The invention relates to an adaptive optical system (1) comprising: an adaptive optical device (2) comprising an optical processing surface (3) and a driving device (5) for controllably modifying the optical behaviour of said optical processing surface (3), an optical analyser (6) intended to be subjected to an input light beam (7) in order to produce, in response, output signals (8, 9, 10), a control device (11) connected to the optical analyser (6) and to the driving device (5) in order to command the latter depending on said output signals (8, 9, 10), characterised in that said optical analyser (6) is designed to spatially demultiplex, via multi-plane light conversion, the input light beams (7) into a plurality of elementary output light beams (80, 90, 100). Adaptive optical systems.

An aerospace mirror having a reaction bonded (RB) silicon carbide (SiC) mirror substrate, and a SiC cladding on the RB SiC mirror substrate forming an optical surface on a front side of the aerospace mirror. A method for manufacturing an aerospace mirror comprising obtaining a green mirror preform comprising porous carbon, silicon carbide (SiC), or both, the green mirror preform defining a front side of the aerospace mirror and a back side of the aerospace mirror opposite the front side; removing material from the green mirror preform to form support ribs on the back side; infiltrating the green mirror preform with silicon to create a reaction bonded (RB) SiC mirror substrate from the green mirror preform; forming a mounting interface surface on the back side of the aerospace mirror from the RB SiC mirror substrate, and forming a reflector surface of the RB SiC mirror substrate on the front side of the aerospace mirror. Additionally, the method can comprise cladding the reflector surface of the RB SiC mirror substrate with SiC to form an optical surface of the aerospace mirror.

An aerospace mirror having a reaction bonded (RB) silicon carbide (SiC) mirror substrate, and a SiC cladding on the RB SiC mirror substrate forming an optical surface on a front side of the aerospace mirror. A method for manufacturing an aerospace mirror comprising obtaining a green mirror preform comprising porous carbon, silicon carbide (SiC), or both, the green mirror preform defining a front side of the aerospace mirror and a back side of the aerospace mirror opposite the front side; removing material from the green mirror preform to form support ribs on the back side; infiltrating the green mirror preform with silicon to create a reaction bonded (RB) SiC mirror substrate from the green mirror preform; forming a mounting interface surface on the back side of the aerospace mirror from the RB SiC mirror substrate, and forming a reflector surface of the RB SiC mirror substrate on the front side of the aerospace mirror. Additionally, the method can comprise cladding the reflector surface of the RB SiC mirror substrate with SiC to form an optical surface of the aerospace mirror.

An information display apparatus and an information display method configured to display video information of a virtual image on a windshield of conveyance is provided. The information display apparatus includes: a display configured to display the video information; and a virtual image optical system configured to display a virtual image at a front of the conveyance by reflecting light emitted from the display by means of the windshield. The virtual image optical system includes a concave mirror and an optical element. A reflective film is formed on a reflecting surface of the concave mirror. A protective film for preventing moisture absorption is formed on a facing surface. By forming end surfaces of the two surfaces as a curved surface or an inclined surface and forming them on the end surfaces to block moisture, moisture absorption of plastic is prevented.

An information display apparatus and an information display method configured to display video information of a virtual image on a windshield of conveyance is provided. The information display apparatus includes: a display configured to display the video information; and a virtual image optical system configured to display a virtual image at a front of the conveyance by reflecting light emitted from the display by means of the windshield. The virtual image optical system includes a concave mirror and an optical element. A reflective film is formed on a reflecting surface of the concave mirror. A protective film for preventing moisture absorption is formed on a facing surface. By forming end surfaces of the two surfaces as a curved surface or an inclined surface and forming them on the end surfaces to block moisture, moisture absorption of plastic is prevented.

A head-up display device includes: a display unit that produces a display light for the left eye by modulating a first illumination light derived from superimposing first illumination light beams output from a first region of a fly eye lens and produces a display light for the right eye by modulating a second illumination light derived from superimposing second illumination light beams output a second region of the fly eye lens; and an image processing unit that produces an image for the left eye and produces an image for the right eye; and a display control unit that causes a display unit to display the image for the left eye when the first illumination light is produced and causes the display unit to display the image for the right eye when the second illumination light is produced.

A head-up display device includes: a display unit that produces a display light for the left eye by modulating a first illumination light derived from superimposing first illumination light beams output from a first region of a fly eye lens and produces a display light for the right eye by modulating a second illumination light derived from superimposing second illumination light beams output a second region of the fly eye lens; and an image processing unit that produces an image for the left eye and produces an image for the right eye; and a display control unit that causes a display unit to display the image for the left eye when the first illumination light is produced and causes the display unit to display the image for the right eye when the second illumination light is produced.

A head-up display includes: a display medium; a display that displays an image; and a projection optical system that forms a virtual image by guiding the image displayed by the display to the display medium. The projection optical system includes a first mirror disposed above the display and reflecting display light of the image. 3<α−(θ+φ)/2<11.7 is satisfied, where θ denotes an angle between a line segment connecting centers of the first mirror and the display and a normal line at the center of the first mirror, α denotes an angle between the line segment connecting the centers of the first mirror and the display and a normal line at the center of the display, and φ denotes an inclination angle at an edge of the first mirror closer to the display relative to the center of the first mirror.

A picture generation unit comprises a light emitter array that is disposed on a substrate and provides a projection imaging light. The light emitter array includes a plurality of light emitting units. Each of the light emitting units includes a plurality of mini LED chips. An electronic control unit is electrically coupled to the substrate to control the mini LED chips to generate the projection imaging light. The light emitter array may emit light as well as present controllable images simultaneously. Because the picture generation unit abandons using the conventional backlight source and the module thereof, it can effectively utilize light energy and reduce radiation heat/waste heat. A vehicular head-up display system using the picture generation unit may improve operation reliability thereof.

A picture generation unit comprises a light emitter array that is disposed on a substrate and provides a projection imaging light. The light emitter array includes a plurality of light emitting units. Each of the light emitting units includes a plurality of mini LED chips. An electronic control unit is electrically coupled to the substrate to control the mini LED chips to generate the projection imaging light. The light emitter array may emit light as well as present controllable images simultaneously. Because the picture generation unit abandons using the conventional backlight source and the module thereof, it can effectively utilize light energy and reduce radiation heat/waste heat. A vehicular head-up display system using the picture generation unit may improve operation reliability thereof.