Abstract: A miniaturized structured light projection module is provided. The miniaturized structured light projection module includes a light source assembly and a projecting lens. The light source assembly has a plurality of light source units, each of which is provided with a default projected pattern on its surface. The projecting lens is disposed above the light source units. The default projected patterns of the light source units are disposed on a front focal plane of the projecting lens.

Abstract: The present disclosure discloses a light emitting diode (LED) package structure, a heat-dissipating substrate, and a method for manufacturing a heat-dissipating substrate. The heat-dissipating substrate includes a first heat-dissipating block, a heat-dissipating plate and a second heat-dissipating block, spaced apart each other, and a lateral insulating member connected to thereof so as to electrically isolate the first heat-dissipating block, the second heat-dissipating block, and the heat-dissipating plate from each other. The first heat-dissipating block, the second heat-dissipating block, and the heat-dissipating plate each has two protrusions respectively formed on two opposite surfaces thereof. A height of each of the protrusions is at a micro level.

Abstract: An LED package structure includes a multilayer circuit board, an LED chip, and a cover. The multilayer circuit board has a conductive layer, a first resin layer disposed on the conductive layer, and a first circuit layer disposed on the first resin layer. The first resin layer has a first opening, and a portion of the conductive layer is partially exposed from the first resin layer via the first opening such that a mounting region is exposed. The first circuit layer has a second opening, and the second opening exposes the mounting region. The LED chip is fixed on the mounting region by passing it through the first and second openings, and the LED chip is connected to the first circuit layer by wires. The cover is disposed on the first resin layer and covers the LED chip and the first circuit layer.

Abstract: A lead frame includes a main plate and a side plate. The main plate has a support portion and a projecting portion. The support portion has two opposite first sides and a support face located between the first sides. The projecting portion projects upward from one of the first sides in a direction opposite to the support face. The side plate is disposed separately from the one of the first sides of the support portion and is spaced apart from the projecting portion.

Abstract: An LED package structure includes a multilayer circuit board, an LED chip, and a cover. The multilayer circuit board has a conductive layer, a first resin layer disposed on the conductive layer, and a first circuit layer disposed on the first resin layer. The first resin layer has a first opening, and a portion of the conductive layer is partially exposed from the first resin layer via the first opening such that a mounting region is exposed. The first circuit layer has a second opening, and the second opening exposes the mounting region. The LED chip is fixed on the mounting region by passing it through the first and second openings, and the LED chip is connected to the first circuit layer by wires. The cover is disposed on the first resin layer and covers the LED chip and the first circuit layer.

Abstract: An optical sensor module has a light receiver and a light-emitter which is surrounded by a light blocking wall, wherein the light receiver is disposed on a main plate and the light-emitter is disposed on a side plate separately from the main plate. The light blocking wall is formed as a light barrier wall between the light receiver and the light-emitter. A projecting portion projecting upward from the main plate is enclosed by the light barrier wall, and a top face of the projecting portion is higher than the light receiving face and the light-emitting face.

Abstract: An LED package structure includes a substrate, an electrode layer and an insulating layer disposed on the substrate with a coplanar arrangement, an LED chip mounted on the electrode layer and the insulating layer, a phosphor plate covering a top surface of the LED chip, and a reflective housing disposed on the electrode layer and the insulating layer and covering side surfaces of the LED chip and side surfaces of the phosphor plate. An opening is formed on the top surface of the reflective housing so as to expose a light emitting surface of the phosphor plate. A distance between the top surface of the reflective housing and the substrate is greater than a distance between the light emitting surface of the phosphor plate and the substrate. A distance between the top surface of the reflective housing and the light emitting surface is in a range of 10˜30 ?m.

Abstract: An LED package structure includes a substrate, an electrode layer and an insulating layer in a coplanar arrangement and disposed on the substrate, an LED chip mounted on the electrode layer and the insulating layer, a phosphor sheet covering entirely a top surface of the LED chip, a first translucent layer disposed on a light emitting surface of the phosphor sheet, and a reflective housing covering the side surfaces of the LED chip and the side surfaces of the phosphor sheet. The light emitting surface has a central region and a ring-shaped region surrounding the central region. The first translucent layer covers at least 60% of an area of the ring-shaped region. A refractive index of the first translucent layer is larger than one and is smaller than that of the phosphor sheet. A top surface of the reflective housing is substantially flush with the light emitting surface.

Abstract: An optical sensor module has a light receiver and a light-emitter which is surrounded by a light blocking wall, wherein the light receiver is disposed on a main plate and the light-emitter is disposed on a side plate separately from the main plate. The light blocking wall is formed as a light barrier wall between the light receiver and the light-emitter. A projecting portion projecting upward from the main plate is enclosed by the light barrier wall, and a top face of the projecting portion is higher than the light receiving face and the light-emitting face.

Abstract: An LED package structure includes a chip carrier and an LED chip. The chip carrier includes a ceramic substrate, a circuit layer, a ceramic reflective plate disposed on the ceramic substrate, and a metal slug. The ceramic substrate has a first thru-hole. A main portion of the metal slug is embedded in the first thru-hole, and partially protrudes from the first thru-hole with a height of 10˜30 ?m to define as a protrusion block. An extending portion of the metal slug is connected to the outer edge of protrusion block, and the top surfaces of extending portion and protrusion block are coplanar to define a mounting surface. The ceramic reflective plate has a second thru-hole, and the mounting surface is exposed from the ceramic reflective plate via the second thru-hole. The LED chip is fixed on the mounting surface and is electrically connected to the circuit layer.

Abstract: An optical sensor module includes a support unit, a light-receiving unit and a light-emitting unit. The support unit includes a main plate, and a side plate inclined relative to the main plate. The light-receiving unit includes a photodetector disposed on the main plate and having a light-receiving surface located away from the main plate, and a light-blocking member covering part of the photodetector. The light-emitting unit emits light toward an imaginary line perpendicular to the light-receiving surface, and is disposed on the side plate. A wearable device including the optical sensor is also disclosed.

Abstract: A method of manufacturing LED packages includes the steps of: forming a conductive circuit layer on a substrate; screen printing a wall layer on the conductive circuit layer to form a trellis with a plurality of wall units, so that regions of the conductive circuit layer surrounded by the wall units are exposed; mounting and electrically connecting at least one LED die on the conductive circuit layer within each of the wall units; molding a transparent layer to cover the LED dies; and cutting along the wall units to form a plurality of LED packages.

Abstract: An LED package structure includes a substrate, a circuit layer and an insulating layer both disposed on the substrate, a light-emitting unit, and a reflective housing integrally formed with the insulating layer. The light-emitting unit includes an LED chip and a fluorescent body encapsulating the LED chip. The light-emitting unit is mounted on the insulating layer and the circuit layer. The fluorescent body of the light emitting unit is spaced apart from the circuit layer with a gap in a range of 3˜10 ?m. The reflective housing is formed on the insulating layer and the circuit layer and is further filled within the gap. A top plane of the reflective housing arranged away from the substrate is lower than or equal to that of the light-emitting unit, and a distance between the two top planes is in a range of 0˜30 ?m.

Abstract: An LED carrier includes a substrate, a metallic layer, an insulating layer, and a reflecting layer. The metallic layer is disposed on the substrate and has a die bonding region and a ring-shaped wiring region separated from the die bonding region. A region arranged between the die bonding region and the ring-shaped wiring region is defined as an insulating region. The insulating layer at least partially covers the insulating region. The reflecting layer is arranged above the die bonding region and at least partially covers the top surface of the insulating layer. Moreover, the instant disclosure also provides a manufacturing method of an LED carrier.

Abstract: An LED package includes a chip carrier, an adhesive layer, one high-voltage LED die, and an encapsulating member. The chip carrier defines a receiving space. The adhesive layer is disposed in the receiving space and has a thermal conductivity of larger than or equal to 1 W/mK. The high-voltage LED die is attached to the adhesive layer to be received in the reflective space and has a top surface formed with a trench. The trench of the high-voltage LED die is disposed at an optical center of the receiving space. The encapsulating member encapsulates the high-voltage LED die and includes a plurality of diffusers. The trench is embedded with the encapsulating member and has a width ranging from 1 ?m to 10 ?m and a depth of less than or equal to 50 ?m.

Abstract: An LED package structure includes a chip carrier and an LED chip. The chip carrier includes a ceramic substrate, a circuit layer, a ceramic reflective plate disposed on the ceramic substrate, and a metal slug. The ceramic substrate has a first thru-hole. A main portion of the metal slug is embedded in the first thru-hole, and partially protrudes from the first thru-hole with a height of 10˜30 ?m to define as a protrusion block. An extending portion of the metal slug is connected to the outer edge of protrusion block, and the top surfaces of extending portion and protrusion block are coplanar to define a mounting surface. The ceramic reflective plate has a second thru-hole, and the mounting surface is exposed from the ceramic reflective plate via the second thru-hole. The LED chip is fixed on the mounting surface and is electrically connected to the circuit layer.

Abstract: A metallic frame of an LED structure includes two conductive frames spaced apart from each other with a gap and a plurality of extending arms respectively and integrally extended from the conductive frames. Each conductive frame includes a top surface, a bottom surface, and a lateral surface connecting the top and bottom surfaces. Each top surface comprises a sealed region and a mounting region surrounded by the sealed region, and the sealed and mounting regions of each conductive frame are defined by an insulating body. Each conductive frame has at least one slot concavely formed on the sealed region, and the lateral surface is formed with two openings and the slot is communicated with the two openings, such that the slot of each of the conductive frames is configured to separate at least one of the extending arms from the mounting region of the conductive frames.

Abstract: A light emitting device includes a substrate having a top surface, upper and lower metal layers, multiple LED chips, at least one Zener diode, multiple conductive wires and an encapsulant. The top surface includes a central region bounded by an imaginary boundary with a profile conforming to an outline of a circle stacked with a polygon. The central region has a die bonding area corresponding to the circle, and at least one polygonal extension area formed outside the die bonding area. The upper metal layer includes multiple conducting pads surrounding the central region. The LED chips are disposed on the die bonding area. The Zener diode is disposed on the polygonal extension area. The encapsulant is disposed on the substrate and covers the LED chips.

Abstract: An LED package structure includes a multilayer circuit board, an LED chip, and a cover. The multilayer circuit board has a conductive layer, a first resin layer disposed on the conductive layer, and a first circuit layer disposed on the first resin layer. The first resin layer has a first opening, and a portion of the conductive layer is partially exposed from the first resin layer via the first opening such that a mounting region is exposed. The first circuit layer has a second opening, and the second opening exposes the mounting region. The LED chip is fixed on the mounting region by passing it through the first and second openings, and the LED chip is connected to the first circuit layer by wires. The cover is disposed on the first resin layer and covers the LED chip and the first circuit layer.

Abstract: A method of manufacturing LED packages includes the steps of: forming a conductive circuit layer on a substrate; screen printing a wall layer on the conductive circuit layer to form a trellis with a plurality of wall units, so that regions of the conductive circuit layer surrounded by the wall units are exposed; mounting and electrically connecting at least one LED die on the conductive circuit layer within each of the wall units; molding a transparent layer to cover the LED dies; and cutting along the wall units to form a plurality of LED packages.