Picture quality deterioration is curbed. A solid-state imaging device according to an embodiment includes: a semiconductor substrate (131) including a light-receiving element; an on-chip lens (132) disposed on a first surface of the semiconductor substrate; a resin layer (133) covering the on-chip lens; and a glass substrate (134) disposed on the side of the first surface of the semiconductor substrate separately from the resin layer.

A semiconductor package includes a substrate including a first semiconductor chip including a first wiring structure, a first bonding pad, and a first alignment key on the first wiring structure to be spaced apart in a first direction, a second semiconductor chip including a second wiring structure, a second bonding pad on the second wiring structure and connected to the first bonding pad, and a second alignment key on the second wiring structure to be spaced apart from the second bonding pad and not overlapping the first alignment key in the second direction, the first wiring structure including a first wiring pattern connected to the first bonding pad and not overlapping the first and second alignment keys in the second direction, and the second wiring structure including a second wiring pattern connected to the second bonding pad and not overlapping the first and second alignment keys in the second direction.

A package comprising a carrier, an electronic component mounted on the carrier, and an identifier indicative of an origin of the package and being formed on and/or in the carrier is disclosed.

A device includes a molding compound encapsulating a first integrated circuit die and a second integrated circuit die; a dielectric layer over the molding compound, the first integrated circuit die, and the second integrated circuit die; and a metallization pattern over the dielectric layer and electrically connecting the first integrated circuit die to the second integrated circuit die. The metallization pattern comprises a plurality of conductive lines. Each of the plurality of conductive lines extends continuously from a first region of the metallization pattern through a second region of the metallization pattern to a third region of the metallization pattern; and has a same type of manufacturing anomaly in the second region of the metallization pattern.

A solar module architecture features a plurality of photovoltaic strips separated from a cell workpiece. The cell workpiece comprises alignment mark(s) located in cell quadrants close to the workpiece edge. According to specific embodiments, an alignment mark is positioned at a break in a bus bar. As a result of this location, in the assembled solar module containing the separated strip, the alignment mark is hidden from view by an overlapping module element. In particular embodiments, the overlapping module element is another separated PV strip in a shingled configuration.

The present publication discloses a method for manufacturing a circuit-board structure. In the method, a conductor layer is made, which comprises a conductor foil and a conductor pattern on the surface of the conductor foil. A component is attached to the conductor layer and the conductor layer is thinned, in such a way that the conductor material of the conductor layer is removed from outside the conductor pattern.

A packaging unit, a component packaging structure and a preparation method thereof. The packaging unit includes a bonding substrate and spacers formed on the bonding substrate through a patterning process, wherein the bonding substrate is reserved with packaging regions for applying sealant. When the packaging unit is used to package a component, because the spacer(s) is supported between the bonding substrate and the base substrate, the packaging unit is easy to separate from the base substrate At the same time, the packaging unit has little or no damage to the base substrate and elements formed on the base substrate, thus effectively protecting the performance of the base substrate and the elements on the base substrate.

A display device and a detection method are provided. The display device includes a display panel including an effective area and a peripheral area located around the effective area; and a cover plate attached to the display panel, the cover plate including a visible region, and the boundary of the visible region of the cover plate is located outside the boundary of the effective region of the display panel in a direction parallel to the display panel; at least one pair of light sensitive luminescent marks disposed on the display panel and located near mutually opposite edges of the display panel. Each of the at least one pair of light sensitive luminescent marks is disposed inside or outside an effective area of the display panel in a direction parallel to the display panel.

The invention provides an array substrate and chip bonding method, the array substrate comprising: an active area, and a bonding area located around the active area, wherein the bonding area is provided with an input terminal group, a first output terminal group and a second output terminal a group; the first output terminal group is located at a side of the input terminal group away from the active area, and the second output terminal group is located between the first output terminal group and the input terminal group; when bonding chips, the first output terminal group or the second output terminal group is selected to cooperate with the input terminal group for chip bonding according to the chip type. By simultaneously providing the first and second output terminal groups, the bonding of the second type chip increases the distance between the chip and the edge of the array substrate.

A semiconductor package system includes a substrate, a first and a second semiconductor package, a first thermal conductive layer, a first passive device, and a heat radiation structure. The first and second semiconductor package and first passive device may be mounted on a top surface of the substrate. The first semiconductor package may include a first semiconductor chip that includes a plurality of logic circuits. The first thermal conductive layer may be on the first semiconductor package. The heat radiation structure may be on the first thermal conductive layer, the second semiconductor package, and the first passive device. The heat radiation structure may include a first bottom surface physically contacting the first thermal conductive layer, and a second bottom surface at a higher level than that of the first bottom surface. The second bottom surface may be on the second semiconductor package and/or the first passive device.