A circuit assembly is provided and includes a printed circuit board (PCB) having a circuit element region and defining a trench surrounding an entirety of the circuit element region, a circuit element disposed within the circuit element region of the PCB; and a Faraday wall. The Faraday wall includes a solid, unitary body having a same shape as the trench. The Faraday wall is disposed within the trench to surround an entirety of the circuit element.

An electronic device is provided. The electronic device includes a housing, a first printed circuit board disposed in an internal space of the housing and including first conductive terminals, and a second printed circuit board disposed parallel to the first printed circuit board in the internal space and including second conductive terminals electrically connected to the first conductive terminals. The second printed circuit board includes at least some conductive terminals of the second conductive terminals, or at least one connection failure prevention structure disposed around at least some conductive terminals of the second conductive terminals.

An integrated circuit (IC) chip module includes a carrier, a stiffening frame, an IC chip, a first directional heat spreader, and a second directional heat spreader. Presented herein is a fabrication method that includes attaching the stiffening frame to the carrier. The stiffening frame includes a central opening, a base portion, a first pair of opposing sidewalls, and a second pair of opposing sidewalls. The method includes electronically coupling the semiconductor chip to the carrier concentrically arranged within the central opening. The method includes thermally contacting the first directional heat spreader to the semiconductor chip. The first directional heat spreader transfers heat from the semiconductor chip towards the first pair of opposing sidewalls. The method includes thermally contacting the second directional heat spreader to the first directional heat spreader. The second directional heat spreader transfers heat from the first directional heat spreader towards the second pair of opposing sidewalls.

An electronic assembly (100) includes a mechanical carrier (102), a plurality of integrated circuits (104A, 104B) disposed on the mechanical carrier, a fan out package (108) disposed on the plurality of integrated circuits, a plurality of singulated substrates (112A, 112B) disposed on the fan out package, a plurality of electronic components (114A, 114B) disposed on the plurality of singulated substrates, and at least one stiffness ring (116A, 116B, 116C) disposed on the plurality of singulated substrates. A method for constructing an electronic assembly includes identifying a group of known good singulated substrates, joining the group of known good singulated substrates into a substrate panel, attaching at least one bridge to the substrate panel that electrically couples at least two of the known good singulated substrates, and mounting a plurality of electronic components onto the substrate panel, each electronic component of the plurality of electronic components corresponding to a respective known good singulated substrate.

A system for controlling a robotic arm is disclosed. The system includes a robotic arm including a surgical tool, a tool driver, and at least two sensors disposed on the robotic arm to redundantly monitor a status of the robotic arm and to verify an operational parameter of the surgical robotic tool. A central control circuit is configured to measure a first physical property of the robotic arm based on readings from the first sensor, measure a second physical property of the robotic arm based on readings from the second sensor, and determine a status of the robotic arm based on the first and second measurements of the first and second physical properties of the robotic arm.

Printed circuit boards include conductive metallic paths, such as vias, traces, and pads on the printed circuit board. One or more metal additive structures are additively manufactured onto the printed circuit boards in a manner that forms a continuous weld with at least one of the conductive metallic paths. As a result, the metal additive structures are continuous with the printed circuit board and do not require separate attachment mechanisms (e.g., soldering or mechanical fastening). The metal additive structures may include shield cans, frames, antennas, or heat sinks for the printed circuit board, for example.

A computing system is provided. The computing system includes a semi-flexible printed circuit board assembly (PCBA) with a first element and a second element. The first element is configured to move in a non-planar direction with respect to the second element. The computing system also includes an internal trace connecting the first element and the second element of the semi-flexible PCBA. The computing system also includes a support mechanism, which is configured to constrain relative movements between the first element with respect to the second element of the semi-flexible PCBA.

A circuit board heat dissipation assembly includes a circuit board, a heat sink, a metal back plate, a heat pipe, and a pressing member. The circuit board has a front side and a rear side, and the front side has at least one heat generating area. The heat sink is disposed in the heat generating area. The metal back plate is disposed at a spacing from the rear side of the circuit board. The heat pipe has a first end, a bend segment, and a second end. The first end is connected to the heat sink. The second end is in contact with the metal back plate. The bend segment connects the first end and the second end at a side edge of the circuit board. The pressing member is fixed on the metal back plate and presses the second end onto the metal back plate.

A power delivery module includes a frame having rails defining an opening that receives an electronic package. A bottom of the frame is mounted to a host circuit board and faces an upper surface of the electronic package. The frame is a layered structure including a power plate, a ground plate, and an insulator electrically isolating the power plate from the ground plate. The power deliver module includes module power contacts electrically connected to the power plate and extending from the bottom for electrical connection to package power contacts of the electronic package. Module ground contacts are electrically connected to the ground plate and extend from the bottom for electrical connection to package ground contacts of the electronic package. The module power contacts and the module ground contacts deliver power to the electronic package.

An arrangement for electromagnetic shielding of an electronic component attached to a substrate is described. The arrangement comprises an electrically conductive frame which is attached to the substrate in such a way that the frame frames the component. The arrangement further comprises an electrically conductive covering which is attached at least to a portion of a top side of the component, and which is electrically conductively attached at least to a portion of the frame. Furthermore, a method for electromagnetic shielding of the electronic component attached to the substrate and also a computer program product for carrying out the method are described.