Abstract: An LED die includes a multi-layer semiconductor with a first surface, a second surface opposite to the first surface, an inclined plane connecting to the first surface and the second surface, a first electrode and a second electrode respectively positioned on the first surface and the second surface, a first heat dissipation layer made of electrically-insulating and thermally conductive material being coated on the first surface and the inclined plane with a first opening exposing the first electrode, and a second heat dissipation layer made of electrically and thermally conductive material being coated on the first heat dissipation layer and contacting and electrically connecting with the first electrode.

Abstract: An LED package includes a base, an LED chip, and an encapsulant. The LED chip is mounted on the base, and is enclosed by the encapsulant. The base includes a substrate and a blocking wall integrally formed with the substrate. The blocking wall divides a surface of the substrate into a first bonding area and a second bonding area. An electrically conductive layer and a solder are formed on the bonding area in sequence. The blocking wall can block the first and second solder to overflow outside the first and second bonding area at soldering respectively. A method for manufacturing the LED package is also provided.

Abstract: An optical engine of a light emitting diode (LED) light module comprises a heat dissipation device, an LED light bar and an optical component. The heat dissipation device comprises a base plate and a plurality of fin plates vertically welded onto a surface of the base plate. The LED light bar is disposed on an opposite surface of the base plate so that the LED light bar can dissipate heat through the fin plates. The optical component having a space for accommodating the LED light is provided to form a desired light distribution pattern.

Abstract: A package structure of a light emitting diode for a backlight comprises a long-wavelength LED die and a short-wavelength LED die. The lights emitted from the two LED dies are mixed with the light emitted from excited fluorescent powders for serving as the backlight of a liquid crystal display. A partition plate is disposed between the two LED dies for separating them from each other. The effective light output of the package structure is increased because each of the two LED dies cannot absorb the light from the other.

Abstract: A planar light source apparatus includes a plurality of elongated lighting elements disposed in a common plane, and a plurality of mirror reflectors arranged perpendicular to the common plane and facing the lighting elements. The lighting elements are equidistantly spaced from each other. The lighting elements face a same direction. The mirror reflectors frame the lighting elements. The mirror reflectors each have a reflecting surface facing the lighting elements. The reflecting surfaces are perpendicular to the common plane. A distance between one of the reflectors and its nearest lighting element is maximum of half the distance between two adjacent lighting elements.

Abstract: A method for fabricating an LED chip is provided. Firstly, a SiO2 pattern layer is formed on a top surface of a substrate. Then, lighting structures are grown on a portion of the top surface of substrate without the SiO2 pattern layer thereon. Thereafter, the SiO2 pattern layer is removed by wet etching to form spaces between bottoms of the lighting structures and substrate. An etching solution is used to permeate into the spaces and etch the lighting structures from the bottoms thereof, whereby the lighting structures each with a trapezoid shape is formed. Sidewalls of each of the lighting structures are inclined inwardly along a top-to-bottom direction.

Abstract: A method of manufacturing a vertical light emitting diode includes: providing a first substrate; forming a lapping stop layer on the first substrate, the lapping stop layer being harder than the first substrate; depositing an epitaxial layer on the lapping stop layer; bonding a second substrate on the epitaxial layer; and removing the first substrate from the lapping stop layer.

Abstract: An LED package structure includes a transparent substrate having a supporting face and a light-emergent face opposite to the supporting face, a housing disposed on the supporting face, two electrodes disposed on the housing, an LED chip disposed on the supporting face and electrically connected to the two electrodes, a reflecting layer covering the LED chip to reflect light emitted by the LED chip toward the transparent substrate, and a phosphor layer formed on the light-emergent face of the substrate. The phosphor layer includes a plurality of layers each having a specific light wavelength conversion range to generate a light with a predetermined color.

Abstract: A wavelength conversion layer is formed on a surface of a light emitting device for transforming a portion of light emitted from the light emitting device into light of a different wavelength. The transformed light is mixed with the untransformed light, and thus the light emitting device can emit light having preferred CIE coordinates.

Abstract: A semiconductor device fabrication method is disclosed. A buffer layer is provided and a first semiconductor layer is formed on the buffer layer. Next, a first intermediate layer is formed on the first semiconductor layer by dopant with high concentration during an epitaxial process. A second semiconductor layer is overlaid on the first intermediate layer. A semiconductor light emitting device is grown on the second semiconductor layer. The formation of the intermediate layer and the second semiconductor layer is a set of steps.

Abstract: A method for separating a semiconductor from a substrate is disclosed. The method comprises the following steps: forming a plurality of columns on a substrate; epitaxially growing a semiconductor on the plurality of columns; and injecting etching liquid into the void among the plurality of columns so as to separate the semiconductor from the substrate. The method of this invention can enhance the etching efficiency of separating the semiconductor from the substrate and reduce the fabrication cost because the etching area is increased due to the void among the plurality of columns. In addition, the method will not confine the material of the above-mentioned substrate.

Abstract: An LED lamp includes an illumination apparatus and a heat-dissipating waterproof cover. The illumination apparatus includes LED modules; and the heat-dissipating waterproof cover is configured to cover the LED modules. The heat-dissipating waterproof cover includes a plurality of drain members, and a gap is formed between every two drain members so as to increase the air convection, thereby increasing heat dissipation efficiency of the LED modules. Every two adjacent drain members are partially overlapping in vertical to prevent the intrusion of water.

Abstract: A method for manufacturing a number of LED packages includes following steps: providing an electrode plate and at least one insulating plate; thermally pressing the electrode plate and the at least insulating plate together, wherein the electrode has a plurality of first and second electrodes; grinding two ends of the electrode plate to expose the first and second electrodes for obtaining a substrate; disposing a plurality of LED chips on the substrate plate and electrically connecting the LED chips to the first and second electrodes; and cutting the substrate plate to obtain the number of LED packages.

Abstract: A planar light source apparatus includes a number of lighting elements disposed in a common plane, and a number of mirror reflectors arranged perpendicular to the common plane and facing the lighting elements. The mirror reflectors each have a reflecting surface facing the lighting elements. The light elements are arranged in a lattice such that the distance from one of the reflectors to the nearest lighting element is a maximum of the half the distance between two adjacent lighting elements.

Abstract: A light module of a LCD backlight module includes a circuit board and a plurality of light-emitting diodes (LEDs) arranged on the circuit board. Each of the LEDs has a wide far-field pattern, and each of the LEDs includes at least one LED chip and a molding unit packaging the LED chip. The LED chip is electrically connected to the circuit board.

Abstract: A light emitting diode (LED) lighting device is provided. The LED lighting device includes an LED light bar and a passive heat sink. The passive heat sink includes a base and a plurality of heat sink fins. The LED light bar is placed on one side of the base, and the heat sink fins are placed on the other side of the base. The fins are fixed on the base by soldering.

Abstract: A method for fabricating a photoelectric device initially provides a ceramic substrate comprising a thermal dissipation layer on a bottom layer of the ceramic substrate, an electrode layer on the top surface of the ceramic substrate, and a reflective structure in cavities of the ceramic substrate. Next, a plurality of photoelectric dies is disposed on the top surface of the ceramic substrate. Then, a first packaging layer is formed on the top surfaces of the photoelectric dies. Next, the ceramic substrate is placed between an upper mold and a lower mold. Finally, a plurality of lenses is formed on the top surface of the first packaging layer by using an injection molding technique or a transfer molding technique.