KR930010608A - camera - Google Patents

Abstract

The present invention decomposes light information emitted by a subject into stereoscopic light information of two components through optical information decomposing means of light attached to a stereoscopic camera, and records stereoscopic image information on the film, or again stereoscopic image having stereoscopic image information. The optical information emitted by the subject, or the optical information of the two components through an equal width multiple slit grating in which the width of the transparent portion and the opacity portion attached to the stereoscopic movie camera are the same and the array of the grid is arranged perpendicular to the ground. Or three-dimensional optical information through an unequal-width multiple-slit grating where the width of the opaque part is wider than the width of the transparent part and recorded on the positive film, or projected by the projector again to a stereoscopic image. Make or attach light information emitted by a subject to a stereoscopic television camera or a stereoscopic video camera The width of the transparent part and the width of the opaque part are the same, and the arrangement of the lattice is decomposed into stereoscopic optical information through an equal width multi-slit grating arranged with respect to the ground, and then converted into an electrical signal having stereoscopic image information. To the stereoscopic image through the stereoscopic TV receiver of the two images (映像) of the right image (r) and the left image (1) of the optical information or four images of the left image (1₂, 1₁) right Recording of images decomposed into stereoscopic optical information such as stereoscopic projectors or stereoscopic television receivers for projecting stereoscopic image by projecting the optical information of the image (r₁, r₂) or more stereoscopic image optical information on the stereoscopic image reproduction screen, respectively; and It consists of a group of inventions over stereoscopic image reproduction.

Description

camera

Since this is an open matter, no full text was included.

14 is a configuration diagram of a stereoscopic television camera or a stereoscopic video camera which is an embodiment of the present invention, and FIG. 15 is a stereoscopic television receiver which is an embodiment of the present invention using the stereoscopic image reproduction screen 61 of the present invention. Fig. 16 is a block diagram of a rear reflection type stereoscopic television receiver which is an embodiment of the present invention using the first-dimensional stereoscopic image reproduction screen 61 of the present invention, and Fig. 17 is a conventional television receiver. Fig. 18 shows a state in which the ancestors 51 of the color cells of the pixel have a vertical structure, and Fig. 18 shows the ancestry 52 of the color cells of the pixel in the stereoscopic television receiver of the present invention. 55 is a fourth embodiment of the stereoscopic movie of the present invention using the fourth embodiment of the stereoscopic image reproduction screen 81 of the present invention, and FIG. 56 is a cross-sectional view of FIG.

Claims (177)

The collimation of the subject passes through the optical inlet of the stereograph with the right y light inlet including the optical system and the left y light inlet including the optical system. The ratio of the width of the transparent and opaque portions of the grating, which is a means for decomposing stereoscopic optical information, is set to 1: 2 (2y-1), and the optical information of the subject is separated by a predetermined distance in front of the top surface of the stereoscopic apparatus. The image of the subject which has passed through the multi-slit grating arranged vertically and is decomposed into three-dimensional image information, and then converted into an electrical signal, reproduced through the CRT in the received television receiver, and then reproduced. Stereoscopic image reproduction screen, characterized in that the image of the subject having stereoscopic image information is composed of a translucent image plane and a lenticular screen again through an optical system A stereoscopic television system that reproduces stereoscopic images by projecting on y (y is a natural number of 1 or more). The stereoscopic imager according to claim 1, wherein the stereoscopic imager is used to take a picture of a subject decomposed into stereoscopic image information, convert it into an electrical signal, and then transmit it through a CRT in a received television receiver. A stereoscopic image television system for projecting stereoscopic images by projecting images with stereoscopic image information back to a stereoscopic image reproduction screen comprising a translucent image plane and a lenticular screen through an optical system. The stereoscopic reproduction apparatus according to claim 1, wherein the stereoscopic imager is a stereoscopic video imager, which captures an image of a subject decomposed into stereoscopic image information, converts it into an electrical signal, and then reproduces and records it through a CRT in a television receiver. And a stereoscopic image television system for projecting a stereoscopic image by projecting an image having the image information back to a stereoscopic image reproduction screen comprising a translucent image plane and a lenticular screen through an optical system. 2y independent images of varying wide angles at which the subject is photographed by a stereoscopic camera having y left light incidence spheres including the optical system of the right y light incidence sphere including the optical system. Is converted to an electrical signal and reproduced through 2y CRTs in a television receiver that has been transmitted or recorded, and the 2y independent images thus reproduced are again obtained through the optical system. The ratio of 1: is (2y-1) and the three-dimensional image is projected according to the stereoscopic image reproduction screen, which is composed of a translucent image plane and a lenticular screen in a multi-slit grid arranged perpendicular to the ground. A stereoscopic television system that reproduces (y is a natural number of 1 or more). 5. The reproduction according to claim 4, wherein the stereoscopic imager is a stereoscopic television set, and is reproduced through 2y CRTs in a television receiver which receives and transmits each of 2y independent images of varying wide angles at which the subject is photographed by an electrical signal. The 2y independent images reproduced in this way are multiplied by the optical system, and the ratio of the width of the transparent and opaque portions of the grating, which is a means for decomposing stereoscopic optical information, is 1: 2 (2y-1) and is arranged perpendicular to the ground. A stereoscopic television system for reproducing stereoscopic images by projecting onto stereoscopic images grafted screens comprising a slit grating, a translucent imaging surface and a lenticular screen. (Y is a natural number of 1 or more). The stereoscopic imager according to claim 4, wherein the stereoscopic imager is used to reproduce each of 2y independent images of varying wide angles at which the subject is photographed and converted into electrical signals for reproduction through 2y CRTs in a television receiver. The reconstructed 2y independent images are again slit through the optical system, and the ratio of the width of the transparent and opaque portions of the grating, which is a means for resolving stereoscopic optical information, is 1: 2 (2y-1) and is arranged perpendicular to the ground. A stereoscopic television system for reproducing stereoscopic images by projecting onto a stereoscopic image reproduction screen characterized in that the grid comprises a translucent image plane and a lenticular screen. (Y is a natural number of 1 or more). 2y independent images of varying wide angles at which the subject is photographed by a stereoscopic camera having y right light entrance spheres containing the optical system and y left light entrance spheres containing the optical system. The ratio of the width of the transparent and opaque portions of the lattice, which is a means for resolving stereoscopic optical information, to the film through the projector is 1: 2 (2y-1), and the translucent imaging plane is arranged in a multi-slit lattice arranged perpendicular to the ground. A stereoscopic television system for reproducing stereoscopic images by projecting onto stereoscopic image reproduction screens, characterized by consisting of lenticular screens (y being one or more natural numbers). 8. The ratio of the widths of the transparent and opaque portions of the lattice, which is a means for decomposing stereoscopic optical information, to the independent 2y movie films having different wide angles of photographing a subject using the stereoscopic cinematograph. Reproduce stereoscopic images by projecting them in conformity to a stereoscopic image reproduction screen, characterized by consisting of a translucent image plane and a lenticular screen in a multiple slit grid arranged perpendicular to the ground with (比) = 1 (2y-1). Stereoscopic television system (y is one or more natural numbers). The collimation of the subject passes through the optical inlet of the stereograph with the right y light inlet including the optical system and the left y light inlet including the optical system. The ratio of the width of the transparent and opaque portions of the grating, which is a means for decomposing stereoscopic optical information, is set at a distance of 1 to 2y-1 and the optical information of the subject is spaced in front of the top surface of the stereoscopic camera. A stereoscopic image comprising a translucent image plane and a lenticular screen taken through a projector by photographing an image of a subject decomposed into stereoscopic image information by passing through a vertically arranged multiple slit grating on a positive film. Stereoscopic movie system that reproduces stereoscopic images by projecting on a reproduction screen (y is a natural number of 1 or more). 10. The apparatus of claim 9, wherein the stereoscopic imager is a stereoscopic cinematographer, which captures an image of a subject decomposed into stereoscopic image information on a positive film, and the positive film is composed of a semi-transparent image plane and a lenticular screen through a projector. Stereoscopic movie system for reproducing stereoscopic images by projecting onto a stereoscopic image reproduction screen. In recording or transmitting three-dimensional image information, the right y light incidence spheres including the wide-angle system with respect to the subject to obtain 2y three-dimensional image information having different wide angles with respect to the subject. The ratio of the width of the transparent part and the opaque part to the process beam of the collimated subject passing through the optical inlet port of the stereoscopic camera having the left y light inlet port including the optical system Is 1: (2y-1), and passes through a multi-slit grating, which is a means for decomposing stereoscopic optical information arranged perpendicular to the ground, to 2y stereoscopic image information (r₁r₂r₃ …… r _y , 1₁1₂1₃ …… 1 _y ). The right y-dimensional image information (r₁r₂r₃ …… r _y ) and the left y-dimensional image information (1₁1₂1₃ …… 1 _y ) do not overlap and there is no defect in an upper surface that is separated by a certain distance behind the lattice. texture Method of decomposing stereoscopic optical information (y is a natural number of 1 or more). 12. The optical information of the subject collimated through two light incidence openings constructed using the stereo photographic adapter of the present invention when y = 1, wherein the ratio of the width of the transparent portion to the opaque portion If (比) is 1: (2y-1), two stereoscopic image information (r, 1) does not overlap on one surface by passing it through a multi-slit grating which is a stereoscopic optical information decomposition means arranged perpendicularly to the ground. Decomposition method of stereoscopic optical information that allows imaging without defects (y is a natural number of 1 or more). In recording or transmitting three-dimensional image information, the right y light incidence spheres including the wide-angle system with respect to the subject to obtain 2y three-dimensional image information having different wide angles with respect to the subject. The ratio of the width of the transparent part and the opaque part to the process beam of the collimated subject passing through the optical entrance port of the stereoscopic camera having the left y optical entrance port including the optical system Is 1: (2y-1), and passes through a multi-slit grating, which is a means for decomposing stereoscopic optical information arranged perpendicular to the ground, to 2y stereoscopic image information (r₁r₂r₃ …… r _y , 1₁1₂1₃ …… 1 _y ). is not decomposed by a certain distance by the upper surface y of the right three-dimensional image information (r₁r₂r₃ ...... r _y) in the left and y of three-dimensional image (1₁1₂1₃ ...... 1 _y) away in the rear of the grid superposed to be imaged without defect bankruptcy Three-dimensional information is optical resolving means. (Y is the number 1 or more natural). The optical information of the subject collimated through two light incidence spheres constructed using the stereo photographic adapter of the present invention when y = 1, the ratio of the width of the transparent portion to the opaque portion of claim 13 If (比) is 1: (2y-1), two stereoscopic image information (r, 1) does not overlap on one surface by passing it through a multi-slit grating which is a stereoscopic optical information decomposition means arranged perpendicularly to the ground. And means for decomposing stereoscopic optical information without missing parts (y is one or more natural numbers). In reproducing a stereoscopic image, a light incidence sphere of a stereoscopic apparatus having y right incidence spheres containing an optical system and y left incidence spheres containing an optical system with respect to a subject. The ratio of the width of the transparent portion and the opaque portion of the grating, which is a means for decomposing stereoscopic optical information, provided that the optical information of the subject collimated through the entrances is separated by a predetermined distance in front of the upper surface of the stereoscopic apparatus. (2y-1), which passes through the multiple slit grids arranged perpendicular to the ground, and shoots the image of the subject decomposed into stereoscopic image information through the stereoscopic camera, and the captured image is again translucent image plane and lenticular screen. Projection to a stereoscopic image reproduction screen, characterized in that consisting of a method for reproducing a stereoscopic image. (Y is a natural number of 1 or more). In reproducing a stereoscopic image, a light incidence sphere of a stereoscopic apparatus having y right incidence spheres containing an optical system and y left incidence spheres containing an optical system with respect to a subject. The ratio of the width of the transparent portion and the opaque portion of the grating, which is a means for decomposing stereoscopic optical information, provided that the optical information of the subject collimated through the entrances is separated by a predetermined distance in front of the upper surface of the stereoscopic apparatus. (2y-1), which passes through the slit grid arranged vertically with respect to the ground, and shoots the image of the subject decomposed into stereoscopic image information through the stereoscopic camera, and the photographed image is again translucent image plane and lenticular screen. Apparatus for reproducing stereoscopic images by projecting on a stereoscopic image reproduction screen, characterized in that (y is a natural number of 1 or more). In reproducing a stereoscopic image, a wide angle photographed by a stereoscopic camera having y right light entrance spheres containing an optical system and y left light entrance spheres containing an optical system is different for a subject. In each of the left y images and the right y images, the ratio of the width of the transparent portion and the opaque portion is 1: 2 (2y-1), and the multi-slit is a stereoscopic optical information decomposing means arranged vertically with respect to the ground. 3) A method of reproducing a stereoscopic image by projecting on a stereoscopic image reproducing screen comprising a trellis grid, a semi-transparent imaging plane, and a lenticular screen (y is a natural number of 1 or more). In reproducing a stereoscopic image, a wide angle photographed by a stereoscopic camera having y right light entrance spheres including an optical system and y left light entrance spheres including an optical system is different for a subject. Multi-slit, which is a three-dimensional optical information decomposition means in which the y-images on the left and y-images on the right of the independent and opaque portions have a ratio of 1: (2y-1) and are perpendicular to the ground. An apparatus for reproducing stereoscopic images by projecting onto a stereoscopic image reproduction screen, characterized in that it comprises a lattice, a translucent imaging plane, and a lenticular screen (y is a natural number of 1 or more). An optical system 18 for collimating the light information emitted by the subject 17, and decomposition means 20 for decomposing the collimated light information positioned behind the optical system into this light information for realizing a stereoscopic image again. And a film 23 installed on the upper surface 19 existing at a predetermined distance behind the disassembling means 20, so that the stereoscopic camera can record stereoscopic image information. 20. A stereoscopic camera according to claim 19 constructed using multiple slit gratings arranged vertically with respect to the ground as the disassembling means (20). 21. The stereoscopic camera according to claim 20, wherein the grating is composed of a multi-slit grating (20 ') having the same width of the transparent part (100) and the opaque part (200) and both of which are alternately arranged. 21. A stereoscopic camera as set forth in claim 20, wherein the grating is constructed using a photographic plate grating (20 "). 21. The transparent and opaque part of claim 20, wherein the grating is a stereoscopic camera having y right light entrance spheres including an optical system and left y light entrance spheres including an optical system with respect to a subject. Three-dimensional cameras constructed using a ratio of width 1: 1 (2y-1), both of which are grids arranged alternately perpendicular to the ground (y being one or more natural numbers). The optical information of the object 17 collimated through three or more light incidence portions of the optical system 18 on which the light shielding film having a lattice structure having an equal width and an opacity portion arranged vertically with respect to the ground is opaque. The number of light incidence spheres formed on the optical system 18 through an uneven width multiple slit grating arranged vertically with respect to the ground at a constant rate wider than the width of the transparent portion. The stereoscopic optical information is decomposed into the same number of stereoscopic optical information as shown in (iii), and the stereoscopic optical information for realizing the stereoscopic image on the upper surface 19 existing at a certain distance behind the uneven width multiple slit lattice is present. How to get missing. 25. The optical information of the subject 17 according to claim 24, wherein two or more optical systems 18 are provided at a predetermined distance, and three or more light incidence portions formed on each optical system 18 are respectively used. The number of light incidence apertures formed on the optical system 18 through each of the uneven width multiple slit gratings arranged vertically with respect to the ground at a constant rate wider than the width of the transparent portion. Each optical system provided with two or more pieces having three or more pieces of stereoscopic optical information decomposed in the same number as (iii) at a certain distance behind each of the above-described inequality multiple slit gratings. 18) stereoscopic optical information for forming a stereoscopic image on each upper surface (19) corresponding to the image 18). The optical information of the object 17 collimated through three or more light incidence portions of the optical system 18 on which the light shielding film having a lattice structure having an equal width and an opacity portion arranged vertically with respect to the ground is opaque. The number of light incidence spheres formed on the optical system 18 through an uneven width multiple slit grating arranged vertically with respect to the ground at a constant rate wider than the width of the transparent portion. The stereoscopic optical information is decomposed into the same number of stereoscopic optical information as shown in (iii), and the stereoscopic optical information for realizing the stereoscopic image on the upper surface 19 existing at a certain distance behind the uneven width multiple slit lattice is present. Device to make an image. 27. The optical information of the subject 17 according to claim 26, wherein two or more optical systems 18 are provided at a predetermined distance, and three or more light incidence portions formed on each optical system 18 are respectively used. A light incident portion formed on each optical system 18 through each of the uneven width multiple slit gratings arranged perpendicularly to the ground at a constant rate wider than the width of the transparent portion. Each of three or more pieces of stereoscopic optical information decomposed into the same number as is present at a predetermined distance behind each of the inequality width multiple slit grids described above. Apparatus for forming stereoscopic optical information for implementing a stereoscopic image on each of the upper surface (19) corresponding to the optical system (18). The optical information of the object 17 collimated through three or more light incidence portions formed on the optical system 18 having a lattice structured light shielding film having an equal width transparent portion and an opacity portion arranged perpendicularly to the ground is opaque. The number of light incidence portions formed on the optical system 18 through an uneven width multiple slit grating arranged perpendicularly to the ground where the width of the portion is fixed at a ratio equal to the width of the transparent portion. Stereoscopic optical information is decomposed into the same number of stereoscopic optical information as shown in (iii), and the stereoscopic optical information for realizing the stereoscopic image on the upper surface 19 existing at a certain distance behind the uneven width multiple slit lattice is present. Stereo camera to make an image. 29. The stereoscopic camera is a stereoscopic television camera according to claim 28. 29. The stereoscopic camera is a stereoscopic cinematograph. 29. The stereoscopic camera is a stereoscopic camera according to claim 28. 29. The optical information of the subject 7 according to claim 28, wherein two or more optical systems 18 are provided at a predetermined distance, and three or more light incidence units formed on each optical system 18 are respectively used. A light incident portion formed on each optical system 18 through each of the uneven width multiple slit gratings arranged perpendicularly to the ground, the width of which is equal to the width of the transparent portion. Each of three or more pieces of stereoscopic optical information decomposed into the same number as is present at a predetermined distance behind each of the above inequality multiple slit lattice. The stereoscopic imager for forming stereoscopic optical information for realizing a stereoscopic image on each of the upper surface (19) corresponding to the optical system (18). 33. The stereographer according to claim 32, wherein the stereographer is a stereoscopic television setter. 33. The stereoscopic camera is a stereoscopic movie camera. 33. The stereoscopic camera is a stereoscopic camera according to claim 32. Uneven width multiple slits in which the optical information of the subject 17 collimated through the optical system 18 without the light shielding film is arranged vertically with respect to the ground where the width of the opaque portion is fixed at a constant ratio to the width of the transparent portion. Decomposed into stereoscopic optical information through the grating, the stereoscopic optical information for forming a stereoscopic image on the upper surface 19 existing at a certain distance behind the inequality multiple slit lattice to form an image . 37. The optical information of the subject 17 in which at least two or more optical systems 18 are provided at a predetermined distance and collimated through each of the optical systems 18 is such that the width of the opaque portion is constant than that of the transparent portion. After each unequal multiple slit grating, each stereoscopic optical information decomposed through each unequal multiple slit grating arranged vertically with respect to the wide ground at a rate is described above. 3. A method of allowing stereoscopic optical information to form a stereoscopic image on each image surface 19 corresponding to two or more optical systems 18 provided at a plurality of distances. Unequal width multiple slits in which the optical information of the subject 17 collimated through the optical system 18 without the light shielding film is arranged perpendicularly to the ground where the width of the opaque portion is less than the width of the transparent portion. Decomposed into stereoscopic optical information through the grating, so that the upper surface 19 existing at a constant distance behind the inequality multiple slit grating to form a stereoscopic optical information for realizing a stereoscopic image . 39. The optical information of the subject 17 is provided with two or more optical systems 18 at a constant distance, and the optical information of the subject 17 collimated through each of the optical systems 18 is constant in width than the transparent portion. After each unequal multiple slit grating, each stereoscopic optical information decomposed through each unequal multiple slit grating arranged vertically with respect to the wide ground at a rate is described above. An apparatus for allowing stereoscopic optical information to form a stereoscopic image on each image surface (19) corresponding to each of two or more optical systems (18) provided at a plurality of distances. Unequal width multiple slits in which the optical information of the subject 17 collimated through the optical system 18 without the light shielding film is arranged perpendicularly to the ground where the width of the opaque portion is less than the width of the transparent portion. Stereoscopic information that is decomposed into stereoscopic optical information through the grating and forms stereoscopic optical information for realizing stereoscopic images on the upper surface 19 existing at a constant distance behind the inequality width multiple slit grating. Camera. 41. The stereoscopic camera is a stereoscopic television camera. 41. The stereoscopic camera is a stereoscopic movie camera. 41. The stereoscopic camera is a stereoscopic camera according to claim 40. 41. The optical information of the subject 17 according to claim 40, wherein two or more optical systems 18 are provided at a predetermined distance and collimated through the respective optical systems 18, wherein the width of the opaque portion is constant than the width of the transparent portion. After each unequal multiple slit grating described above, each stereoscopic optical information decomposed through each unequal multiple slit grating arranged perpendicular to the ground at a rate A stereoscopic imager which allows stereoscopic optical information for forming a stereoscopic image to be imaged on each of the upper surfaces 19 corresponding to the two or more optical systems 18 provided at a predetermined distance. 45. The stereoscopic camera is a stereoscopic television camera. 45. The stereoscopic camera is a stereoscopic movie camera. 45. The stereoscopic camera is a stereoscopic camera according to claim 44. The optical information of the subject collimated through the optical system 18 passes through the stereoscopic optical information decomposing means 20 to be decomposed into stereoscopic optical information, and is present at a predetermined distance behind the stereoscopic optical information decomposing means 20. A method of allowing stereoscopic optical information for recording a stereoscopic image to be recorded on the film (23) installed on the upper surface (19). A method according to claim 48, wherein the stereoscopic optical information decomposing means (20) is used to record stereoscopic optical information using multiple slit gratings arranged perpendicular to the ground. 50. The apparatus of claim 49, wherein the grating is a multi-slit grating 20 'having the same width of the transparent part 100 and the opaque part 200, and both of which are alternately arranged. Way. A method according to claim 49, wherein the grating is a photographic grating (20 ") so that stereoscopic optical information is recorded. 50. The transparent unit according to claim 49, wherein the grating is a stereoscopic imager having y right light entrance spheres including an optical system and y left light entrance spheres including an optical system with respect to a subject. A method of causing three-dimensional optical information to be recorded by using a lattice having a width ratio of 1: 2 (2y-1), both of which are arranged alternately perpendicular to the ground. (Y is a natural number of 1 or more) ). The optical information of the collimated subject 17 through the optical system 18 is passed through the stereoscopic optical information decomposing means 20 for realizing a stereoscopic image, and decomposed into stereoscopic optical information, behind the stereoscopic optical information decomposing means 20. A stereoscopic image for realizing a stereoscopic image created by developing an exposed film obtained by recording decomposed stereoscopic optical information as one image in one frame on the film 23 provided on the upper surface 19 existing at a predetermined distance. Film with visual information. A film according to claim 53, wherein stereoscopic image information obtained by using multiple slit gratings arranged perpendicular to the ground as the stereoscopic optical information decomposing means (20) is recorded. 55. The film according to claim 54, wherein the grating is a multi-slit grating (20 ') having the same width of the transparent part (100) and the opaque part (200) and both of which are alternately arranged. 55. The film according to claim 54, wherein stereoscopic image information obtained by using the grating is a photographic plate grating (20 ") is recorded. 55. The transparent portion of claim 54 wherein the grating is a stereoscopic imager having y right light entrance spheres containing the optical system and y left light entrance spheres containing the optical system with respect to the subject. A film that records stereoscopic image information using a ratio of the width of the opaque portion to a width of 1: 2 (2y-1) and the two of which are arranged perpendicularly to the ground (y is a natural number of 1 or more). The optical information of the collimated subject 17 through the optical system 18 passes through the stereoscopic optical information decomposing means 20 again, and is positioned on the upper surface 19 existing at a predetermined distance behind the optical information decomposing means 20. Stereoscopic photograph to obtain a stereoscopic image by placing a lenticular screen on a photograph on which a stereoscopic image information obtained by developing and printing the stereoscopic image information decomposed into a negative film is recorded as one image in one frame. How to realize. 60. The stereoscopic photographic realization method according to claim 58, wherein the stereoscopic optical information decomposing means (20) obtains a stereoscopic image using a multi-slit grating arranged perpendicularly to the ground. 60. The stereoscopic photo realization according to claim 59, wherein the lattice is a multi-slit lattice 20 'having the same width of the transparent part 100 and the opaque part 200, and both of which are alternately arranged. Way. 60. The method of claim 59, wherein the grating is a photographic plate grating (20 ") to obtain a stereoscopic image. 60. The transparent portion of claim 59 wherein the grating is a stereoscopic imager having y right light entrance spheres containing an optical system and y left light entrance spheres containing an optical system with respect to the subject. A stereoscopic image realization method in which a ratio of the width of an opaque portion to a width of 1: (2y-1) is obtained by using a grid in which both are arranged alternately perpendicular to the ground. Natural mission.) The optical information of the collimated subject 17 through the optical system 18 passes through the stereoscopic optical information decomposing means 20 again, and is positioned on the upper surface 19 existing at a predetermined distance behind the optical information decomposing means 20. A stereoscopic image made by placing a lenticular screen on a picture on which a stereoscopic image information obtained by developing and printing the film, which is made by recording three-dimensional optical information decomposed on a negative film, is recorded in one frame. 64. The lenticular screen according to claim 63, wherein the stereoscopic optical information decomposing means 20 is made from a negative film on which stereoscopic image information obtained using multiple slit gratings arranged perpendicular to the ground is recorded. Three-dimensional picture of the top. 65. The negative film of claim 64, wherein the grating is a multi-slit grating 20 'having the same width of the transparent part 100 and the opaque part 200, and both of which are alternately arranged. Stereoscopic photograph made by placing a lenticular screen on a photograph of stereoscopic image information. 66. A stereoscopic image made by placing a lenticular screen on a photograph with stereoscopic image information made from a negative film on which stereoscopic image information obtained using the grating is a photographic plate grating (20 ") is recorded. 65. The transparent portion of claim 64, wherein the grating is a stereoscopic imager having y right light entrance spheres containing the optical system and y left light entrance spheres containing the optical system with respect to the subject. The stereoscopic image information made from the negative film where the ratio of the width of the opaque portion to the width ratio of 1: 2 (2y-1) and both of which are alternately arranged perpendicular to the ground is recorded. 3D photographs made of lenticular screens on photographs (y is one or more natural numbers). A stereoscopic image advertising device made by placing a lenticular screen on a photograph on which stereoscopic image information is recorded from a negative film on which stereoscopic image information is recorded, and then installing a lighting device on the back of the lenticular screen. 2y independent images of different angles in which the subject is photographed by a stereoscopic camera having y right light incident parts including the optical system and y left light incident parts including the optical system. This film was filmed through a projector, and the ratio of the width of the transparent and opaque portions of the lattice, which is means for resolving stereoscopic optical information, is 1: 2 (2y-1), and the multi-slit lattice and translucent imaging arranged perpendicular to the ground. 3D image advertisement device for reproducing a stereoscopic image by projecting onto a stereoscopic image reproduction screen, characterized in that the surface and the lenticular screen. (Y is a natural number of 1 or more). The collimation is performed through the light incidence part of a stereoscopic camera having y light incidence parts on the right side including the optical system and y light incidence parts on the left side including the optical system. The ratio of the width of the transparent and opaque portions of the grating, which is the means for decomposing stereoscopic optical information, is set at a distance of 1 to 2y-1 in front of the top surface of the stereoscopic apparatus. A stereoscopic image comprising a translucent image plane and a lenticular screen, which are photographed on a positive film, which passes through a vertically arranged multiple slit grid and is decomposed into stereoscopic information. Stereoscopic image advertising device that reproduces stereoscopic images by projecting images on screen (y is a natural number of 1 or more). The optical information of the collimated subject 17 through the optical system 18 passes through the stereoscopic optical information decomposing means 20 again, and is positioned on the upper surface 19 existing at a predetermined distance behind the optical information decomposing means 20. 3D image information for realizing a three-dimensional image obtained by developing and printing the film made by the three-dimensional optical information decomposed to the negative film 23 to be recorded in one frame. A photograph in which stereoscopic image information obtained as a negative film on which stereoscopic image information obtained by using a multi-slit grating in which stereoscopic optical information decomposing means (20) is arranged perpendicular to the ground is recorded. 73. The negative film of claim 72, wherein the grating is a multi-slit grating 20 'having the same width of the transparent part 100 and the opaque part 200, and both of which are alternately arranged. Photographs recorded with stereoscopic information obtained from the image. 72. The picture recorded with the stereoscopic image information obtained by the negative film in which the stereoscopic image information obtained by using the grating is a photographic plate grating (20 ") is recorded. 73. The stereoscopic imager of claim 72, wherein the grating is a stereoscopic imager having y right light entrance spheres containing the optical system and y left light entrance spheres containing the optical system with respect to the subject. The stereoscopic image information made from the negative film in which the stereoscopic information obtained by using the ratio of the width of the opaque portion is 1: 2 (2y-1) and both are arranged in alternating perpendicular to the ground is recorded. (Y is a natural number of 1 or more). Stereoscopic optical information decomposing means 20 and a transparent conductive film for implementing a stereoscopic image for converting optical information of the collimated subject 17 through the optical system 18 into an electrical signal having stereoscopic image information. 37) and an imaging tube of a stereoscopic television camera comprising an imaging surface 35 composed of a face plate, a stereoscopic optical information decomposing means 20, a transparent conductive film, and an optical conductive film. . 77. An imaging tube having an image pickup surface according to claim 76, wherein the stereoscopic optical information decomposing means (20) is composed of multiple slit gratings arranged perpendicularly to the ground. 78. The image pickup tube according to claim 77, wherein the grating is a multi-slit grating (20 ') having the same width of the transparent part (100) and the opaque part (200) and both of which are alternately arranged. 78. The imaging tube having an image pickup surface according to claim 77, wherein the grating is a photographic plate grating (20 "). 78. The transparent portion of claim 77 wherein the grating is a stereoscopic television camera having right y light incidence spheres containing an optical system and y left light incidence spheres containing an optical system with respect to the subject. An imaging tube having an imaging plane, wherein the ratio of the width of the opaque part to the width of the film is 1: 2 (2y-1), both of which are arranged alternately perpendicular to the ground (y is a natural number of 1 or more). Stereoscopic optical information decomposing means 20, a transparent conductive film 37, and a photoconductive film 38 for decomposing the optical information of the subject collimated through the optical system 18 into stereoscopic optical information. Or an imaging surface 35 composed of a face plate 36 and a three-dimensional process beam decomposing means 20 and a transparent conductive film 37 and a photoconductive film 38. A stereoscopic television camera or a stereoscopic video camera, which is provided with an imaging tube and can convert optical information of a collimated subject through an optical system 18 located in front of an imaging surface into an electrical signal having stereoscopic image information. 83. A stereoscopic television camera or stereoscopic video camera with an imaging surface according to claim 81, characterized in that the stereoscopic optical information decomposing means (20) consists of multiple slit gratings arranged perpendicular to the ground. 83. A stereoscopic television camera or a stereoscopic television camera having an imaging surface as claimed in claim 82, wherein the grating is a multi-slit grating 20 'having the same width of the transparent part 100 and the opaque part 200, both of which are alternately arranged. Video camera. 83. A stereoscopic television camera or stereoscopic video camera with an imaging surface according to claim 82, wherein the grating is a photographic grating (20 "). 82. The transparent apparatus of claim 82, wherein the grating is a stereoscopic television camera having y right light entrance spheres containing an optical system and y left light entrance spheres containing an optical system with respect to a subject. A stereoscopic television camera or stereoscopic video camera having an imaging surface, wherein the ratio of the width of the negative and opaque portions is 1: 2 (2y-1) and both are arranged alternately perpendicular to the ground. Is one or more natural numbers). Stereoscopic film installed on the upper surface 19 provided at a predetermined distance from the decomposition means 20 through the decomposition means 20 for decomposing the optical information of the subject collimated through the optical system 18 into stereoscopic optical information. Stereoscopic cinematograph that allows continuous recording of images with visual information. 86. The stereoscopic cinemagraph according to claim 86, wherein the stereoscopic optical information decomposing means (20) is a multiple slit grating arranged perpendicular to the ground. 88. The stereoscopic cinematograph according to claim 87, wherein the grating is a multi-slit grating (20 ') having the same width of the transparent part (100) and the opaque part (200). 88. The stereoscopic cinematograph according to claim 87, wherein the lattice is a photographic lattice (20 "). 88. The apparatus according to claim 87, wherein the grating is a stereoscopic cinematograph having a right y light incidence sphere with an optical system and a left y light incidence sphere with an optical system with respect to the subject. Stereoscopic cinematograph using the ratio of the width of the negative and opaque parts to 1: 1 (2y-1), both of which are arranged alternately perpendicular to the ground (y being a natural number of 1 or more). The distance between the two mirrors (24, 25) facing the subject is spaced at a predetermined distance, and the two inner mirrors (26, 27) opposed to the two mirrors are formed at a constant angle (α). The optical information of the subject reflected by the two mirrors 24 and 25 facing back is again reflected by the two inner mirrors 26 and 27 having a constant angle α, which is collimated by the optical system 18 and placed on the upper surface. When it arrives, the light information from the subject passes through two different light paths. Stereo image adapter (29) is formed so that the two images in one place to match, so that one picture can be taken in one frame of the film located on the upper surface. Imaging surface having as one component a stereoscopic optical information decomposing means 20 composed of multiple slit gratings arranged vertically with respect to the ground capable of decomposing the process beam of the collimated subject into stereoscopic optical information through the optical system 18. A recording medium in which stereoscopic image information captured by a stereoscopic television camera or a stereoscopic video camera having an image pickup tube is converted into a code or various types of signals through direct or indirect media to record stereoscopic image information. 93. The recording medium of claim 92, wherein the grating is a multi-slit grating (20 ') having the same width of the transparent part (100) and the opaque part (200) and both of which are alternately arranged. 95. The recording medium of claim 92, wherein the grating is a photo plate grating (20 "). 92. The stereoscopic television camera or stereoscopic video camera of claim 92, wherein the grating has a right y light entrance sphere with optical systems and a left y light entrance sphere with optical systems for the subject. The ratio of the width of the transparent portion to the opaque portion is 1: 2 (2y-1), and the recording medium characterized by the fact that both are arranged alternately perpendicular to the ground (y is a natural number of 1 or more). Anti-reflective coating surface to prevent the projected image from being reflected from the opposite direction of the observer (H), translucent imaging surface to form the projected image and lenticular screen formed with a plurality of cylindrical lenses on one side Stereoscopic image reproduction screen. 98. The viewer according to claim 96, wherein the stereoscopic image reproducing screen has an antireflective coating layer 63 formed on an outer surface opposite to the viewer H, and a translucent imaging surface 65 is formed on the opposite side thereof. Second screen, which is a lenticular screen that is super planar at a thickness f 'equal to the focal length of a plurality of fine cylindrical lenses 67 having only a constant curvature in the horizontal direction directed toward H). Second type stereoscopic image reproduction screen 62 made by combining (66). 98. The stereoscopic image reproduction screen according to claim 96, wherein an air medium layer is formed between the translucent imaging surface of the stereoscopic image reproduction screen and the lenticular screen. 99. The translucent imaging surface 54 of claim 98, wherein the stereoscopic image reproducing screen is formed with an antireflective coating layer 56 on an outer surface opposite to the observer H, and an image with an image having stereoscopic image information formed therein. And a plurality of fine cylindrical lenses 59 having only a constant curvature in a horizontal direction facing the first screen 55 and the translucent imaging surface 54 of the first screen 55. The focal point of the physical lens 59 constituting the second screen 60 is an object distance s, which is composed of a second screen 60 that is a lenticular screen and is a distance of the air layer 57 existing between the two screens. (Iii) A first-dimensional stereoscopic image reproduction screen 61 configured in the same manner as the distance. On the other side of the lenticular screen composed of a plurality of fine cylindrical lenses 70 having only a constant curvature in the horizontal direction directed toward the observer H, a translucent imaging plane 69 for forming an image with stereoscopic image information is provided. Is formed and the third type stereoscopic image is reproduced so that the thickness f 'from the vertex of the cylindrical lens 70 to the semi-transparent imaging surface 69 is equal to the focal length of the cylindrical lens 70. Screen 68. 3D optical information decomposing means having anti-reflective coating surface and 3D optical information decomposing function, and 3D optical information decomposing means having 3D optical information decomposing function and 3D to prevent the projected image reflected from the firefly direction of observer H 3. A stereoscopic image reproduction screen comprising a translucent imaging surface for forming an image decomposed into image information and a lenticular screen in which a plurality of cylindrical lenses are formed on one side. 102. The stereoscopic image reproduction screen of claim 101, wherein an anti-reflective coating surface 74 is formed on the outer surface opposite to the viewer H, and the transparent portion 75 'and the opaque portion 75 " The first screen 77 on which the multi-slit grating 75 or the multi-photographic lattice grating is arranged at an equal width perpendicularly to the ground, and the image decomposed into stereoscopic image information may be formed on the viewer H side. A second screen 78 having a constant thickness 78 'having a semi-transparent imaging surface 76 formed therein and a cylindrical lens 79' having a constant horizontal curvature toward the viewer H are formed. A fourth type stereoscopic image reproduction screen 81 composed of a third screen 79 that is a lenticular screen whose thickness f 'is equal to the focal length of the cylindrical lenses 79'. 102. The three-dimensional image reproducing screen of claim 101 has an antireflective coating surface 94 on the outer side opposite to the viewer H, and an inner side of the transparent portion 93 'and the opaque portion 93 arranged perpendicular to the ground. The first screen 95 and the observer (H) formed with an uneven width multiple slit grating 93 or an uneven width multiple photo plate grating having a width ratio of 1 to 1: 3. The second screen 78 having a constant thickness (78 ') and a cylindrical lens facing toward the observer (H) having a semi-transparent imaging surface 76 formed thereon to form an image decomposed into stereoscopic image information. And a seventh form stereoscopic image reproduction screen (97) consisting of a third screen (79) that is a lenticular screen having a thickness of the focal length (f '). 102. The stereoscopic image reproduction screen according to claim 101, wherein the stereoscopic optical information decomposition means is arranged vertically with respect to the ground. 107. The stereoscopic image reproduction screen according to claim 104, wherein the grating is a multi-slit grating 20 'having the same width of the transparent part and the opaque part 200, both of which are alternately arranged. 107. The stereoscopic image reproduction screen according to claim 104, wherein the grating is a photo plate grating (20 "). 107. The transparent portion according to claim 104, wherein the grating has y number of left image light sources and y number of right image light sources of a subject projected on the screen. A stereoscopic image reproduction screen using a ratio of the width of the opaque portion to a ratio of 1: 2 (2y-1) and the two arranged alternately perpendicular to the ground (y is a natural number of 1 or more). Anti-reflective coating surface that prevents the projected image from being reflected from the opposite direction of the observer H, stereoscopic optical information decomposing means having a stereoscopic optical information decomposition function, and semi-transparent imaging surface and air which forms an image decomposed into stereoscopic image information A stereoscopic image reproduction screen comprising a lenticular screen having a medium layer and a plurality of cylindrical lenses formed on one side thereof. 109. The anti-reflective coating surface 74 is formed on the outer surface opposite to the viewer H, and the transparent portion 75 'and the opaque portion 75 " The first screen 77 and the observer H on which the multi-slit grating 75 or the multi-photographic lattice grating are arranged equidistantly perpendicularly to the ground, and the translucent image so that an image decomposed into stereoscopic image information can be formed. A cylindrical lens 82 having a constant curvature in the horizontal direction facing the second screen 78 having a constant thickness 78 'having an image forming surface 76 and the translucent film 76 of the second screen 78. And a third screen 82 which is a lenticular screen made of '), and the distance f between the translucent imaging surface 76 of the second screen 78 and the third screen 82 is the third screen 82. Is the same as the focal length of the cylindrical lens 82 'and the second screen 78 and the third lens. The fifth aspect stereoscopic image reproducing screen (83), wherein the air layer (85) between the screens (82) is used as a light transmission medium. 109. The stereoscopic image reproducing screen of claim 108 has an anti-reflective coating layer 94 on the outside of the viewer H, with a transparent portion 93 'and an opaque portion 93 " On the first screen 95 and the observer (H) where an uneven width multiple slit grating 93 or an uneven width multiple photographic plate grating having a width ratio of 1: 3 is 1: 3. A second screen 78 having a constant thickness 78 'and a semi-transparent imaging surface 76 of the second screen 78 having a semi-transparent imaging surface 76 on which an image decomposed into stereoscopic image information can be formed. ) Is composed of a third screen 82, which is a lenticular screen composed of cylindrical lenses 82 'having only a constant curvature in the horizontal direction, and is a translucent imaging surface 76 and a third of the second screen 78. The distance F between the screens 82 is the same as the focal length of the cylindrical lens 82 'constituting the third screen 82 and the second screen ( An eighth-dimensional stereoscopic image reproduction screen (99), characterized in that an air layer (85) between the third screen (82) and the third screen (82) is used as a light transmission medium. 109. The stereoscopic image reproduction screen according to claim 108, wherein the stereoscopic optical information decomposing means is arranged vertically with respect to the ground. 119. The stereoscopic image reproduction screen according to claim 111, wherein the grating is a multi-slit grating 20 'having the same width of the transparent part and the opaque part 200, which are alternately arranged. 123. A stereoscopic image reproduction screen according to claim 111, wherein the grating is a photographic plate grating (20 "). 117. The transparent part according to claim 111, wherein when the left image light source of the subject projected on the screen is y in number and y in the right image light source, A stereoscopic image reproduction screen using a grid in which the width ratio of the opaque portion is 1: 1 (2y-1) and both are arranged alternately perpendicular to the ground (y is a natural number of 1 or more). Anti-reflective coating surface to prevent the image reflected from the opposite direction of the observer (H), stereoscopic optical information decomposing means having a stereoscopic optical information decomposition function, an air medium layer and a plurality of cylinders formed on one side of the lenticular screen A stereoscopic image reproduction screen comprising a reticular screen having a translucent imaging surface for forming an image decomposed into stereoscopic image information on an ultra-plane at a focal length of a curl lens. 117. The stereoscopic reproduction screen according to claim 115, wherein the anti-reflective coating surface 74 is on the outer side opposite to the viewer H, and the transparent portion 75 'and the opaque portion 75 "of the same width are on the inner side. An observer (H) facing the first screen (77) on which the photographic plate grating or the multi-slit grating (75) is formed, arranged perpendicularly and equilaterally with respect to the grating plane formed on the first screen (77). The translucent imaging surface 87, in which an image decomposed into stereoscopic image information, may be formed on the hyperplane at the focal length f 'of the cylindrical lenses 86' facing toward each other. It is composed of a second screen 86, which is a lenticular screen formed, and uses the air layer 90 having a constant distance 89 between the first screen 77 and the second screen 86 as a light transmission medium. Sixth aspect stereoscopic image reproduction screen (92). 116. The stereoscopic reproduction screen according to claim 115, wherein the anti-reflective coating surface 94 is on the outer side opposite to the viewer H, and on the inner side is a transparent portion 93 'and an opaque portion 93 arranged perpendicular to the ground. The first screen 95 and the first screen 95 in which an uneven multiple slit grating 93 or an uneven multiple photographic plate grating has a width ratio of 1: 3; Decomposed into stereoscopic image information on the hyperplane at the focal length f 'of the cylindrical lenses 86' facing the viewer H, facing the lattice plane formed on the screen 95. It is composed of a second screen 86, which is a lenticular screen on which a translucent imaging surface 87, on which an image can be imaged, is formed, and is formed between the first screen 95 and the second screen 86. A ninth aspect stereoscopic image reproducing screen 101, characterized in that the air layer 90 at a distance 89 is used as a light transmission medium. 117. The stereoscopic image reproduction screen according to claim 115, wherein the stereoscopic optical information decomposing means is arranged vertically with respect to the ground. 119. The stereoscopic image reproduction screen of claim 118, wherein the grating is a multi-slit grating (20 ') having the same width of the transparent part (100) and the opaque part (200). 119. A stereoscopic image reproduction screen according to claim 118, wherein the grating is a photographic plate grating (20 "). 119. The transparent portion of claim 118, wherein the grid is y when the number of left image light sources and y of the right image light source of the subject projected on the screen is y. A three-dimensional image reproduction screen using a grid having a ratio of width of 1 to opacity of 1: 2 (2y-1), which are alternately arranged perpendicular to the ground (y is a natural number of 1 or more). To reduce the perspective inversion of stereoscopic images, the width of the transparent portion and the width of the opaque portion are the same on the hyperplane at the focal length of the cylindrical lens formed on one side of the lenticular screen. Perspective inversion, wherein the multiple slit gratings are arranged in the form of oblique oblique lines at an angle with respect to the long axis of the cylindrical lens constituting the lenticular screen. Stereoscopic reproduction screen for reduction. A first screen 55 having an anti-reflective coating layer 56 formed on an outer surface opposite to the viewer H and a translucent imaging surface 54 for forming an image having stereoscopic image information on the inner surface thereof; and To a second screen 60, which is a lenticular screen composed of a plurality of fine cylindrical lenses 59 having only a constant curvature in the horizontal direction facing the translucent imaging surface 54 of the first screen 55. A first distance configured such that an object distance s, which is a distance of the air layer 57 existing between these two screens, is equal to a focal length of the cylindrical lens 59 constituting the second screen 60. In the three-dimensional image reproducing screen 61, the translucent imaging surface 54 forming the same has a width of the transparent portion and a red transparent portion having the same width, and a slit lattice constituting the second screen 60 in which both are alternately arranged. At a constant angle with respect to the long axis of the radical lens 59 Jin diagonal (斜線) in which the stereoscopic image reproducing screen for an inverted trapezoidal (遠近 反轉) reduced form in the form of. The antireflective coating layer 63 is formed on the outer surface opposite to the observer H, and only the first screen 64 and the transverse constant curvature in the transverse direction toward the observer H are formed. A second type three-dimensional structure made by combining a second screen 66, which is a lenticular screen that forms a hyperplane at a distance f 'equal to a focal length of a plurality of fine cylindrical lenses 67 having In the image reproduction screen 62, a multi-slit lattice in which the width of the transparent portion and the width of the opaque portion are the same on the super plane of the second screen 66, which is a lenticular screen constituting the same, are alternately arranged. For reducing the perspective inversion formed in the form of an oblique oblique line at an angle with respect to the long axis of the cylindrical lens 67 formed on one side of the second screen 66. Stereoscopic image reproduction screen. On the other side of the lenticular screen composed of a plurality of fine cylindrical lenses 70 having only a constant curvature in the horizontal direction directed toward the observer H, a translucent imaging plane 69 for forming an image with stereoscopic image information is provided. Is formed and the third type stereoscopic image is configured such that the thickness f ′ from the vertex of the cylindrical lens 70 to the translucent imaging surface 69 is equal to the focal length of the cylindrical lens 70. On the long axis of the cylindrical lens 70 in which the width of the transparent part and the width of the opaque part of the reproduction screen 68 are the same, and the width of the opaque part is alternately arranged. Stereoscopic image reproduction screen for reducing perspective inversion formed in the form of oblique slanted lines at an angle. The anti-reflective coating surface 74 is formed on the outer surface opposite to the observer H, and the transparent portion 75 'and the opaque portion 75 "of the same width are arranged on the inner surface at an equal width perpendicularly to the ground. The first screen 77 on which the multi-slit grating 75 or the multi-photographic lattice grating is formed, and the translucent imaging surface 76 is formed on the viewer H to form an image decomposed into stereoscopic image information. A cylindrical lens 79 'having a second curvature 78' having a constant thickness 78 'and having only a constant curvature in the horizontal direction directed toward the observer H is formed and the thickness f' is a cylindrical lens. The ultra-planar surface of the lenticular screen, which is the third screen 79, which constitutes the fourth type stereoscopic image reproduction screen 81 including the third screen 70, which is the lenticular screen equal to the focal length of the 79's. The width of the transparent portion and the width of the opaque portion on the flat surface are the same, and both are alternately arranged. Perspective in which the middle slit grating is formed in the form of an oblique oblique line at an angle with respect to the long axis of the cylindrical lens 79 'formed on one side of the lenticular screen that is the third screen 79 Stereoscopic reproduction screen for reducing inversion. An anti-reflective coating surface 74 is formed on the outer surface opposite to the observer H, and on the inner surface, transparent portions 75 'and opaque portions 75 "of the same width are arranged equidistantly perpendicular to the ground. The first screen 77 on which the multi-slit grating 75 or the multi-photographic lattice grating is formed and a predetermined thickness on which the translucent imaging surface 76 is formed so that an image decomposed into stereoscopic image information can be formed on the side of the viewer H. A third lenticular screen composed of cylindrical lenses 82 'having a constant curvature in the horizontal direction facing the second screen 78 of the second screen 78 and the translucent film 76 of the second screen 78; And a distance f between the semi-transparent imaging surface 76 of the second screen 78 and the third screen 82 is a cylindrical lens 82 constituting the third screen 82. ') Is the same as the focal length and the air layer 85 between the second screen 79 and the third screen 82 The width of the transparent portion and the width of the opaque portion are the same on the translucent imaging surface 76 of the second screen 78 of the fifth type stereoscopic image reproducing screen 83, which is characterized in that it is characterized in that both are alternate. Perspective inversion in which multiple slit gratings arranged in the form of oblique inclination are formed at an angle with respect to the long axis of the cylindrical lens 82 'constituting the third screen 82 ( Stereoscopic image reproduction screen for reduced reflex. Photographic plate with anti-reflective coating surface 74 on the outer side opposite the observer H, with the transverse portion 75 'and opaque portion 75 "of the same width arranged vertically and equilaterally with respect to the ground Cylindrical lens 86 'facing toward the viewer H facing the first screen 77 on which the grating or multiple slit grating 75 is formed and the grating plane formed on the first screen 77. The second screen 86, which is a lenticular screen having a translucent imaging surface 87 on which an image decomposed by stereoscopic imaging is formed on a hyperplane at the focal length f 'of the pupil. 6D stereoscopic image reproduction, characterized in that the air layer 90 having a constant distance 89 between the first screen 77 and the second screen 86 is used as a light transmission medium. Transparent on the translucent imaging surface 87, which is the superplane of the lenticular screen, which is the second screen 86, which constitutes the screen 92). Multiple slits gratings having the same width and width of the opaque portion and the two arranged alternately with respect to the long axis of the cylindrical lens 86 'constituting the lenticular screen as the second screen 86 A stereoscopic image reproduction screen for reducing perspective inversion formed in the form of oblique diagonal lines. There is an antireflective coating layer 94 on the outer side opposite to the observer H, and on the inner side the ratio of the width of the transparent portion 93 'and the opaque portion 93 "arranged perpendicular to the ground is 1: An image decomposed into three-dimensional image information of an observer H and a first screen 95 having three uneven width multiple slit gratings 93 or an uneven width multiple photographic plate grating are formed. The focal length f 'of the cylindrical screen 79' towards the viewer H and the second screen 78 of constant thickness 78 'with a translucent imaging surface 76 which may be formed. The width of the transparent portion on the super plane of the lenticular screen, which is the third screen 79 of the seventh form stereoscopic image reproducing screen 97 consisting of the third screen 79, which is a lenticular screen having a thickness of On the one side of the lenticular screen, which is the third screen 79, a multi-slit lattice in which the widths of the opaque parts are the same and the both are alternately arranged. 3. A stereoscopic image reproduction screen for reducing perspective inversion formed in the form of an oblique oblique line at an angle with respect to the long axis of the formed cylindrical lens 79 '. There is an anti-reflective coating surface 94 on the outer surface opposite to the observer H, and on the inner surface, the transparent portion 93 'and the opaque portion 93 "arranged perpendicularly to the ground have a ratio of width. ) Is an image decomposed into stereoscopic image information on the first screen 95 and the observer (H) on which the unequal wide slit grating 93 or the unequal wide multiple photo plate grating having a 1: 3 is formed. The transverse curvature of the second screen 78 and the translucent imaging surface 76 of the second screen 78 and the constant thickness 78 'with the translucent imaging surface 76 formed thereon can be formed. It is composed of a third screen 82, which is a lenticular screen made of cylindrical lenses 82 'having a bay, and the distance f between the translucent imaging surface 76 of the second screen 78 and the third screen 82. Is equal to the focal length of the cylindrical lens 82 'constituting the third screen 82, and the air layer 85 between the second screen 78 and the third screen 82The width of the transparent portion and the width of the opaque portion are the same on the translucent imaging surface 76 which is the second screen 78 of the eighth type stereoscopic image reproducing screen 99 characterized in that it is used as a transmission medium. And a multi-slit grating in which both are arranged alternately in the form of an oblique oblique line at an angle with respect to the long axis of the cylindrical lens 82 'constituting the third screen 82. A stereoscopic image reproduction screen for reducing perspective inversion. There is an anti-reflective coating surface 94 on the outer surface opposite to the observer H, and on the inner surface, the transparent portion 93 'and the opaque portion 93 "arranged perpendicularly to the ground have a ratio of width. The first screen 95 and the grating plane formed on the first screen 95 are formed with an uneven width slit grating 93 or an uneven width multiple photo plate grating having a width of 1: 3. ) Can be imaged on the hyperplane at the focal length f 'of the cylindrical lenses 86' facing toward the observer (H). The second screen 86 is a lenticular screen having a translucent imaging surface 87 formed thereon, and transmits light through the air layer 90 at a predetermined distance 89 between the first screen 95 and the second screen 86. Among the ninth-dimensional stereoscopic image reproduction screens 101, which are used as a medium, an ultra-planar surface of a lenticular screen, which is a second screen 86, which constitutes the same. The cylindrical lens 86 'constituting the lenticular screen, which is the second screen 86, has a multi-slit grating in which the width of the transparent portion and the width of the opaque portion are the same on the transparent imaging surface 87. A stereoscopic image reproduction screen for reducing perspective inversion formed in the form of an oblique oblique line at an angle with respect to the long axis. 3D optical information decomposing means 20, a transparent conductive film 37 and a photoconductive film 38, or face plate 36, which decompose the process report of the subject collimated through the optical system 18 into stereoscopic optical information. And an imaging surface 35 composed of the stereoscopic optical information decomposing means 20, the transparent conductive film 37, and the optical conductive film 38. The optical system of the stereoscopic television camera or the stereoscopic video camera having the imaging tube, The optical information of the collimated subject is converted into an electrical signal having stereoscopic image information and transmitted to the stereoscopic television receiver having the stereoscopic image reproduction screens 61, 62, and 68 of the present invention to reproduce the stereoscopic image. Way. 134. The method according to claim 132, wherein the disassembly means (20) consists of multiple slits gratings arranged perpendicular to the ground. 138. The grating of claim 133, wherein the grating consists of multiple slits gratings 20 'in which alternating transparent portions 100 and opaque portions 200 are alternately arranged. 138. The grid of claim 133 being comprised of a photographic grid 20 ". 133. The transparent portion of claim 133, wherein the grating is a stereoscopic imager having a right y light incident aperture containing an optical system and a left y light incident aperture comprising an optical system with respect to the subject. Consisting of a lattice in which the width and opacity ratios are 1: 2 (2y-1), both of which are arranged alternately perpendicular to the ground (y is a natural number of 1 or more). Magnifies the image from a television system that uses two dichroic mirrors (39, 40) and three CRTs (43, 41, 42) to optically synthesize the color signal of the image. Stereoscopic optical information decomposing means for disposing orphan information of a collimated subject into stereoscopic optical information by providing an optical system 44 and a stereoscopic image reproduction screen 61, 62, 68 of the present invention. Stereoscopic television camera or stereoscopic television camera having imaging tube having image plane as a component (20). Stereoscopic television which converts stereoscopic image information captured by stereoscopic video camera into electrical signal and transmits it to be reproduced in stereoscopic image. seaplane. 138. The anti-reflective coating layer 56 is formed on an outer surface of the stereoscopic image reproducing screen opposite to the observer H, and a translucent imaging surface 54 for forming an image with stereoscopic image information is formed on the inner surface. A lenticular screen composed of a plurality of fine cylindrical lenses 59 having a constant curvature in the transverse direction facing the first screen 55 and the translucent imaging surface 54 of the first screen 55. The focal length of the cylindrical lens 59 constituting the second screen 60 is an object distance s, which is composed of the second screen 60 and the distance of the air layer 57 existing between these two screens. A stereoscopic television receiver which is a first-dimensional stereoscopic image reproduction screen 61 configured to be equal to a distance. 137. The stereoscopic image reproduction screen according to claim 137, wherein the anti-reflective coating layer 63 is formed on the outer surface opposite to the viewer H, and the first screen 64 and the first screen 64 have a transparent plane on the inner surface. The translucent portion 65 facing the transparent plane, which is the inner surface of the lens, is in close contact with the focal length of the plurality of fine cylindrical lenses 67 having only a constant curvature in the horizontal direction toward the observer H. A stereoscopic television receiver as a second type stereoscopic image reproduction screen (62) made by combining a second screen (66), which is a lenticular screen that is super planar, separated by a thickness (f '). 139. The stereoscopic image reproducing screen of claim 137, on the other side of the lenticular screen composed of a plurality of cylindrical lenses 70 having a constant curvature toward the viewer H, forms an image with stereoscopic image information. A third transmissive portion 69 formed and configured such that the thickness f 'from the apex of the cylindrical lens 70 to the translucent portion 69 is equal to the focal length of the cylindrical lens 70 A stereoscopic television receiver, which is a stereoscopic image reproduction screen 68. 137. The system according to claim 137, wherein the stereoscopic optical information decomposing means consists of multiple slits gratings arranged perpendicularly to the ground. 143. The grating of claim 141, wherein the grating consists of multiple slits gratings 20 'in which alternating transparent portions 100 and opaque portions 200 are alternately arranged. 143. The grating of claim 141, wherein the grating consists of a photographic grating 20 ". 145. The transparent portion of claim 141, wherein the grating is a stereoscopic television camera having y right light entrance spheres containing an optical system and y left light entrance spheres containing an optical system with respect to the subject. Consisting of a lattice in which the width and opacity ratios are 1: 2 (2y-1), both of which are arranged alternately perpendicular to the ground (y is a natural number of 1 or more). Body image information picked up by a television camera or stereoscopic video camera having an imaging tube having an imaging surface comprising a stereoscopic optical information decomposing means 20 that can decompose optical information of a collimated subject through an optical system into stereoscopic optical information Is converted into an electrical signal and reproduced as an image having stereoscopic image information again through the three red, green, and blue CRT tubes 45, 46, and 47 in the television. 48, the image having stereoscopic information enlarged on the stereoscopic image reproduction screens 61, 62, and 68 on the front surface of the mirror 48 is matched and imaged, and the image having the stereoscopic image information formed by the present invention is matched. A rear reflective stereoscopic television receiver for viewing stereoscopic images through stereoscopic image reproduction screens (61, 62, 68). 145. The translucent film 54 of claim 145, wherein the stereoscopic image reproducing screen has an antireflective coating layer 56 formed on an outer surface opposite to the viewer H and an image having stereoscopic image information formed on the inner surface thereof. Lenticular consisting of a plurality of fine cylindrical lenses 59 having a predetermined constant curvature in the horizontal direction facing the first screen 55 and the translucent film 54 of the first screen 55 is formed The object distance s, which is composed of a second screen 60, which is a screen, and the distance of the air layer 57 existing between these two screens, is the cylindrical lens 59 and the focal point constituting the second screen 60. Iii) A rear reflection type stereoscopic television receiver which is a first type stereoscopic image reproduction screen 61 configured in the same manner as the distance. 145. The stereoscopic image reproduction screen according to claim 145, wherein the anti-reflective coating layer 63 is formed on the outer surface opposite to the viewer H, and the first screen 64 and the first screen 64 have a transparent plane on the inner surface. The translucent film 65 which is in close contact with the transparent plane, which is the inner surface of the lens, has a focal length of the plurality of fine cylindrical lenses 67 having only a constant curvature in the horizontal direction toward the observer H. A rear reflection type stereoscopic television receiver as a second type stereoscopic image reproduction screen (62) made by combining a second screen (66), which is a lenticular screen, which is separated by the same thickness (f '). 145. The stereoscopic image reproducing screen according to claim 145, on the other side of the lenticular screen composed of a plurality of cylindrical lenses 70 having only a constant curvature in the horizontal direction toward the observer H, forms an image with stereoscopic image information. The translucent film 69 is formed and the thickness f 'from the advantages of the cylindrical lens 70 to the translucent film 69 is equal to the focal length of the cylindrical lens 70. A rear reflection type stereoscopic television receiver which is a three-dimensional stereoscopic image reproduction screen 68. 145. The method according to claim 145, wherein the disassembly means (20) consists of multiple slits gratings arranged perpendicular to the ground. 149. The grating of claim 149, wherein the grating consists of multiple slits gratings 20 'in which transparent portions 100 and opaque portions 200 of the same width are alternately arranged. 149. The grid of claim 149, wherein the grid is comprised of a photographic plate grid (20 "). 149. The transparent portion of claim 149, wherein the grating is a stereoscopic television camera having right y light incidence spheres containing an optical system and y left light incidence spheres containing an optical system with respect to the subject. Consisting of a lattice in which the width and opacity ratios are 1: 2 (2y-1), both of which are arranged alternately perpendicular to the ground (y is a natural number of 1 or more). By installing a lenticular screen on a liquid crystal panel (LCD) of a liquid crystal color television receiver, an electric signal having a stereoscopic image signal transmitted from a stereoscopic imager having stereoscopic optical information resolving means can be received and reproduced as a stereoscopic image. Stereoscopic liquid crystal television receiver. The ancestors of the three color cells arranged in the transverse direction on the fluorescent screen of the television receiver form one lobe 52 and have the same curvature as the conventional panel glass 49 formed at a constant curvature. A stereoscopic television receiver configured to reproduce an image transmitted as an electrical signal having stereoscopic image information as a stereoscopic image. Using two TV cameras installed at a certain distance from the right to the left with respect to the subject or by attaching an existing stereo photo adapter to one TV camera, the right and left images of the photographed subject are converted into electrical signals and transmitted. The right and left images, which are stereoscopic image information received, are separated into a CRT (R) representing a right image (R) and a CRT (L) representing a left image (1), respectively, in the television set. After passing through the respective optical system, each image (r, 1) coming from the L), the anti-reflective coating layer 74 is formed on the outer surface opposite to the viewer (H) A multi-slit lattice 75 or multi-layered on the inner side with transparent portions 75 'and opaque portions 75 "of equal width alternately arranged perpendicularly to the ground The second screen 78 and the observer (H) having a constant thickness on which the first screen (77) on which the photographic plate grating is formed and the translucent film (76) formed to form an image decomposed into stereoscopic image information on the side of the observer (H) The third screen is a lenticular screen formed with a cylindrical lens 79 'having only a constant curvature in the horizontal direction and whose thickness f' is the same as the focal length of the cylindrical lenses 79 '. In accordance with the fourth aspect stereoscopic image reproducing screen 81 composed of (79), it is enlarged and projected so that the right image (r) information is in the right direction E _r and the left image (1) information is in the left direction (E ₁ ). Stereoscopic television receivers, each made to take independent light paths. Transmit by converting the right and left images of the photographed subject into electrical signals using two TV cameras installed at a certain distance from right to left with respect to the subject, or by attaching an existing stereo photo adapter to a single television camera. The right and left images, which are stereoscopic image information received, are separated into a brown tube (R) representing the right image (r) and a brown tube (L) representing the left image (1), respectively, in the television receiver. Each image (r, 1) from (R. L) is passed through each optical system, and then each of the images (r, 1) is coated on the outer surface opposite to the observer (H) 74. A multi-slit lattice 75 having multiple widths 75 'and opaque portions 75 " of equal width arranged alternately perpendicularly to the ground on the inner surface thereof; A first screen 77 having a photo plate grating formed thereon and a second screen 78 having a constant thickness on which a translucent film 76 is formed to form an image decomposed into stereoscopic image information toward the viewer H; And a third screen 82, which is a lenticular screen made of cylindrical lenses 82 'facing the translucent film 76 of the second screen 78 and having only a constant curvature in the horizontal direction. The distance f between the translucent film 76 of the 78 and the third screen 82 is equal to the focal length of the cylindrical lens 82 'constituting the third screen 82, and The projection screen is enlarged to coincide with the fifth type stereoscopic image reproducing screen 83, characterized in that the air layer 85 between the second screen 78 and the third screen 82 is used as an optical transmission medium. The image (r) information can take independent light paths in the right direction (E _r ) and the left image (1) information in the left direction (E ₁ ). Made stereoscopic television receiver. Using two TV cameras installed at a certain distance from the right to the left with respect to the subject or by attaching an existing stereo photo adapter to one TV camera, the right and left images of the photographed subject are converted into electrical signals and transmitted. The right and left images, which are stereoscopic image information received, are separated into a CRT (R) representing a right image (R) and a CRT (L) representing a left image (1), respectively, in the television set. , Each of these images (r, 1) from L) passes through each optical system, and then each of these images (r, 1) passes through each optical system, and then each of these images (r, 1) On the outer side opposite H), there is an anti-reflective coating layer 74. On the inner side, transparent portions 75 'and opaque portions 75 "of the same width are perpendicular to the ground. Cylinders facing the first screen 77 with alternating multiple slit gratings 75 or photographic plate gratings and facing the grating plane formed on the first screen 77 It is a lenticular screen having a translucent imaging surface 87 on which an image decomposed into stereoscopic image information can be formed on a hyperplane at the focal length f 'of the curl lenses 86'. The second screen 86, and the air layer 90 of a constant distance (89) between the first screen 77 and the second screen 86, characterized in that the optical transmission medium The projection image is enlarged and projected in accordance with the sixth type stereoscopic image reproduction screen 92 so that the right image r information can take independent light paths in the right direction E _r and the left image 1 information in the left direction E ₁ , respectively. Stereoscopic television receiver. The right image (1) of the photographed subject can be used as an electrical signal by using two TV cameras spaced from the right to the left with respect to the subject, or by attaching an existing stereo photo adapter (2) to one TV camera. The converted image is received by a television receiver and separated into independent images, respectively, using a cathode ray tube (R) representing the right image (r) and a cathode ray tube (L) representing the left image (1), respectively. And left image (1) through the respective optical system and then enlarged to match the fourth type stereoscopic image reproduction screen 81 or the fifth type stereoscopic image reproduction screen 83 or the sixth type stereoscopic image reproduction screen 92 A method of reproducing a stereoscopic image by projecting and reproducing a stereoscopic image reproduction screen (81, 83, 92). If y is the number of TV cameras installed on the left side of the subject and y is the number of TV cameras installed on the right side, use 2y TV cameras spaced a certain distance from the left to the right with respect to the subject, or y TVs. Each camera is equipped with an existing stereo photo adapter 2, and the left and right y images transmitted by the television receiver are received by the television receiver, and the independent y images on the left side and the y on the right side are received. It is a method that can reproduce 2y independent images by dividing into 2 pieces of image information, and each independent 2y images reproduced by 2y CRTs in a television receiver are passed through each optical system and then reflected on the outer surface opposite to the observer. A grid of grid perpendicular to the ground on which the anti-coat layer is formed and formed on the inner surface The transparent part of the grid in relation to the ratio of the width and width of the opaque part and the number of left and right angle light sources (y) having the image projected on the stereoscopic image reproduction screen of the present invention. The first screen on which the multi-slit grating or the multi-photographic lattice grating has a ratio of 1: 2y-1 to the width of the opaque portion and an image decomposed into stereoscopic image information on the viewer side 3D projection is made in accordance with a stereoscopic image reproduction screen composed of a second screen having a constant thickness and a third screen, which is a lenticular screen having a thickness equal to the focal length of the cylindrical lenses facing the viewer. Reproducing a stereoscopic image through the stereoscopic image reproduction screen. If y is the number of TV cameras installed on the left side of the subject and y is the number of TV cameras installed on the right side, use 2y TV cameras with a certain distance left to right with respect to the subject, or y TVs. Each camera is equipped with an existing stereo photo adapter 2, and the left and right y images transmitted by the television receiver are received by the television receiver, and the independent y images on the left side and the y on the right side are received. The individual 2y images reproduced by 2y CRT in a television receiver are passed through each optical system in a manner that separates the individual image information and reproduces 2y independent images, and then on the outer surface opposite to the observer. Transparency of the grid perpendicular to the ground with antireflective coating layer formed on the inner side Transparent part of the lattice in relation to the ratio of the width of the negative and opaque parts to the number (y) of the left and right angular light sources having the image projected on the stereoscopic image reproduction screen of the present invention. The first screen on which the multi-slit grating or the multi-photographic lattice grating has a ratio of 1: 2y-1 to the width of the opaque portion and an image decomposed into stereoscopic image information on the viewer side It is projected in accordance with a stereoscopic image reproduction screen consisting of a second screen of a constant thickness having an imageable translucent film formed thereon and a third screen which is a lenticular screen having a thickness equal to the focal length of the cylindrical lenses facing the viewer. And a stereoscopic television receiver for reproducing a stereoscopic image through the stereoscopic image reentry screen. Electrical signals of the left and right two images, which are sent after the image is taken by using four TV cameras spaced from the left to the right with respect to the subject, or by attaching an existing stereo photo adapter (2) to each of the two TV cameras. Can be received from a television receiver and separated into two independent images on the left and two images on the right, and the four independent images can be reproduced and reproduced by CRTs in the television receiver (L₂, L₁, R₁, R₂). Four independent images (l₂, l₁, r₁, r₂) are passed through each optical system and then enlarged and collimated four images are provided on the outer surface opposite to the observer (H). On the inner side, an uneven width multiple slit grating 93 having a ratio of 1: 3 of the width of the transparent portion 93 'and the opaque portion 93 "arranged perpendicular to the ground; The first screen 95 formed with an unequal-width multiple photographic plate grating and a semi-transparent film 76 formed with a semi-transparent film 76 on which an image decomposed into stereoscopic image information can be formed on the viewer H side. A seventh shape stereoscopic consisting of a second screen 78 and a third screen 79, which is a lenticular screen having a thickness equal to the focal length f 'of the cylindrical lenses 79' facing towards the observer H. A stereoscopic television receiver that is enlarged and projected in accordance with an image reproduction screen (97) so as to take independent light paths in two directions (E1 'and E1') on the left side of the two projection (1₁1₂) information on the left. If y is the number of TV cameras installed on the left side of the subject and y is the number of TV cameras installed on the right side, use 2y TV cameras with a certain distance left to right with respect to the subject, or y TVs. The conventional stereo photography adapter 2 is mounted on each of the cameras, and electric signals of the left y images and the right y images transmitted from the television receiver are received by the television receiver, and the independent y images on the left side and the y on the right side are received. It is a method that can reproduce 2y independent images by separating them into individual image information. Each independent 2y images reproduced by 2y CRT tubes in a television receiver are passed through each optical system, and then placed on the outer surface opposite to the observer. A grid perpendicular to the ground on which the antireflective coating layer is formed and formed on the inner surface Transparency of the grid in relation to the ratio of the width of the transparent portion and the opaque portion to the number of left and right angle light sources having an image projected on the stereoscopic image reproduction screen of the present invention. The first screen on which the multi-slit grating or the multi-photographic grating grating having a width-to-noise ratio of 1: 2 (2y-1) is formed, and an image decomposed into stereoscopic image information on the observer's side. And a third screen, which is a lenticular screen composed of a cylindrical screen having a constant thickness in the transverse direction facing the semi-transparent film of the second screen, and a second screen having a predetermined thickness on which an imageable translucent film is formed. The distance between the translucent film of the screen and the third screen is the same as the focal length of the cylindrical lens constituting the third screen, and the air layer between the second screen and the third screen is transferred to the optical transmission medium. Characterized by An enlarged projected to match the stereoscopic image reproducing method for reproducing screen, the stereoscopic image through the stereoscopic image reproduction screen. If y is the number of TV cameras installed on the left side of the subject and y is the number of TV cameras installed on the right side, use 2y TV cameras with a certain distance left to right with respect to the subject, or y units. The conventional stereo photography adapter 2 is mounted on each of the television cameras, and the electric signals of the left y images and the right y images transmitted from the television receiver are received by the television receiver. It is possible to reproduce 2y independent images by separating them into y image information. After passing through each optical system, 2y independent images reproduced by 2y CRT in a television receiver are passed through the optical system, An anti-reflective coating layer is formed on the inner surface of the grid perpendicular to the ground. Transparency of the grid in relation to the ratio of the width of the transparent portion and the opaque portion to the number of left and right angle light sources having an image projected on the stereoscopic image reproduction screen of the present invention. The first screen on which the multi-slit grating or the multi-photographic grating grating having a width-to-noise ratio of 1: 2 (2y-1) is formed, and an image decomposed into stereoscopic image information on the observer's side. And a third screen, which is a lenticular screen composed of a cylindrical screen having a constant thickness in the transverse direction facing the semi-transparent film of the second screen, and a second screen having a predetermined thickness on which an imageable translucent film is formed. The distance between the translucent film of the screen and the third screen is the same as the focal length of the cylindrical lens constituting the third screen, and the air gap between the second screen and the third screen is transferred to the optical transmission medium. Characterized by It is the three-dimensional television receiver for reproducing a stereoscopic image through the stereoscopic image reproducing screen, an enlarged projected to match the three-dimensional image reproduction screen. Electrical signals of the two left and right two images transmitted after using the four television cameras spaced from the left to the right with respect to the subject, or by attaching an existing stereo photo adapter (2) to each of the two television cameras. Can be received from a television receiver and separated into two independent images on the left and two images on the right, and the four independent images can be reproduced and reproduced by CRTs in the television receiver (L₂, L₁, R₁, R₂). Four independent images (1₂, 1₁, r₁, r₂) are passed through each optical system, and then magnified and the four collimated images have an antireflective coating layer 94 on the outer side opposite to the observer (H). On the inner side, an uneven width multiple slit gap having a ratio of 1: 3 of the width of the transparent portion 93 'and the opaque portion 93 "arranged perpendicular to the ground. The first screen 95 in which the ruler 93 or the unequal-width multiple photographic plate lattice is formed and the translucent film 76 in which an image decomposed into stereoscopic image information can be formed on the side of the observer H ( A third lenticular screen composed of cylindrical lenses 82 'having a constant curvature in the horizontal direction facing the second screen 78 of the second screen 78 and the translucent film 76 of the second screen 78; The distance f between the translucent film 76 of the second screen 78 and the third screen 82 is composed of the screen 82 and the cylindrical lens 82 'constituting the third screen 82. Eighth stereoscopic image reproduction, which is the same as the focal length and the air layer 85 between the second screen 78 and the third screen 82 is used as a light transmission medium. The two projection (1₁, 1₂) information on the left is enlarged and projected in accordance with the screen 99 so that the two images (E1₁, E1₂) on the left and the two images (r₁, r₂) on the right Is a stereoscopic television set made to take independent light paths in two directions (E1₁, El2) on the right. If y is the number of TV cameras installed on the left side of the subject and y is the number of TV cameras installed on the right side, use 2y TV cameras with a certain distance left to right with respect to the subject, or y TVs. The conventional stereo photography adapter 2 is mounted on each of the cameras, and the electric signals of the left y images and the right y images transmitted from the television receiver are received by the television receiver, and the independent y images on the left side and the y on the right side are received. It is a method that can reproduce 2y independent images by separating them into individual image information. Each independent 2y images reproduced by 2y CRT tubes in a television receiver are passed through each optical system, and then placed on the outer surface opposite to the observer. Of the grating perpendicular to the ground on which the antireflective coating layer is formed Transparency of the grid in relation to the ratio of the width of the transparent portion and the opaque portion to the number of left and right angle light sources having an image projected on the stereoscopic image reproduction screen of the present invention. A first screen on which a multi-slit grating or a multi-photographic lattice grating having a width-to-noise ratio of 1: 2 (2y-1) and a lattice plane formed on the first screen The second screen is a lenticular screen formed with a translucent image plane where an image decomposed into stereoscopic image can be formed on a hyperplane at the focal length of the cylindrical lenses facing the viewer facing the viewer. And enlarged and projected to match the stereoscopic image reproduction screen, wherein the air layer having a predetermined distance between the first screen and the second screen is used as an optical transmission medium. When reproducing the image How. If y is the number of TV cameras installed on the left side of the subject and y is the number of TV cameras installed on the right side, use 2y TV cameras with a certain distance left to right with respect to the subject, or y TVs. Each of the cameras is equipped with a conventional stereo photo adapter 2, and after receiving images, the electric signals of the left y images and the right y images received from the television receiver are received. It is a method that can reproduce 2y independent images by separating them into y image information. After passing through each optical system, each independent 2y images reproduced by 2y CRT in a television receiver are passed through each optical system. An anti-reflective coating layer is formed on the inner surface of the grid perpendicular to the ground. Transparency of the grid in relation to the ratio of the width of the transparent portion and the opaque portion to the number of left and right angle light sources having an image projected on the stereoscopic image reproduction screen of the present invention. A first screen on which a multi-slit grating or a multi-photographic lattice grating having a width-to-noise ratio of 1: 2 (2y-1) and a lattice plane formed on the first screen A lenticular screen having a semi-transparent imaging surface on which the image decomposed into stereoscopic image information can be formed on the hyperplane at the focal length of the cylindrical lenses facing the viewer. It is composed of a screen, and the projection of the three-dimensional image reproduction screen to match the three-dimensional image reproduction screen, characterized in that the air gap of a certain distance between the first screen and the second screen as a light transmission medium. When reproducing stereoscopic images The key is stereoscopic television receiver. The left two images and the right two images transmitted after using the four TV cameras spaced from the left to the right with respect to the subject or by attaching an existing stereo photo adapter (2) to each of the two TV cameras. The electrical signals of the television receiver can be separated into two independent images on the left and two images on the right, and the four independent images can be reproduced. The CRT, L2, L₁, R₁, Four independent images (1₂, 1₁, r₁, r₂), which were reproduced with R₂), were passed through each optical system, and then enlarged and collimated four images were placed on the outer surface opposite to the observer (H). 94) and on the inner side, an unequal width multiple with a ratio of 1: 3 of the width of the transparent portion 93 'and the opaque portion 93 "arranged perpendicular to the ground. Slender Cylindrical lens facing toward the viewer H, facing the first screen 95 and the grating plane formed on the first screen 95 and the multiple grating 93 or an unequal-width multiple photographic plate grating. A second lenticular screen in which a translucent imaging plane 87 is formed in which an image decomposed into stereoscopic image information can be formed on a hyperplane at the focal length f 'of the 86'. A ninth aspect of the present invention, wherein the air layer 90 having a constant distance 89 between the first screen 95 and the second screen 86 is used as a light transmission medium. The two-dimensional image (1 1, 1₂) information on the left is enlarged and projected to match the shape stereoscopic image reproduction screen 101, and the two images (r₁, r₂) on the left are the two directions on the right. Stereo television set made to take each independent light path of (E1₁, E1₂). Use the four TV cameras spaced a certain distance from the left to the right of the subject, or attach the existing stereo photo adapter (2) to each of the two TV cameras to capture the electrical A signal is received from a television receiver and separated into two independent video images on the left and two video information on the right, and each of the four independent images is reproduced by the CRT in the television receiver (L₂, L₁, R₁, R₂). Four independent images (1₂, 1₁, r₁, r₂) reproduced are passed through each optical system, and then the seventh type stereoscopic image reproduction screen 97 or the eighth type stereoscopic image reproduction screen 99 or the ninth type stereoscopic image Method of reproducing a stereoscopic image through the three-dimensional image reproduction screen (97, 99, 101) by projecting enlarged to match the image reproduction screen (101). When decomposing image information into three-dimensional optical information by using a lattice, y is the number of left, right, and angular light sources irradiated to the lattice. And a multi-slit grating or a multi-photographic plate grating having a ratio of widths of the transparent and opaque portions of the vertical grating being 1: 2 (2y-1). When decomposing image information into three-dimensional optical information by using a lattice, the number of left and right angle light sources irradiated to the lattice is y perpendicular to the ground. A method of decomposing stereoscopic optical information, comprising using a multi-slit grating or a multi-photographic plate grating having a ratio of the width of a transparent part and an opaque part of one grating to be 1: 2 (2y-1). It consists of a front side 137 of the liquid crystal panel 136 and a plurality of cylindrical lenses 140 having only a constant curvature in the horizontal direction toward the front side 137 of the liquid crystal panel 136 and is transparent toward the observer H. A liquid crystal panel including an air layer 139 between the lenticular screens 141 having a flat plane 142 and including a vertex of the cylindrical lens 140 constituting the lenticular screen 141 and an air layer 139. The distance 138 between the image generating unit 135 of 136 is configured to be the same as the focal length of the cylindrical lenses 140 constituting the lenticular screen 141 and such an air layer 139. A stereoscopic liquid crystal television receiver 143, characterized by using?) As an optical transmission medium. On the left side of the positive film 108 where two images of the left top (1) and the right top (r) were taken on the left and right sides of the film in one frame. (1) and a light shielding film 104 are installed around the interface between the upper right side (r) and the concave mirror 102, the light sources 103 and 103 'at the rear of the film 108, An aspherical lens 105, 105 ', a long wavelength light absorbing filter, and a single spherical lens are installed and the right angle prism 109, 109', the mirror 110, 110 'and the image (front) of the film 108 are installed. On the path through the DOVE PRISM (111, 111 ') and the optical system (112, 112') that inverts the left side and post Followed by a stereoscopic projector. Left image (1) and right image (r) on the left and right sides of the film in one frame on the subject. (1) and a light shielding film 104 are installed around the interface between the upper right side (r) and the concave mirror 102, the light sources 103 and 103 'at the back of the film 108, An aspherical lens 105, 105 ', a long wavelength light absorbing filter, and a single spherical lens are installed and the right angle prism 109, 109' and the mirror 110, 110 'and the image (front) of the film 108 are installed. DOVE PRISM (111, 111 ') and the optical system (112, 112') that inverts the left side and the post of the 에 on the path through which light passes The fourth image stereoscopic image reproduction screen 81 or the fifth image stereoscopic image reproduction screen 83 or the sixth image of the right image r and the left image 1 independently and simultaneously Conform to the shape stereoscopic reproduction screen (92) Enlarged image (擴大 映像) by a method for reproducing a stereoscopic image. Left image (1) and right image (r) on the left and right sides of the film in one frame with respect to the subject. (1) and a light shielding film 116 are installed around the interface between the upper right side (r) and the concave mirror 114, the light sources 115 and 115 'at the rear of the film 120, Aspheric lenses 117 and 117 ', a long wavelength light absorbing filter and a single spherical lens are installed, and the right angle prism 121 and 121', the mirror 122 and 122 'and the optical system 123 and 123' are placed in front of the film 120. ) And the mirror (124, 124 ') is a three-dimensional projector installed in sequence along the path through which light passes. Left image (1) and right image (r) on the left and right sides of the film in one frame with respect to the subject. (1) and a light shielding film 116 are installed around the interface between the upper right side (r) and the concave mirror 114, the light sources 15 and 115 'at the rear of the film 120, Aspherical lenses 117 and 117 ', a long wavelength light absorbing filter and a single spherical lens are installed, and right-angle prisms 121 and 121', mirrors 122 and 122 'and optical systems 123 and 123' are placed in front of the film 120. ) And the mirror image (124, 124 ') of the four-dimensional stereoscopic image reproduction screen (81) independently of the right image (r) and the left image (1) by using a three-dimensional projector sequentially installed along the path of light Or a fifth-dimensional stereoscopic image reproduction screen (83) or a sixth-dimensional stereoscopic image reproduction screen (92) to enlarge the image to reproduce the stereoscopic image. Left image (1) and right image (r) on the left and right sides of the film in one frame on the subject. (1) and a light shielding film 132 are installed around the interface between the upper right side (r) and the concave mirrors 125 and 125 'and the light source 126 and 126 behind the film 130. '), Aspherical lens (127, 127'), long wavelength light absorbing filter, single dove lens, and dove for inverting the left side and the right side of the image in front of the film 130. DOVE PRISM (131, 131 '), optical system (133, 133') and a thin prism that changes the optical path by refracting light or HERSCHEL PRISM whose intensity of prism is variable Stereo projector with (134, 134 ') installed in sequence along the light path. Left image (1) and right image (r) on the left and right sides of the film in one frame with respect to the subject. (1) and a light shielding film 132 are installed around the interface between the upper right side (r) and concave mirrors 125 and 125 'and the light source 126 and 126 on the rear side of the film 130. '), Aspherical lens (127, 127'), long wavelength light absorbing filter, and single spherical lens are installed, and the left and right sides of the image are inverted toward the front of the film 130. DOVE PRISM (131, 131 ') and optical system (133, 133') and a thin prism that refracts light to change an optical path or a Hussel prism whose intensity of prism is variable (HERSCHEL PRISM) (134, 134 ') using a stereo projector installed sequentially along the path of light, the upper left image (1) and the upper right image (r) are independently and simultaneously the fourth type stereoscopic image reproduction screen ( 81) or the fifth form Body image reproduction screen 83 or the sixth aspect stereoscopic image reproduction screen 92 is enlarged image (擴大 映像) in correspondence to by a method of reproducing a stereoscopic image. ※ Note: The disclosure is based on the initial application.