Abstract: A device includes first and second semiconductor fins, first, second, third and fourth fin sidewall spacers, and first and second epitaxy structures. The first and second fin sidewall spacers are respectively on opposite sides of the first semiconductor fin. The third and fourth fin sidewall spacers are respectively on opposite sides of the second semiconductor fin. The first and third fin sidewall spacers are between the first and second semiconductor fins and have smaller heights than the second and fourth fin sidewall spacers. The first and second epitaxy structures are respectively on the first and second semiconductor fins and merged together.

Abstract: A package structure is provided. The package structure includes a substrate, a frame structure, and a lens portion. The frame structure is disposed on the substrate. A sidewall of the frame structure has multiple lamination traces thereon. The lens portion covers the substrate. The frame structure has a through hole passing through the sidewall, and the through hole includes an edge, and a portion of the lamination traces overlaps the edge of the through hole.

Abstract: An electronic component sub-mount includes a body having a top surface, a bottom surface, and a supporting surface. The top and bottom surfaces are located on opposite sides of the body. The supporting surface is located on one side of the body, and an angle that is not equal to 0 degrees is formed between the supporting surface and the bottom surface. A first conductive layer is disposed on the bottom surface and includes multiple first conductive lines. A second conductive layer is disposed on the supporting surface, extending to the top surface, and includes multiple second conductive lines. The second conductive lines on the supporting surface have a first pin layout, and the second conductive lines on the top surface have a second pin layout different from the first pin layout. The second pin layout matches the pin layout of first conductive lines on the bottom surface.

Abstract: A detection device includes a substrate, a light-emitter, and a light receiver. The substrate includes a first surface area and a second surface area, in which the first surface area has a first reflectance greater than a second reflectance of the second surface area. The light emitter is disposed on the first surface area, and the light receiver is disposed on the second surface area. The light receiver has a third reflectance which is substantially the same as the second reflectance of the second surface area.

Abstract: An optocoupler is provided, including: at least one light-emitting chip disposed at a first connective region; at least one light-sensing chip disposed at a second connective region; an isolative structure disposed between at least one light-emitting chip and at least one light-sensing chip for isolating an electric field; a first encapsulant covering at least one light-emitting chip, at least one light-sensing chip, first connective region, second connective region and isolative structure; a second encapsulant covering first encapsulant; and a substrate having a recess; wherein first connective region and second connective region are disposed within substrate, at least one light-emitting chip is disposed within recess and electrically connected with first connective region, at least one light-sensing chip is disposed within recess and electrically connected with second connective region, and first encapsulant and second encapsulant are disposed within recess.

Abstract: A display device is provided and includes a light transmissive plate, a substrate, and a plurality of light-emitting units, which are disposed between the substrate and the light transmissive plate. Each of the light emitting units includes of a plurality of light emitting diodes, any one of which can be used as a light-detecting element. Therefore, whenever the display device is at displaying or full black state, the display device can have touch control function, object detection function and/or signal transmission function.

Abstract: A structure of a lead-frame matrix of photoelectron devices is provided. The lead-frame matrix is used to fabricate a first lead-frame array and a second lead-frame array. In the structure of the lead-frame matrix of the photoelectron devices, pins of the first lead-frame array and pins of the second lead-frame array are alternatively inserted.

Abstract: A method of manufacturing photo couplers is provided. At first, a receiver lead-frame array is cut from a lead-frame matrix having a transmitter lead-frame array and the receiver lead-frame array. Then, the receiver lead-frame array is overturned and placed on the lead-frame matrix to allow light-receiver elements on the receiver lead-frame array to face light-emitting elements on the transmitter lead-frame array of the lead-frame matrix. Finally, the receiver lead-frame array and the lead-frame matrix are connected.

Abstract: A structure of a lead-frame matrix of photoelectron devices is provided. The lead-frame matrix is used to fabricate a first lead-frame array and a second lead-frame array. In the structure of the lead-frame matrix of the photoelectron devices, pins of the first lead-frame array and pins of the second lead-frame array are alternatively inserted.

Abstract: A structure of a lead-frame matrix of photoelectron devices is provided. The lead-frame matrix is used to fabricate a first lead-frame array and a second lead-frame array. In the structure of the lead-frame matrix of the photoelectron devices, pins of the first lead-frame array and pins of the second lead-frame array are alternatively inserted.

Abstract: A method of manufacturing photo couplers is provided. At first, a receiver lead-frame array is cut from a lead-frame matrix having a transmitter lead-frame array and the receiver lead-frame array. Then, the receiver lead-frame array is overturned and placed on the lead-frame matrix to allow light-receiver elements on the receiver lead-frame array to face light-emitting elements on the transmitter lead-frame array of the lead-frame matrix. Finally, the receiver lead-frame array and the lead-frame matrix are connected.

Abstract: A structure of a lead-frame matrix of photoelectron devices is provided. The lead-frame matrix is used to fabricate a first lead-frame array and a second lead-frame array. In the structure of the lead-frame matrix of the photoelectron devices, pins of the first lead-frame array and pins of the second lead-frame array are alternatively inserted.