A DC/DC converter includes N inductors and N power modules which correspond to N phases. The N inductors each include a plurality of inductor chips that are electrically connected in parallel to each other. The plurality of inductor chips are mounted separately on a main mounting surface and a sub-mounting surface of a printed circuit board. The sub-mounting surface is opposite to the main mounting surface.

An uneven current distribution among a plurality of provided power semiconductor chips is to be suppressed. A power semiconductor module includes a module main body, a plurality of power semiconductor chips arranged on an upper surface of the module main body, and peripheral structures being insulating ferromagnets surrounding parts of a periphery of the module main body in a plan view, in which the plurality of power semiconductor chips are arranged in a vertical direction and a horizontal direction in a plan view, and at least one of the plurality of power semiconductor chips is arranged so as to be surrounded by other power semiconductor chips.

A printed circuit board (PCB) including a first side and a second side; a conductive layer within the PCB between the first side and the second side; one or more first side electrical components that are physically attached to the first side and electrically connected to the conductive layer; one or more second side electrical components attached to the second side of the PCB and electrically connected to the conductive layer; and a thermally and electrically insulating dielectric layer, within the PCB between the first side electrical components and the second side electrical components, that prevents heat emitted by the first side electrical components from increasing the temperature of the second side electrical components.

A DC/DC converter includes N inductors and N power modules which correspond to N phases. The N inductors each include a plurality of inductor chips that are electrically connected in parallel to each other. The plurality of inductor chips are mounted separately on a main mounting surface and a sub-mounting surface of a printed circuit board. The sub-mounting surface is opposite to the main mounting surface.

An uneven current distribution among a plurality of provided power semiconductor chips is to be suppressed. A power semiconductor module includes a module main body, a plurality of power semiconductor chips arranged on an upper surface of the module main body, and peripheral structures being insulating ferromagnets surrounding parts of a periphery of the module main body in a plan view, in which the plurality of power semiconductor chips are arranged in a vertical direction and a horizontal direction in a plan view, and at least one of the plurality of power semiconductor chips is arranged so as to be surrounded by other power semiconductor chips.

Disclosed is an electronic device. The electronic device may include a printed circuit board (PCB) including at least one conducting wire, a first integrated circuit (IC) placed on the printed circuit board and including a transmit pin electrically connected to the at least one conducting wire, and a second IC placed on the printed circuit board and including a receive pin electrically connected to the at least one conducting wire, wherein the first IC is configured to transmit a specified signal having a first voltage through the transmit pin, and change an internal impedance of the first IC based on a reflected signal of the specified signal at a first time point.

Systems, methods, and apparatus that employ a connector assembly having a substrate layer with an inner aperture and an outer periphery, and one or more signal traces disposed on the substrate that extend from an inner first location to an outer second location of the apparatus, for communicating data between electronic devices positioned within an interior volume of an enclosed vessel and complementary electronic devices positioned in an ambient environment external to the enclosed vessel. An inner connector is conductively connected the signal traces at the inner first location of each signal trace, and an outer connector is conductively connected to the one or more signal traces at the outer second location of each signal trace. A substantially flat exterior surface extends radially over at least a portion of a region between the respective first locations and the respective second locations.

A printed circuit board (PCB) including a first side and a second side; a conductive layer within the PCB between the first side and the second side; one or more first side electrical components that are physically attached to the first side and electrically connected to the conductive layer; one or more second side electrical components attached to the second side of the PCB and electrically connected to the conductive layer; and a thermally and electrically insulating dielectric layer, within the PCB between the first side electrical components and the second side electrical components, that prevents heat emitted by the first side electrical components from increasing the temperature of the second side electrical components.

Provided are an electronic device and a manufacturing method therefor such that, when connecting a first electronic component configured to have a step difference near an external connection terminal to a second electronic component via wiring, the size increase of a manufacturing device can be avoided, wiring can be carried out at a low-cost, and the reliability of the wiring connections can be improved. An LCD (10) and an IC (20) are embedded and exposed in a resin molding (30) in such a manner that a connection electrode (13a) of the LCD (10) and an electrode of the IC (20) are positioned on the same plane.

Heat transfer devices and systems for thermally coupling electrical components to a heatsink can comprise one or more all-metal heat transfer device(s) thermally coupling at least one electrical component to a heatsink. A heat transfer device can comprise a metal cup attached to a metal heatsink, and a metal piston and a compliant device disposed in the cup. The piston is forcible to a secured first position, upon reflowing solder, while compressing the compliant device. Upon reflowing solder again, the compliant device causes the piston to bias and attach to the electrical component to provide an all-metal thermal path and absorb assembly tolerances to avoid using thermal gap fillers. A method is provided for thermally coupling a heatsink to a plurality of electrical components via a plurality of all-metal, expandable heat transfer devices.