Amkor Technology

About: Amkor Technology is a company organization based out in Tempe, Arizona, United States. It is known for research contribution in the topics: Semiconductor package & Substrate (printing). The organization has 1069 authors who have published 1106 publications receiving 26778 citations. The organization is also known as: Amkor & Amkor Technology, Inc..

Electronic component package comprising fan-out and fan-in traces

Abstract: A method of forming an electronic component package includes coupling a first surface of an electronic component to a first surface of a first dielectric strip, the electronic component comprising bond pads on the first surface; forming first via apertures through the first dielectric strip to expose the bond pads; and filling the first via apertures with an electrically conductive material to form first vias electrically coupled to the bond pads. The bond pads are directly connected to the corresponding first vias without the use of a solder and without the need to form a solder wetting layer on the bond pads.

Cavity semiconductor package with exposed leads and die pad

Abstract: A semiconductor chip package and a method of making the package are disclosed. The method includes forming a lead frame having a die pad and leads. At least one of the leads has a tab projecting upward and laterally from a body of the lead. In one embodiment, curved tips are formed on the inner ends of the leads. At least a portion of the lead frame is encapsulated with a mold material to form a package mold having a cavity. The cavity has a floor with a thickness substantially similar to the thickness of the leads so as to expose upper surfaces of the inner ends of the leads. The leads have lower surfaces exposed at the lower surface of the package mold. The lead tab is entirely encapsulated within the package mold. A semiconductor die is mounted on the lead frame subsequent to the encapsulation of at least a portion of the lead frame. The semiconductor die is enclosed in the package mold by placing a covering such as a lid over the semiconductor die. This method yields a cavity semiconductor package which may be used in applications where contact between the package mold and the semiconductor die and/or bond wires is undesirable, while allowing the leads and die pad to be securely held in place by the package mold.

Semiconductor package having a heat spreader with an exposed exterion surface and a top mold gate

Abstract: A semiconductor device has a substrate. A die is attached to a first surface of the substrate. A heat sink is provided having an approximately planer member and support members extending from the planer member. The support members are attached to the first surface of the substrate to form a cavity over the die with the planer member positioned above the die. An encapsulant is provided for encapsulating the device, wherein an exterior surface of the planer member is exposed. A non-tapered opening is formed in the planer member. The encapsulant is injected through the opening to encapsulate the cavity and the encapsulant will partially fill the non-tapered opening.

Method for making an integrated circuit substrate having laminated laser-embedded circuit layers

Abstract: A method for making an integrated circuit substrate having laminated laser-embedded circuit layers provides a multi-layer high-density mounting and interconnect structure for integrated circuits. A prepared substrate, which may be a rigid double-sided dielectric or film dielectric with conductive patterns plated, etched or printed on one or both sides is laminated with a thin-film dielectric on one or both sides. The thin-film is laser-ablated to form channels and via apertures and conductive material is plated or paste screened into the channels and apertures, forming a conductive interconnect pattern that is isolated by the channel sides and vias through to the conductive patterns on the prepared substrate. An integrated circuit die and external terminals can then be attached to the substrate, providing an integrated circuit having a high-density interconnect.

Multi-layer leadframe structure

Abstract: A leadframe and a package including the leadframe are disclosed. At least one lead includes a nonconductive layer on the inner end segment of the lead set back from its inner end. An electrically conductive layer is on a surface of the nonconductive layer. The nonconductive layer electrically isolates the electrically conductive layer from the lead upon which the nonconductive layer is positioned. The lead itself and the electrically conductive layer thereon are separately available for electrical connection to a semiconductor chip. The electrically conductive layer in turn may be electrically coupled to a second lead, with the electrically conductive layer serving as a bridge for an electrical connection between the chip and the second lead.