An electronic control unit includes a substrate, an electronic component, a heat sink, a cover, a heat accumulator, and a screw. A wiring pattern is formed on the substrate. The electronic component is mounted on the substrate and generates heat upon energization thereof. The heat sink is provided on one side of the substrate in its thickness direction. The cover is made of resin and is provided on the other side of the substrate in its thickness direction. The heat accumulator is fixed to a part of the cover on the substrate-side and is in contact with a surface of the substrate on the cover-side. One end of the screw is connected to the heat sink. A central portion of the screw is inserted through a hole passing through the substrate in its thickness direction. The other end of the screw is connected to the heat accumulator.

The present disclosure is related to a power module includes a first printed circuit board (PCB), a second PCB, a magnetic component and a connecting component. A secondary side switch set and a winding are disposed on the first PCB, respectively. A primary side switch set is disposed on the second PCB adjacent to the first PCB. A magnetic component includes an upper magnetic cover disposed on the first side of the first PCB; a lower magnetic cover disposed between the first PCB and the second PCB; and a lateral column located between the two magnetic covers. The lateral column passes through the first PCB, and is fastened with the two magnetic covers. The magnetic component and the winding collaboratively form a transformer. The connecting component is disposed between the two PCBs to connect the corresponding potential points of the two PCBs.

An electronic device includes a circuit board with an insulating substrate, a wiring at the substrate, an electronic component mounted at the substrate and electrically connected to the wiring, at least one through hole through the substrate from one surface to an opposite surface of the one surface of the substrate, and a conductive member arranged at a surface of the through hole and electrically connected to the wiring; and further includes: a sealing resin; and a cap including an annular connection with a part connected to the substrate and a recess recessed from the annular connection. Furthermore, in the cap, at least a part of the connection is connected to the substrate, the cap being sealed integrally with the electronic component by the sealing resin while arranging a space communicating with the through hole; and a terminal is inserted into the through hole and electrically connected to the wiring.

A second lead frame is set onto a conductive layer and a busbar. The second lead frame has holes previously formed at opposite ends thereof, and pieces of solder material or solder pieces are inserted into the holes. Then, the solder pieces are vibrated by an ultrasonically vibrating tool, whereby the solder pieces are melted without having a high temperature. The second lead frame is thus bonded to the conductive layer and the busbar. A semiconductor element and the busbar are connected by a first lead frame and the second lead frame. The connection structure thereof is such that the second lead frame to be bonded by ultrasonic bonding or other bonding methods is not directly in contact with the semiconductor element, which eliminates the risk of damage to the semiconductor element.

Some embodiments include apparatus and methods using a package substrate and a die coupled to the package substrate. The package substrate includes conductive contacts, conductive paths coupled to the conductive contacts, and a resistor embedded in the package substrate. The die includes buffer circuits and a calibration module coupled to the buffer circuits and the resistor. The buffer circuits include output nodes coupled to the conductive contacts through the conductive paths. The calibration module is configured to perform a calibration operation to adjust resistances of the buffer circuits based on a value of a voltage at a terminal of the resistor during the calibration operation.

A power converter includes: a circuit board having an insulating substrate and a plurality of wirings in the insulating substrate; and first and second switching elements on a first surface of the circuit board that are connected in series. The first switching element has first and second electrodes. The second switching element has a third electrode and a fourth electrode. The circuit board has a first wiring connected to the first electrode, a second wiring connected to the second and third electrodes, a third wiring connected to the fourth electrode, a fourth wiring as an output wiring connected to the third electrode, and a fifth wiring connected to the third wiring. The first, second, third and fourth wirings are arranged in order on the first surface, and the fifth wiring on a second surface opposite to the first surface is opposed to the first, second, and third wirings.

The present disclosure relates to electric motors. The teachings thereof may be embodied in a power module, e.g., a power module for the delivery of a phase current for a current phase of an electric motor. For example, a power module may include: a circuit carrier having a surface; at least two first contact surfaces, a second contact surface, at least two third contact surfaces defined on the surface; a first power transistor connected to each of the at least two first contact surfaces; at least two second power transistors connected to the second contact surface; wherein the at least two second power transistors are connected via a further contact surface to one of the at least two third contact surfaces; and the at least two first and the at least two third contact surfaces are arranged one after the other, in one direction, and the second contact surface is disposed next to both the at least two first and the at least two third contact surfaces.

A control board of a power conversion device, the control board includes a board main body, a plurality of drive circuits, a power source control circuit, an insulation region, a plurality of insulation transformers, and a connecting line that electrically connects the plurality of insulation transformers and the power source control circuit to each other, and at least a part of which extends in a region in inner layers of the board main body that overlaps the insulation region when viewed in a perpendicular direction with respect to the surface of the board main body.

An electronic device includes a heat dissipation member, a power element that is thermally coupled to the heat dissipation member, and a first conductive layer to which the power element is electrically coupled. The electronic device further includes a control element that controls a switching operation of the power element, a second conductive layer to which the control element is electrically coupled, and a resin layer arranged between the first conductive layer and the second conductive layer. The power element is embedded in the resin layer. The first conductive layer, the resin layer, and the second conductive layer are stacked on the heat dissipation member in this order from the ones closer to the heat dissipation member.

Disclosed herein is a semiconductor device including: a semiconductor circuit element configured to process an electrical signal having a predetermined frequency; and a transmission line configured to be connected to the semiconductor circuit element via a wire and transmit the electrical signal. An impedance matching pattern having a symmetric shape with respect to a direction of the transmission line is provided in the transmission line.