RU2017125776A - Stereo display (options), a video camera for stereo shooting and a method for computer-based stereo imaging for this stereo display - Google Patents

Claims (21)

1. A stereo display comprising a single-screen stereo screen made of a spherical or ellipsoid or axially symmetric concave mirror located in front of both eyes of the user to form a left and right frames of a horizontal stereo pair in this mirror, followed by reflection and focusing of light beams by this mirror of this screen image into the estimated area of the focal zone of direct vision of the screen images of the left and right frames of a horizontal stereo pair with the same name User Zami; and containing a horizontal stereopair matrix containing a raster of light-modulating elements, with a controller connected to this matrix for generating this matrix and a video signal (supplied through this controller to these light-modulating elements) of the left and right raster video in the form of a horizontal stereopair; characterized in that the front side of this matrix is located at a calculated distance in front of this mirror of the stereo screen and is oriented relative to this mirror with the possibility of direct clear mirror reflection in this mirror of the video image of a stereo pair from this matrix, forming in this mirror a screen image of the left and right frames in the form of a horizontal stereo pair with subsequent reflection and focusing by this mirror of the light rays of this screen image into the focal zone of clear vision of the left and right frames one stereo pair of the same name the user's eyes; additionally, to eliminate visible geometric distortions (for using a flat matrix), the stereo screen mirror is aspherical, and when using a spherical mirror in the stereo screen, this matrix is made spherical and / or with a row raster of pixel elements of video images of stereo frames formed on this matrix with the estimated distortions of this raster for elimination of visible geometric distortions of the raster of pixel elements of stereo frames generated and directly observed by the user in this Ale stereoscreen; in another embodiment, for the correction of geometric distortions when using a matrix of a video screen with a rectangular row raster of light-modulating pixel elements, a converter is installed in the stereo display for converting a standard video signal (forming a rectangular row raster of pixels on these matrices) into a video signal forming video images of these frames with the calculated geometric distortions of the row pixel raster video elements on this matrix for the subsequent formation of the screen of the mapping of left and right frames of the stereopair in the horizontal mirror stereoscreen for direct stereovision of the left and right frames in the mirror of the stereoscreen user without visible geometric distortions of the line raster and correct stereoperspektivoy and taking into account the distance of stereo and stereo-width of the user's eye. 2. The stereo display according to claim 1, further characterized in that in this stereo display the matrix is made on the basis of an LED matrix with a raster of even and odd rows of RGB LEDs; or a matrix made on the basis of a liquid crystal matrix with a raster of even and odd rows of luminal cells to form pixel elements, and with backlighting of this matrix; in the first embodiment, the electron-optical system of this stereo display is designed to simultaneously form a video image of the left frame of a horizontal stereo pair by any such matrix with its light-modulating elements located on this matrix in even rows, and to form a video image of the right frame of this stereo pair by light-modulating elements located on this matrix in odd lines a raster polarizing filter with a raster of even lines with vertical polarization and odd lines with horizontal polarization is formed on the light-modulating elements of any such matrix; even lines of the light filter are superimposed on even lines of the light-modulating matrix elements for vertical polarization of light beams of the light-modulating elements forming the video image of the left frame, and odd lines of this filter are superimposed on the odd lines of the light-modulating matrix elements for horizontal polarization of light beams of the matrix for light-modulating elements forming the video image of the right frame; all such light beams from this matrix are directed to the entire illumination area of the screen mirror to form a left and right frames of a horizontal stereo pair in this mirror, forming light beams of the corresponding polarization reflected by this mirror, focused by this mirror into the common focal zone of selective clear stereo observation of these screen images left and right frames of a horizontal stereo pair with the same eyes of the user using passive stereo glasses with multidirectional polarization inc for the left eye and right eye; or in the second embodiment, the electron-optical circuit of this stereo display is made for alternating in time frame-by-frame formation of a translucent liquid crystal matrix or LED video matrix of the left and right frames of a horizontal stereo pair; a polarizing light filter is formed on the light-modulating elements of any of these matrices for unidirectional polarization by this light filter of these light beams of all light-modulating elements forming a video image of a left and right frame of a horizontal stereo pair with unidirectional polarization on the matrix; each such light beam is directed to the mirror of the stereo screen for time-lagging illumination of the entire area of this mirror, forming a screen image of the left and right frames of a horizontal stereo pair with unidirectional polarization of light beams of this image, reflected and focused by this mirror into a common focal zone for selective clear stereo observation of these screen images of the left and right frames of a horizontal stereo pair with the same eyes of the user using active polarized glasses eoochkov gate type; additionally, if necessary, in the indicated first and second variants of the stereoscopic electron-optical system with matrixes of a video screen with diffuse light scattering of light beams of LEDs of a standard video screen, a lens or focon-lens raster is formed on the surface of these LEDs to concentrate the light beam of each pixel triad of RGB LEDs into an area stereo screen for repeatedly increasing the visual brightness of the observed stereo image on the stereo screen. 3. The stereo display according to claim 1, further characterized in that the matrix is made of LED with a raster of LEDs located in even and odd lines of this raster; or the matrix is made of liquid crystal with a raster of translucent pixel elements with backlighting, in any of these matrices the light-modulating elements are located in even and odd rows of this raster; the stereoscopic electron-optical system in its first embodiment is designed for the simultaneous formation by light-modulating elements in even lines of any of these matrices - video images of the left frame of a horizontal stereo pair, and light-modulating elements in odd lines - video images of the right frame of this stereo pair; a focon-lens optical raster is formed on the light-modulating elements of this matrix, in which each optical element is made in the form of a single focon with a plano-convex lens or in the form of a pair of foci with a common plano-convex lens; each such trick is designed to capture light beams of light-modulating elements forming a light beam of a color pixel element of the RGB-color video image of the left or right frame; in a pair of focons located nearby horizontally, one focon is located in an even vertical row of the matrix to capture the light beam of the pixel pixel of the video image of the left frame, and another focon is located in the vertical odd row of this matrix to capture the light beam of the pixel pixel of the video image of the left frame; any focone is made in the form of a hollow truncated pyramid with a wide entrance window and a narrow exit window and mirrored inner side surfaces; on the plane of the output windows of all the backgrounds is a raster of flat-convex lenses; each optical element of the raster is intended for conversion by the focus and lens of each widely diverging light beam of the pixel element of the matrix into a narrow diverging light beam directed by this lens into the estimated area of the stereo screen mirror to form in this mirror a screen image of a certain frame of a horizontal stereo pair with subsequent reflection and focusing this mirror of these light beams into the focal zone of direct clear vision of the screen image of the corresponding frame of horizontal stereo pairs s with the same eye of the user. 4. The stereo display according to claim 1, further characterized in that the matrix of the stereo pair for generating video images of the left and right frames of the horizontal stereo pair is made of an LED matrix with a raster of light-modulating elements of RGB colors; or a stereo pair matrix is made of a liquid crystal matrix with backlighting of this matrix; an optical raster is formed on the front surface of the light-modulating elements of any stereopair matrix to concentrate the light beam of each light-modulating element into the calculated area of the stereo screen, which ensures the formation of screen images of the left and right frames of the horizontal stereo pair in the mirror of the stereo screen with subsequent reflection and focusing of these light beams by this mirror into the focal areas of the direct vision of these screen images of the left and right frames with the same eyes of the user; for this, the electron-optical stereo display system is configured to alternately form all light-modulating elements of the matrix of pixel light beams that form video images of alternately left and right frames of one or more horizontal stereo pairs, or pixel elements of stereo images or stereo programs of the same or different content for simultaneous individual or collective stereo monitoring stereo images or stereo programs by one or more Household users on common stereoscreen; a three-layer optical raster is formed on the stereopair video matrix; the first layer of this raster is made of a raster of hollow focons; the second layer of this raster is made of a liquid crystal selective matrix for alternately suppressing and transmitting light beams of pixel elements formed by the light modulating elements of this matrix in each output window of the corresponding focon for selectively extinguishing and transmitting the light modulating cells of the selective matrix the necessary light beams into the lens raster to alternately form pixel elements left and right frames, for this, in this optical raster, each optical element is made in Idea: an integrated hollow focon with a mirror or white opaque inner walls with a common luminous input window covering the area of the light-modulating matrix elements forming alternately a pixel pixel video image of the left and right frames of the stereo pair, this focon is made with two or more luminous output windows, each of these output windows is located at the calculated point in the area of the base of the common microlens of this raster and is closed by a light-modulating cell of the selective matrix, and all these cells in the flaps of the exit windows of this focon are closed by a common plane-convex positive microlens, and each such exit window of this focon is located at the calculated point in the base area of this common microlens, which forms light beams of pixel elements of video images on this raster captured and directed by this microlens to the calculated points stereo screen mirrors for the formation of certain pixel elements of the corresponding screen image by these light beams, followed by reflection and focusing of this feces these light beams of the respective pixel element in the display image corresponding to the calculated focal zone direct clear vision screen image frames formed similarly by all the pixel elements of its frame for eye observation of the same name of the corresponding user; in addition, if necessary, the automatic formation of optimal areas and the spatial arrangement of such focal zones for their constant dynamic autonomous alignment with the eyes of each user in the stereo display is equipped with an electron-optical tracking system containing two video cameras for video recording with the left video camera of the image of the left eye of the user, and the right video camera - of his right eyes; a video processor is connected to each video camera to generate signals with spatial coordinates of the location of the pupils of the left and right eyes of the user relative to the same point focal zones of stereo vision, a digital software processor is connected to the video processor to generate control signals supplied to the controller of the liquid crystal selective matrix in this raster for automatic dynamic formation by light-modulating cells of this selective mat optimal light beams that form constantly automatically and dynamically optimal areas and spatial locations of such focal zones, and combining these focal zones with the same eyes of the corresponding user for the possibility of stereo observation from different angles when moving multiple users with individual stereo bases of their eyes with different angles of convergence of the eyes of each stereo monitoring at different distances and in wide angles of field of view. 5. The stereo display according to claim 1, further characterized in that said matrix is located horizontally symmetrically horizontally in front of the stereo screen mirror, and the center of this matrix is located at a calculated distance above or below the main optical axis of this mirror with the possibility of forming a left screen image in this mirror and the right frames of a horizontal stereo pair with subsequent reflection and focusing by this mirror of light beams of these screen images (in free space, respectively, below the lower or upper this matrix) into the estimated area of the focal area of direct clear vision of the screen image of the left frame by the left eye of the user and into the estimated area of the focal zone of direct clear vision of the screen image of the left frame by the right eye of this user. 6. The stereo display according to claim 1, further characterized in that in the stereo display with an LED matrix, on the back of this matrix, all the micro-sites for the location of the light-modulating LEDs on this matrix are opaque and coated with a matte black anti-reflective coating; and between these microplates, luminal cells are formed that are tinted to the level of blackout with the possibility of direct vision through these cells of the screen image in the mirror of the stereo screen when the user does not see the reflections of his eyes in this mirror; the matrix is located in front of the stereo screen mirror horizontally centrally symmetrically to the main optical axis of the stereo screen mirror with the possibility of illuminating the calculated areas of this mirror with pixel light beams of the matrix LEDs to form a left and right frames of a horizontal stereo pair in this mirror with subsequent reflection and focusing of these light beams by this mirror from this screen image through these luminal cells to the focal zone of vision of the screen image of the left-left frame the user's eyes and the focal area of the screen image right frame of vision - right eye of the user. 7. The stereo display according to claim 1, further characterized in that the matrix of this stereo display is made of a translucent liquid crystal matrix with backlight; an optical capacitor is installed in the backlight, covering the entire area of the back side of this matrix; the condenser is made of a positive lens or a Fresnel lens; before this condenser, a lighter is installed, made in the form of: a matrix illuminator from an LED matrix, or from a pair of single LEDs; or of a pair of groups of LEDs, each such illuminator is located at a calculated distance from the back of the matrix and at a calculated distance from the normal to the center of its capacitor to allow LEDs to form any illuminator with a calculated light emission area to form a backlight beam with a calculated incidence angle that illuminates the entire the area of the entrance pupil of the condenser for focusing by this condenser of this light beam into the translucent pixel cells of the matrix under this condenser, forming on this Ritse brightness modulated pixel light beams corresponding video elements stereopair frame, and these light beams are directed to the matrix in the calculated area of mirror of the stereoscreen; and to each any illuminator a controller is connected for programmatically turning on the control signal of the required LEDs for the respective illuminators to form a corresponding stereo pair on the video image matrix; additionally, to reduce the depth of the backlight structure, this backlight is made in the form of cell cells; for mutual light insulation and the possibility of changing the distance from the plane of the matrix to the illuminators in the backlight, these cells are made with thin walls forming telescopically sliding tubes of rectangular or square section located on the back of the matrix next to the shape of honeycombs and the side walls are tight to each other, these walls made anti-reflective with matte black interior surfaces; on the area of the exit windows of all the cells, an LED matrix of a matrix illuminator or a pair of LED illuminators or a pair of illuminators from single LEDs or from groups of LEDs is installed; the output window of each tube encompasses along the contour a part of the back of the matrix with translucent pixel elements on which a separate condenser from a Fresnel lens is mounted; a controller is connected to any illuminator for programmatically turning on the control LEDs of the required LEDs of the corresponding illuminator, forming a beam of light in its cell, directed to the entire area of its condenser of this illumination cell, and this condenser focuses this beam of light of this illumination on all translucent light-modulating pixel cells of this matrices located under this condenser, and these matrix pixel cells modulate pixel light beams forming part of the video image corresponding frame of the stereopair in the matrix; similarly to all illumination cellular cells and a matrix, the video images of the whole left and whole right frames of this stereo pair are alternately formed with the subsequent illumination of each video beam from the matrix of the estimated area of the stereo screen mirror to form the left and right frames of the horizontal stereo pair in this mirror with subsequent reflection and focusing the light beams of these screen images with this mirror into the focal areas of direct clear vision of this screen image Nia left and right frames of a stereo pair of the same name the user's eyes; Electromechanical drives are installed in the stereo display, mechanically connected with the LED matrix of the illuminator or with each LED illuminator; a stereo semi-automatic electronic controller or a manual remote control with a software processor that generates control signals supplied to the controllers of these illuminators and / or mechanical drives for the spatial arrangement of these illuminators relative to the matrix and generates control signals supplied to the controllers of the LED matrix of the illuminator or LED controllers of other illuminators for adjusting incidence angles and beam cross-sectional area light backlights video screen matrix to select the optimum program user such adjustment for optimal alignment of the focal zones of direct clear vision of left and right frames with similar eyes of the user with the location coordinates of his eyes relative to the main optical axis and a center of mirror of the stereoscreen, considering the width of stereobase of his eyes; taking into account the support of zero vertical parallaxes and optimal horizontal parallaxes of the observed screen image for stereo surveillance with increased comfort; in another embodiment of the stereo display for full-fledged stereo surveillance with similar backlights, a matrix illuminator of such a backlight is mounted on an electro-mechanical auto-drive to automatically shift this matrix along a line perpendicular to the matrix; in the stereo display, an electron-optical tracking system is installed, containing two video cameras for video recording of the image of the user's left eye with the left video camera, and his right eye with the right video camera; a video processor is connected to each camcorder to generate signals with spatial coordinates of the location of the pupils of the left and right eyes of the user relative to the same point focal zones of stereo vision, a digital program processor is connected to the video processor to generate control signals supplied to the controller of the LED matrix of the illuminator and to the electromechanical Auto drive LED backlight illuminator matrix for continuous automatic lighting Iterative dynamic program regulation by the tracking system and the backlight of the matrix of the spatial location of the calculated light emission area of the illuminator for auto-adjustment of the tilt angle of the backlight beam to continuously automatically form the optimal area and spatial alignment of the focal zone of the left and right frames with the same eyes of a user or several users for an individual or collective stereo viewing at different distances to erased oekrana from different angles stereovision, taking into account the various stereo users' eyes and taking into account the convergence of individual instant eye corners each user. 8. The stereo display according to claim 1, further characterized in that in this stereo display the matrix is made on the basis of a DLP matrix or a reflective liquid crystal LCOS matrix with a flat or cylindrical or spherical concave shape with frontal illumination of any such matrix; the backlight contains: an optical lens condenser in the form of a flat convex positive lens or a Fresnel lens, or contains a mirror-spherical reflector, each of which is designed to focus and orient light beams from the backlight to the matrix; the backlight contains a fixed or movable illuminator made in the form of an LED matrix illuminator or illuminators in the form of a pair or a pair of groups of lens LEDs, any illuminator is located in front of its condenser or reflector in the calculated three-dimensional coordinates and at the calculated distance; a controller is connected to any illuminator; in the stereo display, a software digital processor is installed and connected to the controllers of these illuminators with a manual controller for turning on the required LEDs of any illuminator with the required brightness for adjusting the light emission area of the light beam of any illuminator, adjusting the light scattering angles of the illuminator light beams, the angle of incidence of any light illuminator on the matrix plane for alternating in time of frame-by-frame formation by light beams of such from illuminators on a DLP-matrix or LCOS-matrix of pixel light beams of video images of the left and right frames of a horizontal stereo pair directed by these matrices into the calculated illumination areas of the stereo screen mirror to alternately form screen images of the left and right frames of this stereo pair in this mirror and with subsequent reflection and focusing by this mirror of the stereo screen of these light beams of this screen image into the calculated focal areas areas of direct clear vision of the left frame - with the left eye of the user and the focal zone of direct clear vision of the right frame - with the right eye about the user; in addition, for full-fledged stereo viewing in wide angles of field of view, an electron-optical tracking system is installed in the stereo-display, containing two video cameras for video shooting with the left video camera of the image of the left eye of the user, and the right video camera - of his right eye, a video processor is connected to each video camera to generate signals with information about spatial the coordinates of the location of the pupils of the left and right eyes of the user relative to the same point focal zones of stereo vision, a digital software processor is connected to the e-processor for generating control signals supplied to, connected to it, the controller of the LED illuminator matrix or the controller of each LED illuminator for automatic electron-optical adjustment by the tracking system of the tilt angles to the plane and the light scattering angles of the light beams of the LED illuminator; in another embodiment and / or in addition to the stereo display, an electromechanical auto-drive, or several electro-mechanical auto-drives, is installed, each separate such auto-drive is mechanically connected to the specified stereo screen or to a common LED matrix of the illuminator or to each individual LED illuminator of this backlight, each auto-drive is connected to this digital software processor for automatic software mechanical control by a tracking system of the spatial location of any such lighting Ithel respect to the center DLP-matrix or LCOS-matrix for continuous automatic adjustment of these auto-drives with mechanical angle of inclination to the plane of the video screen and the matrix light scattering angles of light beams of LED illumination fixture with the distance from the user's eyes to the stereoscreen mirror; and mechanical auto-drives of the stereo screen - to constantly combine the focal zone of vision of the left frame with the left eye of the user and the focal zone of vision of the right frame with the right eye of this user. 9. The stereo display according to claim 1, further characterized in that said horizontal stereopair matrix is made of an LED matrix or a backlit liquid crystal matrix with backlight; an electron-optical stereo display system is configured to simultaneously form any one or two or three identical or different stereo images with any such matrix; on the front surface of this matrix, an optical lens raster is formed of spherical or vertically cylindrical plane-convex lenses; the base of each cylindrical lens is located in the estimated area of the vertical row of the matrix with the estimated number of light-modulating elements of the matrix; or the base of each spherical lens is located in the estimated area of the matrix with the estimated number of light-modulating elements of the matrix; each light-modulating pixel element is located at a calculated point relative to the center of the spherical lens or relative to the vertical center line of the cylindrical lens to form a specific pixel pixel of the video image by this light-modulating element to form a left or right frame of a certain horizontal stereo pair (formed by this matrix) with the ability to capture and orient this the lens of this pixel beam of light into the calculated illumination area of the mirror stereo screen and for forming in this mirror a screen image of the left or right frame of a horizontal stereopair with subsequent reflection and focusing of all such pixel light beams by this mirror, forming a screen image of the whole left or right frame of a horizontal stereopair into the corresponding estimated area of the focal zone of vision of the left or right frame of the horizontal stereopair with the same eye of the corresponding user; similarly, other light-modulating matrix elements are arranged for generating pixel light beams forming other video images of stereo frames and corresponding screen images forming similarly other pairs of focal zones providing simultaneous viewing by different users of stereo pairs of screen images of the same or different content; and for full-fledged individual or collective simultaneous stereo monitoring on a common stereo screen, taking into account the individual distance from each user's eyes to the stereo screen, individual stereo viewing angles, different stereo views of the eyes and instant individual convergence angles of each user's eyes, an electron-optical tracking system is installed in the stereo display for automatic dynamic constant autonomous combining focal zones of vision of the left and right frames with the same eyes mi its user when changing the spatial location of each eye of the user relative to the stereoscreen mirror; the tracking system contains two cameras for video shooting with one camera the image of the left eye of the user, and the second camera for video of his right eye, a video processor is connected to each camera for generating signals with information about the spatial coordinates of the pupils of the left and right eyes of the user relative to the same point focal zones of stereo vision, a digital software processor is connected to this video processor to generate control signals supplied to the matrix controller assigned to it for automatically generating, by certain translucent pixel cells of this matrix, the corresponding pixel elements forming focal zones of stereo vision in the calculated viewing angles of stereo observation with constant dynamic automatic autonomous combination of each such focal zone of vision of the left and right frames with the same eyes of the corresponding user. 10. The stereo display according to claim 1, further characterized in that said stereo screen is partially transparent, or said stereo screen and matrix are mounted horizontally at a calculated distance between them, and between them there is an inclined flat partially transparent mirror inclined at an angle of about 45 degrees in the vertical planes with a center located horizontally symmetrical with respect to the center between the user's eyes with the possibility of passing through this inclined mirror of pixel light beams of a video image the left and right frames of the horizontal stereo pair from the matrix to the mirror of the stereo screen to form a screen image of this stereo pair in this mirror, followed by reflection and focusing of the light beams of this screen image by the mirror of the stereo screen on this inclined mirror for subsequent reflection and deflection of these light beams by this inclined mirror into the calculated focal area of direct clear vision of the screen image of the left frame of a horizontal stereo pair - with the left eye of the user and into the calculated focal area Well, a direct clear vision of the screen image of the right frame of this stereo pair - with the right eye of this user; if necessary, on the outside of the stereo display behind a partially transparent stereo screen or tilting mirror, an opaque removable flat or spherical light-shielding shutter or a flat or spherical light-shielding illuminated electron-optical liquid crystal panel is installed that completely covers the back surface of this screen with an electronic transparency regulator connected to this panel for manual adjustment user transparency level of this panel. 11. A stereo display comprising: a two-screen stereo screen (formed from a left frame screen and a right frame screen), a left frame matrix with a raster of light modulating elements for generating a video image of a horizontal stereo pair's left frame, and a right frame matrix with a raster of light modulating elements to form a video image of the right frame of this stereo pair; characterized in that the matrix of the left frame is located on the estimated distance in front of the mirror of the screen of the left frame and is oriented relative to this mirror for direct illumination by pixel light beams of the video of the left frame from this matrix of the area of this mirror, forming in this mirror a screen image of the left frame of a horizontal stereo pair with subsequent reflection and focusing by this mirror of the light beams of this screen image into the calculated area of the focal zone of direct clear vision Screen shot of the left image - the left eye of the user; and the matrix of the right frame on the front side is located at the calculated distance in front of the mirror screen of the right frame and is oriented relative to this mirror with the possibility of direct clear reflection in this mirror of the video image of the right frame for direct illumination of the area of this mirror by pixel beams of light of this video image of the right frame from this matrix, forming in This mirror screen image of the right frame of this stereo pair with subsequent reflection and focusing by this mirror of the light beams of this screen image eniya in the estimated area of the focal zones of vision of the right screen frame picture - his right eye; in addition, in the stereo display, to exclude visible geometric distortions when using a flat matrix, the mirror of the stereo screen is aspherical; and when using spherical mirrors in the left and right screens of the stereo screen, the matrix of the left frame and the matrix of the right frame are made spherical and / or with a row raster of pixel elements of video images of stereo frames generated on this matrix with calculated distortions of this raster to eliminate visible geometric distortions of the raster of pixel elements of stereo frames formed and directly observed by the user in the mirror of the screen of the left frame and in the mirror of the screen of the right frame; or in another embodiment, for the correction of geometric distortions in the stereo display by the matrices of the video screen of the left frame and the video screen of the right frame with a rectangular raster of light-modulating pixel elements, a converter is installed to convert the standard video signal (forming a rectangular line raster of pixels on these matrices) into a video signal that generates video images of these frames with calculated geometric distortions of the line raster of pixel elements of video images on these matrices for subsequent formation the screen image of the left frame in the mirror of the screen of the left frame and the screen image of the right frame in the mirror of the screen of the right frame for direct stereo viewing by the user of these screen images of these frames of a horizontal stereo pair without visible geometric distortion of their format and stereo perspective and taking into account the width of the stereo image of this user's eyes and taking into account stereo observation distances. 12. The stereo display according to claim 11, further characterized in that its electron-optical system is configured to simultaneously form a left-frame matrix — video images of the left frame, and right-frame matrices — video images of the right frame; each such matrix is made with a raster of light-modulating elements made of LED; on the surface of the LEDs of each such matrix, a lens or focon-lens optical raster is formed to convert the optical beams of the light beams of the pixel elements of the video image of the left frame, formed by the matrix of the left frame into narrow diverging light beams, aimed at the estimated area of illumination of the mirror of the left frame screen, forming in this mirror a screen image of the left frame with subsequent reflection and focusing by this mirror of the light beams of this screen image into the focal hydrochloric zone left frame direct clear vision - a left eye of a user; and for converting by this raster of light beams the pixel elements of the video image of the right frame formed by the matrix of the right frame into narrow diverging light beams directed to the calculated illumination areas of the mirror of the screen of the right frame to form a screen image of the right frame in this mirror with subsequent reflection and focusing by this mirror of these light beams of this screen image into the focal zone of vision of the right frame — by the right eye of this user, taking into account the formation of the minimum areas of these focal s vision zones, providing the maximum field of view angles during stereovision horizontal stereopair. 13. The stereo display according to claim 11, further characterized in that each matrix of the left frame and the matrix of the right frame are made on the basis of a DLP matrix or an LCOS matrix with a flat or cylindrical or spherical concave shape and with frontal LED illumination of each such matrix; each such illumination contains a focusing optical lens condenser made in the form of a positive lens or a positive Fresnel lens or contains a mirror-spherical reflector, as well as fixed or movable LED illuminators located at the calculated point in front of such a condenser or reflector; each such illuminator is made of an LED matrix or one pair or several pairs of lens LEDs with controllers connected to them; a software processor with a manual brightness control for the LEDs of the illuminators and the inclusion of the LEDs of each illuminator in the calculated coordinates relative to the center of this condenser or reflector is installed in the stereo display connected to these controllers for optimal adjustment of the scattering angle and the tilt angle to the plane of the light beam matrix of such a illuminator to illuminate DLP micromirrors -matrix or reflective cells of LCOS-matrix, modulating pixel light beams forming on the matrix of the video screen of the left frame of the video The image horizontal stereopair left frame, and right frame matrix video screen - the video frame of the stereopair right; these light beams are directed from the matrices with the video image of the left frame — into the calculated areas of the mirror of the screen of the left frame to form a horizontal stereo pair in the mirror image of the left frame in this mirror, and from the matrix with the video image of the right frame — into the calculated areas of the mirror of the screen of the right frame to form in this mirror a screen image of the right frames of this stereo pair with subsequent reflection and focusing by these mirrors of these light beams of these screen images into the calculated areas of the focal zone of the direct etkogo vision left frame - a left eye and a user's right frame focal zone direct clear vision - right eye of the user; for full-fledged stereo surveillance in wide angles of field of view, an electron-optical tracking system is installed in the stereo-display, containing two video cameras for video recording of the left eye of the user with the left video camera, and the right eye with the right video camera; a video processor is connected to each video camera to generate signals with information about the spatial coordinates of the location of the pupils of the left and right eyes of the user relative to the same point focal zones of stereo vision; a digital program processor is connected to the video processor to generate control signals supplied to the coupled LED matrix controllers connected to it, or to the LED controller pair of illuminators for constant dynamic automatic electron-optical adjustment of the tilt angles to the plane of the corresponding matrix of the video screen and the light scattering angles of LED light beams backlight illuminators; if necessary, automatically adjust the backlight when changing the distance from the user's eyes to the stereo screen in the stereo display installed electromechanical auto-drives; the auto-drive is mechanically connected to the LED matrix of the illuminator; or each such automatic drive is mechanically connected to a separate LED illuminator; each such automatic drive is connected to this digital software processor for automatic spatial spatial mechanical displacement of this LED illuminator matrix or each LED illuminator relative to the center of its DLP matrix or LCOS matrix; using the control signals of this processor to shift the illuminators, automatic adjustment of the tilt angles to the matrix plane and the light scattering angles of the light beams of the LED illuminators is provided for the continuous automatic formation of optimal areas and the shape of the focal vision zone of the left frame and focal zone of vision of the right frame and focal zone of vision of the right frame with automatic constant combination of these zones of vision of the left and right frames with the same eyes of the user taking into account om the distance of stereo observation and stereo base of the eyes of the convergence angles of this user's eyes. 14. The stereo display according to claim 11, further characterized in that the center of the matrix of the left frame is located horizontally centrally symmetrical to the main optical axis of the mirror of the screen of the left frame, with a calculated displacement of this center below or above this optical axis, taking into account subsequent reflection and focusing by this mirror light rays (screen image of the left frame in this mirror) in free space, respectively, above the upper edge or below the lower edge of this matrix into the focal area of direct clear vision of this screen image zheniya - the left eye of the user; and the center of the matrix of the right frame is located equally horizontally centrally symmetrical to the main optical axis of the mirror of the screen of the right frame with the calculated offset of this center respectively below or above this optical axis, taking into account the subsequent reflection and focusing of the screen mirror of the right frame of light rays (screen image of the right frame, this mirror) in free space, respectively, above the upper edge or below the lower edge of this matrix into the focal area of direct clear vision of the screen image of the right frame and - the right eye of this user. 15. The stereo display according to claim 11; further characterized in that in this stereo display, the LED matrix of the left frame is made with a raster of pixel LEDs to form light beams of pixel video elements of the left frame of a horizontal stereo pair, and the LED matrix of the right frame is made with a raster of pixel LEDs to form light beams of pixel video elements of the right frame of this stereo pair ; in each such matrix, the back side of any cell with a pixel LED visible to the user's eye is made with a matte black coating; between these cells of pixel LEDs are located raster luminal cells, tinted to the level of invisibility by the user through this luminous raster of the reflection of his eyes in the mirror of the corresponding screen; the center of the matrix of the left frame is located vertically and horizontally centrally symmetrically to the main optical axis of the mirror of the screen of the left frame for direct illumination from this matrix with a beam of light of each of its LEDs of the estimated area of the screen of the left frame to form a screen image of the left frame in this mirror with subsequent reflection and focusing this mirror of light beams of this screen image through the luminal cells of the matrix into the focal zone of direct clear vision of the screen image of the left frame - the left eye p user and the center of the matrix of the right frame is located vertically and horizontally centrally symmetrical to the main optical axis of the mirror of the screen of the right frame for direct illumination with this matrix by the lights of each of its LEDs of the estimated area of the screen of the left frame to form a screen image of the right frame in this mirror and then reflect and focus it a mirror of light beams of this screen image through the luminal cells of the matrix into the focal zone of direct clear vision of this screen image of the right frame - m the eye of the user. 16. The stereo display according to claim 11, further characterized in that in this stereo display the screen of the left frame and the screen of the right frame, and, if necessary, the matrix of the left frame and the matrix of the right frame are partially transparent, or in another embodiment of the stereo display the screen of the left frame with the matrix of the left the frames are mounted parallel horizontally at a calculated distance between them, and between them there is an inclined flat partially transparent mirror located in front of the left eye and tilted at an angle of about 45 degrees in a vertical plane a bone parallel to the main optical axis of the mirror of this screen with the possibility of passing through this inclined mirror of pixel light beams the video of the left frame from the matrix of the left frame to the mirror of the screen of the left frame to form a screen image of the left frame in this mirror, followed by reflection and focusing of the left frame screen by this mirror light beams of the screen image of the left frame onto this inclined mirror to reflect and deflect these light beams by this inclined mirror into the focal area direct direct vision of this screen image of the left frame — by the left eye of the user; the screen of the right frame with the matrix of the right frame is installed horizontally at the estimated distance between them, and between them there is an inclined flat partially transparent mirror located in front of the user's right eye and tilted at an angle of about 45 degrees in a vertical plane parallel to the main optical axis of the mirror of this screen with the possibility passing through this oblique mirror of pixel light beams of the video of the right frame from the matrix of the right frame to the screen mirror of the right frame to form in the right-hand screen image mirror with subsequent reflection and focusing of these light beams by this right-hand screen mirror image of the light beams of this screen image onto an inclined mirror to be reflected and deflected by this inclined mirror into the focal area of direct clear vision of this right-screen image - with the right eye This user if necessary, on the outside of the stereo display behind partially transparent stereo screens or tilting mirrors, behind each partially transparent stereo screen or behind each partially transparent tilting mirror, an opaque removable flat or spherical light-shielding curtain or partially transparent flat or spherical flat or spherical light-shielding curtain or a flat or spherical light-shielding transparent Electron-optical liquid crystal flat or spherical panel, completely close th the back surface of the screen is connected to the electronic controller panel transparency of the panel to manually adjust the level of transparency of the panel by the user. 17. A stereo display comprising a two-screen stereo screen formed from the screen of the left frame (located in front of the left eye of the user) to form a screen video image of the left frame of a horizontal stereo pair and formed from the screen of the right frame (located in front of the right eye of this user) to form the screen video of the right frame, the fact that the screen of the left frame is made of a matrix of the left frame for the direct formation of this screen video image of the left frame, and the left side of the frame matrix is located in front of the left eye of the user for the direct observation of the on-screen video image of the left frame - this left eye; the screen of the right frame is made of a matrix of the right frame, the front side of the matrix of the right frame is located in front of the right eye of this user for direct observation of this screen video image of the right frame with this right eye; the electron-optical stereo-display system is made for the simultaneous formation by these matrices of screen images of the left and right frames formed on the screen of the left frame in the form of one single-angle left frame, and on the screen of the right frame in the form of one single-angle right frame, or for the simultaneous formation of these matrices on the screen of the left frame of the screen video image in the form of two or three different angles of the left frames, and on the screen of the right frame - in the form of two or three different angles of the right frames; an optical raster is formed on the screen of the left frame for collimating the light beams of the pixel elements of these on-screen video images of the left frames with each raster focusing these collimated light beams into the focal points of vision of the left frames, respectively, with the left eye of the user; an optical raster is formed on the screen of the right frame for collimating the light beams of the pixel elements of these screen video images of the right frames with subsequent focusing of these collimated light beams by this raster into the focal points of vision of the right frames, respectively, with the right eye of this user; in the first embodiment, each collimating optical raster is made of one layer of plane-convex ellipsoid positive microlenses; the base of each one such microlens covers one or more light-modulating elements of the corresponding matrix located at design points relative to the optical axis of this micro-lens for capturing and collimating the light beams of each light-modulating element with subsequent selective direction of the light beam of each light-modulating element to the corresponding point focal zone of vision of the left or right a stereo pair frame with the same eye of the user; in the second embodiment, each collimating optical raster is made of two layers; the first layer is made of a raster of optical short fibers in the form of hollow foci; each such trick is made in the form of a hollow truncated pyramid or a truncated cone with a luminous wide entrance window and a luminous narrow exit window with mirrored or white opaque side inner walls, with a wide open entrance window and a narrow open exit window; the input window of each one focon closes the area of the triad of light-modulating elements of RGB colors to form light beams of a colored pixel element, forming on this matrix a video image of the corresponding frame of a horizontal stereo pair; in the third embodiment, each collimating optical raster is made of three layers: the first layer is made of a raster of focons, similar to the raster specified in the first embodiment, on the first layer of the raster of focons a second layer of raster is formed from flat corner micromirror reflectors, and on this second layer a third layer of raster is formed parabolic micromirrors (located on the outside of this third raster layer); each optical element of a three-layer raster is made of one or two or three hollow focons located normal to the area of this element; the exit lumen window of each focon is closed by a flat lumen window with an optically dense medium of the second raster layer; on the exit windows of the foci of this optical element at a 45 degree angle to the longitudinal axis of the parabolic micromirror there is one retroreflector micromirror, the retroreflector is made of two flat micromirrors inclined mutually to the longitudinal axis of the parabolic micromirror at a 45 degree angle with a common edge of these micromirrors (located on the side raster of focons); in the area of the output windows of the focons of this element, the center of one micromirror of this reflector is located; in the center of this micromirror, one or two or three lumen windows are made; each such one window is combined with the output window of its focus; the output windows of these focons are located closer to the main optical axis and the focus of this parabolic micromirror of the mirror for capturing the input window of the second layer of the raster of light beams from all the output windows of the focons of the optical element with the subsequent illumination of this parabolic mirror by these light beams for subsequent collimation and back reflection of these light beams a parabolic mirror on this flat reflector micromirror followed by reflection of these light beams by this micromirror on the second micromirror it a retroreflector for subsequent reflection by this second micromirror of these collimated light beams through the luminous window of the third raster layer out into the corresponding point focal zones of vision of the left and right frames with the same eyes of the user with the possibility of two or three point focal zones of vision of two or three point focal zones of vision of different left angles or misleading right frames of a horizontal stereo pair with the same eyes of the user. 18. The stereo display according to claim 17, further characterized in that in this stereo display the left-frame screen and the right-frame screen are movable, electro-mechanical auto-drives are installed in the stereo-display: one auto-drive is mechanically connected to the left-frame screen for constant mechanical automatic dynamic auto-correction of spatial location and the angular orientation of this screen relative to the left eye of the user during stereo observation; another auto-drive is mechanically connected to the screen of the right frame for constant mechanical automatic dynamic automatic correction of the spatial location and angular orientation of this screen relative to the center of the pupil of the right eye of the user during stereo observation; in a stereo display, the electron-optical system comprises a tracking system; the tracking system comprises a video camera for capturing the user's left eye, and a video camera for capturing the user's right eye; a video processor is connected to each video camera to generate signals with spatial coordinates of the location of the pupils of the left and right eyes of the user relative to the same point focal zones of stereo vision, a digital program processor is connected to the video processor to generate control signals supplied to these mechanical auto-drives for the specified mechanical auto-correction of these screens by these automatic drives, providing continuous automatic combination of all point focal points n vision left frames and right frames with the calculated points of the user's eye pupils of like and / or in which continuous automatic adjustment of the optical system for stereo displays in full comfort stereoviewing wide angles of view. 19. The stereo display according to claim 17, further characterized in that the screen of the left frame and the screen of the right frame are mounted parallel to the horizontal plane; in front of the screen of the left frame and in front of the left eye there is an oblique flat raster mirror inclined at an angle of about 45 degrees in the vertical plane, and in front of the screen of the right frame and in front of the right eye there is an oblique flat raster mirror inclined at an angle of about 45 degrees in the vertical plane, each the mirror is made of a raster with opaque mirror cells mirrored from the side of its screen and blackened from the back of this oblique mirror; between the mirror elements of the raster there are translucent cells of the raster for transmitting collimated light beams through these cells into the point focal zones of direct observation of the left and right frames of the horizontal stereo pair with the same eyes of the user. 20. A stereoscopic video camera for video recording and recording signals of 3D video images, for subsequent stereo observation of these images on stereo screens and stereo displays, containing an electron-optical system with one common photosensitive matrix or two photosensitive matrices: a matrix for video recording of the left frame and a matrix for video recording of the right horizontal stereo pair and containing a stereoscopic optical video system for simultaneous simultaneous video recording from the left angle and from right angle; a video processor is connected to each such photomatrix to process video data from this photomatrix to generate video data signals of captured images to generate signals for recording stereo frames on a digital medium (connected to this video processor); characterized in that each optical block of the left frame and the optical block of the right frame of the optical video filming system is made with one, or two, or three microlenses, or with one, two, or three hole input holes similar to aperture in shooting micro-lenses or aperture openings for forming a hole chamber such as a pinhole camera; this optical system has an electronic automatic shutter for single-frame video recording on the common photomatrix of the left or right frame using synchronous aperture in both blocks of these micro lenses and output holes for the simultaneous simultaneous frame-by-frame opening of one micro lens or one hole in each block when other micro lenses or holes are closed respectively in these blocks for sequential video shooting of two or three different angles of the same name frames on a common photomatrix or on two photosensitive matrices for simultaneous video recording of signals of one-way left and right frames of a horizontal stereopair or, respectively, different-view left and right frames of a horizontal stereopair or different-view left and right frames with sequential recording of these two or three different-view frames of the same name; for this, these microlenses or inlet openings are located in the area of the left and right entrance pupil of the video optical system in the areas of the vertices of an equilateral triangle located in the area of the corresponding entrance pupil, taking into account the possibility of the claimed stereo displays displaying similar single-angle left and right frames formed and observed in the corresponding point focal zones of vision of one-way left and right frames of a horizontal stereo pair or similar are different views x left and right frames of a horizontal stereo pair in the corresponding point focal zones of simultaneous viewing of two-way or three-way views of the same left and right frames automatically aligned with the calculated points in the pupil area of the user's eyes of the same name. 21. A computer-based method for generating 3D images observed on stereo screens or on stereo displays, including programmatically generating, using a 3D video system of a computer or a 3D game console, 3D images in the form of left and right frames of a horizontal stereo pair observed on stereo displays or displayed on 3D - video monitors or on the screens of 3D TVs; characterized in that the computer video system and software are capable of 3D and systemic generation of 3D images in a display format of two or three angles of the same name left and right frames of a horizontal stereo pair for their simultaneous and synchronous stereo observation on the proposed stereo displays with the possibility of simultaneous stereo observation in this stereo display of screen images these stereo frames of a horizontal stereo pair of frames from the corresponding point focal zones of the stereo Eden, with full comfort stereoviewing with natural reflex user's eyes focus, convergence angles agreed with his eyes gaze at any point.