The invention relates to an apparatus for regulating electrical power in an electricity transmission network, the apparatus including: a DC contactor; a transmission network connector including live terminal(s) connected to live connection(s) and a neutral terminal connected to a neutral or earth of the electricity transmission network; switches connected to the DC contactor; electronic controlling devices coupled to the switches and control the switches to independently regulate electrical power on each of the live connection(s) and the neutral connection, the electronic controlling devices receive voltage reading of the live connection(s); calculate average of the voltage reading for the live connection(s); if the average is larger than an upper value, control the switches to reduce voltage on the live connection; if the average is less than a lower value, control the switches to increase voltage supplied on the live connection(s).

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 metal-core printed circuit board (MCPCB) and method of generating an ultra-narrow, high-current pulse driver with a MCPCB is provided. The MCPCB includes a rigid, metal heat sink layer and at least one electrically conductive top layer. At least one electrically insulating dielectric layer is positioned between the conductive top layer and rigid, metal heat sink layer, wherein the dielectric layer has a thickness of less than 0.007 inches.

A wideband termination circuit layout is provided for high power applications. The circuit layout may include a dielectric layer having a first surface and a second surface. The circuit layout may also include an input port disposed over the first surface. The circuit layout may further include at least two resistive film patches disposed over the first surface of the dielectric layer and a tuning line between the at least two resistive films disposed over the first surface of the dielectric layer. The at least two resistive film patches are connected in series with the at least one tuning line.

A semiconductor light-emitting device includes: a board including a front surface, a back surface facing an opposite side of the front surface, a first wiring pattern formed on the front surface, and a second wiring pattern formed on the side of the back surface with respect to the first wiring pattern; and a light-emitting element, a switching element, and a capacitor, which are electrically connected to one another by both the first wiring pattern and the second wiring pattern. Among the light-emitting element, the switching element, and the capacitor, a first predetermined element and a second predetermined element are arranged in a first direction and the second predetermined element and a third predetermined element are arranged in a second direction. The second wiring pattern forms a second current path opposite to a direction of a first current path. The second current path overlaps the first current path.

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.

An example sensor interposer employing castellated through-vias formed in a PCB includes a planar substrate defining a plurality of castellated through-vias; a first electrical contact formed on the planar substrate and electrically coupled to a first castellated through-via; a second electrical contact formed on the planar substrate and electrically coupled to a second castellated through-via, the second castellated through-via electrically isolated from the first castellated through-via; and a guard trace formed on the planar substrate, the guard trace having a first portion formed on a first surface of the planar substrate and electrically coupling a third castellated through-via to a fourth castellated through-via, the guard trace having a second portion formed on a second surface of the planar substrate and electrically coupling the third castellated through-via to the fourth castellated through-via, the guard trace formed between the first and second electrical contacts to provide electrical isolation between the first and second electrical contacts.

An axial field rotary energy device with a PCB stator having interleaved PCBs is disclosed. The device can include rotors that have magnets and an axis of rotation. A stator assembly can be located axially between the rotors to operate electrical phases. The stator assembly can include PCB panels. Each PCB panel can have layers, and each PCB panel can be designated to one of the electrical phases. Each electrical phase of the stator assembly can be provided by a plurality of the PCB panels. In addition, the PCB panels for each electrical phase can be axially spaced apart from and intermingled with each other.

A capacitor is disposed on a substrate that is insulative. An inductor is disposed on the substrate. The inductor includes a conductor pattern having at least one end connected to the capacitor. The capacitor includes a dielectric film that mainly contains the same constituent element as a constituent element mainly contained in the substrate and at least two electrodes that face each other with the dielectric film interposed therebetween.

The electronic circuit device includes: a first wiring pattern which is formed on a first main surface of a circuit board, has circuit elements including a switching element and mounted along a predetermined direction, and includes a virtual shortest current path connecting the circuit elements to each other along the predetermined direction; a second wiring pattern which is formed on a second main surface, and includes an opposing current path that opposes an area where the virtual shortest current path is formed; vias electrically connecting the first and second wiring patterns; and vias for heat transfer, connecting a mount area for the switching elements on the first main surface with an area on a side of the opposing current path on the second main surface. The heat dissipation member is in contact with the second main surface.