In one embodiment, an electronic system includes a printed circuit board, one or more packaged semiconductor devices, and a vapor chamber having a top and a bottom and enclosing a sealed cavity that is partially filled with a coolant. The vapor chamber comprises a thermo-conductive and electro-conductive material. The top of the vapor chamber has one or more depressions formed therein, each depression receiving and thermo-conductively connected to at least part of a bottom of a corresponding packaged semiconductor device, which is mounted through a corresponding aperture in the PCB. A heat sink may be thermo-conductively attached to the bottom of the vapor chamber.

A roll-to-roll printing process for large scale manufacturing of nanosensor systems for sensing pathophysiological signals is disclosed. The roll-to-roll manufacturing process may include three processes to improve the throughput and to reduce the cost in manufacturing: fabrication of textile based nanosensors, printing conductive tracks, and integration of electronics. The wireless nanosensor systems can be used in different monitoring applications. The fabric sheet printed and integrated with the customized components can be used in a variety of different applications. The electronics in the nanosensor systems connect to remote severs through adhoc networks or cloud networks with standard communication protocols or non-standard customized protocols for remote health monitoring.

Monolithic power stage (Pstage) packages and methods for using same are provided that may be implemented to provide lower thermal resistance/enhanced thermal performance, reduced noise, and/or smaller package footprint than conventional monolithic Pstage packages. The conductive pads of the disclosed Pstage packages may be provided with a larger surface area for contacting respective conductive layers of a mated PCB to provide a more effective and increased heat transfer away from a monolithic Pstage package. In one example, the increased heat transfer away from the monolithic Pstage package results in lower monolithic Pstage package operating temperature and increased power output. In another example, a monolithic Pstage package may be provided with an adaptive application-oriented interface and a multi-function pin that allows the same monolithic Pstage package to automatically detect and select between a relatively higher power information handling system application, and a relatively lower power information handling system VR application.

A method of manufacturing a driver board assembly includes embedding one or more power device assemblies within a first PCB material layer, forming one or more cooling channels within a surface of the first PCB material layer such that the one more cooling channels extend proximate to the one or more power device assemblies, forming a plurality of thermally conductive vias extending between a surface of the one or more power device assemblies and the one or more cooling channels, and bonding a second PCB material layer to the first PCB material layer to enclose the one or more cooling channels between the first PCB material layer and the second PCB material layer.

Provided is a novel printing process for fabricating metallic, conductive and transparent ultra-thin nanowires and patterns including same on a substrate. The process includes two different controllable steps, each designed to achieving a useful and efficient pattern.

A component carrier including a stack with at least one electrically conductive layer structure and/or at least one electrically insulating layer structure. A component embedded in the stack, and a heat removal body configured for removing heat from the component is connected to the stack and preferably to the component. The heat removal body including a component-sided first heat removal structure thermally coupled with the component, and a second heat removal structure thermally coupled with the first heat removal structure and facing away from the component.

An electronic module is provided. The electronic module includes: a magnetic device having a magnetic body, electronic devices, and a substrate, wherein a first lead extends out from a first lateral surface and a second lead extends out from a second lateral surface opposite to the first lateral surface of the magnetic body and the substrate and the second lead of the magnetic device are located at a same lateral side of the magnetic body and the second lead is extended from the second lateral surface of the magnetic body to the substrate to electrically connect the magnetic device and the substrate.

An embodiment includes an apparatus comprising: a rod-shaped substrate including a rod long axis; a first layer, including a first interconnect, substantially surrounding the substrate in a first plane that is orthogonal to the rod long axis; and a second layer, including a second interconnect, substantially surrounding the first layer in the first plane. Other embodiments are described herein.

Described herein are apparatuses and methods for applying high voltage, sub-microsecond (e.g., nanosecond range) pulsed output to a biological material, e.g., tissues, cells, etc., using a high voltage (e.g., MOSFET) gate driver circuit having a high voltage isolation and a low inductance. In particular, described herein are multi-core pulse transformers comprising independent transformer cores arranged in parallel on opposite sides of a substrate. The transformer cores may have coaxial primary and secondary windings. Also describe are pulse generators including multi-core pulse transformers arranged in parallel (e.g., on opposite sides of a PCB) to reduce MOSFET driver gate inductance.

A semiconductor device includes an insulating substrate including an insulating plate and a circuit plate disposed on a main surface of the insulating plate; a semiconductor chip having a front surface provided with an electrode and a rear surface fixed to the circuit plate; a printed circuit board facing the insulating substrate and including a metal layer; a conductive post having one end electrically and mechanically connected to the electrode and another end electrically and mechanically connected to the metal layer; a passive element fixed to the printed circuit board; and a plurality of positioning posts fixed to the printed circuit board to position the passive element.