A magnetic field device, with a first magnet, a first ferromagnetic element positioned adjacent to the first magnet, a second magnet, a second ferromagnetic element positioned adjacent to the second magnet and relative to the first ferromagnetic element to create a gap between the first ferromagnetic element and the second ferromagnetic element, and a third magnet positioned between the first ferromagnetic element and the second ferromagnetic element and within the gap.

A magnetic field generator including: a yoke; and a plurality of main magnetic pole magnets and a plurality of secondary magnetic pole magnets, the main magnetic pole magnets and the secondary magnetic pole magnets comprising a rare earth sintered magnet, having magnetic pole orientations different from each other by substantially 90°, and being alternately arranged in a linear Halbach magnet array without gaps and fixed to the yoke, wherein near contact surfaces of the main magnetic pole magnets and the secondary magnetic pole magnets, a grain boundary diffusion layer is formed in which at least one of Dy or Tb being heavy rare earth elements or a compound of at least one of the Dy or the Tb is diffused into internal grain boundaries from the contact surfaces.

An organizer for a plurality of metallic objects has a nonmetallic housing and a magnetic core. The nonmetallic housing has opposing top and bottom external surfaces. A ridge projects from a periphery of the top external surface. The magnetic core attracts metal towards the geometric center of the top external surface and towards the ridge at the periphery of the top external surface. In some implementations, portions of the magnetic field attract metal in the directions: (i) perpendicular to the geometric center of the top external surface; (ii) outward from the geometric center of the top external surface; and (iii) toward the ridge on the top external surface. Implementations have the magnetic core with a square cross section and north and south poles separated by a distance substantially less than the width of the substantially square cross section, and with its magnetic field in the shape of a torus.

A control device includes a moving portion, a magnetic element coupled to the moving portion, at least one magnetic sensing circuit responsive to magnetic fields, and at least one magnetic flux pipe structure. The magnetic element may comprise alternating positive and negative sections configured to generate a magnetic field. The magnetic element may be any shape, such as circular, linear, etc. The magnetic sensing circuit may be radially offset from the magnetic element, and the magnetic flux pipe structure may be configured to conduct the magnetic field generated by the magnetic element towards the magnetic sensing circuit. The magnetic element may generate the magnetic field in a first plane, and the magnetic sensing may be responsive to magnetic fields in a second direction that is angularly offset from the first plane. The magnetic flux pipe structure may redirect the magnetic field towards the magnetic sensing circuit in the second direction.

A device for online gaming includes a memory that stores instructions. A processor coupled to the memory, responsive to executing the instructions, performs operations including receiving a selection of a gaming accessory, receiving a selection of a game, and receiving inputs corresponding to selections of parameters for generating a vibration effect at the gaming accessory. The parameters include a control component of the gaming accessory, a game event associated with the control component, a vibration frequency of the vibration effect associated with the game event, a vibration intensity and duration, and a delay time associated with the event. The processor stores the selected parameters and presents the vibration effect during the game in accordance with occurrence of the game event and in accordance with the selected parameters; the vibration effect is presented after the occurrence of the game event in accordance with the delay time.

A permanent magnet in the form of a multi-pole magnet, comprising an isotropic magnetic material, having a central axis, magnetised such that the magnetic field, considered on a virtual circle lies substantially in a virtual plane tangential to the circle, and rotates inside that virtual plane, depending on the position on the circle. A method of producing a magnet comprising: a) providing a shaped body comprising an isotropic magnetic material; b) providing at least four electrical conductor segments; c) simultaneously make currents flow in each conductor segment. A magnet made in this way. Use of such a magnet for angular position sensing. An angular position sensor system comprising such a magnet.

A magnetic field device, with a first magnet, a first ferromagnetic element positioned adjacent to the first magnet, a second magnet, a second ferromagnetic element positioned adjacent to the second magnet and relative to the first ferromagnetic element to create a gap between the first ferromagnetic element and the second ferromagnetic element, and a third magnet positioned between the first ferromagnetic element and the second ferromagnetic element and within the gap.

Disclosed herein is a nonreciprocal circuit element that includes a magnetic rotator disposed between first and second ground conductors, and a permanent magnet that applies a DC magnetic field to the magnetic rotator. The magnetic rotator includes a first ferrite core having a first surface covered with the first ground conductor, a second ferrite core having a second surface covered with the second ground conductor, a first center conductor directly fixed to a third surface of the first ferrite core positioned opposite to the first surface, and a second center conductor directly fixed to a fourth surface of the second ferrite core positioned opposite to the second surface.

A magnetic structure for an electromagnetic resonator is provided. The magnetic structure comprises at least a solenoid and a permanent magnet, wherein the solenoid and the permanent magnet are concentrically arranged to each other such that the magnetic field lines provided by the permanent magnet are at least essentially perpendicular to magnetic field lines of a magnetic field generated by the solenoid. The arrangement of the permanent magnet and the solenoid may be housed by an element with a high magnetic permeability.

A magnetic structure for an electromagnetic resonator is provided. The magnetic structure comprises at least a solenoid and a permanent magnet, wherein the solenoid and the permanent magnet are concentrically arranged to each other such that the magnetic field lines provided by the permanent magnet are at least essentially perpendicular to magnetic field lines of a magnetic field generated by the solenoid. The arrangement of the permanent magnet and the solenoid may be housed by an element with a high magnetic permeability.