According to one configuration, a fabricator fabricates a core of a circuit component to include magnetic permeable material. The fabricator further produces the circuit component to include multiple electrically conductive paths extending through the core of the magnetic permeable material. In one arrangement, the multiple electrically conductive paths include a first electrically conductive path and a second electrically conductive path. The fabricator fabricates the circuit component and, more specifically, the core of the magnetic permeable material to include at least one cutaway portion operative to reduce inductive coupling between the first electrically conductive path and the second electrically conductive path disposed in the core.

An inductive transmission element comprising a magnetically conductive electrically insulating, MCEI, annular core. The core comprises an outer wall and an inner wall apart from the outer wall. The respective walls are joined by a planar top surface. The inner wall and the outer wall form an annular trough opening adjacent the top surface. The open annular trough comprises opposed diagonal walls that intersect the top surface and a circular region at the distal end of the opposed diagonal walls. The annular trough opening may be wider or narrower than the planar top surface between the diagonal walls and outer surface. The annular core may be disposed within an annular housing comprising a polymeric block. The diagonal walls may intersect the top surface at an angle greater than 93°. The diagonal walls may intersect the circular region at an angle greater than 93°. The top surface may be polished.

An inductive transmission element comprising a magnetically conductive electrically insulating, MCEI, annular core. The core comprises an outer wall and an inner wall apart from the outer wall. The respective walls are joined by a planar top surface. The inner wall and the outer wall form an annular trough opening adjacent the top surface. The open annular trough comprises opposed diagonal walls that intersect the top surface and a circular region at the distal end of the opposed diagonal walls. The annular trough opening may be wider or narrower than the planar top surface between the diagonal walls and outer surface. The annular core may be disposed within an annular housing comprising a polymeric block. The diagonal walls may intersect the top surface at an angle greater than 93°. The diagonal walls may intersect the circular region at an angle greater than 93°. The top surface may be polished.

A gatedriver circuit for controlling a power electronic switch. The circuit provides a galvanic separation and is magnetically immune. The gatedriver circuit comprises a transformer arranged with two separate cores of magnetically conductive material each forming a closed loop. A first electrical conductor has windings around a part of both cores, and a second electrical conductor also has windings around part of both cores. The two cores are positioned close to each other to allow mutual magnetic interaction. The windings of the first and second electrical conductors around the first core have the same winding direction, and the windings of the first and second electrical conductors around the second core have opposite winding direction of the windings of the first and second electrical conductors around the first core, so as to counteract electric influence induced by a common magnetic field through the closed loops of the first and second cores. Hereby, such gatedriver circuit is suitable for controlling power switches in environments with strong magnetic fields, e.g. inside a high power wind turbine.

A gatedriver circuit for controlling a power electronic switch. The circuit provides a galvanic separation and is magnetically immune. The gatedriver circuit comprises a transformer arranged with two separate cores of magnetically conductive material each forming a closed loop. A first electrical conductor has windings around a part of both cores, and a second electrical conductor also has windings around part of both cores. The two cores are positioned close to each other to allow mutual magnetic interaction. The windings of the first and second electrical conductors around the first core have the same winding direction, and the windings of the first and second electrical conductors around the second core have opposite winding direction of the windings of the first and second electrical conductors around the first core, so as to counteract electric influence induced by a common magnetic field through the closed loops of the first and second cores. Hereby, such gatedriver circuit is suitable for controlling power switches in environments with strong magnetic fields, e.g. inside a high power wind turbine.

It is highly desirable in electronic systems to conserve space on printed circuit boards (PCB). This disclosure describes voltage regulation in electronic systems, and more specifically to integrating voltage regulators and associated passive components into semiconductor packages with at least a portion of the circuits whose voltage(s) they are regulating.

An inductor built-in substrate includes a core substrate having openings, a magnetic resin filled in the openings and having through holes, and through-hole conductors formed in the through holes respectively such that each of the through-hole conductors includes a metal film. The magnetic resin is formed such that each of the through holes has an angle part having an obtuse angle formed by an upper surface of the magnetic resin and a side wall of a respective one of the through holes.

A toroidal inductor includes a toroidal core and at least one coil is disclosed. Each coil comprises at least one first winding portion, and at least one second winding portion. At least one first winding portion comprises at least one alpha electrical pathway which extends between a first alpha pathway end to a second alpha pathway end. At least one second winding portion comprises at least one beta electrical pathway which extends between a first beta pathway end to a second beta pathway end (30B). The first and second winding portions are electrically connected to form at least one coil wound around the toroidal core. Each coil is comprised of a plurality of pathway units, and each pathway unit comprises an alpha electrical pathway connected to a beta electrical pathway.

A dust core contains a powder of a crystalline magnetic material powder and a powder of an amorphous magnetic material. The sum of the content of the crystalline magnetic material powder and the content of the amorphous magnetic material powder is 83 mass percent or more. The mass ratio of the content of the crystalline magnetic material powder to the sum of the content of the crystalline magnetic material powder and the content of the amorphous magnetic material powder is 20 mass percent or less. The median diameter D50a of the amorphous magnetic material powder is greater than or equal to the median diameter D50c of the crystalline magnetic material powder. A 10% cumulative diameter D10a in a volume-based cumulative particle size distribution of the amorphous magnetic material powder is 9.5 μm or less.

A dust core contains a powder of a crystalline magnetic material powder and a powder of an amorphous magnetic material. The sum of the content of the crystalline magnetic material powder and the content of the amorphous magnetic material powder is 83 mass percent or more. The mass ratio of the content of the crystalline magnetic material powder to the sum of the content of the crystalline magnetic material powder and the content of the amorphous magnetic material powder is 20 mass percent or less. The median diameter D50a of the amorphous magnetic material powder is greater than or equal to the median diameter D50c of the crystalline magnetic material powder. A 10% cumulative diameter D10a in a volume-based cumulative particle size distribution of the amorphous magnetic material powder is 9.5 μm or less.