Abstract: A light emitting device comprises a novel low-loss array of conductive vias embedded in a dielectric multilayer stack, to act as an electrically-conductive, low-loss, high-reflectivity reflector layer (CVMR). In one example the CVMR stack is employed between a reflective metal bottom contact and a p-GaN semiconductor flip chip layer. The CVMR stack comprises at least (3) layers with at least (2) differing dielectric constants. The conductive vias are arranged such that localized and propagating surface plasmons associated with the structure reside within the electromagnetic stopband of the CVMR stack, which in turn inhibits trapped LED modes coupling into these plasmonic modes, thereby increasing the overall reflectivity of the CVM R. This technique improves optical light extraction and provides a vertical conduction path for optimal current spreading in a semiconductor light emitting device. A light emitting module and method of manufacture are also described.

Abstract: Provided is a dispensing device including a cylinder; a static mixer that is mounted in the cylinder such that the outer circumferential surface thereof is closely attached to the entire inner wall surface of the cylinder; and a flow path block that has a flow path formed therein and is mounted on the upper portion of the cylinder, the flow path diverging into two or more flow paths. Fluids passing through the static mixer are continuously transferred while being repeatedly divided and mixed.

Abstract: There is provided a light emitting module and a method of manufacturing the same. The light emitting module includes a circuit board, and a plurality of light emitting devices disposed on the circuit board, wherein the plurality of light emitting devices include at least one light emitting device having a driving voltage less than an average driving voltage of the plurality of light emitting devices and at least one of light emitting devices adjacent thereto having a driving voltage greater than the average driving voltage. In the light emitting module, variations in driving voltages between light emitting modules that may be caused due to driving voltage dissipation in a light emitting device may be minimized.

Abstract: There is provided a light emitting module including: a circuit board; at least one light source part disposed on the circuit board; a wavelength conversion part coupled with the circuit board, the wavelength conversion part covering alight emitting surface of the light source part and converting a wavelength of light; and a coupling part coupling the wavelength conversion part to the circuit board.

Abstract: A heat sink and a method of manufacturing a heat sink for an LED light fixture. The heat sink is fabricated by roll forming a thin sheet of aluminum into a heat dissipating structure that has at least one surface that reflects light generated by the LEDs.

Abstract: Provided are a flip-chip nitride-based light emitting device having an n-type clad layer, an active layer and a p-type clad layer sequentially stacked thereon, comprising a reflective layer formed on the p-type clad layer and at least one transparent conductive thin film layer made up of transparent conductive materials capable of inhibiting diffusion of materials constituting the reflective layer, interposed between the p-type clad layer and reflective layer; and a process for preparing the same. In accordance with the flip-chip nitride-based light emitting device of the present invention and a process for preparing the same, there are provided advantages such as improved ohmic contact properties with the p-type clad layer, leading to increased wire bonding efficiency and yield upon packaging the light emitting device, capability to improve luminous efficiency and life span of the device due to low specific contact resistance and excellent current-voltage properties.

Abstract: A light emitting diode (LED) package including: an LED chip; a first lead frame having a heat transfer unit with a top where a groove for stably mounting the LED chip is formed; a second lead frame disposed separately from the first lead frame; a package body having a concave portion encapsulating a portion of the heat transfer unit and the second lead frame but exposing a portion of the top of the heat transfer unit and a portion of the lead frame, and a ring-shaped portion extended in a ring shape along an inner wall of the groove of the heat transfer unit and forming an aperture in a center thereof; and a phosphor layer formed on the aperture of the ring-shaped portion and applied to the LED chip, wherein the LED chip is disposed in the inside of the aperture of the ring-shape portion.

Abstract: Provided is a ceramic package for headlamp, and a headlamp module having the same. The ceramic package for headlamp includes a body part, a pair of internal electrodes, and an electrode exposing part. The body part has a cavity formed therein. The cavity is upwardly opened to expose a light emitting diode mounted on a mounting part. The pair of internal electrodes in the body part is electrically connected to the light emitting diode. The electrode exposing part is stepped at either side of the body part to upwardly expose the internal electrode to the outside.

Abstract: Provided is a nitride semiconductor light emitting diode (LED) including a substrate; an n-type nitride semiconductor layer formed on the substrate; an active layer formed on a portion of the n-type nitride semiconductor layer; a p-type nitride semiconductor layer formed on the active layer; a p-type contact layer formed on the p-type nitride semiconductor layer and doped with more than 1×1020/cm3 of p-type impurities; a transparent oxide electrode formed on the p-type contact layer; a p-electrode formed on the transparent oxide electrode; and an n-electrode formed on the n-type nitride semiconductor layer where the active layer is not formed.

Abstract: Provided is a method of manufacturing an LED package, the method including preparing a mold die which includes an upper surface and a lower surface having an outer circumferential surface and a concave surface surrounded by the outer circumferential surface, the mold die having an outlet extending from the upper surface to the lower surface; preparing a base having a light emitting section formed therein; forming an inlet formed in a predetermined region of the base excluding the region where the light emitting section is formed; positioning the mold die on the light emitting section; forming a mold member by injecting a molding compound into the inlet of the base; and removing the mold die.

Abstract: The present invention relates to an apparatus for forming a nano pattern capable of fabricating the uniform nano pattern at a low cost including a laser for generating a beam; a beam splitter for splitting the beam from the laser into two beams with the same intensity; variable mirrors for reflecting the two beams split by the beam splitter to a substrate; beam expansion units for expanding diameters of the beams by being positioned on paths of the two beams traveling toward the substrate; and a beam blocking unit, installed on an upper part of the substrate, transmitting only a specific region expanded through the beam expansion unit and blocking regions a remaining region, and a method for forming the nano pattern using the same.

Abstract: The invention relates to an LED package having a large beam angle of light emitted from an LED, simplifying a shape of a lens and an assembly process, and to a backlight unit using the same. The LED package includes a housing with a seating recess formed therein and at least one LED seated in the seating recess. The LED package also includes a lens having a predetermined sag on an upper side thereof, covering an upper part of the LED. The LED package and the backlight unit using the same can emit light uniformly without bright spots formed in an output screen, uses a simpler shaped lens with an increased beam angle, and minimizes a color mixing region to achieve miniaturization.

Abstract: A vertical nitride-based semiconductor LED comprises a structure support layer; a p-electrode formed on the structure support layer; a p-type nitride semiconductor layer formed on the p-electrode; an active layer formed on the p-type nitride semiconductor layer; an n-type nitride semiconductor layer formed on the active layer; an n-electrode formed on a portion of the n-type nitride semiconductor layer; and a buffer layer formed on a region of the n-type nitride semiconductor layer on which the n-electrode is not formed, the buffer layer having irregularities formed thereon. The surface of the n-type nitride semiconductor layer coming in contact with the n-electrode is flat.

Abstract: Provided is a light emitting diode (LED) package including a phosphor substrate; an LED chip mounted on the phosphor substrate; a circuit board mounted on the other region of the phosphor substrate excluding the region where the LED chip is mounted; an electrode connection portion for electrically connecting the LED chip and the circuit board; and a sealing member that covers the LED chip, the circuit board, and the phosphor substrate.

Abstract: An LED display with a reduced thickness is described. In one embodiment, the LED display includes a second support plate between a front support plate and a back support plate. The second support plate enables the front support plate to be thinner than if the second support plate was not included. The second support plate increases the distance between an LED chip and a light exit surface thereby allowing the front support plate thickness to be reduced by about the thickness of the second support plate. In one embodiment, the second support plate allows the thickness of an LED display to be thinner. The second support plate adds structural integrity to a back support plate. Therefore, the back support plate can be thinner, and thickness of the LED display can be reduced.

Abstract: An alternating current (AC) driven light emitting device includes a substrate, K number of first light emitting diode (LED) cells arranged in a row on a top surface of the substrate, where K is an integer satisfying K?3, K number of second LED cells arranged in a row parallel to the row of the first LED cells on the top surface of the substrate, and (K?1) number of third LED cells arranged in a row between the respective rows of the first and second LED cells on the top surface of the substrate. The AC driven light emitting device has a connection structure between LED cells to be operable at an AC.

Abstract: The present invention provides a compound semiconductor light emitting device including: an Si—Al substrate; protection layers formed on top and bottom surfaces of the Si—Al substrate; and a p-type semiconductor layer, an active layer, and an n-type semiconductor layer which are sequentially stacked on the protection layer formed on the top surface of the Si—Al substrate, and a method for manufacturing the same.