A method for manufacturing a packaged component with a composite pin structure has: dividing a substrate into a body area and a pin area, wherein a chip is arranged on the body area of the substrate and is electrically connected to conductive layers on the opposite surfaces of the substrate. The pin area is pre-defined with multiple parallel pin positions. After the electrical connection of the chip is completed in the body area, a cutting tool is used to cut along the peripheries of the body area and the pin positions to obtain a packaged component body and multiple pins. Each of the pins is integrally formed by the substrate of the packaged component body without using a conventional lead frame.

A semiconductor device package includes a carrier, an electronic component and a connector. The electronic component is disposed on the carrier. The connector is disposed on the carrier and electrically connected to the electronic component. A S 11 parameter of the connector is less than −20 dB.

A semiconductor device package includes a carrier, an electronic component and a connector. The electronic component is disposed on the carrier. The connector is disposed on the carrier and electrically connected to the electronic component. A S11 parameter of the connector is less than −20 dB.

A semiconductor device includes a shielding wire formed across a semiconductor die and an auxiliary wire supporting the shielding wire, thereby reducing the size of a package while shielding the electromagnetic interference generated from the semiconductor die. In one embodiment, the semiconductor device includes a substrate having at least one circuit device mounted thereon, a semiconductor die spaced apart from the circuit device and mounted on the substrate, a shielding wire spaced apart from the semiconductor die and formed across the semiconductor die, and an auxiliary wire supporting the shielding wire under the shielding wire and formed to be perpendicular to the shielding wire. In another embodiment, a bump structure is used to support the shielding wire. In a further embodiment, an auxiliary wire includes a bump structure portion and wire portion and both the bump structure portion and the wire portion are used to support the shielding wire.

Techniques are disclosed herein for creating over and under interconnects. Using techniques described herein, over and under interconnects are created on an IC. Instead of creating signaling interconnects and power/ground interconnects on a same side of a chip assembly, the signaling interconnects can be placed on an opposing side of the chip assembly as compared to the power interconnects.

A semiconductor and a method of fabricating the semiconductor having multiple, interconnected die including: providing a semiconductor substrate having a plurality of disparate die formed within the semiconductor substrate, and a plurality of scribe lines formed between pairs of adjacent die of the plurality of disparate die; and fabricating, by a lithography system, a plurality of inter-die connections that extend between adjacent pair of die of the plurality of die.

An electronic device structure having a shielding structure includes a substrate with an electronic component electrically connected to the substrate. The shielding structure includes conductive spaced-apart pillar structures that have proximate ends connected to the substrate and distal ends spaced apart from the substrate, and that are laterally spaced apart from the first electronic component. In one embodiment, the conductive pillar structures are conductive wires attached at one end to the substrate with an opposing end extending away from the substrate so that the conductive wires are provided generally perpendicular to the substrate. A package body encapsulates the electronic component and the conductive spaced-apart pillar structures. In one embodiment, the shielding structure further includes a shielding layer disposed adjacent the package body, which is electrically connected to the conductive spaced-apart pillar structures. In one embodiment, the electrical connection is made through the package. In another embodiment, the electrical connection is made through the substrate.

A method of fabricating (a distributed write driving arrangement for a semiconductor memory device) includes: forming bit cells and a local write driver in a first device layer; forming a local write bit (LWB) line and a local write bit_bar (LWB_bar) line in a first metallization layer; connecting each of the bit cells correspondingly between the LWB and LWB_bar lines; connecting the local write driver to the LWB line and the LWB_bar line; forming a global write bit (GWB) line and a global write bit_bar (GWBL_bar) line in a second metallization layer; connecting the GWB line to the LWB line; connecting the GWB line and the GWBL_bar line to the corresponding LWB line and LWB_bar line; forming a global write driver in a second device layer; and connecting the global write driver to the GWB line and the GWBL_bar line.

Provided are a semiconductor module capable of easily connecting extraction pin with a wiring board and having reliable connections, and a method for manufacturing the same. A semiconductor module includes: a multilayer board having a semiconductor device mounted thereon, the multilayer board electrically connecting to the semiconductor device; an extraction pin electrically connecting to one of the semiconductor device and the multilayer board; and a wiring board bonded to the extraction pin for electrical connection. The extraction pin has a press-fit. The wiring board has a hole portion bonded with the press-fit of the extraction pin. The base materials of the press-fit of the extraction pin and the hole portion of the wiring board are copper (Cu). A bonded portion between the base materials of press-fit and the corresponding hole portion of the wiring board includes a CuSnNi alloy layer.

The present disclosure provides an electronic package. The electronic package includes a substrate, an electronic component, a plurality of conductive elements, a metal sheet and a molding layer. The electronic component is disposed on the substrate and electrically connected to the substrate. The conductive elements are disposed on the substrate and electrically connected with the grounding circuit on the substrate. The metal sheet is disposed above the electronic component and is in electrical contact with the conductive elements. The molding layer is formed between the substrate and the metal sheet to enclose the electronic component and the conductive elements. The present disclosure further provides a method of manufacturing the above electronic package.