A portable short-focus near-eye display system is provided, which relates to the field of near-eye display technologies, and solves the problem of contradiction between optical performance and volumes in an existing AR technology. The system includes a microdisplay, an inner lens, and a concave partial reflector. The inner lens is closer to a pupil position, and the concave partial reflector is farther away from the pupil position. The microdisplay includes a rotating linear display or a transparent display. Through multiple reflections, an optical path is folded, so that a distance between a convex partial reflector and the concave partial reflector is shortened, and a thickness of glasses can be maximally reduced, thereby achieving thinning.

A head-up display device includes a first mirror having power, a second mirror having power, and a light-blocking member that is provided with an aperture. An image reflective surface has a convergence action. Display light emitted from an image display surface is reflected by the first mirror and the second mirror in this order, passes through the aperture, and reaches the image reflective surface. The image display surface is disposed on the same side as an observer and on a side opposite to the first mirror with respect to luminous flux that travels toward the aperture from the second mirror. The first mirror is a concave mirror. The shape of the cross-section of the second mirror taken along a front-rear direction is a convex shape.

An information-processing system having spherical and parabolic reflectors, optical signal processors, and detectors comprising optically active surfaces. The spherical reflector has an internal light-reflecting surface and a spherical processor with internal and external optically active surfaces, with its center coincident with that of the spherical reflector. The optical signal processor's internal and external surfaces include transmitters and detectors for transmitting and receiving a optically encoded signals along various distinct paths. A portion of the internal path coincides with a line that passes through the center of the sphere. Optical signals emitted from the external surface of the processing sphere and reflected by the internal surface of the external spherical reflector to neighboring regions of the processing sphere, enabling external relay of information around the sphere without congesting the internal cavity of the sphere. This makes possible multiple uses of the same optical frequency during a given time period.

A small information display apparatus capable of displaying video information on a windshield as a virtual image is provided. An information display apparatus configured to display video information of a virtual image on a windshield of a conveyance includes: a liquid crystal panel arranged as a video display apparatus configured to form the video information; and a virtual image optical system provided with a windshield for displaying the virtual image at a front of the conveyance by reflecting video of the liquid crystal panel by means of the windshield. The virtual image optical system is configured by arranging a concave mirror and an optical element between the concave mirror and the video display apparatus.

The three-dimensional image display apparatus includes the following structural elements: an optical system including a concave mirror, and a light transmitting section provided to the concave mirror at a boundary between a first space and a second space, the optical system forming a real image in the second space, with an aid of the concave mirror, of an object disposed in the first space available on the concave mirror; and an image output device disposed at a place so as not to substantially block an optical path of light rays forming the real image of the object.

Disclosed herein are devices, methods and systems for producing hologram-based indicia for a vehicle dashboard/cockpit. By employing the aspects disclosed herein, indicia (electronically coupled to the vehicle's microprocessor), is lighted and projected in a three-dimensional virtual manner. The aspects disclosed herein may be embedded in various portions in the vehicle and thus, not consume extra space or area required to create virtual images through other techniques.

An optical module includes: a first holding device with a circumference extending in a first circumferential direction; and a plurality of first supporting devices configured to support a first optical element, the first supporting devices being fixed at the circumference of the first holding device. Along the first circumferential direction, at least one of the first supporting devices is located in a non-equidistant manner between two neighboring first supporting devices. The optical module is configured to be used in a microlithography objective.

Disclosed herein are devices, methods and systems for producing hologram-based indicia for a vehicle dashboard/cockpit. By employing the aspects disclosed herein, indicia (electronically coupled to the vehicle's microprocessor), is lighted and projected in a three-dimensional virtual manner. The aspects disclosed herein may be embedded in various portions in the vehicle and thus, not consume extra space or area required to create virtual images through other techniques.

The three-dimensional image display apparatus includes the following structural elements: an optical system including a concave mirror, and a light transmitting section provided to the concave mirror at a boundary between a first space and a second space, the optical system forming a real image in the second space, with an aid of the concave mirror, of an object disposed in the first space available on the concave mirror; and an image output device disposed at a place so as not to substantially block an optical path of light rays forming the real image of the object.

Disclosed is an optical module for a lens, especially a microlithographic apparatus, comprising a first holding device (2) with an inner circumference (2.1) that extends in a first circumferential direction (2.2), and at least one first supporting device (3.1) which is fastened to the inner circumference (2.1) of said first holding device (2) and is used for supporting a first optical element (5.1), an annular circumferential first assembly space (3.18) being defined by displacing the first supporting device (3.1) once in a revolving manner along the first circumferential direction (2.2). At least one second supporting device (3.2) which is fixed to the inner circumference (2.1) of the first holding device (2) is provided for supporting a second optical element (5.2), an annular circumferential second assembly space (3.28) being defined by displacing the second supporting device (3.2) once in a revolving manner along the first circumferential direction (2.2). The first assembly space (3.18) intersects the second assembly space (3.28).