An LED fog lamp includes a lamp seat and a light-emitting unit. The lamp seat includes a main housing defining a light cavity with a rear opening, and a lampshade mounted to and covering a front side of the main housing. The light-emitting unit includes a heat-dissipating seat having a mounting portion extending into the light cavity via the rear opening, and a light-emitting module mounted on the mounting portion. A light guide unit is mounted inside the light cavity. A positioning mechanism includes a first aligning member disposed on the main housing, a second aligning member disposed on the heat-dissipating seat, and a positioning member detachably interconnecting the first and second aligning members.

An optoelectronic device and a method for producing an optoelectronic device are disclosed. An embodiment of an optoelectronic device includes a carrier, an electrically conductive layer arranged on the carrier, at least one semiconductor chip comprising an active layer for generating electromagnetic radiation, wherein the semiconductor chip is electrically conductively and mechanically connected with the carrier via the electrically conductive layer. The device further comprises a holder, wherein a surface of the carrier remote from the semiconductor chip is arranged on the holder, wherein the carrier is mechanically connected with the holder by at least one fastening element and is fastened to the holder, wherein the fastening element passes completely through the carrier, and wherein the semiconductor chip is electrically conductively connected to the holder by the fastening element.

A vehicular lamp includes a light source; and a light guide disposed such that light emitted from the light source is incident on an end face of the light guide. The light guide emits light, guided into its interior, heading vehicle-forward from an exit face of the light guide running along the light guide's lengthwise extension. The light guide includes reflection steps formed on a surface of the light guide on a side reverse from the exit face, for reflecting light guided into the light-guide interior toward the exit face; and a plurality of diffusion flutes formed on said end face, each being arcuate in substantially horizontal cross-section through said end face, and each being of constant form in substantially perpendicular extension.

A lamp includes a lamp base unit, a light emitting unit, and a light shape piece. The lamp base unit includes a base seat, a first seat extending from the base seat, and a second seat extending from the first seat. The light emitting unit includes an LED high beam light module disposed on one of the first seat and the second seat, and an LED low beam light module disposed on the other one of the first seat and the second seat and having a light irradiation direction different from that of the LED high beam light module. The light shape piece is disposed on one of the first seat and the second seat for refracting light emitted from a corresponding one of the LED high beam light module and the LED low beam light module to form a light shape having a cut-off line.

A lighting apparatus includes: a light source; a sealed housing accommodating the light source therein; and an aiming screw rotatably supported in a through-hole which extends through the housing. Therefore, an optical axis of light emitted from the light source can be adjusted by rotating the aiming screw. A breathing passage communicating inside and outside of the housing with each other is provided inside the aiming screw, so that it is unnecessary to separately provide a breathing passage, thereby enabling decrease in the number of parts, and simplification of the structure. Accordingly, breathing of the housing of the lighting apparatus is achieved using a simple and compact structure.

An LED taillight with an integrated GPS tracking system is disclosed therein. The GPS tracking system is hidden behind the LED portion of the LED taillight so that the GPS tracking system is not noticeable by someone inspecting a trailer on which the LED taillight is installed. Additionally, power sent to the LED taillight to power the LEDs also recharge a battery associated with the GPS tracking system and power the GPS tracking system during use.

The invention describes a gas-discharge lamp comprising an inner vessel enclosing a pair of electrodes separated by a gap; and an outer vessel enclosing the inner vessel; and wherein the lamp comprises a lateral stripe arranged on the surface of a vessel such that the lateral stripe lies below a horizontal plane through a longitudinal axis through the center of the lamp, and wherein the lateral stripe extends essentially only over a region corresponding to the gap between the electrodes.

A light bulb locking device (11) for mounting to a lamp reflector unit (5) having a mounting aperture for receiving a replaceable light bulb (9). The locking device (1) includes: a resilient retainer clip (13) with a clamp portion (41) for connecting to a lamp reflector unit (5), and a bracket body (15) for engaging a light bulb (9) in the lamp reflector unit (5). The bracket body (15) having a hinge pin (17) pivotally embraced by a substantially cylindrical portion (45) of the retainer clip (13). The bracket body (15) thereby is pivotable between an open position enabling a light bulb (9) to be replaced, and a locked position in which a light bulb (9) is firmly held with respect to the lamp reflector unit (5). The clamp portion (41) of the retainer clip (13) has a beveled lip (43) at a free end thereof opposite the substantially cylindrical portion (45), and the bracket body (15) has at least one click finger (33A, 33B) for engaging the beveled lip (43) when in the locked position.

A lighting apparatus is disclosed with a light generating device, at least one collimator lens, first and second parabolic mirrors, an optical diaphragm embodied in a light reflecting fashion, and a spherical mirror. The diaphragm is arranged between the parabolic mirrors, extending as far as a common focus of them. The parabolic mirror, the device and the lens are arranged so that light emitted by the device and collimated by the lens is directed onto the first parabolic mirror reflection surface and light reflected by the first parabolic mirror reflection surface impinges on the second parabolic mirror reflection surface or on the diaphragm. The spherical mirror is arranged so that its focus is arranged at the common focus of the parabolic mirrors and light reflected at the diaphragm impinges on the spherical mirror reflection surface and is directed from the reflection surface onto the second parabolic mirror reflection surface.

Provided is an illumination device which has a coherent light source that emits a first coherent light beam and a second coherent light beam, an optical device that diffuses the first coherent light beam to illuminate a first illumination zone and diffuses a wave of the second coherent light beam to illuminate a second illumination zone, and a timing control unit that individually controls incidence timing of the first coherent light beam and the second coherent light beam on the optical device or illumination timing of the first illumination zone and the second illumination zone, wherein the optical device includes a first diffusion region on which the first coherent light beam is incident, and a second diffusion region on which the second coherent light beam is incident, the first diffusion region is capable of illuminating the first illumination zone by diffusion of the incident first coherent light beam.