It is provided a heat discharge structure for a light source device emitting a semiconductor laser. The structure fixes the light source device and discharges heat. The structure includes a film of a nitride of a group 13 element having a first main face, a second main face and an outer side end face. The structure further includes a portion for containing the light source device. The portion has a through hole opening at the first main face and the second main face, and a fixing face for fixing the light source device. The fixing face faces the through hole and contacts the light source device.

The present invention provides a LED package in which deterioration in heat radiation performance is suppressed. The LED package comprises a substrate, a light-emitting device mounted on the substrate, sealing resin sealing the light-emitting device and mixed with phosphor, a heat sink provided on a rear surface of the substrate, and a rear electrode provided on the rear surface of the substrate and electrically connected to the light-emitting device. The heat sink is provided at a distance from the rear electrode in a region except for the rear electrode. The heat sink is divided into eighteen small heat sinks by grooves formed in a rectangular lattice pattern. When the LED package is mounted on a mounting substrate, the gas generated from solder is efficiently discharged through the grooves to the outside, thereby suppressing the generation of air bubbles between the heat sink and the solder.

A light emitting device includes a first semiconductor laser element configured to emit light in a first direction, and second and third semiconductor laser elements spaced apart in a second direction perpendicular to the first direction, a base member, and wires. The base member includes a bottom part, a frame part, and first and second electrode layers. The second electrode layer is disposed on a planar surface of the frame part intersecting at least a part of an inner surface. In the top view, the planar surface is not arranged on a side spaced apart from the semiconductor laser elements in the first direction. The wire connecting the second semiconductor laser element to the base member is bonded to the second electrode layer disposed on the planar surface arranged on a side spaced apart from the semiconductor laser elements in a direction opposite to the first direction.

A light source cooling body (100), a light source assembly, a luminaire and a method to manufacture a light source cooling body or a light source assembly are provided. The light source cooling body comprises a homogeneous body (104) made of a thermally conductive material. The homogenous body comprises an open space that comprises a wick structure, a condenser (112) and an evaporator (116). Near the evaporator the light source cooling body has an interface area (102) to thermally couple with a light source and to receive heat from the light source. The condenser is arranged away from the interface area. A portion 114 of the open space is tubular shaped. The open space may hold a cooling liquid partially in the gaseous phase and partially in the liquid phase and the wick structure is configured to transport the cooling material in the liquid phase towards the evaporator.

There is provided an electronic component mounting substrate which excels in resistance to migration, and is thus capable of maintaining high thermal conductivity and insulation performance for a long period of time. An electronic component mounting substrate includes: a metallic substrate formed of aluminum or an aluminum-based alloy; an alumite layer disposed on the metallic substrate, having a network of crevices at an upper surface thereof; and a ceramic layer disposed on the alumite layer, part of the ceramic layer extending into the crevices.

The present invention provides various embodiments for apparatuses, systems, and methods of manufacturing surface mountable devices. Some embodiments provide surface mount devices comprising a casing with a first and second surface and at least one side surface. A recess is formed in the first surface and extends into the casing. plurality of leads is partially encased by the casing, and one or more electronic devices are coupled with at least one of the plurality of leads and are at least partially exposed through the recess. A heat sink may be included for heat dissipation.

The present disclosure is to provide an optoelectronic device. The optoelectronic device comprises a heat dispersion substrate; a first connecting layer on the heat dispersion substrate; a diode stack structure comprising a protection layer and a second connecting layer on the protection layer, wherein the protection layer is on the first connecting layer; a light-emitting structure on the diode stack structure, wherein the light-emitting structure comprises a first conductivity type semiconductor layer, a second conductivity type semiconductor layer, and an active layer between the first conductivity type semiconductor layer and the second conductivity type semiconductor layer; and a first electrode electrically connected to the diode stack structure and the light-emitting structure.

A light emitting diode package for a directional display may comprise light emitting diodes and a protection diode. The protection diode may be arranged in a well that is at a different location to the well that the light emitting diodes are arranged. The directional display may include a waveguide. The waveguide may include light extraction features arranged to direct light from an array of light sources by total internal reflection to an array of viewing windows and a reflector arranged to direct light from the waveguide by transmission through extraction features of the waveguide to the same array of viewing windows. The brightness of the directional display can be increased. An efficient and bright directional display system can be achieved. Efficient light baffling for light escaping from the edge of the waveguide is achieved through light deflecting extraction films.

A light emitting device package including a base including a top flat surface; an insulating layer on the base; a light emitting diode on the base; an optical member comprising a light transmissive material such that light emitted from the light emitting diode passes therethrough; a guiding member to guide the optical member, the guiding member having a ring shape; an electrical circuit layer electrically connected to the light emitting diode, the electrical circuit layer including an electrode portion and an extended portion, the electrode portion disposed inside the guiding member and electrically connected to the light emitting diode, the extended portion extended from the electrode portion to outside the guiding member; and an electrode layer on the electrode portion of the electrical circuit layer and electrically connected to the light emitting diode.

A substrate includes a plurality of through electrodes. The through electrode has a nanocomposite structure including a nm-sized carbon nanotube and is a casting formed by using a via formed in the substrate as a mold.