Abstract: An antenna is described on ceramics that may be used for a packaged die. In one example, a package has a die, a ceramic substrate over the die, an antenna attached to the ceramic substrate, and conductive leads electrically connecting the antenna to the die.

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 of the disclosure are directed to a chip package that includes a base that includes a redistribution layer; an optical transducer circuit element on the base electrically connected to the redistribution layer; an optical element adjacent to the optical transducer circuit element and at an edge of the base; and an encasement encasing the optical transducer circuit element and a portion of the optical element, wherein one side of the optical element is exposed at an edge of the encasement and at the edge of the printed circuit board.

Abstract: A system and method for aligning components is disclosed. A system arranges a plurality of components in a first component alignment. The system places two L-shaped fine placement tools in a position surrounding the plurality of components, wherein the L-shaped fine placement tools include a plurality of pins. The system applies a force to the pins included in the two L-shaped fine placement tools to shift the plurality of components from the first component alignment to a second component alignment, wherein the second component alignment has less unused space than the first component alignment. The system removes the two L-shaped fine placement tools. The system attaches the plurality of components to a carrier arranged in the second component alignment.

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.

Abstract: A flexible band wearable electronic device includes a plurality of rigid links. The flexible band wearable electronic device also includes a number of pivot joints coupling the plurality of rigid links together. The flexible band wearable electronic device further includes a first electronic device on a first of the plurality of rigid links, and a second electronic device on a second of the plurality of rigid links. The flexible band wearable electronic device still further includes an electrical communication pathway between first electronic device and the second electronic device and through at least a portion of one of the number of pivot joints.

Abstract: Conductive paths through a dielectric are described that have a high aspect ratio for semiconductor devices. In one example, a semiconductor device package has a semiconductor substrate having circuitry formed on the substrate. A plurality of conductive connection pads are on the semiconductor substrate to connect to the circuitry. A post is on each of a subset of the connection pads, the posts being formed of a conductive material. A dielectric layer is over the semiconductor substrate including over the connection pads and the posts. Filled vias are over each connection pad that is not of the subset and over each post of the subset of the connection pads and a connector is over each filled via.

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: 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: 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 multi-chip module includes two silicon bridge interconnects and three components that are tied together by the bridges with one of the components in the center. At least one of the silicon bridge interconnects is bent to create a non-planar chip-module form factor. Cross-connected multi-chip silicon bent-bridge interconnect modules include the two silicon bridges contacting the center component at right angles to each other, plus a fourth component and a third silicon bridge interconnect contacting the fourth component and any one of the original three components.

Abstract: A method includes aligning a wire with a package body having a contact pad and moving the wire through the package body to form electrical contact with the contact pad.

Abstract: A bent-bridge semiconductive apparatus includes a silicon bridge that is integral to a semiconductive device and the silicon bridge is deflected out of planarity. The silicon bridge may couple two semiconductive devices, all of which are from an integral processed die.

Abstract: Embodiments are generally directed to package stacking using chip to wafer bonding. An embodiment of a device includes a first stacked layer including one or more semiconductor dies, components or both, the first stacked layer further including a first dielectric layer, the first stacked layer being thinned to a first thickness; and a second stacked layer of one or more semiconductor dies, components, or both, the second stacked layer further including a second dielectric layer, the second stacked layer being fabricated on the first stacked layer.

Abstract: A system-in-package device includes at least three electrical device components arranged in a common package. A first electrical device component includes a first vertical dimension, a second electrical device component includes a second vertical dimension and a third electrical device component comprises a third vertical dimension. The first electrical device component and the second electrical device component are arranged side by side in the common package. Further, the third electrical device component is arranged on top of the first electrical device component in the common package. At least a part of the third electrical device component is arranged vertically between a front side level of the second electrical device component and a back side level of the second electrical device component.

Abstract: An electrical device includes a redistribution layer structure, an inter-diffusing material contact structure and a vertical electrically conductive structure located between the redistribution layer structure and the inter-diffusing material contact structure. The vertical electrically conductive structure includes a diffusion barrier structure located adjacently to the inter-diffusing material contact structure. Further, the diffusion barrier structure and the redistribution layer structure comprise different lateral dimensions.

Abstract: Embodiments of the present disclosure relate to a cooler for semiconductor devices. The semiconductor device may be electrically coupleable to a power source. The device may generate heat when the power source supplies power to the device during use of the device. The cooler may be coupled to one or more surfaces of the device. The cooler may include a hydrophilic material to adsorb water from ambient air. During operation of the device, the cooler may cool the device by conduction of heat away from the device to the cooler. The cooler may include water that is evaporated during use of the device to increase cooling capacity of the cooler. The cooler may be recharged with water from humidity in air when the device is not operated or operated at a lower power level. Other embodiments may be described and/or claimed.

Abstract: An electronic component assembly includes a substrate having a first face and an opposed second face. One or more electronic components are coupled with either or both of the first and second faces. A filler interface heat transfer system is coupled with the substrate. The filler interface heat transfer system includes at least one enclosure shell coupled with one of the first or second faces. The at least one enclosure shell surrounds a filler cavity including the one or more electronic components therein. A heat transfer filler is within the filler cavity, the heat transfer filler includes a contoured filler profile conforming to at least the one or more electronic components.

Abstract: A microelectronic package including a passive microelectronic device disposed within a package body, wherein the package body is the portion of the microelectronic package which provides support and/or rigidity to the microelectronic package. In a flip-chip type microelectronic package, the package body may comprise a microelectronic substrate to which an active microelectronic device is electrically attached. In an embedded device type microelectronic package, the package body may comprise the material in which the active microelectronic device is embedded.

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.