Abstract: Embodiments of the invention include a current sensing device for sensing current in an organic substrate. The current sensing device includes a released base structure that is positioned in proximity to a cavity of the organic substrate and a piezoelectric film stack that is positioned in proximity to the released base structure. The piezoelectric film stack includes a piezoelectric material in contact with first and second electrodes. A magnetic field is applied to the current sensing device and this causes movement of the released base structure and the piezoelectric stack which induces a voltage (potential difference) between the first and second electrodes.

Abstract: Embodiments include a sensor node, a method of forming the sensor node, and a vehicle with a communication system that includes sensor nodes. A sensor node includes an interconnect with an input connector, an output connector, and an opening on one or more sidewalls. The sensor node also includes a package with one or more sidewalls, a top surface, and a bottom surface, where at least one of the sidewalls of the package is disposed on the opening of interconnect. The sensor node may have a control circuit on the package, a first millimeter-wave launcher on the package, and a sensor coupled to the control circuit, where the sensor is coupled to the control circuit with an electrical cable. The sensor node may include that at least one of the sidewalls of the package is crimped by the opening and adjacent and co-planar to an inner wall of the interconnect.

Abstract: Embodiments of the invention include a microelectronic device that includes a substrate having transistor layers and interconnect layers including conductive layers to form connections to transistor layers. A capacitive bump is disposed on the interconnect layers. The capacitive bump includes a first electrode, a dielectric layer, and a second electrode. In another example, an inductive bump is disposed on the interconnect layers. The inductive bump includes a conductor and a magnetic layer that surrounds the conductor.

Abstract: Embodiments of the invention include a piezoelectric package integrated filtering device that includes a film stack. In one example, the film stack includes a first electrode, a piezoelectric material in contact with the first electrode, and a second electrode in contact with the piezoelectric material. The film stack is suspended with respect to a cavity of an organic substrate having organic material and the film stack generates an acoustic wave to be propagated across the film stack in response to an application of an electrical signal between the first and second electrodes.

Abstract: Embodiments of the invention include a filtering device that includes a first electrode, a piezoelectric material in contact with the first electrode, and a second electrode in contact with the piezoelectric material. The piezoelectric filtering device expands and contracts laterally in a plane of an organic substrate in response to application of an electrical signal between the first and second electrodes.

Abstract: Embodiments of the invention include a microelectronic device that includes a die having at least one transceiver unit, a redistribution package coupled to the die, and a substrate coupled to the redistribution package. The substrate includes an antenna unit for transmitting and receiving communications at a frequency of approximately 4 GHz or higher.

Abstract: Embodiments of the invention include a microelectronic device that includes a first substrate having organic dielectric material, conductive layers, and a first portion of a distributed antenna unit. The first substrate supports at least one radio frequency (RF) component. A second substrate is coupled to the first substrate. The second substrate is integrated with a housing of the microelectronic device and includes a second portion of the distributed antenna unit for transmitting and receiving communications at a frequency of approximately 4 GHz or higher.

Abstract: Embodiments of the invention include a base station that includes a central transceiver unit (CTU) having a plurality of transceiver cores and a substrate. A printed circuit board (PCB) supports the substrate and at least one antenna unit is coupled to the PCB with at least one of a cable and a waveguide. The at least one antenna unit transmits and receives communications at a frequency of approximately 4 GHz or higher.

Abstract: Embodiments include a waveguide bundle, a dielectric waveguide, and a vehicle. The waveguide bundle includes dielectric waveguides, where each dielectric waveguide has a dielectric core and a conductive coating around the dielectric core. The waveguide bundle also has a power delivery layer formed around the dielectric waveguides, and an insulating jacket enclosing the waveguide bundle. The waveguide bundle may also include the power deliver layer as a braided shield, where the braided shield provides at least one of a DC and an AC power line. The waveguide bundle may further have one of the dielectric waveguides provide a DC ground over their conductive coatings, where the AC power line does not use the braided shield as reference or ground. The waveguide bundle may include that the power delivery layer is separated from the dielectric waveguides by a braided shield, where the power delivery layer is a power delivery braided foil.

Abstract: Embodiments of the invention include a microelectronic device having a sensing device and methods of forming the sensing device. In an embodiment, the sensing device includes a mass and a plurality of beams to suspend the mass. Each beam comprises first and second conductive layers and an insulating layer positioned between the first and second conductive layers to electrically isolate the first and second conductive layers. The first conductive layer is associated with drive signals and the second conductive layer is associated with sense signals of the sensing device.

Abstract: Embodiments of the invention include a sensing device that includes a base structure having a proof mass that is positioned in proximity to a cavity of an organic substrate, a piezoelectric material in contact with a first electrode of the base structure, and a second electrode in contact with the piezoelectric material. The proof mass deflects in response to application of an external force or acceleration and this deflection causes a stress in the piezoelectric material which generates a voltage differential between the first and second electrodes.

Abstract: A device package and a method of forming the device package are described. The device package includes a substrate having a ground plane and dies disposed on the substrate. The dies are electrically coupled to the substrate with solder balls or bumps surrounded by an underfill layer. The device package has a mold layer disposed over and around the dies, the underfill layer, and the substrate. The device package further includes an additively manufactured electromagnetic interference (EMI) shield layer disposed on an outer surface of the mold layer. The additively manufactured EMI shield layer is electrically coupled to the ground plane of the substrate. The outer surface of the mold layer may include a topmost surface and one or more sidewalls that are covered with the additively manufactured EMI shield layer. The additively manufactured EMI shield may include a first and second additively manufactured EMI shield layers and an additively manufactured EMI shield frame.

Abstract: An inductor in a device package and a method of forming the inductor in the device package are described. The inductor includes a first conductive layer disposed on a substrate. The inductor also has one or more hybrid magnetic additively manufactured (HMAM) layers disposed over and around the first conductive layer to form one or more via openings over the first conductive layer. The inductor further includes one or more vias disposed into the one or more via openings, wherein the one or more vias are only disposed on the portions of the exposed first conductive layer. The inductor has a dielectric layer disposed over and around the one or more vias, the HMAM layers, and the substrate. The inductor also has a second conductive layer disposed over the one or more vias and the dielectric layer.

Abstract: Hybrid filters and more particularly filters having acoustic wave resonators (AWRs) and lumped component (LC) resonators and packages therefor are described. In an example, a packaged filter includes a package substrate, the package substrate having a first side and a second side, the second side opposite the first side. A first acoustic wave resonator (AWR) device is coupled to the package substrate, the first AWR device comprising a resonator. A plurality of inductors is in the package substrate.

Abstract: Embodiments of the invention include an acoustic wave resonator (AWR) module. In an embodiment, the AWR module may include a first AWR substrate and a second AWR substrate affixed to the first AWR substrate. In an embodiment, the first AWR substrate and the second AWR substrate define a hermetically sealed cavity. A first AWR device may be positioned in the cavity and formed on the first AWR substrate, and a second AWR device may be positioned in the cavity and formed on the second AWR substrate. In an embodiment, a center frequency of the first AWR device is different than a center frequency of the second AWR device. In additional embodiment of the invention, the AWR module may be integrated into a hybrid filter. The hybrid filter may include an AWR module and other RF passive devices embedded in a packaging substrate.

Abstract: Packaged RF front end systems including a hybrid filter and an active circuit in a single package are described. In an example, a package includes an active die comprising an acoustic wave resonator. A package substrate is electrically coupled to the active die. A seal frame surrounds the acoustic wave resonator and is attached to the active die and to the package substrate, the seal frame hermetically sealing the acoustic wave resonator in a cavity between the active die and the package substrate.

Abstract: Embodiments of the invention include an acoustic transducer device having a base structure that is positioned in proximity to a cavity of an organic substrate, a piezoelectric material in contact with a first electrode of the base structure, and a second electrode in contact with the piezoelectric material. In one example, for a transmit mode, a voltage signal is applied between the first and second electrodes and this causes a stress in the piezoelectric material which causes a stack that is formed with the first electrode, the piezoelectric material, and the second electrode to vibrate and hence the base structure to vibrate and generate acoustic waves.

Abstract: Embodiments of the invention include a microelectronic device that includes a first die formed with a silicon based substrate and a second die coupled to the first die. The second die is formed with compound semiconductor materials in a different substrate (e.g., compound semiconductor substrate, group III-V substrate). An antenna unit is coupled to the second die. The antenna unit transmits and receives communications at a frequency of approximately 4 GHz or higher.

Abstract: RF front end systems or modules with an acoustic wave resonator (AWR) on an interposer substrate are described. In an example, an integrated system includes an active die, the active die comprising a semiconductor substrate having a plurality of active circuits therein. An interposer is also included, the interposer comprising an acoustic wave resonator (AWR). A seal frame couples the active die to the interposer, the seal frame surrounding the acoustic wave resonator and hermetically sealing the acoustic wave resonator between the active die and the interposer.

Abstract: Embodiments of the invention include a microelectronic device that includes a transceiver coupled to a first substrate and a second substrate coupled to the first substrate. The second substrate includes an antenna unit for transmitting and receiving communications at a frequency of approximately 4 GHz or higher. An interposer substrate can provide a spacing between the first and second substrates.