Abstract: A circuit structure of a package carrier including a plurality of chip pads, a first electrode, a second electrode, a third electrode and a fourth electrode is provided. These chip pads are arranged in an M×N array. A first bonding pad, a second bonding pad, a third bonding pad and a fourth bonding pad are disposed clockwise in the peripheral area of each chip pad in sequence. The orientations of each of the first, second, third, and fourth bonding pads of the (S?1)th row rotated by 90 degrees are equal to the orientations of each of the first, second, third and fourth bonding pads of the Sth row, respectively. The first electrode is connected with each first bonding pad. The second electrode is connected with each second bonding pad. The third electrode is connected with each third bonding pad. The fourth electrode is connected with each fourth bonding pad.

Abstract: The light emitting structure disclosed includes a light emitting device, a metal frame, and a repressing fastener. The light emitting device has a plurality of first coupling terminals, and the metal frame has a plurality of second coupling portions. The light emitting device is disposed in the metal frame, and the first coupling terminals touch the second coupling portions to electrically connect the light emitting device and the metal frame. The repressing fastener is disposed on the light emitting device and fastened to the metal frame to secure the light emitting device in the metal frame. An LED securing device is also disclosed.

Abstract: An LED package structure comprises an LED chip and a fuse electrically connected to the LED chip in series. The fuse has a low melting point such that the fuse melts under a high current to form an open circuit to prevent the high current from flowing through the LED chip.

Abstract: A tilt sensor including a body, an LED, a first photosensitive device, a second photosensitive device, and a moving thin-element is provided. The body has a movement region, a first containing region, a second containing region, and a third containing region. The first, second, and third containing regions have an opening respectively and are connected with the movement region through the openings. The LED providing a light beam is disposed in the first containing region. The first and second photosensitive devices are disposed in the second and third containing regions respectively. When the body tilts toward different tilt directions, the moving thin-element moves in the tilt direction, allowing the light beam provided from the LED to reflect directly to the first and second photosensitive devices, or shielding the light beam provided from the LED from being transmitted to the first and second photosensitive devices.

Abstract: A light emitting diode (LED) package and a manufacturing method therefor are disclosed. In one aspect, a manufacturing method of a light emitting diode package may: heat a first light transmission insulation material to cause the first light transmission insulation material to become a sticky member; connect a lead frame to the sticky member; perform a chip-bonding step that bonds at least one light-emitting diode chip on the sticky member using a light transmission glue; encapsulate the at least one light-emitting diode chip with a second light transmission insulation material; and perform a drying step that forms the sticky member and the second light transmission insulation material into shape.

Abstract: A light emitting diode structure including a light emitting device layer, a patterned dielectric layer, a first ohmic contact layer, a conductive layer, a first electrode layer and a second electrode layer is provided. The light emitting device layer has a first surface and a second surface opposite to the first surface. The patterned dielectric layer disposed on the first surface has a plurality of openings exposing a portion of the light emitting device layer. The first ohmic contact layer is disposed on the patterned dielectric layer and connected with the first light emitting device layer through the openings. The conductive layer is disposed on the first ohmic contact layer. The first electrode layer is disposed on the conductive layer, and the conductive layer is located between the first ohmic contact layer and the second electrode layer. A fabrication method of the light emitting diode structure is also provided.

Abstract: A light-emitting diode packaging structure comprises a light-emitting diode and first and second metal plates on which the light-emitting diode is mounted. The light-emitting diodes includes first and second electrode leads, the second electrode lead having first and second contact surfaces on an outer edge of the second electrode lead. The first metal plate includes at least one clamping portion that clamps and fixes the first electrode lead on the first metal plate. The second metal plate includes at least first and second clamping portions. The first contact surface of the second electrode lead contacts the first clamping portion, and the second contact surface of the second electrode lead contacts the second clamping portion, such that the light-emitting diode is fixed on the second metal plate in at least two dimensions parallel to a primary surface of the second metal plate on which the light-emitting diodes is mounted.

Abstract: A multi-chip package comprises a plurality of chip pads and a plurality of LED chips. The chip pads are arranged in an M×N array, M and N each a positive integer greater than 1. A peripheral area of each chip pad comprises a respective first bonding pad, a respective second bonding pad, and a respective third bonding pad arranged in sequence in a clockwise direction. A first orientation of the respective first to third bonding pads in a first row of the N rows differs from a second orientation of the respective first to third bonding pads in a second row of the N rows by 90 degrees. Each of the LED chips is disposed on a respective one of the chip pads and electrically connected to two of the respective first to third bonding pads on a same side of the respective LED chip.

Abstract: The present disclosure provides a light emitting diode. The light emitting diode includes a substrate having a first surface and an opposite second surface. At least one light emitting diode chip is disposed on the first surface of the ceramic substrate. A plurality of thermal metal pads are disposed on the second surface of the substrate, wherein the thermal metal pads are electrically isolated from the at least one light emitting diode chip.

Abstract: Various embodiments of a lighting module are described. In one aspect, a lighting module comprises a metal support, a circuit board, and a plurality of light emitting diodes. The metal support has a recess, sidewalls, and a plurality of holes on the sidewalls. The circuit board is fastened on a bottom portion of the recess of the metal support and has two long sides, two short sides, and a respective plurality of flanges on each of the two long sides. The flanges are inserted into the holes of the metal support to compact the circuit board and the metal support. The light emitting diodes are disposed on the circuit board.

Abstract: A light emitting diode (LED) package includes a LED package substrate, first LED chips and second LED chips. The LED package substrate includes a substrate, a first bonding pad, second bonding pads and a third bonding pad. The first, second and third bonding pads are disposed on the substrate. The second bonding pads are arranged in an array. The first and third bonding pads are located adjacent respectively to first and last column of the array. The first LED chips are die-bonded on the first bonding pad and wire-bonded respectively to the second bonding pads arranged in first column of the array. The second LED chips are die-bonded on the second bonding pads respectively. In each row except last column, each second LED chip is wire-bonded to the second bonding pad arranged in next column. The second LED chips located in last column are wire-bonded to the third bonding pad.

Abstract: A power supply unit with a dimming function which is adapted for a light emitting apparatus including a power system is provided. The power supply unit includes at least one output channel, a power stage, a detecting unit, and a micro controller unit (MCU). The power stage receives a first output of the power system and provides a first signal. The detecting unit detects a second output of the power system and provides a second signal. The MCU receives the first signal and the second signal, controls the at least one output channel, and is programmed to set a dimming ratio for the at least one output channel according to the first signal and the second signal. Furthermore, a light emitting apparatus and a dimming method are also provided.

Abstract: A light cover and an illuminating apparatus applying the same are provided. The illuminating apparatus comprises the light cover and a plurality of light sources. The light cover comprises a substrate provided with a plurality of recesses on a front surface and a plurality of lenses integrated with the substrate and respectively located in the recesses. The lenses are oriented in a same direction. The light sources are disposed corresponding to the lenses. Each of the light sources is adapted to emit a light. Each of the lenses is adapted to receive the light and transform the light into a predefined light output.