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.

The present disclosure provides a method of fabricating an integrated fan-out package including the following steps. A semiconductor die is laterally encapsulated by an insulating encapsulant. A redistribution circuit structure is formed on the insulating encapsulant and the semiconductor die, and the redistribution circuit structure is electrically connected to the semiconductor die. A forming method of the redistribution circuit structure includes the following steps. A conductive wiring is formed over the insulating encapsulant and the semiconductor die. A dielectric material is formed on the insulating encapsulant and the semiconductor die to cover the conductive wiring. A sacrificial layer is formed on the dielectric material, wherein a first top surface of the sacrificial layer is flatter than a second top surface of the dielectric material. The sacrificial layer and a portion of the dielectric material are removed until the conductive wiring is revealed to form a dielectric layer, wherein the conductive wiring is embedded in the dielectric layer.

A semiconductor device package includes an electronic device, a conductive frame and a first molding layer. The conductive frame is disposed over and electrically connected to the electronic device, and the conductive frame includes a plurality of leads. The first molding layer covers the electronic device and a portion of the conductive frame, and is disposed between at least two adjacent ones of the leads.

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.

Electromagnetic interference shielding is described for a semiconductor package using bond wires. In one example, a package has a substrate having a ground plane and a top side to carry a microelectronic die, the top side further having a conductive pad coupled to the ground plane, a microelectronic die having a bottom side attached to the substrate and a top side opposite the bottom side, and a plurality of bond wires connected to the top conductive pad to form a wire mesh electromagnetic interference shield for the substrate.

A method for preparing fan-out antenna packaging structure, includes: providing a carrier and a release layer structure; forming a single-layer antenna structure and a redistribution layer on an upper surface of the release layer; disposing a semiconductor chip electrically connected with the redistribution layer; forming a leading-out conducting wire on the redistribution layer at least on one side of the semiconductor chip; forming a plastic packaging layer wrapping the chip and the leading-out conducting wire; removing part of the plastic packaging layer to expose the chip and the leading-out conducting wire; forming an under-bump metal layer and a solder ball bump on an upper surface of the plastic packaging layer; removing the carrier and the release layer to expose the single-layer antenna structure; soldering a substrate on the solder ball bump; and forming a layer of cooling fins on a second surface of the semiconductor chip.

An electronics package includes an insulating substrate, an electrical component having a back surface coupled to a first surface of the insulating substrate, and an insulating structure surrounding at least a portion of a perimeter of the electrical component. A first wiring layer extends from the first surface of the insulating substrate and over a sloped side surface of the insulating structure to electrically couple with at least one contact pad on an active surface of the electrical component. A second wiring layer is formed on a second surface of the insulating substrate and extends through at least one via therein to electrically couple with the first wiring layer.

A method for preparing fan-out antenna packaging structure, includes: providing a carrier and a release layer structure; forming a single-layer antenna structure and a redistribution layer on an upper surface of the release layer; disposing a semiconductor chip electrically connected with the redistribution layer; forming a leading-out conducting wire on the redistribution layer at least on one side of the semiconductor chip; forming a plastic packaging layer wrapping the chip and the leading-out conducting wire; removing part of the plastic packaging layer to expose the chip and the leading-out conducting wire; forming an under-bump metal layer and a solder ball bump on an upper surface of the plastic packaging layer; removing the carrier and the release layer to expose the single-layer antenna structure; soldering a substrate on the solder ball bump; and forming a layer of cooling fins on a second surface of the semiconductor chip.

The present disclosure provides a semiconductor IC structure having vertical wire bonding and method of making it. The method includes two steps. First step: providing a semiconductor chip, disposing a first solder joint and a second solder joint separately on its surface, disposing a wire bonding pad at the first solder joint, to connect to an internal functioning device of the semiconductor chip, and disposing a dummy pad at the second solder joint. Second step: bonding a metal wire on the wire bonding pad, cutting the metal wire on the dummy pad, and breaking the metal wire by pulling above the wire bonding pad, to obtain a vertical conductive column connected to the wire bonding pad.

Base pads are spaced by a pitch on a support surface. Conducting members, optionally Cu or other metal pillars, extend up from the base pads to top pads. A top pad interconnector connects the top pads in a configuration establishing an inductor current path between the base pads.