According to one embodiment, an illumination device includes a light source module, and a reflector opposed to the light source module. The reflector includes a plurality of incidence openings on which light from the light source module is made incident, a plurality of emission openings opposed to the incidence openings, a plurality of reflective surfaces extending from the incidence openings to the emission openings, respectively, and reflective films formed on the reflective surfaces. The reflector includes a plurality of blocks, and the blocks are bonded to each other to form the reflector.

Non-imaging radiation collecting and concentrating devices, and assemblies, are disclosed. The non-imaging radiation collecting and concentrating devices comprise an entrance aperture for receiving incoming radiation, an exit aperture located opposite to the entrance aperture for outputting concentrated radiation, and one or more concaved reflectors arranged between the entrance and exit apertures. The concaved reflectors define an acceptance angle of the device relative to an optical axis thereof and configured such that their optical focuses are located between edges of the exit aperture and the optical axis, thereby substantially preventing escape of the incoming radiation received in the entrance aperture within the acceptance angle and providing substantial uniform radiation collection at the exit aperture of the device.

An optical device is mounted to an electronic circuit having a main face with at least one light source. The optical device is made from a block which includes, for each light source, a corresponding opening that passes through the block. The opening includes a cylindrical part with a threading on an inside surface.

A light guide system for a vehicle includes, among other things, a housing that includes a first section and a second section that are secured together to provide a chamber A light emitter is disposed within the chamber. A light source is disposed outside the chamber A reflector system directs light emitted from the light source to the light emitter within the chamber. A vehicle lighting method includes, among other things, securing a first and second section of a housing assembly together to provide a chamber, and operatively coupling a reflector system within the chamber and a light source outside the chamber such that the reflector system can redirect light from the light source to a light emitter held within the chamber.

A phosphor element includes an incident face for an excitation light, an emitting face opposing the incident face and a side face, and the element converts at least a part of the incident excitation light incident onto the incident face to fluorescence and emits the fluorescence from the emitting face. The emitting face has an area larger than an area of the incident face. The phosphor element comprises an inclination region in which an inclination angle of the side face with respect to a vertical axis perpendicular to the emitting face is monotonously increased from the incident face toward the emitting face, viewed in a cross-section perpendicular to the emitting face and along the longest dividing line halving the emitting face.

A lighting device is provided that includes a light source and an optical element. The light source emits primary light having a primary emission characteristic. The optical element has a light entry face and a light exit face. The optical element includes light guiding elements each forming part of the light entry and exit faces. The light entry faces inject the primary light into the optical element. The light guiding elements each have a boundary surface that totally internally reflects the primary light so that the light exit face emits a secondary light. The optical element reduces a divergence of the primary light such that the secondary light has a secondary emission characteristic with an emission angle (β) that is smaller than an emission angle (α) of the primary emission characteristic. The light exit face is larger than the light entry face.

Aspects relate to a compact material analyzer including a light source, a detector, and a module including a first optical window on a first side of the module, a second optical window on a second side of the module opposite the first side, and a light modulator. The light source produces input light at a high power that is passed through the first optical window to the light modulator. The light modulator is configured to attenuate the input light, produce modulated light based on the input light, and direct the modulated light through the second optical window to the sample. The modulated light produced by the light modulator is at a lower power safe for the sample. The detector is configured to receive output light from the sample produced from interaction with the modulated light through the second optical window and to detect a spectrum of the output light.

An illumination system includes: a laser array assembly including: a laser configured to generate a laser light; a crystal phosphor waveguide, adjacent to the laser and in the laser light, configured to: generate of a luminescent light based on receiving the laser light, and direct the luminescent light away from a base end; and a compound parabolic concentrator (CPC), coupled to the crystal phosphor waveguide opposite the base end, configured to: collect the luminescent light from the crystal phosphor waveguide, project the luminescent light away from the crystal phosphor waveguide.

A light source apparatus includes a holder configured to hold a lamp including a metal base having a cylindrical surface, a condensing mirror configured to condense light generated by the lamp, and a nozzle including an ejection hole configured to eject a gas to cool the metal base. A distance between a straight line including a center axis of the ejection hole and a center axis of the metal base ranges from not less than ½ of a radius of the cylindrical surface to not more than the radius.

A light source module includes a light-collecting lens, a first light source unit, a first light-combining element, a second light source unit, a second light-combining element, and a third light source unit. The first, second, and third light source units are respectively configured to emit a first, second, and third light beams. The first and second light-combining elements are configured to respectively reflect the first and second light beams to the light-collecting lens disposed in a transmission path of the third light beam. An optical axis of the light-collecting lens is parallel to a first direction, and an optical axis of the first light source unit is parallel to a second direction. The first and second light source units and the first and second light-combining elements are disposed in an alternating manner in a third direction perpendicular to the first and second directions. A projection device is also provided.