Abstract: A flip chip light emitting diode package structure includes a package carrier, a light guiding unit and at least one light emitting unit. The light guiding unit and the light emitting unit are disposed on the package carrier, and the light emitting unit is located between the light guiding unit and the package carrier. A horizontal projection area of the light guiding unit is greater than that of the light emitting unit. The light emitting unit is adapted to emit a light beam, and the light beam enters the light guiding unit and emits from an upper surface of the light guiding unit away from the light emitting unit.

Abstract: An optical assembly that is adapted to be located at a light path of light emitted from at least one light source and spaced apart from the at least one light source by a distance is provided. The optical assembly includes a wavelength converting device, which is a spatial structure, and a reflector. The reflector covers a portion of the wavelength converting device and exposes at least a portion of a region of at least one surface of the wavelength converting device. The light emitted from the at least one light source enters or leaves the wavelength converting device from at least the portion of area which is not covered by the reflector. An optical module including the light source and the optical assembly is further provided.

Abstract: A light emitting device includes a heat dissipation casing and an LED module. The heat dissipation casing includes an upper cover, a lower cover and a plurality of side covers. The upper cover has a plurality of first holes. The lower cover and the upper cover are opposite to each other. The side covers are connected to the upper cover and the lower cover, wherein there are at least two chamfered surfaces between the at least two side covers and the upper cover, and the chamfered surfaces have a plurality of second holes. The LED module is disposed inside the heat dissipation casing and located on the lower cover. The LED module has a light emitting surface, and the light emitting surface and the first and the second holes are respectively located on opposite sides of the LED module.

Abstract: An epitaxy base adapted to form a light-emitting device on is provided. The epitaxy base includes a substrate and a patterned wavelength conversion structure disposed on a part of the substrate and protruding out from the substrate. A light-emitting device including the epitaxy base, a first type semiconductor layer, an emitting layer and a second type semiconductor layer is provided. The first type semiconductor layer is disposed on the substrate and the patterned wavelength conversion structure. The emitting layer is disposed on the first type semiconductor layer. The second type semiconductor layer is disposed on the emitting layer.

Abstract: A touch sensing display including a carrier, a plurality of light emitting devices arranged in an array on the carrier, a driving unit electrically connected to the light emitting devices and a processing unit electrically connected to the light emitting devices and the driving unit is provided. The driving unit is configured to control the light emitting devices, so as to make a first part of the light emitting devices emit a first light. A second part of the light emitting devices are configured to receive a second light which is related to an object, and the processing unit is configured to determine a location of the object touching or approaching the carrier according to the electrical changes generated by the light emitting devices, which sense the second light, of the second part.

Abstract: A flip chip light emitting diode package structure includes a package carrier, a light guiding unit and at least one light emitting unit. The light guiding unit and the light emitting unit are disposed on the package carrier, and the light emitting unit is located between the light guiding unit and the package carrier. A horizontal projection area of the light guiding unit is greater than that of the light emitting unit. The light emitting unit is adapted to emit a light beam, and the light beam enters the light guiding unit and emits from an upper surface of the light guiding unit away from the light emitting unit.

Abstract: An optical module including a reflecting component, a plurality of first light sources and a wavelength conversion body is provided. The reflecting component has a main axis and a focal point located on the main axis. The first light sources are located at one side of the reflecting component and each of the first light sources emits a first light parallel to the main axis towards the reflecting component. The wavelength conversion body is disposed on the focal point, wherein the first lights are reflected to the focal point via the reflecting component and a part of the first lights are converted to a second light via the wavelength conversion body. The second light and another part of the first lights are projected to the reflecting component and form a light beam parallel to the main axis via reflection by the reflecting component.

Abstract: An optical module includes a first light source, a second light source and a wavelength conversion member. The first light source and the second light source emit light with different colors. The first light source and the second light source have a first light axis and a second light axis, respectively, and there is an intersection point of the first light axis and the second light axis. The wavelength conversion member is disposed at the intersection point of the first light axis and the second light axis.

Abstract: An optical module including a light source, an adjustable reflector and a wavelength conversion set is provided. The adjustable reflector is disposed in a light path of light emitted from the light source and adaptable to adjust between a first position and a second position. The wavelength conversion set includes a first wavelength conversion member and a second wavelength conversion member. When the adjustable reflector is at the first position, light emitted from the light source is reflected to the first wavelength conversion member by the adjustable reflector. When the adjustable reflector is at the second position, light emitted from the light source is reflected to the second wavelength conversion member by the adjustable reflector.

Abstract: A light-emitting diode package structure includes a package carrier, a light guiding component and a light emitting unit. The light guiding component is disposed on the package carrier. The light emitting unit is disposed on an upper surface of light guiding component relatively distant from the package carrier. A horizontal projection area of the light guiding component is greater than that of the light emitting unit. The light emitting unit is adapted to emit a light beam, and a portion of the light beam enters the light guiding component and emits from the upper surface of the light guiding component. An included angle existing between the light beam and a normal direction of the upper surface ranges from 0 degree to 75 degrees.

Abstract: A light-emitting module including a light emitting component, a heat dissipation element, and a light-converting component is provided. The light-emitting component is adapted to emit a light beam. The heat dissipation element is disposed at one side of the light-emitting component, wherein the heat dissipation element has a light through hole and the light through hole is located at a transmission path of the light beam. The light-converting component is connected to the heat dissipation element and covers the light through hole.

Abstract: An optical assembly that is adapted to be located at a light path of light emitted from at least one light source and spaced apart from the at least one light source by a distance is provided. The optical assembly includes a wavelength converting device, which is a spatial structure, and a reflector. The reflector covers a portion of the wavelength converting device and exposes at least a portion of a region of at least one surface of the wavelength converting device. The light emitted from the at least one light source enters or leaves the wavelength converting device from at least the portion of area which is not covered by the reflector. An optical module including the light source and the optical assembly is further provided.

Abstract: An optical module including at least one light source, a wavelength conversion member and a concave reflector is provided. Light emitted from the at least one light source enters the wavelength conversion member and then is sent out toward all directions. The concave reflector is disposed at one side of the wavelength conversion member, and a part of the light sent from the wavelength conversion member is reflected by the concave reflector.

Abstract: An epitaxy base adapted to form a light-emitting device thereon is provided. The epitaxy base includes a substrate and a patterned wavelength conversion structure disposed on a part of the substrate and protruding out from the substrate. A light-emitting device including the epitaxy base, a first type semiconductor layer, an emitting layer and a second type semiconductor layer is provided. The first type semiconductor layer is disposed on the substrate and the patterned wavelength conversion structure. The emitting layer is disposed on the first type semiconductor layer. The second type semiconductor layer is disposed on the emitting layer.

Abstract: A package material for packaging a photoelectric device includes a first molding portion and a second molding portion. The first molding portion is disposed on the photoelectric device. The first molding portion includes a first molding compound and a plurality of nano-scale metal oxide particles, wherein the nano-scale metal oxide particles are doped in the first molding compound. The second molding portion is disposed on the first molding portion and away from the photoelectric device. The second molding portion includes a second molding compound and a plurality of submicron-scale metal oxide particles, wherein the submicron-scale metal oxide particles are doped in the second molding compound. A whole refractive index of the first molding portion is larger than a whole refractive index of the second molding portion.

Abstract: A flip chip light emitting diode package structure includes a package carrier, a light guiding unit and at least one light emitting unit. The light guiding unit and the light emitting unit are disposed on the package carrier, and the light emitting unit is located between the light guiding unit and the package carrier. A horizontal projection area of the light guiding unit is greater than that of the light emitting unit. The light emitting unit is adapted to emit a light beam, and the light beam enters the light guiding unit and emits from an upper surface of the light guiding unit away from the light emitting unit.

Abstract: A light-emitting diode package structure includes a package carrier, a light guiding component and a light emitting unit. The light guiding component is disposed on the package carrier. The light emitting unit is disposed on an upper surface of light guiding component relatively distant from the package carrier. A horizontal projection area of the light guiding component is greater than that of the light emitting unit. The light emitting unit is adapted to emit a light beam, and a portion of the light beam enters the light guiding component and emits from the upper surface of the light guiding component. An included angle existing between the light beam and a normal direction of the upper surface ranges from 0 degree to 75 degrees.

Abstract: The present invention provides a pattern substrate structure for light emitting angle convergence and a light emitting diode device using the same. The pattern substrate structure has a plurality of enclosed geometric regions defined by at least three stripe-shaped parts on a substrate to provide the light reflection effect through the uneven surface of the substrate and thereby converge the light emitting angle of the light emitting diode element into 100˜110 degrees. Therefore, the illuminant efficiency of the light emitting diode device using the pattern substrate structure is substantially raised because of the improved directivity.

Abstract: A light emitting diode device includes an epitaxial substrate, at least one passivation structure, at least one void, a semiconductor layer, a first type doping semiconductor layer, a light-emitting layer and a second type doping semiconductor layer. The passivation structure is disposed on the epitaxial substrate and has an outer surface. The void is located at the passivation structure and at least covering 50% of the outer surface of the passivation structure. The semiconductor layer is disposed on the epitaxial substrate and encapsulating the passivation structure and the void. The first type doping semiconductor layer is disposed on the semiconductor layer. The light-emitting layer is disposed on the first type doping semiconductor layer. The second type doping semiconductor layer is disposed on the light emitting layer.

Abstract: The present invention provides a pattern substrate structure for light emitting angle convergence and a light emitting diode device using the same. The pattern substrate structure has a plurality of enclosed geometric regions defined by at least three stripe-shaped parts on a substrate to provide the light reflection effect through the uneven surface of the substrate and thereby converge the light emitting angle of the light emitting diode element into 100˜110 degrees. Therefore, the illuminant efficiency of the light emitting diode device using the pattern substrate structure is substantially raised because of the improved directivity.