According to the present disclosure, a semiconductor apparatus comprises a housing a semiconductor chip installed in the housing, and a first radio tag installed on the housing. The first radio tag is installed in a state where rewriting from outside is not limited.

A semiconductor device includes a substrate, a conductive part formed on a front surface of the substrate, a semiconductor chip disposed on the front surface of the substrate, a control unit that controls the semiconductor chip, a sealing resin that covers the semiconductor chip, the control unit and the conductive part, and a first lead bonded to the conductive part and partially exposed from the sealing resin. The conductive part includes a first pad and a second pad disposed apart from each other. The first lead is bonded to the first pad and the second pad.

A bonded structure is disclosed. The bonded structure can include an interconnect structure. The bonded structure can also include a first die directly bonded to the interconnect structure. The bonded structure can also include a second die mounted to the interconnect structure. The second die is spaced apart from the first die laterally along an upper surface of the interconnect structure. The second die is electrically connected with the first die at least partially through the interconnect structure. The bonded structure can further include a dielectric layer that is disposed over the upper surface of the interconnect structure between the first die and the second die.

A method for manufacturing a semiconductor apparatus includes the steps of: applying a first adhesive having heat dissipation property and thermosetting property onto each of surfaces of a plurality of devices joined to a surface of a substrate, and thereafter mounting heat dissipation blocks, and performing bonding by heat treatment; applying a second adhesive having heat dissipation property and thermosetting property onto each of surfaces of the heat dissipation blocks, so as to be higher than a height A of a molding resin that seals the devices in a later step; and curing the second adhesives by heat treatment while aligning, by using thicknesses of the second adhesives, heights to surfaces of the second adhesives so that the heights are matched with the height A of the molding resin.

A semiconductor device includes a heat sink, a base material including an insulating layer and mounted on the heat sink on one side in a first direction, a first conductive layer bonded to the base material and located on a side opposite the heat sink with respect to the base material, a first semiconductor element bonded to the first conductive layer, a first power terminal electrically connected to the first conductive layer and the first semiconductor element, and a sealing resin covering the first conductive layer and the first semiconductor element. The first power terminal is exposed from the sealing resin. The first power terminal is surrounded by a peripheral edge of the sealing resin as viewed in the first direction.

Bonded die structures and methods of fabricating bonded die structures including improved positioning of the dies used to form the structures. Improved positioning may be achieved by providing non-linear alignment features around the periphery of the dies that may facilitate accurate positioning of the dies with respect to one or more alignment marks on the target structures on which the dies are placed. The non-linear alignment features may include features formed in the peripheral edges of the dies, such as indent portions extending inwardly from the peripheral edges of the dies and/or outward bulge portions extending outwardly from the peripheral edges of the dies. Alternatively, or in addition, the non-linear alignment features may be features formed in a seal ring structure of the dies. The non-linear alignment features may improve the accuracy of the positioning of the dies relative to alignment mark(s) on the target structures using optical detection systems.

A semiconductor structure may be provided by forming a first molding compound around a first semiconductor die such that a top surface of the first molding compound is coplanar with a top dielectric surface of the first semiconductor die; forming a combination of at least one bonding-level dielectric layer, first bonding pads, and dummy pads over the first semiconductor die and the first molding compound, wherein each of the bonding pads is formed directly on a respective conductive structure within the first semiconductor die; and attaching a second semiconductor die including second bonding pads therein to the first semiconductor die by performing a bonding process that bonds the second bonding pads to the first bonding pads by metal-to-metal bonding such that a first subset of the dummy pads has an areal overlap in a plan view with the second semiconductor die.

A method of manufacturing a semiconductor device packaging panel is provided. The method includes forming a packaging substrate having a plurality of grooves orthogonally arranged and substantially surrounding a plurality of package sites. A plurality of semiconductor die is affixed on a first major side of the packaging substrate. Each semiconductor die of the plurality of semiconductor die is affixed at a unique package site of the plurality of package sites. An encapsulant encapsulates the first major side of the packaging substrate such that each semiconductor die of the plurality of semiconductor die is encapsulated by the encapsulant. A singulation cut is formed along each groove of the plurality of grooves of the packaging substrate to form individual semiconductor device units.

A semiconductor package assembly, comprising: a semiconductor package comprising: a semiconductor die mounted on a substrate; a pair of interconnection blocks mounted at opposite sides of the semiconductor die; and an encapsulant layer, wherein the pair of interconnection blocks have respective top surfaces exposed and a top surface of the semiconductor die is exposed; and an inductor block mounted on the semiconductor package, comprising: an inductor extending through the insulation body in a horizontal direction, and having a pair of inductor contact pads exposed at a bottom surface of the insulation body, wherein the pair of inductor contact pads are aligned to and electrically coupled to the pair of interconnection blocks; and a thermally conductive coating formed at an outer surface of the insulation body and extending in a vertical direction of the insulation body from the bottom surface to a top surface of the insulation body.

Apparatuses relating generally to a microelectronic package having protection from electromagnetic interference are disclosed. In an apparatus thereof, a platform has an upper surface and a lower surface opposite the upper surface and has a ground plane. A microelectronic device is coupled to the upper surface of the platform. Wire bond wires are coupled to the ground plane with a pitch. The wire bond wires extend away from the upper surface of the platform with upper ends of the wire bond wires extending above an upper surface of the microelectronic device. The wire bond wires are spaced apart from one another to provide a fence-like perimeter to provide an interference shielding cage. A conductive layer is coupled to at least a subset of the upper ends of the wire bond wires for electrical conductivity to provide a conductive shielding layer to cover the interference shielding cage.