A chip package includes a sensing element, a dam layer, and a light transmissive cover. A surface of the sensing element has a sensing area and a conductive pad. The conductive pad is adjacent to an edge of the surface of the sensing element. The dam layer is located on the surface of the sensing element and surrounds the sensing area. The dam layer has a main portion and plural mark portions. The mark portions are respectively located in plural corners of the main portion, located in a sidewall of the main portion, respectively located on plural corners of the sensing element, respectively located on plural inner edges of the main portion, or respectively located on plural outer edges of the main portion. The light transmissive cover is located on the dam layer.

A chip comprises a semiconductor substrate having a first side and a second side opposite to the first side, a plurality of conductive metal patterns formed on the first side of the semiconductor substrate, a plurality of solder balls formed on the first side of the semiconductor substrate, and at least one code pattern formed using laser marking on the first side of the semiconductor substrate in a space free from the plurality of conductive metal patterns and the plurality of solder balls, wherein the at least one code pattern is visible from a backside of the chip, the at least one code pattern represents a binary number having four bits; and the binary number represents a decimal number to represent a tracing number of the chip.

Provided are package-on-package (POP)-type semiconductor packages including a lower package having a first size and including a lower package substrate in which a lower semiconductor chip is, an upper redistribution structure on the lower package substrate and the lower semiconductor chip, and alignment marks. The packages may also include an upper package having a second size smaller than the first size and including an upper package substrate and an upper semiconductor chip. The upper package substrate may be mounted on the upper redistribution structure of the lower package and electrically connected to the lower package, and the upper semiconductor chip may be on the upper package substrate. The alignment marks may be used for identifying the upper package, and the alignment marks may be below and near outer boundaries of the upper package on the lower package.

A module that improves heat-dissipation efficiency and can prevent a warp and a deformation of the module is provided. A module includes a substrate, a first component mounted on an upper surface of the substrate, a heat-dissipation member, and a sealing resin layer that seals the first component and the heat-dissipation member. The heat-dissipation member is formed to be larger than the area of the first component when viewed in a direction perpendicular to the upper surface of the substrate and prevents heat generation of the module by causing the heat generated from the first component to move outside the module. The heat-dissipation member has through holes, and the through holes are packed with a resin, which can prevent the sealing resin layer from peeling off.

A semiconductor package includes a package substrate, at least one semiconductor chip mounted on the package substrate, and a molding member that surrounds the at least one semiconductor chip. The molding member includes fillers. Each of the fillers includes a core and a coating layer that surrounds the core. The core includes a non-electromagnetic material and the coating layer includes an electromagnetic material. The molding member includes regions respectively have different distributions of the fillers.

A semiconductor device includes a stacked structure disposed on a substrate. The stacked structure includes a plurality of insulation layers and a plurality of electrode layers alternately stacked in a third direction intersecting with first and second directions. A plurality of channel structures extends through the stacked structure in the third direction. A first wiring group includes a plurality of first horizontal wirings disposed on the stacked structure that are arranged in the first direction and extends in the second direction. A second wiring group includes a plurality of second horizontal wirings disposed on the stacked structure that are arranged in the first direction and extends in the second direction. Each of the plurality of first and second horizontal wirings are connected to corresponding one of the plurality of channel structures. A first line identifier is disposed between the first wiring group and the second wiring group.

An aligner system includes a motor, a rotating device, a control device, and a sensor. The motor generates a rotational drive force. The rotating device 11 is rotated by the rotational drive force generated by the motor, while supporting a wafer. The control device controls rotation of the rotating device, and performs a process of setting a rotational phase of the wafer to a predetermined value. The sensor emits a plurality of light beams traveling in different directions toward an edge of the wafer, and receives the light beams to detect a defect in the edge of the wafer.

An apparatus includes a product substrate having a transfer surface, and a semiconductor die defined, at least in part, by a first surface adjoined to a second surface that extends in a direction transverse to the first surface. The transfer surface includes ripples in a profile thereof such that an apex on an individual ripple is a point on a first plane and a trough on the individual ripple is a point on a second plane. The semiconductor die is disposed on the transfer surface between the first plane and the second plane such that the second surface of the semiconductor die extends transverse to the first plane and the second plane.

According to one embodiment, a semiconductor device includes a substrate, first stacked components, second stacked components, and a coating resin. The first stacked components include first chips and are stacked on a surface of the substrate. The second stacked components include second chips and are stacked on the surface. The coating resin covers the surface, the first stacked components, and the second stacked components. A first top surface of a second farthest one of the first chips away from the surface differs in position in a first direction from a second top surface of second farthest one of the second chips away from the surface.

Semiconductor device packages and associated methods are disclosed herein. In some embodiments, the semiconductor device package includes (1) a first surface and a second surface opposite the first surface; (2) a semiconductor die positioned between the first and second surfaces; and (3) an indication positioned in a designated area of the first surface. The indication includes a code presenting information for operating the semiconductor die. The code is configured to be read by an indication scanner coupled to a controller.