A semiconductor package includes a leadframe having a die pad and a plurality of pins disposed around the die pad, a metal interposer attached to a top surface of the die pad, and a semiconductor die attached to a top surface of the metal interposer. A plurality of bond wires with same function is bonded to the metal interposer. The die pad, the metal interposer and the semiconductor die are stacked in layers so as to form a pyramidal stack structure.

Semiconductor module including a semiconductor and including a shaped metal body that is electrically contacted by the semiconductor, for forming a contact surface for an electrical conductor, wherein the shaped metal body is bent or folded. A method is also described for establishing electrical contacting of an electrical conductor on a semiconductor, said method including the steps of: fastening a bent or folded shaped metal body of a constant thickness to the semiconductor by means of a first fastening method and then fastening the electrical conductor to the shaped metal body by means of a second fastening method.

The disclosure describes a semiconductor device and a method for fabricating a semiconductor device. The semiconductor device includes: a first module and a second module stacked vertically on the first module, each module includes multiple dies stacked vertically within an insulation layer, wherein each die higher than a lower die is laterally offset from the lower die forming a terraced structure, wherein the second module comprises vertical wires connecting the overhang portions of the terraced structure of the second module to a top dielectric layer of the first module underneath the second module, and the insulation layer of the first module further includes through-insulation vias (TIVs) connecting the top dielectric layer to a bottom dielectric layer through the insulation layer, such that the dies of the second module are coupled to the bottom dielectric layer of the first module through the top dielectric layer and TIVs.

A power package includes at least one power substrate having at least one power trace, at least one power device on the at least one power trace, signal terminals, and at least one signal connection assembly. The at least one signal connection assembly includes at least one of the following: at least one signal trace that is thinner than the at least one power trace; at least one embedded routing layer within the at least one power substrate; and/or at least one routing layer on the at least one power substrate.

A package comprising a first integrated device; a second integrated device coupled to the first integrated device through an adhesive; a first plurality of wire bonds coupled to the first integrated device; a second plurality of wire bonds coupled to the second integrated device; an encapsulation layer at least partially encapsulating the first integrated device, the second integrated device, the first plurality of wire bonds and the second plurality of wire bonds; and a plurality of pillar interconnects.

A semiconductor package includes a substrate, a first semiconductor die disposed on the substrate, a second semiconductor die stacked on the first die and offset from it in a first direction and a second direction that are perpendicular to each other, and a third semiconductor die stacked on the first and second dies and offset from them in the first direction. The first semiconductor die includes a first pad and a second pad, arranged successively in the second direction. The second semiconductor die includes a third pad and a fourth pad, and the third semiconductor die includes a fifth pad and a sixth pad, each arranged successively in the second direction. A first conductive pattern connects the first and fifth pads, while a second conductive pattern connects the second, fourth, and sixth pads. The first and second conductive patterns are spaced apart from the third pad.

A chip package structure includes a die pad, input/output pads, a chip, first bonding wires, a molding compound, a solder resist layer, first solder balls and second solder balls. The input/output pads are configured around the die pad. The chip is configured on the die pad. The first bonding wires are electrically connected to the chip and the input/output pads. The molding compound covers the chip, the die pad, the input/output pads and the first bonding wires, and exposes a first lower surface of the die pad and a second lower surface of each input/output pad. The solder resist layer is configured on the first lower surface of the die pad and has multiple openings exposing a portion of the die pad. The first solder balls are respectively configured in the openings of the solder resist layer, and the second solder balls are respectively configured on the input/output pads.

An electronic package is provided, in which an electronic element is arranged on a carrier structure having a plurality of wire-bonding pads arranged on a surface of the carrier structure, and a plurality of bonding wires are connected to a plurality of electrode pads of the electronic element and the plurality of wire-bonding pads. Further, among any three adjacent ones of the plurality of wire-bonding pads, a long-distanced first wire-bonding pad, a middle-distanced second wire-bonding pad and a short-distanced third wire-bonding pad are defined according to their distances from the electronic element. Therefore, even if the bonding wires on the first to third wire-bonding pads are impacted by an adhesive where a wire sweep phenomenon occurred when the flowing adhesive of a packaging layer covers the electronic element and the bonding wires, the bonding wires still would not contact each other, thereby avoiding short circuit problems.

An electronic device package includes a frame, an electronic device mounted to the frame, surface-mount leads, and a gel at least partially filling a cavity between the electronic device and the frame. The electronic device includes electronic circuitry provided on an electronic device substrate, and the surface-mount leads are electrically connected to the electronic circuitry and extend laterally and outwardly from an outer perimeter of the frame. The gel in the cavity covers the electronic circuitry.

A power module is provided. The power module includes a first lead frame, a first die, a substrate, a second lead frame, and a second die. The first lead frame has a first part and a second part. The first die is arranged on top of the first part of the first lead frame. A first power device is formed on the first die. The substrate is arranged on top of the second part of the first lead frame. The second lead frame is arranged on top of the substrate. The second die is arranged on top of the second lead frame. A first control circuit is formed on the second die, and the first control circuit is configured to control the first power device.