A noise filter (10) used for a plurality of conducting members (20), the noise filter includes, a ring-shaped core (30) made from a magnetic material, the ring-shaped core is attached to the plurality of conducting members to reduce noise of currents flowing through each of the plurality of the conducting members. The ring-shaped core including: a base core (41) having a plurality of support pillar portions (42) extending outward in radial directions; and a plurality of divisional cores (45) each being placed between two of the plurality of the support pillar portions adjacent to each other in the circumferential direction, and each having two end surfaces connected to end portions of the two of the plurality of the support pillar portions.

An isolation transformer includes a transformer core. First and second through-bores extend through the transformer core from a first surface to a second surface. Each through-bore has an elongated profile with at least a portion of the elongated profile providing a respective flat winding surface. The flat winding surfaces are spaced apart by a central portion of the transformer core. The transformer is wound with a six-wire cable having a central non-conductive core. First, second, third, fourth, fifth and sixth conductive wires are positioned around and adjacent to the central non-conductive core in a substantially equally spaced angular relationship. The second conductive wire is positioned between the first conductive wire and the third conductive wire; and the fifth conductive wire is positioned between the fourth conductive wire and the sixth conductive wire. The conductive wires are twisted about the central non-conductive core at a selected twist density.

According to one configuration, an inductor device comprises: core material and one or more electrically conductive paths. The core material is magnetically permeable and surrounds (envelops) the one or more electrically conductive paths. Each of the electrically conductive paths extends through the core material of the inductor device from a first end of the inductor device to a second end of the inductor device. The magnetically permeable core material is operative to confine (guide, carry, convey, localize, etc.) respective magnetic flux generated from current flowing through a respective electrically conductive path. The core material stores the magnetic flux energy (i.e., first magnetic flux) generated from the current flowing through the first electrically conductive path. One configuration herein includes a power converter assembly comprising a stack of components including the inductor device as previously described as well as a first power interface, a second power interface, and one or more switches.

An inductor includes a magnetic core composed of a magnetic material having variable permeability characteristics based on at least one of design parameters or operational parameters of the inductor that includes one or more air gaps. A coil is wound through the one or more air gaps and is configured to be excited by an electric current.

A noise filter (100, 200, 300) provided with: a coil (1a, 1b) having a winding pattern configured by stacking flat plate-shaped conductors (50); a magnetic core (2) around which the coil (1a, 1b) is wound; and a heat dissipation member (3) electrically insulated from and closely attached to an end of the coil (1a, 1b) in a stacking direction, wherein a thermal resistance of one of the conductors (50), disposed at the end in the stacking direction of the coil (1a, 1b), is the lowest compared with the thermal resistances of the other conductors (50).

An inductor includes a magnetic core composed of a magnetic material having variable permeability characteristics based on at least one of design parameters or operational parameters of the inductor that includes one or more air gaps. A coil is wound through the one or more air gaps and is configured to be excited by an electric current.

An apparatus includes a carrier substrate, a ferrite core, a first set of wire windings, a second set of wire windings, a third set of wire windings, and a fourth set of wire windings. The ferrite core is attached to the carrier substrate. The first set of wire windings, the second set of wire windings, the third set of wire windings, and the fourth set of wire windings pass through the ferrite core and between the ferrite core and the carrier substrate to which the ferrite core is attached.

A surface mount power inductor component for a circuit board including multi-phase power supply circuitry includes a single piece, integrally fabricated magnetic core piece formed with vertically extending interior passageways provided with vertically elongated pre-formed conductive windings that are not magnetically coupled to reduce the footprint of the inductor component while increasing its power capacity. A distributed gap material is also provided in the vertical passageways with the conductive windings that respectively connect to each phase of electrical power.

Embodiments disclosed herein include coreless interposers with embedded inductors. In an embodiment, a coreless interposer comprises a plurality of buildup layers, where electrical routing is provided in the plurality of buildup layers. In an embodiment, the coreless interposer further comprises an inductor embedded in the plurality of buildup layers. In an embodiment, the inductor comprises a magnetic shell, and a conductive lining over an interior surface of the magnetic shell.

A coil includes a plurality of coil conductor pieces, first and second cores and a case. The plurality of coil conductor pieces is made of a high magnetic permeability material. The first and second cores include through-holes in parallel. The through-holes allow penetration of the coil conductor pieces. The first core and the second core are stored in the case. At least one end part of one of the coil conductor pieces penetrating through the through-holes of the first core and the second core is coupled to an end part of the other coil conductor piece on the outside of the case. A coil conductor circling between the first and second cores is made up of the plurality of coil conductor pieces.