The magnetic sensor can prevent an increase of a positional detection error of a subject/object even in the case of applying an external magnetic field with a magnetic field intensity exceeding a predetermined range. A magnetic sensor is equipped with a magnetoresistive effect element (MR element) 11 that can detect an external magnetic field and a soft magnetic body shield 12. The soft magnetic body shield(s) 12 are/is positioned above and/or below the MR element 11 in a side view, and the size of the MR element 11 is physically included within a perimeter of the soft magnetic body shield 12.

A modulated inductance module includes an inductor including one or more electrical conductors disposed around a ferromagnetic ceramic element formed on a semiconductor die, wherein the inductor further has two or more metal oxides having fluctuations in metal-oxide compositional uniformity less than or equal to 1.50 mol % throughout said ceramic element, the ceramic element has crystalline grain structure having a diameter that is less than or equal to 1.5× a mean grain diameter, and the semiconductor die contains active semiconductor switches or rectifying components that are in electrical communication with the one or more electrical conductors of the inductor.

A modulated inductance module includes an inductor including one or more electrical conductors disposed around a ferromagnetic ceramic element formed on a semiconductor die, wherein the inductor further has two or more metal oxides having fluctuations in metal-oxide compositional uniformity less than or equal to 1.50 mol % throughout said ceramic element, the ceramic element has crystalline grain structure having a diameter that is less than or equal to 1.5× a mean grain diameter, and the semiconductor die contains active semiconductor switches or rectifying components that are in electrical communication with the one or more electrical conductors of the inductor.

A transformer having a transformer core that forms a magnetic flux path between and through a top yoke, leg, and bottom yoke of the transformer core. A winding can be disposed about the leg. Further, a flitch plate, which can have at least one slot that is configured to reduce eddy losses generated by the winding, can be disposed adjacent to the leg and extend between the top yoke and the bottom yoke. The flitch plate can be clamped to the top and bottom yokes by top and bottom clamps, respectively. The top and bottom clamps can each include at least one cutout that reduces an attraction of stray flux from the winding and into the corresponding top and bottom clamps. Additionally, at least one of the top clamp and the bottom clamp can include an internal lattice structure.

A transformer having a transformer core that forms a magnetic flux path between and through a top yoke, leg, and bottom yoke of the transformer core. A winding can be disposed about the leg. Further, a flitch plate, which can have at least one slot that is configured to reduce eddy losses generated by the winding, can be disposed adjacent to the leg and extend between the top yoke and the bottom yoke. The flitch plate can be clamped to the top and bottom yokes by top and bottom clamps, respectively. The top and bottom clamps can each include at least one cutout that reduces an attraction of stray flux from the winding and into the corresponding top and bottom clamps. Additionally, at least one of the top clamp and the bottom clamp can include an internal lattice structure.

An electromagnetic coil through which current is passed to generate a magnetic flux, a fixed core, a movable core, a magnetic spring disposed between the cores and, and a yoke are provided. The magnetic spring includes a magnetic substance, and biases the movable core in a direction in which the movable core is separated from the fixed core in a Z direction. Additionally, the magnetic spring includes a leaf spring member including the magnetic substance and spirally wound, and a central portion of the magnetic spring is located biased toward one side in the Z direction compared to a peripheral portion of the magnetic spring. When the movable core is attracted to the access position, the magnetic spring is prevented from being deformed to a minimum spring length corresponding to a width of the leaf spring member.

A small size reactor that effectively utilizes a space is provided. This reactor includes: a reactor body which includes a core and a coil attached to the core, a casing which houses therein the reactor body and which has an opening where a part of the reactor body protrudes outwardly, a bus bar which is a conductive component electrically connected to the coil and which covers a part of a side of the reactor body protruding from the opening, and a terminal stage which includes an extended portion formed of a resin material where a part of the bus bar is embedded and provided along an edge of the opening, and which supports an electrical connection portion between the bus bar and an exterior.

A small size reactor that effectively utilizes a space is provided. This reactor includes: a reactor body which includes a core and a coil attached to the core, a casing which houses therein the reactor body and which has an opening where a part of the reactor body protrudes outwardly, a bus bar which is a conductive component electrically connected to the coil and which covers a part of a side of the reactor body protruding from the opening, and a terminal stage which includes an extended portion formed of a resin material where a part of the bus bar is embedded and provided along an edge of the opening, and which supports an electrical connection portion between the bus bar and an exterior.

Disclosed are devices and methods for fabricating devices. A device can include a passive portion having at least one metal insulator metal (MIM) capacitor and at least one 2-dimensional (2D) inductor. The device further includes a substrate and the passive portion is formed on the substrate. A magnetic core is embedded in the substrate. A 3-dimensional (3D) inductor is also included having windings formed at least in part in the substrate and at least a portion of the windings being formed around the magnetic core.

Disclosed are devices and methods for fabricating devices. A device can include a passive portion having at least one metal insulator metal (MIM) capacitor and at least one 2-dimensional (2D) inductor. The device further includes a substrate and the passive portion is formed on the substrate. A magnetic core is embedded in the substrate. A 3-dimensional (3D) inductor is also included having windings formed at least in part in the substrate and at least a portion of the windings being formed around the magnetic core.