the reflective layer 3 is located from the working surface of the raster relief 4. In this case, the reflective layer 3 can be applied directly to the working surface of the raster relief 4 of the raster screen 1, for example, by thermal vacuum deposition of aluminum, it can also be located on a certain distance behind it, providing the ability to create images of 2 lens elements 10 above the front surface 5 of the raster screen 1.

 Moreover, the reflective layer 3 can be arranged to move relative to the working surface of the raster relief 4 of the raster screen 1. In this case, the display layer 3 is made, for example, on a base mounted on guides and mounted perpendicular to the working surface of the raster relief 4. Moving the base with a reflective layer 3 in a vertical plane relative to the working surface of the raster terrain 4 can be carried out manually or using a mechanical or electric drive. So, when moving the reflecting layer 3 relative to the working surface of the raster relief 4, for example, according to a predetermined program, the size and distance from the front surface 5 of the created image 2 of the lens elements 10 and the volumetric specified image 8 formed by the outline of the composition of the lens elements 10 obtained with them will be change in a given way.

 The implementation of the reflective layer 3 with the color of the reflective surface corresponding to the individual elements 9 of the given image 8 or separate sections 6 different from the color of the rest of the surface of the reflective layer 3, allows you to create a specified image 8 above the front surface 5 of the raster screen 1, painted in colors corresponding to the painted parts the corresponding part of the reflective surface (Fig. 2). So, for example, the reflecting surface of layer 3 made of aluminum corresponds to silver, golden copper, yellow brass, reddish bronze, grayish-gray steel and molybdenum, etc.

 Application of a color-bearing transparent coating 12, for example, a blue-colored color-bearing transparent lacquer, etc. to a part of the front surface 5 of the raster screen 1. with a color different from the color of the material of the corresponding raster screen 1 allows you to highlight the individual elements of the volume of the specified image 8 in a given color (Fig. 3). It should be noted that in this case, the individual elements 9 of the volumetric predetermined image 8, for example, butterflies, can also have different colors depending on the color of the material 11 involved in the raster screen 1 or / and the color of the coating 12 applied to its front surface 5. Thus, the wings butterflies can be in one or several shades, the head of a different color, the body of the third, etc. (Fig. 2,3).

 In addition to the above-described predetermined image 8 created above the front surface 5 of the raster screen 1, an image of objects other than the above may also be observed, such as a light source (light bulb), an image of the observer himself, for example, his face, the environment of the interior of the room and other similar object , which may be one of the elements in a multi-level composition of the created volumetric color preset image 8, including being at the same time at the corresponding preset level in it, or It is generally not related to the composition of a given image 8.

If it is necessary to invert the image of the object (if any) in the given image 8, as well as the individual elements 9 of the given image 8 themselves, projection lenses can be used that rotate the image of the actual object by 180 ^o and mounted, for example, between the object and the front surface 5 raster screen 1.

A positive technical result of the invention is:
The expansion of the functionality of the raster device when building images above the front surface of the raster screen due to the possibility of creating voluminous multi-level dynamically changing colorful decorative and artistic compositions.

 Providing the possibility of varying the color gamut of the resulting decorative and artistic composition and its apparent change.

 Providing the ability to create printing products with elements that appear when you open it, such as pages that seem to “soar” over the last voluminous colorful multi-level dynamically changing images of literary heroes, etc.

 Providing the ability to create volumetric colorful multilevel dynamically changing “floating” images in the air under scattered light, and observed in a range of angles up to 2 radians.

Claims (9)

 1. A raster device for viewing an image containing a raster screen and a reflective layer, wherein the raster screen has a front surface and a working surface with a raster relief made of lens elements, characterized in that the raster screen along the external contour is made in the form of a predetermined image contour, and the reflective layer is applied either to the surface of the raster relief, or is located behind it at a distance that provides the image of the corresponding lens elements above its front surface th.  2. The device according to p. 1, characterized in that the reflective layer is arranged to move from the surface of the raster relief in a vertical plane.  3. The device according to claim 1, characterized in that the reflective layer is made along the outer contour in the form of a contour of a given image.  4. The device according to p. 1, characterized in that the raster screen is made of at least two sections in the form of elements of a given image, installed with the ability to move relative to each other.  5. The device according to claim 4, characterized in that at least one section of the raster screen is made with a step or focus of its lens elements different from the step or focus of the lens elements of the remaining sections of the screen.  6. The device according to p. 4, characterized in that at least one lens element of at least one section of the raster screen is made with a focus different from the focus of the remaining lens elements of the corresponding section.  7. The device according to claim 4, characterized in that at least a portion of the reflective surface of the layer corresponding to at least one element of a given image or at least one section is made with a color different from the color of the rest of the surface of the reflective layer.  8. The device according to claim 1, characterized in that at least part of the raster screen is made of transparent color-bearing material.  9. The device according to claim 1, characterized in that at least part of the front surface of the raster screen is coated with a transparent transparent coating with a color different from the color of the material of the raster screen.

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