A method of making illumination systems for illuminating building interiors comprises positioning first and second opaque, rigid reflective side walls at a distance from one another with reflective surfaces facing each other. The method further comprises positioning a reflective grid panel with parallel longitudinal walls and parallel transverse walls joining the longitudinal walls between the side walls, defining rectangular light-transmitting openings. The method also includes positioning an LED light source above the grid panel to illuminate it at incidence angles ranging from 0 to at least 45. Additionally, the method comprises positioning a light diffusing sheet of optically transmissive dielectric material approximately coextensive with the grid panel parallel to the grid panel between the side walls above the grid panel. The transverse walls of the grid panel and the reflective side walls are configured to diffusely reflect portions of light transmitted through the rectangular openings.

This invention relates to illumination systems, namely, to automotive headlamps and can be used as the principal head lighting of light and cargo vehicles. The automotive headlamp includes at least one LED and a system of lenses. The system of lenses includes both composite diverging and regulating lenses. The composite diverging lens is made up of two plano-concave lenses. The composite regulating lens is made up of the converging plano-convex lens and the refracting right-angled wedge placed in a series through the luminous flux. The composite regulating lens is placed between the LED and the composite diverging lens, which is suitable for controllable obscuration of the light flux. The invention enhances the reliability of the high/low-beam switch system.

In some embodiments of the disclosed subject matter, an extreme ultraviolet (EUV) light source is provided. The EUV light source comprises: a droplet nozzle array droplet nozzle array comprising multiple nozzles arranged in a ring, the nozzles are configured for sequentially ejecting droplets towards an annular radiation position; a laser source for generating a laser beam, wherein the laser beam is controlled to rotate and sequentially bombard the droplets that reach the annular radiation position; and an integrated rotary structure located between the droplet nozzle array and the laser source, the integrated rotary structure includes: a condenser mirror comprising a first surface and a second surface opposing to the first surface, and a motor driving shaft that is integrally connected with the condenser mirror.

A foam sandwich reflector and a method for making a foam sandwich reflector. The reflector and method incorporate a foam slab having a top and bottom surface. Each of the top and bottom surface of the foam slab have a coating of an adhesive layer. The adhesive coating on the bottom surface of the foam slab is a lower bonding layer that bonds the foam slab to the bottom high modulus layer. The adhesive coating on the top surface of the foam slab is an upper bonding layer that bonds the foam slab to the top high modulus layer; bottom high modulus layer composed of a metal, e.g., aluminum or steel. The reflector and method also include an optically smooth, highly reflective high modulus layer. The reflector is curved in one dimension, and the curve is configured to concentrate light when the reflector is in use.

Provided are microcellular plastic articles having improved reflective properties. Also provided are methods of utilizing the disclosed articles.

A heliostat contained within a mechanical enclosure is described that optimizes the heliostat for domestic applications by emphasizing features of durability, protection from outside weather, low cost of manufacture, self-powering, light-weight, and aesthetics.

A heliostat optimized to be positioned near a skylight or other aperture is disclosed. The heliostat comprises a plurality of reflective elements arranged in a substantially planar array, each element being mounted so as to be rotatable about a longitudinal axis of rotation. A first motor rotates the array about an axis substantially perpendicular to the plane of the array; and a second motor rotates the reflective elements about their respective axes of rotation. A processor provides control signals to operate the first motor as required to orient the array such that the respective axes of rotation of the reflective elements are substantially perpendicular to an azimuth to the sun and to operate the second motor as required to rotate the reflective elements about their respective axes of rotation to position the reflective element to reflect the sun's light to a target area.

An optical apparatus includes a rotatable reflecting member including a first reflecting surface and a second reflecting surface, an optical system including a plurality of reflecting surfaces and configured to sequentially reflect light having been reflected at the first reflecting surface at the plurality of reflecting surfaces to make the light incident on the second reflecting surface, a driving part configured to change an angle of the reflecting member, a control unit configured to control the driving part to change a path of light emitted from the reflecting member after being reflected at the second reflecting surface, and a light incident portion configured to recognize a position of the light having been reflected at the first reflecting surface.

A device for increasing the optical power of a solid state light source in the green and/or yellow bands, is disclosed. The device has an integral body having an ingress surface configured to receive light from an emitting portion of the solid state light source, an egress surface substantially opposite the ingress surface, and a recess formed within the body. The recess has an input opening in the ingress surface, an output opening in the egress surface, and a recess surface within the body extending between the input opening and the output opening. The recess surface is configured to reflect visible light with Lambertian scatter characteristics.

In one aspect, an optical lens assembly (herein referred to also as an optic) is provided that comprises a plurality of lenses (or lens segments) adapted to receive light from a light source, each of said lenses (or lens segments) having an input surface and an output surface and a lateral surface extending between the input and output surfaces. The lenses are arranged relative to one another and positioned relative to the light source such that each of the lenses receives at its input surface a different portion of light emitted by the source, e.g., each lens receives at its input surface light emitted by the source into an angular subtense (solid angle) different than an angular subtense associated with another lens. Each lens (or lens segment) guides at least a portion of the received light to its output surface via reflection, e.g., via total internal reflection (TIR).