Abstract: A microelectronic package includes at least two semiconductor die, one die stacked over at least partially another. At a least the upper die is oriented with its active surface facing in the direction of a redistribution structure, and one or more wires are coupled to extend from contacts on that active surface into conductive structures in the redistribution structure.

Abstract: A semiconductive device stack, includes a baseband processor die with an active surface and a backside surface, and a recess in the backside surface. A recess-seated device is disposed in the recess, and a through-silicon via in the baseband processor die couples the baseband processor die at the active surface to the recess-seated die at the recess. A processor die is disposed on the baseband processor die backside surface, and a memory die is disposed on the processor die. The several dice are coupled by through-silicon via groups.

Abstract: A package on a die having a low resistive substrate, wherein the package comprises an inductor on low-k dielectric and a capacitor on high-k dielectric. The stacked arrangement having different dielectric materials may provide an inductor having a high Q-factor while still having a high capacitance density. In addition, moving the inductor from the die to the package and fabricating the high density capacitor on the package reduces the silicon area required permitting smaller RF/analog blocks on the chip.

Abstract: A package on a die having a low resistive substrate, wherein the package comprises an inductor on low-k dielectric and a capacitor on high-k dielectric. The stacked arrangement having different dielectric materials may provide an inductor having a high Q-factor while still having a high capacitance density. In addition, moving the inductor from the die to the package and fabricating the high density capacitor on the package reduces the silicon area required permitting smaller RF/analog blocks on the chip.

Abstract: A microelectronic device may include a substrate, a component, a first plate, a second plate, and a shield. The component may be disposed at least partially within the substrate. The first plate may be disposed on a first side of the component. The second plate may be disposed on a second side of the component. The shield may be disposed around at least a portion of a periphery of the component.

Abstract: Embodiments of the invention include a microelectronic device and methods of forming a microelectronic device. In an embodiment the microelectronic device includes a semiconductor die and an inductor that is electrically coupled to the semiconductor die. The inductor may include one or more conductive coils that extend away from a surface of the semiconductor die. In an embodiment each conductive coils may include a plurality of traces. For example, a first trace and a third trace may be formed over a first dielectric layer and a second trace may be formed over a second dielectric layer and over a core. A first via through the second dielectric layer may couple the first trace to the second trace, and a second via through the second dielectric layer may couple the second trace to the third trace.

Abstract: Embodiments include semiconductor packages and methods of forming the semiconductor packages. A semiconductor package includes a die over a substrate, a first conductive layer over the die, and a conductive cavity antenna over the first conductive layer and substrate. The conductive cavity antenna includes a conductive cavity, a cavity region, and a plurality of interconnects. The conductive cavity is over the first conductive layer and surrounds the cavity region. The semiconductor package also includes a second conductive layer over the conductive cavity antenna, first conductive layer, and substrate. The conductive cavity extends vertically from the first conductive layer to the second conductive layer. The cavity region may be embedded with the conductive cavity, the first conductive layer, and the second conductive layer. The plurality of interconnects may include first, second, and third interconnects.

Abstract: Embodiments include semiconductor packages and methods of forming the semiconductor packages. A semiconductor package includes a die over a substrate, a first conductive layer over the die, and a cavity resonator antenna over the first conductive layer and substrate. The cavity resonator antenna includes a conductive cavity, a cavity region, and a plurality of interconnects. The conductive cavity is over the first conductive layer and surrounds the cavity region. The semiconductor package also includes a second conductive layer over the cavity resonator antenna, first conductive layer, and substrate. The conductive cavity may extend vertically from the first conductive layer to the second conductive layer. The cavity region may be embedded with the conductive cavity, the first conductive layer, and the second conductive layer. The plurality of interconnects may include first, second, and third interconnects.

Abstract: Disclosed is a package comprising a substrate having a patterned surface with an optical contact area, an optical redistribution layer (oRDL) feature, and a build-up material extending over the patterned surface of the substrate and around portions of the oRDL features. In some embodiments, the package comprises a liner sheathing the oRDL features. In some embodiments, the oRDL feature extends through openings in an outer surface of the build-up material and forms posts extending outward from the outer surface. In some embodiments, the package comprises an electrical redistribution layer (eRDL) feature, at least some portion of which overlap at least some portion of the oRDL feature. In some embodiments, the package comprises an optical fiber coupled to the oRDL features.

Abstract: An embedded-bridge substrate connector apparatus includes a patterned reference layer to which a first module and a subsequent module are aligned and the two modules are mated at the patterned reference layer. At least one module includes a silicon bridge connector that bridges to two devices, through the patterned reference layer, to the mated module.

Abstract: Embodiments of the invention include a microelectronic device and methods of forming a microelectronic device. In an embodiment the microelectronic device includes a semiconductor die and an inductor that is electrically coupled to the semiconductor die. The inductor may include one or more conductive coils that extend away from a surface of the semiconductor die. In an embodiment each conductive coils may include a plurality of traces. For example, a first trace and a third trace may be formed over a first dielectric layer and a second trace may be formed over a second dielectric layer and over a core. A first via through the second dielectric layer may couple the first trace to the second trace, and a second via through the second dielectric layer may couple the second trace to the third trace.

Abstract: An embedded-bridge substrate connector apparatus includes a patterned reference layer to which a first module and a subsequent module are aligned and the two modules are mated at the patterned reference layer. At least one module includes a silicon bridge connector that bridges to two devices, through the patterned reference layer, to the mated module.

Abstract: A semiconductor package includes a first semiconductor die, a semiconductor device comprising a second semiconductor die, and one or more wire bond structures. The wire bond structure includes a bond interface portion. The wire bond structure is arranged next to the first semiconductor die. The first semiconductor die and the bond interface portion of the wire bond structure are arranged at the same side of the semiconductor device. An interface contact structure of the semiconductor device is electrically connected to the wire bond structure.

Abstract: The present disclosure is directed to systems and methods for fabricating a semiconductor inductor that includes a coil deposited on a stop layer that is deposited on a sacrificial substrate. The semiconductor inductor may be fabricated on a silicon wafer and singulated. The sacrificial substrate beneficially provides structural support for the singulated semiconductor inductor. The singulated semiconductor inductor advantageously requires minimal active die surface area. The removal of the sacrificial substrate after coupling to the active die beneficially reduces the overall thickness (or height) of the semiconductor package, providing a decided advantage in low profile, portable, electronic devices.

Abstract: A patch antenna array is fabricated with a package-on-package setup that contains a transceiver. The patch antenna array has a footprint that intersects the transceiver footprint. The package-on-package setup includes through-mold vias that couple to a redistribution layer disposed between the patch antennas and the package-on-package setup.

Abstract: Electronics devices, having vertical and lateral redistribution interconnects, are disclosed. An electronics device comprises an electronics component (e.g., die, substrate, integrated device, etc.), a die(s), and a separately formed redistribution connection layer electrically coupling the die(s) to the electronics component. The redistribution connection layer comprises dielectric layers on either side of at least one redistribution layer. The dielectric layers comprise openings that expose contact pads of the at least one redistribution layer for electrically coupling die(s) and components to each other via the redistribution connection layer. The redistribution connection layer is flexible and wrap/folded around side edges of die(s) to minimize vertical vias. Various devices and associated processes are provided.

Abstract: Package devices (systems and methods for their manufacture) may have an integrated circuit (IC) chip mounted on a top surface of a package substrate of and IC package, and embedded in a mold compound formed onto the top surface. They may also have conductive elements mounted on the top surface of the package substrate, embedded in the mold compound, horizontally disposed at a first vertical sidewall of the package device, and having vertical contact pads exposed at the first vertical sidewall. Conductor material traces of the IC package may electrically couple contacts of the chip to the conductive elements. Traces of the IC package may also electrically couple contacts of the chip to bottom surface contacts of the IC package. The vertical contact pads provide a shorter signal path to another device having vertically mounted surface contacts or opposing contact pads, thus improving signaling to the other device.

Abstract: Systems and methods are provide to form one or more pads on at least one surface associated with a portion of a component, for example, a component associated with a surface-mounted device (SMD). Further, the systems and methods are directed to providing metal (for example, copper, Cu) layers on the surface of one or more terminations (for example, solder termination pads) of an electrical component. In one embodiment, the metal layers include metal termination pads that are fabricated on a carrier layer; components can be soldered to these termination pads, then the components with the metal pads can be debonded from the carrier layer. As such, the solder terminations of the components can be covered by the metal pads. The disclosed systems and methods can permit or otherwise facilitate a wider selection and easy availability of the components to be electrically and/or mechanically connected to semiconductor packages.

Abstract: A microelectronic package includes at least two semiconductor die, one die stacked over at least partially another. At a least the upper die is oriented with its active surface facing in the direction of a redistribution structure, and one or more wires are coupled to extend from contacts on that active surface into conductive structures in the redistribution structure.

Abstract: A semiconductor device includes a plurality of circuit regions formed at a circuit semiconductor layer of a semiconductor die. The semiconductor device includes an etch stop layer of the semiconductor die arranged between the circuit semiconductor layer of the semiconductor die and a handling layer of the semiconductor die. The semiconductor device includes one or more trench structures extending through the handling layer of the semiconductor die. The one or more trench structures extends to at least the etch stop layer and to at most the circuit semiconductor layer of the semiconductor die.