In an embodiment, a device includes: a first reflective structure including first doped layers of a semiconductive material, alternating ones of the first doped layers being doped with a p-type dopant; a second reflective structure including second doped layers of the semiconductive material, alternating ones of the second doped layers being doped with a n-type dopant; an emitting semiconductor region disposed between the first reflective structure and the second reflective structure; a contact pad on the second reflective structure, a work function of the contact pad being less than a work function of the second reflective structure; a bonding layer on the contact pad, a work function of the bonding layer being greater than the work function of the second reflective structure; and a conductive connector on the bonding layer.

A semiconductor device, and a method of forming the device, are provided. The semiconductor device includes a first die having a first plurality of contact pads and a second die having a second plurality of contact pads. A substrate is bonded to a first contact pad of the first plurality of contact pads and a first contact pad of the second plurality of contact pads in a face-to-face orientation with the first die and the second die. A first through via extends through the substrate. Molding material is interposed between the first die, the second die and the substrate, the molding material extending along sidewalls of the first die, the second die, and the substrate. A second through via is positioned over a second contact pad of the first plurality of contact pads, the second through via extending through the molding material.

An electronic module on a flexible planar circuit substrate with a conductor configuration on a first substrate surface and a plurality of electronic components on the opposite, second substrate surface, wherein the components have component contacts, which are electrically connected selectively by way of vias in the circuit substrate and the conductor configuration, wherein the circuit substrate is a thermoplastic polymer and the component contacts are melted or thermally pressed into the second substrate surface in the region of the vias.

One of semiconductor packages includes a substrate and a package structure. The package structure is bonded to the substrate and includes a first redistribution layer structure, a first logic die, a plurality of second logic dies, a first memory die, a first heat conduction block and a first encapsulant. The first logic die and the second logic dies are disposed over and electrically connected to the first redistribution layer structure. The first memory die is disposed over the first logic die and the second logic dies and electrically connected to first redistribution layer structure. The first heat conduction block is disposed over the first logic die and the second logic dies. The first encapsulant encapsulates the first memory die and the first heat conduction block.

A semiconductor package includes a first semiconductor die, a second semiconductor die, a semiconductor bridge, an integrated passive device, a first redistribution layer, and connective terminals. The second semiconductor die is disposed beside the first semiconductor die. The semiconductor bridge electrically connects the first semiconductor die with the second semiconductor die. The integrated passive device is electrically connected to the first semiconductor die. The first redistribution layer is disposed over the semiconductor bridge. The connective terminals are disposed on the first redistribution layer, on an opposite side with respect to the semiconductor bridge. The first redistribution layer is interposed between the integrated passive device and the connective terminals.

A semiconductor package structure and a method of manufacturing the semiconductor package structure are disclosed. The semiconductor package structure includes a first semiconductor device having an active surface, a redistribution structure in electrical connection with the first semiconductor device, and a second semiconductor device bonded to the active surface of the first semiconductor device, and disposed between the first semiconductor device and the redistribution structure.

A semiconductor product in the form of a stack chip package and a method of manufacturing the same, where a plurality of semiconductor chips are stacked one on another so as to enable the exchange of electrical signals between the semiconductor chips, and where a conductive layer is included for inputting and outputting signals to and from individual chips. A stack chip package having a compact size may, for example, be manufactured by stacking, on a first semiconductor chip, a second semiconductor chip having a smaller surface area by means of interconnection structures so as to enable the exchange of electrical signals between the first and second semiconductor chips, and by using a conductive layer for inputting and outputting signals to and from individual semiconductor chips, in lieu of a thick substrate. Furthermore, heat dissipation effects can be enhanced by the addition of a heat dissipation unit.

There is provided a fingerprint sensor module comprising a fingerprint sensor device comprising a sensing array and at least one connection pad for electrically connecting the fingerprint sensor device to external circuitry, the sensing array and connection pad being located on a first side of the fingerprint sensing device; at least one electrically conductive via connection arranged adjacent to the fingerprint sensor device and in electrical contact with the connection pad via at least one conductive trace located in the same plane as the connection pad; a mold layer arranged to cover a backside of the fingerprint sensor device and to fill a volume between the fingerprint sensor device and the via connection, wherein an end portion of the via connection is exposed for connecting the fingerprint sensor module to external circuitry. There is also provided a method for manufacturing such a fingerprint sensor module.

Apparatuses and methods are described. This apparatus includes a bridge die having first contacts on a die surface being in a molding layer of a reconstituted wafer. The reconstituted wafer has a wafer surface including a layer surface of the molding layer and the die surface. A redistribution layer on the wafer surface includes electrically conductive and dielectric layers to provide conductive routing and conductors. The conductors extend away from the die surface and are respectively coupled to the first contacts at bottom ends thereof. At least second and third IC dies respectively having second contacts on corresponding die surfaces thereof are interconnected to the bridge die and the redistribution layer. A first portion of the second contacts are interconnected to top ends of the conductors opposite the bottom ends thereof in part for alignment of the at least second and third IC dies to the bridge die.

An electronic component mounting package includes a semiconductor element which is disposed such that an active surface faces a main surface of a wiring portion, and which is electrically connected to the wiring portion via a first terminal; and a thin film passive element which is disposed between the active surface of the semiconductor element and the main surface of the wiring portion when seen in a lamination direction, and which is electrically connected to the semiconductor element. A part of the first terminal is disposed on an outer side with respect to the thin film passive element in a plan view. A length of the first terminal in the lamination direction disposed on the outer side with respect to the thin film passive element is larger than a thickness of the thin film passive element in the lamination direction.