Abstract: A curved full-array LED light panel, a curved backlight module including the curved full-array LED light panel, and a curved LCD including the backlight module are disclosed. The curved full-array LED light panel includes a flexible reflective sheet and a plurality of LED light bars wherein a plurality of LEDs are disposed. The plurality of LED light bars are attached to a sheet-rear side of the flexible reflective sheet alone a direction parallel to the height direction of the full-array LED light panel, and the plurality of LEDs disposed on the LED light bars are exposed from a plurality of openings of the flexible reflective sheet toward an LCD panel. Along a direction parallel to the width direction of the full-array LED light panel, the flexible reflective sheet is deformed to form a curved reflective surface. Each of the LED light bars further comprises a bar-shaped PCB, and a plurality of LED dimming-zone circuits are disposed on the bar-shaped PCB.

Abstract: A chip-scale packaging (CSP) light-emitting device (LED) is provided with an electrode polarity identifier, and includes a light-emitting semiconductor chip and a packaging structure. A first horizontal direction and a perpendicular second horizontal direction are specified on a semiconductor-chip-upper surface. The packaging structure covers the semiconductor-chip-upper surface, a first semiconductor-chip-side surface and a second semiconductor-chip-side surface of the light-emitting semiconductor chip, and includes a first package-side surface and a second package-side surface. A first region is between the first package-side surface and the first semiconductor-chip-side surface, and a second region is between the second package-side surface and the second semiconductor-chip-side surface, wherein an area of the first region is different from an area of the second region.

Abstract: A chip-scale linear light-emitting device includes a submount substrate, light-emitting diode (LED) semiconductor chips, a chip-scale packaging structure and a reflective structure. The LED semiconductor chips, the packaging structure and the reflective structure are disposed on the submount substrate, wherein the packaging structure partially covers the chip-upper surface and/or the chip-edge surfaces of the LED semiconductor chips, and the reflective structure partially covers the package-top surface and/or the package-side surfaces of the packaging structure. If one of the chip-edge surfaces and the package-side surface of the packaging structure are exposed from the reflective structure as a primary light-emitting side surface, a side-view type linear light-emitting device is formed. If the package-top surface of the packaging structure is exposed from the reflective structure as a primary light-emitting top surface, a top-view type linear light-emitting device is formed.

Abstract: An asymmetrically shaped chip-scale packaging (CSP) light-emitting device (LED) includes an LED chip, a photoluminescent structure (or a light-transmitting structure), and a reflective structure. The photoluminescent structure covers the upper surface and/or the edge surface of the LED chip; and the reflective structure at least partially covers the edge surface of the photoluminescent structure. The reflective structure partially reflects the primary light emitted from the edge surface of the LED chip or the converted secondary light radiated from the edge surface of the photoluminescent structure, therefore shaping the radiation pattern asymmetrically.

Abstract: A chip-scale linear light-emitting device includes a submount substrate, light-emitting diode (LED) semiconductor chips, a chip-scale packaging structure and a reflective structure. The LED semiconductor chips, the packaging structure and the reflective structure are disposed on the submount substrate, wherein the packaging structure partially covers the chip-upper surface and/or the chip-edge surfaces of the LED semiconductor chips, and the reflective structure partially covers the package-top surface and/or the package-side surfaces of the packaging structure. If one of the chip-edge surfaces and the package-side surface of the packaging structure are exposed from the reflective structure as a primary light-emitting side surface, a side-view type linear light-emitting device is formed. If the package-top surface of the packaging structure is exposed from the reflective structure as a primary light-emitting top surface, a top-view type linear light-emitting device is formed.

Abstract: A light-emitting device includes a flip-chip LED semiconductor chip to provide a primary light, a photoluminescent (PL) structure disposed on the LED semiconductor chip and a moisture-barrier reflective structure covering a chip-edge surface of the LED semiconductor chip and a photoluminescent-side surface of the PL structure. The sequentially stacked PL structure includes a first PL layer, a transparent isolation layer, a second PL layer and a transparent moisture barrier layer. For example, the LED semiconductor chip emits a blue light, the first PL layer includes a red phosphor material, and the second PL layer includes a green quantum dot (QD) material. Therefore, the red phosphor material of the first PL layer can convert a portion of the higher-energy-level blue light into a lower-energy-level converted red light, so as to reduce an intensity of an unconverted portion of the blue light reaching the green QD material within the second PL layer.

Abstract: An asymmetrically shaped chip-scale packaging (CSP) light-emitting device (LED) includes an LED chip, a photoluminescent structure (or a light-transmitting structure), and a reflective structure. The photoluminescent structure covers the upper surface and/or the edge surface of the LED chip; and the reflective structure at least partially covers the edge surface of the photoluminescent structure. The reflective structure partially reflects the primary light emitted from the edge surface of the LED chip or the converted secondary light radiated from the edge surface of the photoluminescent structure, therefore shaping the radiation pattern asymmetrically.

Abstract: A chip-scale linear light-emitting device includes a submount substrate, light-emitting diode (LED) semiconductor chips, a chip-scale packaging structure and a reflective structure. The LED semiconductor chips, the packaging structure and the reflective structure are disposed on the submount substrate, wherein the packaging structure partially covers the chip-upper surface and/or the chip-edge surfaces of the LED semiconductor chips, and the reflective structure partially covers the package-top surface and/or the package-side surfaces of the packaging structure. If one of the chip-edge surfaces and the package-side surface of the packaging structure are exposed from the reflective structure as a primary light-emitting side surface, a side-view type linear light-emitting device is formed. If the package-top surface of the packaging structure is exposed from the reflective structure as a primary light-emitting top surface, a top-view type linear light-emitting device is formed.

Abstract: A chip scale packaging (CSP) light emitting diode (LED) device includes a flip-chip LED semiconductor die and a beam shaping structure (BSS) to form a monochromatic CSP LED device. A photoluminescent structure can be disposed on the LED semiconductor die to form a phosphor-converted white-light CSP LED device. The BSS is fabricated by dispersing light scattering particles with concentration equal to or less than 30% by weight into a polymer resin material, and is disposed adjacent to the edge portion of the photoluminescent structure or the LED semiconductor die; or disposed remotely above the photoluminescent structure or the LED semiconductor die. The BSS disposed at the edge portion of the device can reduce the edge-emitting light of the device; while the BSS disposed at the top portion of the device can reduce the top-emitting light of the device, therefore shaping the radiation pattern and the viewing angle of the device.

Abstract: A light emitting device, including an LED semiconductor die, a photoluminescent structure and a reflector, is disclosed. The photoluminescent structure with a beveled edge surface is disposed on top of the LED semiconductor die, wherein a lower surface of the photoluminescent structure adheres to an upper surface of the LED semiconductor die. A reflective resin material is disposed surrounding edge surfaces of the LED semiconductor die and the photoluminescent structure forming a beveled reflector. A method to manufacture the above light emitting device is also disclosed. Advantages of this light emitting device with beveled reflector include increasing the light extraction efficiency, making the viewing angle tunable, improving spatial color uniformity and reducing the light source etendue realized in a compact form-factor size.

Abstract: An asymmetrically shaped chip-scale packaging (CSP) light-emitting device (LED) includes an LED chip, a photoluminescent structure (or a light-transmitting structure), and a reflective structure. The photoluminescent structure covers the upper surface and/or the edge surface of the LED chip; and the reflective structure at least partially covers the edge surface of the photoluminescent structure. The reflective structure partially reflects the primary light emitted from the edge surface of the LED chip or the converted secondary light radiated from the edge surface of the photoluminescent structure, therefore shaping the radiation pattern asymmetrically.

Abstract: A method for mass arrangement of micro-component devices includes the following process stages: disposing the micro-component devices to float on a liquid suspending medium, wherein the micro-component devices are spaced apart from each other with a larger initial gap along a first direction and along a second direction; using electromagnetic force to actuate the floating micro-component devices to move closer so that the micro-component devices become spaced apart from each other with a smaller specified target gap along the first and the second directions; and transferring the arranged micro-component devices with the target gap on a carrier substrate. A system for arranging the micro-component devices is also disclosed to implement the method. Therefore, a precisely arranged array of the micro-component devices can be formed on a target application substrate.

Abstract: A vacuum system for film lamination, including a vacuum chamber module, a film-pressing module, a substrate susceptor module and a hot-plate heating module, is disclosed, wherein the film-pressing module includes a film-pressing platen, and the substrate susceptor module includes a substrate susceptor supported by a spring-loaded mechanism. During a film-lamination process, the film-pressing platen is actuated to move downwards to attach a laminating film onto a substrate, and the substrate susceptor is actuated to move downwards and finally rest on the hot-plate heating module. Therefore an adhesive glue disposed between the laminating film and the substrate can be thermally cured. After completing the film-lamination process, the film-pressing platen is actuated upwards so that the substrate susceptor also is actuated to move upwards to its initial position by a restoring force exerted by the spring-loaded mechanism.

Abstract: A monochromatic chip-scale packaging (CSP) light emitting diode (LED) device with an asymmetrical radiation pattern, including a flip-chip LED semiconductor die, and a reflective structure, is disclosed. A white-light broad-spectrum CSP LED device with asymmetrical radiation pattern is also disclosed by further including a photoluminescent structure in the CSP LED device. The photoluminescent structure covers at least the upper surface of the LED semiconductor die. The reflective structure adjacent to the LED semiconductor die and the photoluminescent structure reflects at least partial light beam emitted from the edge surface of the LED semiconductor die or the edge surface of the photoluminescent structure, therefore shaping the radiation pattern asymmetrically. A method to fabricate the aforementioned CSP LED device is also disclosed.

Abstract: A Chip-Scale Packaging (CSP) LED device and a method of manufacturing the same are disclosed. The CSP LED device includes a flip-chip LED semiconductor die and a packaging structure, wherein the packaging structure comprises a soft buffer layer, a photoluminescent structure and an encapsulant structure. The soft buffer layer includes a top portion formed on top of the flip-chip LED semiconductor die, and an edge portion formed covering an edge surface of the flip-chip LED semiconductor die, wherein the top portion has a convex surface, and the edge portion has an extension surface smoothly adjoining the convex surface. The photoluminescent structure is formed on the soft buffer layer covering the convex surface and the extension surface of the soft buffer layer. The encapsulant structure, which has a hardness not lower than that of the buffer layer, is formed on the photoluminescent structure.

Abstract: A photoluminescent display device includes a blue light source and a photoluminescent display panel adjoining the blue light source. The photoluminescent display panel includes a transparent substrate, a color filter structure and a photoluminescent structure. The color filter structure includes a red pixel region, a green pixel region and a blue pixel region arranged adjacent to one another on the transparent substrate. The photoluminescent structure, which is disposed on the color filter structure and is facing toward the blue light source, includes a red light-conversion layer and a green light-conversion layer, wherein the red light-conversion layer is disposed on the green light-conversion layer.

Abstract: A chip-scale packaging (CSP) LED device, comprising an LED semiconductor die and a packaging structure, is disclosed. The LED semiconductor die is encapsulated by the packaging structure, wherein the lower surface of the packaging structure has a recessed space underneath. A manufacturing method of the CPS LED device is also disclosed.

Abstract: A chip-scale packaging (CSP) light-emitting device (LED), including a light-emitting semiconductor die, a photoluminescent layer, a chip-side-spacer structure, and a beveled chip reflective structure, is disclosed. The beveled reflective structure is disposed surrounding the chip-edge surfaces of the light-emitting semiconductor die, wherein the chip-side-spacer structure is disposed between the beveled reflective structure and the chip-edge surfaces of the light-emitting semiconductor die. A manufacturing method to fabricate the CSP LED is also disclosed. The CSP LED with a beveled chip reflector can effectively reflect the light radiated from the light-emitting semiconductor die toward the photoluminescent layer so that the light extraction efficiency is improved.

Abstract: A chip-scale linear light-emitting device includes a submount substrate, light-emitting diode (LED) semiconductor chips, a chip-scale packaging structure and a reflective structure. The LED semiconductor chips, the packaging structure and the reflective structure are disposed on the submount substrate, wherein the packaging structure partially covers the chip-upper surface and/or the chip-edge surfaces of the LED semiconductor chips, and the reflective structure partially covers the package-top surface and/or the package-side surfaces of the packaging structure. If one of the chip-edge surfaces and the package-side surface of the packaging structure are exposed from the reflective structure as a primary light-emitting side surface, a side-view type linear light-emitting device is formed. If the package-top surface of the packaging structure is exposed from the reflective structure as a primary light-emitting top surface, a top-view type linear light-emitting device is formed.

Abstract: A chip-scale packaging (CSP) light-emitting device (LED) is provided with an electrode polarity identifier, and includes a light-emitting semiconductor chip and a packaging structure. A first horizontal direction and a perpendicular second horizontal direction are specified on a semiconductor-chip-upper surface. The packaging structure covers the semiconductor-chip-upper surface, a first semiconductor-chip-side surface and a second semiconductor-chip-side surface of the light-emitting semiconductor chip, and includes a first package-side surface and a second package-side surface. A first region is between the first package-side surface and the first semiconductor-chip-side surface, and a second region is between the second package-side surface and the second semiconductor-chip-side surface, wherein an area of the first region is different from an area of the second region.