An exemplary hearing device includes a housing and a chip package disposed within the housing. The chip package may comprise a printed circuit board, an integrated circuit configured to perform an electronic function associated with the hearing device, and a plurality of solder bumps on a bottom surface of the integrated circuit. The plurality of solder bumps may provide conductive connectivity between the integrated circuit and the printed circuit board. The plurality of solder bumps may comprise a first group of solder bumps located within a center region of the bottom surface of the integrated circuit and a second group of solder bumps located within a peripheral region of the bottom surface, the peripheral region surrounding the center region. All signals required for the integrated circuit to perform the electronic function may be provided by way of the first group of solder bumps.

A semiconductor package includes a redistribution structure, a first semiconductor chip above the redistribution structure, a second semiconductor chip on, and offset relative to, the first semiconductor chip, a plurality of first conductive posts extending from a bottom surface of the second semiconductor chip to a top surface of the redistribution structure, a third semiconductor chip on the second semiconductor chip, a plurality of second conductive posts extending from a bottom surface of the third semiconductor chip to the top surface of the redistribution structure, and a molding layer between the top surface of the redistribution structure and the bottom surface of the third semiconductor chip.

A semiconductor device has a semiconductor wafer or substrate including a plurality of semiconductor die. A plurality of first bumps is formed over an active surface of the semiconductor wafer. A plurality of second bumps is formed within a saw street of the semiconductor wafer separating the plurality of semiconductor die. A top surface of the first bumps is coplanar with a top surface of the second bumps. The second bumps are formed within a first saw street of the semiconductor wafer and further within a second saw street of the semiconductor wafer different from the first saw street. The first bumps are electrically connected to the semiconductor die to provide a function for the semiconductor die. The second bumps are dummy bumps that have no electrical function for the semiconductor die. The semiconductor wafer is singulated through the saw street and second bumps.

A display panel comprising a display substrate having a display area and a pad area disposed around the display area. A connection wire is disposed on the pad area of the display substrate. A signal wire is disposed on the connection wire. A supporter is disposed between the display substrate and the connection wire. The connection wire directly contacts the supporter.

A three-dimensional (3D) integrated circuit (IC) (3DIC) package with a bottom die layer employing an interposer substrate, and related fabrication methods. To facilitate the ability to fabricate the 3DIC package using a top die-to-bottom wafer process, a bottom die layer of the 3DIC package includes an interposer substrate. This interposer substrate provides support for a bottom die(s) of the 3DIC package. The interposer substrate is extended in length to be longer in length than the top die. The interposer substrate provides additional die area in the bottom die layer in which a larger length, top die can be bonded. In this manner, the bottom die layer, with its extended interposer substrate, can be formed in a bottom wafer in which the top die can be bonded in a top die-to-bottom wafer fabrication process.

A structure includes at least one ball, at least one bump and at least one route. The at least one route is configured to couple the at least one ball to the at least one bump. The at least one route comprises a plurality of first route edges and a plurality of second route edges, and an angle between one of plurality of first route edges and one of plurality of second route edges is approximately equal to an angle between another one of plurality of first route edges and another one of plurality of second route edges.

The present disclosure relates to the field of semiconductor packaging technologies, and in particular, to a panel-level chip packaging structure and method based on a steel plate platform. The packaging structure includes: a steel plate; a gold-nickel layer plated on the steel plate, where the gold-nickel layer is provided with upwardly protruding pins corresponding to a chip; the chip flipped to the corresponding pins; and a molded body coating the corresponding chip and the gold-nickel layer. According to the packaging structure and method of the present disclosure, an overall thickness of a chip-packaged product can be reduced. A wire bonding process and an electroplating process are further omitted, so that the overall thickness of chip packaging can be further reduced. An ultra-thin packaging structure can be implemented, the chip packaging efficiency can further be improved, and a complete-process chip packaging cycle can be shortened.

A semiconductor package includes a semiconductor chip including a semiconductor substrate having an active layer, ground chip pads on the semiconductor substrate, and signal chip pads on the semiconductor substrate and a package substrate supporting the semiconductor chip, the package substrate including a substrate insulating layer, a plurality of signal line patterns extending in the substrate insulating layer and electrically connected to the signal chip pads, and a plurality of ground line patterns extending in the substrate insulating layer at a same level as a level of the plurality of signal line patterns and electrically connected to the ground chip pads. At least one of the plurality of ground line patterns extends between the plurality of signal line patterns.

An electronic device package includes a circuit layer, a first semiconductor die, a second semiconductor die, a plurality of first conductive structures and a second conductive structure. The first semiconductor die is disposed on the circuit layer. The second semiconductor die is disposed on the first semiconductor die, and has an active surface toward the circuit layer. The first conductive structures are disposed between a first region of the second semiconductor die and the first semiconductor die, and electrically connecting the first semiconductor die to the second semiconductor die. The second conductive structure is disposed between a second region of the second semiconductor die and the circuit layer, and electrically connecting the circuit layer to the second semiconductor die.

A semiconductor device with a two-sided redistribution layer is disclosed. The semiconductor device comprises a host device and one or more memory stack cubes. A redistribution layer is disposed between and couples the host device and the memory stack cubes. This redistribution layer features an edge surface extending between the host device and the memory stack cubes. The semiconductor device includes first connective circuitry that extends through the redistribution layer, is coupled with the host device, and is exposed at the edge surface of the redistribution layer. Additionally, second connective circuitry extends through the redistribution layer, is coupled with the memory stack cubes, and is exposed at the edge surface of the redistribution layer. Connective structures couple the first and second connective circuitry exposed at the edge surface of the redistribution layer.