An axial field rotary energy device has a PCB stator panel assembly between rotors with an axis of rotation. Each rotor has a magnet. The PCB stator panel assembly includes PCB panels. Each PCB panel can have layers, and each layer can have conductive coils. The PCB stator panel assembly can have a thermally conductive layer that extends from an inner diameter portion to an outer diameter portion thereof. Each PCB panel comprises discrete, PCB radial segments that are mechanically and electrically coupled together to form the respective PCB panels.

A circuit board is disclosed, including a circuit board body and at least one via apparatus provided on the circuit board body. The via apparatus includes a via (101) formed on the circuit board body, a via pad (201) surrounding the via and separately provided from the via, and an electrical conductor (301) electrically connecting the via pad (201) with the via (101).

A surface mountable laser driver circuit package is configured to mount on a host printed circuit board (PCB). A surface mount circuit package includes a lead-frame. A plurality of laser driver circuit components is mounted on and in electrical communication with the lead-frame of the surface mount circuit package. A dielectric layer is located between the lead-frame and the host PCB and includes portals through the dielectric layer each arranged to accommodate an electrical connection between the lead-frame and the host PCB. The lead-frame and the dielectric layer are arranged such that a first lead-frame portion and a first dielectric layer portal align with a first end of a host PCB trace configured to provide a current return path for the surface mount laser driver, and a second lead-frame portion and a second dielectric layer portal align with a second end of the host PCB trace.

An apparatus includes a substrate, a switching device, a capacitor device, a first via, a second via, a third via and a fourth via. The substrate has a first surface and a second surface and includes a plurality of copper layers including M positive copper layers and N negative copper layers. The M positive copper layers and the N negative copper layers are alternated. The switching device is disposed on the first surface and includes a switching positive terminal and a switching negative terminal. The capacitor device is disposed on the first surface and includes a capacitor positive terminal and a capacitor negative terminal, and the capacitor device forms a capacitor area. The projections of the adjacent positive and negative copper layers and the capacitor area on the first surface at least partially overlap with each other.

A method of connecting an electronic component on a mounting substrate where the electronic component is arranged with a first surface of the electronic component facing the mounting substrate and an opposite surface of the electronic component is facing away from the mounting substrate. A first component-side conductor on the second surface of the electronic component is electrically connected to a first substrate-side conductor on the mounting substrate by an electrically-conductive adhesive.

A component which is configured to switch an electrical signal, the component includes an insulating substrate bearing a semiconductor chip which ensures switching of the signal; a sole plate on which the substrate is secured, the sole plate being configured to discharge heat emitted during switching of the component; a conductive plane positioned between the sole plate and the insulating substrate, the conductive plane being insulated electrically against the sole plate; a specific component with impedance of at least 1 Ohm and/or at least 1 .Math.H, by means of which the conductive plane is connected to a reference voltage.

A transmission line device includes a first multilayer substrate with a transmission line including laminated insulating base materials and a conductor pattern on the insulating base materials, and a second multilayer substrate defining a connected member to which the transmission line of the first multilayer substrate is connected. The conductor pattern includes a signal conductor pattern and a signal electrode pad electrically connected to the signal conductor pattern. The first multilayer substrate includes a resist film provided on a surface of a laminate of the insulating base materials, and the resist film includes an opening that is separated from an outer edge of the signal electrode pad in a surface direction of the laminate of the insulating base material and exposes the signal electrode pad.

An axial field rotary energy device has a PCB stator panel assembly between rotors with an axis of rotation. Each rotor has a magnet. The PCB stator panel assembly includes PCB panels. Each PCB panel can have layers, and each layer can have conductive coils. The PCB stator panel assembly can have a thermally conductive layer that extends from an inner diameter portion to an outer diameter portion thereof.

The invention concerns a device for controlling at least one diode 2, the control device comprising an electrical card 4 comprising a printed circuit 5 on which the following are mounted: a diode 2, a front component 7 and a storage capacitor 9 connected in such a way as to form a circuit loop 17 extending substantially in a thickness of the electrical card 4.

A power converter module includes a multilayer printed circuit board, a switching device, a capacitor device, a first via, a second via, a third via and a fourth via. The multilayer printed circuit board has a first surface and a second surface and includes a plurality of copper layers including a plurality of positive copper layers and negative copper layers. The plurality of positive copper layers and the negative copper layers are disposed in staggered arrangement. The switching device is disposed on the first surface and includes a switching positive terminal and a switching negative terminal. The capacitor device is disposed on the first surface and includes a capacitor positive terminal and a capacitor negative terminal, and the capacitor device forms a capacitor area. The projections of the adjacent positive and negative copper layers and the capacitor area on the first surface at least partially overlap with each other.