A chip-on-film (COF) package includes a base film, a semiconductor chip mounted on a chip mounting region of a top surface of the base film, a plurality of top inner output conductive patterns, a plurality of bottom inner output conductive patterns and a plurality of landing vias. The top inner output conductive patterns are formed on the top surface of the base film and respectively connected to chip inner output pads formed on a bottom surface of the semiconductor chip. The bottom inner output conductive patterns are formed on a bottom surface of the base film. The landing vias are formed to vertically penetrate the base film and to respectively connect the top inner output conductive patterns and the bottom inner output conductive patterns. The landing vias are arranged within the chip mounting region to form a two-dimensional shape.

Semiconductor devices are disclosed. According to some embodiments, a semiconductor device may include a memory array area and a peripheral area. The memory array area may include a number of memory cells and a number of array pads configured to receive an input voltage. The peripheral area may include a number of peripheral pads for interfacing with the memory array area. In these or other embodiments, the peripheral area may be arranged adjacent to a first edge of the semiconductor device and the number of array pads may be arranged proximate to a second edge of the semiconductor device. The second edge may be perpendicular to the first edge. The memory array area may also include an array distribution conductor configured to variously electrically connect the number of memory cells to the number of array pads. A semiconductor-device package and system are also disclosed.

Semiconductor devices are disclosed. According to some embodiments, a semiconductor device may include a memory array area and a peripheral area. The memory array area may include a number of memory cells and a number of array pads configured to receive an input voltage. The peripheral area may include a number of peripheral pads for interfacing with the memory array area. In these or other embodiments, the peripheral area may be arranged adjacent to a first edge of the semiconductor device and the number of array pads may be arranged proximate to a second edge of the semiconductor device. The second edge may be perpendicular to the first edge. The memory array area may also include an array distribution conductor configured to variously electrically connect the number of memory cells to the number of array pads. A semiconductor-device package and system are also disclosed.

Embodiments of the present disclosure are directed to a microfluidic delivery system that includes a microfluidic semiconductor die coupled to a flexible interconnect substrate to form an assembly. At least one embodiment is directed to a semiconductor die having an active surface that includes a layout that has electrically active bond pads along one side of the active surface of the die. A second side of the active surface of the die includes one or more mechanical pads.

Provided is a multi-chip package in which a plurality of semiconductor chips having different sizes are stacked. A multi-chip package may include a substrate, and a plurality of semiconductor chips stacked on the substrate, each of the plurality of semiconductor chips having a different size. Each of the plurality of semiconductor chips including a pad group and a reference region associated with the pad group, each pad group having a plurality of pads, and the plurality of pads in each pad group located at same coordinates with respect to the associated reference region, and each of the plurality of semiconductor chips having their reference regions vertically aligned.

A semiconductor device with improved reliability is provided. The semiconductor device is characterized by its embodiments in that sloped portions are formed on connection parts between a pad and a lead-out wiring portion, respectively. This feature suppresses crack formation in a coating area where a part of the pad is covered with a surface protective film.

A semiconductor package includes a package substrate which includes a substrate base and a plurality of wiring patterns, a lower semiconductor chip, and an upper semiconductor chip. The substrate base includes a chip-accommodating cavity and the plurality of wiring patterns include a plurality of bottom wiring patterns on a bottom surface of the substrate base and a plurality of top wiring patterns on a top surface of the substrate base. The lower semiconductor chip is disposed in the chip-accommodating cavity and is connected to the plurality of bottom wiring patterns through a plurality of lower bonding wires. The upper semiconductor chip includes a first portion which is attached to the lower semiconductor chip and a second portion which overhangs the lower semiconductor chip.

A multi-chip package structure includes outer leads, a first chip and a second chip. The outer leads are disposed on four sides of a chip bonding area of a package carrier thereof, respectively. The first chip is fixed on the chip bonding area and includes a core and a seal ring. Input/output units, and first bonding pads are disposed, in an outward order, on the sides of the core. Each first bonding pad is electrically connected to a corresponding outer lead through a first wire. Dummy pads are disposed between the input/output units and the at least one side of the core. The second chip is stacked on the core and includes second bonding pads connected to the corresponding outer leads through second wires and dummy pads, so as to prevent from short circuit caused by soldering overlap and contact between the wires.

A semiconductor device has a semiconductor chip having a plurality of pads and wires electrically connected to the plurality of pads, respectively. The plurality of pads includes a plurality of first pads which is electrically connected to a circuit included in the semiconductor chip and to which first wires are bonded and a second pad which is an electrode pad for wire connection test and to which a second wire is bonded.

A display device may include: a substrate including a display area having first to third areas, and a non-display area; first pixels in the first area, second pixels in the second area, and third pixels in the third area; a pad part located in the non-display area, and electrically connected to the first to third pixels; a line part including a first line between the pad part and the first area, a second line between the pad part and the second area, and a third line between the pad part and the second area; a bridge line extending in a first direction, and located in the second and third areas; and an extension line extending in a second direction, and located in the second area and electrically connected with the bridge line. The extension line may be electrically connected with the third line.