Abstract: An optoelectronic package and a method for producing the optoelectronic package are provided. The optoelectronic package includes a carrier, a photonic device, a first encapsulant and a second encapsulant. The photonic device is disposed on the carrier. The first encapsulant covers the carrier and is disposed around the photonic device. The second encapsulant covers the first encapsulant and the photonic device. The first encapsulant has a topmost position and a bottommost position, and the topmost position is not higher than a surface of the photonic device.

Abstract: A semiconductor assembly includes a substrate, a retaining wall, a light emitting unit, and a reflective layer. The substrate has a mounting surface. The retaining wall is disposed on the mounting surface and has an inner surface. An accommodation space is defined by the inner surface and the mounting surface. The light emitting unit is disposed in the accommodation space and disposed on the mounting surface. The light emitting unit has an upper light emitting surface and a side light emitting surface. The reflective resin layer is disposed in the accommodation space and disposed between the inner surface and the side light emitting surface. The reflective resin layer contains a based resin, a UV absorber, and reflective particles.

Abstract: A light emitting device including a lighting unit and a conversion material is disclosed. The conversion material is configured to convert a part of the invisible light emitted from the lighting unit into a visible light, which indicates that the lighting unit is in operation. The spectral energy of visible light is less than 20% of the spectral energy measured within a wavelength range of 200 nm to 380 nm.

Abstract: A method of manufacturing the light emitting package structure is provided. The method includes: a preparation process: mounting a light emitting unit on a substrate; a dispensing process: coating a sealant on a first joint area of the substrate; a cover-enclosing process: disposing a cover element having a second joint area on the substrate, the first joint area and the second joint area joined to each other by the sealant; a vacuum process: reducing an ambient pressure to a first pressure lower than the original ambient pressure; a pressure-adjusting process: adjusting the ambient pressure around the package structure to a second pressure higher than the first pressure; and a curing process: curing the sealant.

Abstract: A light emitting package structure and a method of manufacturing the light emitting package structure are provided. The method includes: a preparation process: mounting a light emitting unit on a substrate; a dispensing process: coating a sealant on a first joint area of the substrate; a cover-enclosing process: disposing a cover element having a second joint area on the substrate, the first joint area and the second joint area joined to each other by the sealant; a vacuum process: reducing an ambient pressure to a first pressure lower than the original ambient pressure; a pressure-adjusting process: adjusting the ambient pressure around the package structure to a second pressure higher than the first pressure; and a curing process: curing the sealant.

Abstract: A package structure is provided. The package structure includes a substrate, a pair of electrodes, a lighting unit, a wall, and a package compound. The pair of electrodes and the wall are disposed on the substrate, and the wall and the substrate jointly define an accommodating space. The lighting unit is disposed in the accommodating space. The package compound is disposed in the accommodating space such that a top end of the package compound has a W-shaped cross section and the lighting unit is embedded in the package compound.

Abstract: An optical sensor structure is provided. The optical sensor structure includes a substrate, a light sensing unit, a peripheral wall, and a reflective layer. The substrate includes a plurality of metal pads. The light sensing unit is disposed on the substrate and electrically connected to the plurality of metal pads. The peripheral wall is disposed on the substrate, and the peripheral wall and the substrate define an accommodating space. The metal pads and the light sensing unit are positioned in the accommodating space. The reflective layer is disposed in the accommodating space and surrounds the light sensing unit.

Abstract: A light emitting structure includes a substrate, at least one light emitting chip disposed on the substrate and, a side wall disposed on the substrate and surrounding the at least one light emitting chip, a cover disposed on the side wall, an anti-reflective coating disposed on the cover, and a protective layer disposed on outside of the cover, wherein the cover, the side wall and the substrate define an enclosed space for accommodating the at least one light emitting chip.

Abstract: A light emitting device including a lighting unit and a conversion material is disclosed. The conversion material is configured to convert a part of the invisible light emitted from the lighting unit into a visible light, which indicates that the lighting unit is in operation. The spectral energy of visible light is less than 20% of the spectral energy measured within a wavelength range of 200 nm to 380 nm.

Abstract: A package structure is provided. The package structure includes a substrate, a pair of electrodes, a lighting unit, a wall, and a package compound. The pair of electrodes and the wall are disposed on the substrate, and the wall and the substrate jointly define an accommodating space. The lighting unit is disposed in the accommodating space. The package compound is disposed in the accommodating space such that a top end of the package compound has a W-shaped cross section and the lighting unit is embedded in the package compound.

Abstract: A light-emitting diode (LED) package structure includes a substrate, an LED, a side wall, an encapsulant, and a waterproof protective coating. The LED is disposed on the substrate, the side wall defines a through hole and is disposed on the substrate, and the LED is accommodated in the through hole. The encapsulant is filled in the through hole and covers the LED. A heterojunction is disposed between the encapsulant and the side wall, and the waterproof protective coating seals the heterojunction. Furthermore, the encapsulant includes a first fluoropolymer, the waterproof protective coating includes a second fluoropolymer, and the light transmittance of the first fluoropolymer is greater than that of the second fluoropolymer.

Abstract: An optoelectronic package and a method for producing the optoelectronic package are provided. The optoelectronic package includes a carrier, a photonic device, a first encapsulant and a second encapsulant. The photonic device is disposed on the carrier. The first encapsulant covers the carrier and is disposed around the photonic device. The second encapsulant covers the first encapsulant and the photonic device. The first encapsulant has a topmost position and a bottommost position, and the topmost position is not higher than a surface of the photonic device.

Abstract: An optical sensor structure is provided. The optical sensor structure includes a substrate, a light sensing unit, a peripheral wall, and a reflective layer. The substrate includes a plurality of metal pads. The light sensing unit is disposed on the substrate and electrically connected to the plurality of metal pads. The peripheral wall is disposed on the substrate, and the peripheral wall and the substrate define an accommodating space. The metal pads and the light sensing unit are positioned in the accommodating space. The reflective layer is disposed in the accommodating space and surrounds the light sensing unit.

Abstract: A method of determining overlay (“OVL”) in a pattern in a semiconductor wafer manufacturing process comprises capturing images from a cell in a metrology target formed in at least two different layers in the wafer with parts of the target offset in opposing directions with respect to corresponding parts in a different layer. The images may be captured using radiation of multiple different wavelengths, each image including +1 and ?1 diffraction patterns. A first and second differential signal may be determined for respective pixels in each image by subtracting opposing pixels from the +1 and ?1 diffraction orders for each of the multiple wavelengths. An OVL for the respective pixels may be determined based on analyzing the differential signals from multiple wavelengths simultaneously. Then an OVL for the pattern may be determined as a weighted average of the OVL of the respective pixels.

Abstract: A package structure and a method for manufacturing the same are provided. The package structure includes a substrate, a wall, a photonic device, an inner covering layer, and an outer covering layer. The wall is disposed on the substrate, and a space is formed between the substrate and the wall. The photonic device is accommodated in the space and disposed on the substrate. The photonic device includes a p-contact and an n-contact, and a gap is defined between the p-contact and the n-contact. The inner covering layer is disposed in the gap between the p-contact and the n-contact. The outer covering layer is covered on an upper surface of the substrate, an inner surface of the wall, and an outer surface of the photonic device.

Abstract: A package structure is provided. The package structure includes a substrate, an electrode layer, a lighting unit, a wall, and a package compound. The substrate and the wall that is disposed on the substrate jointly define an accommodating space. The lighting unit in the accommodating space and is electrically connected to the electrode layer disposed on the substrate. The package compound covers the electrode layer, and the lighting unit. The package compound includes an attaching portion disposed on a top surface of the lighting unit and a surrounding portion that is arranged around the attaching portion. The surrounding portion has an annular slot arranged on a top surface thereof. A bottom end of the annular slot is located at a position aligning with 25%˜90% of a thickness of the lighting diode along a height direction.

Abstract: An package structure includes a substrate, a pair of electrodes and a solder pad layer both electrically connected to each other and respectively disposed on two opposite surfaces of the substrate, a lighting diode arranged above the substrate and electrically connected to the pair of electrodes, a wall disposed on the substrate and arranged around the lighting diode, and a package compound disposed inside of the wall and covering the lighting diode. The package compound includes an attaching portion disposed on a top surface of the lighting diode, and a surrounding portion arranged around the attaching portion. The surrounding portion has an annular slot arranged on a top surface thereof. A bottom end of the annular slot is located at a position aligning with 25%˜90% of a thickness of the lighting diode along a height direction.

Abstract: A light emitting structure includes a substrate, at least one light emitting chip disposed on the substrate and, a side wall disposed on the substrate and surrounding the at least one light emitting chip, a cover disposed on the side wall, an anti-reflective coating disposed on the cover, and a protective layer disposed on outside of the cover, wherein the cover, the side wall and the substrate define an enclosed space for accommodating the at least one light emitting chip.

Abstract: A light-emitting diode (LED) package structure includes a substrate, an LED, a side wall, an encapsulant, and a waterproof protective coating. The LED is disposed on the substrate, the side wall defines a through hole and is disposed on the substrate, and the LED is accommodated in the through hole. The encapsulant is filled in the through hole and covers the LED. A heterojunction is disposed between the encapsulant and the side wall, and the waterproof protective coating seals the heterojunction. Furthermore, the encapsulant includes a first fluoropolymer, the waterproof protective coating includes a second fluoropolymer, and the light transmittance of the first fluoropolymer is greater than that of the second fluoropolymer.

Abstract: A method of determining overlay (“OVL”) in a pattern in a semiconductor wafer manufacturing process comprises capturing images from a cell in a metrology target formed in at least two different layers in the wafer with parts of the target offset in opposing directions with respect to corresponding parts in a different layer. The images may be captured using radiation of multiple different wavelengths, each image including +1 and ?1 diffraction patterns. A first and second differential signal may be determined for respective pixels in each image by subtracting opposing pixels from the +1 and ?1 diffraction orders for each of the multiple wavelengths. An OVL for the respective pixels may be determined based on analyzing the differential signals from multiple wavelengths simultaneously. Then an OVL for the pattern may be determined as a weighted average of the OVL of the respective pixels.