A magnetic sensor device includes a first magnetic sensor including a ring-shaped first magnetosensitive part whose magnetoresistance value changes due to interaction with a radial magnetic field produced by a magnet, and a second magnetic sensor and a third magnetic sensor that are arranged based on an ideal trajectory of the magnet passing through the center of the first magnetic sensor, include a ring-shaped second magnetosensitive part and a ring-shaped third magnetosensitive part, respectively, and are arranged inside the first magnetic sensor so as to face each other without overlapping.

A magnetic sensor device includes a first magnetic sensor including a ring-shaped first magnetosensitive part whose magnetoresistance value changes due to interaction with a radial magnetic field produced by a magnet, and a second magnetic sensor and a third magnetic sensor that are arranged based on an ideal trajectory of the magnet passing through the center of the first magnetic sensor, include a ring-shaped second magnetosensitive part and a ring-shaped third magnetosensitive part, respectively, and are arranged inside the first magnetic sensor so as to face each other without overlapping.

Provided is a wire diagnosis apparatus mounted on a lifting device, which has a platform having a hook disposed at a lower portion to lift an object. The wire diagnosis apparatus includes: a standing unit detachably combined with any one among an inlet and an outlet where a wire of the platform comes in and out; a sensing holder unit formed in a cylindrical shape perforated in the middle and detachably combined with a stand combining part of the standing unit to sense the wire; and a coupling unit detachably combining the sensing holder unit with the stand combining part of the standing unit.

A magnetic field sensor includes a plurality of magnetic field sensing elements configured to generate at least two measured magnetic field signals indicative of a magnetic field affected by an object and having a first predetermined phase difference with respect to each other. A controller responsive to the measured magnetic field signals is configured to generate at least one virtual magnetic field signal having a second predetermined phase difference with respect to at least one of the measured magnetic field signals. The controller is configured to calculate a virtual tangent of the virtual magnetic field signal and at least one measured magnetic field signal and compute a second derivative of an arctangent extraction of the virtual tangent. Coefficients used to generate the virtual magnetic field signals are regulated in a feedback system in order to achieve a desired phase difference between a reference and a virtual magnetic field signal.

The present invention discloses a magnetic rolling bearing capable of reducing the balance radial force of the gear pump, which includes a magnetized inner ring, a rolling body, a cage, and a magnetized outer ring assembly. The inner ring is magnetized to make the inner and outer ring surfaces of the magnetized inner ring have different magnetic properties; the magnetized outer ring assembly consists of four components, namely an upper ring surface of the magnetized outer ring assembly, a lower ring surface of the magnetized outer ring assembly, and two components in left and right. The left and right components are not magnetized, they are connected by recesses and are fixed with bolts, and the four components are alternately connected to form a complete ring.

A method of detecting a magnetic field interference includes obtaining magnetic field information measured by each one of n magnetometers carried by a movable object, determining magnetic differences between the magnetic field information measured by m magnetometers of the n magnetometers, and determining whether the movable object is subject to a magnetic field interference based on the magnetic differences. n is an integer greater than or equal to 2, and m is an integer greater than or equal to 2 but smaller than or equal to n.

Magnetic field sensors and sensing methods are provided. A magnetic sensor module is configured to measure a magnetic field whose magnitude oscillates between a first extrema and a second extrema. The magnetic sensor module includes a magnetic sensor configured to generate measurement values in response to sensing the magnetic field, and a sensor circuit. The sensor circuit is configured to generate a measurement signal based on the measurement values, adjust an offset of the measurement signal according to an offset update algorithm and a first characteristic of the measurement signal, generate a pulsed output signal having pulses that are generated based on the adjusted measurement signal crossing the switching threshold, and selectively enable and disable the offset update algorithm based on a second characteristic of the measurement signal.

A blade angle feedback assembly for a variable-pitch aircraft propeller rotor rotatable about an axis and having an adjustable blade pitch angle is provided. A feedback device is coupled to rotate with the rotor and to be displaced axially along the axis with adjustment of the blade pitch angle. Sensor(s) mounted adjacent the feedback device are configured to detect a passage of position marker(s) provided on the feedback device as the feedback device rotates. A magnetic shield mounted to the sensor(s) is configured to define a magnetic return path for some magnetic flux of a magnetic field exiting from a first pole of the magnet toward a second pole opposite the first pole. The magnetic shield comprises a wall member positioned adjacent the position marker(s) and configured to span a distance over which the position marker(s) are configured to be displaced with axial displacement of the feedback device.

A method and system of infrastructure re-purposed magnetic signatures for mobile device indoor navigation and positioning. The method comprises determining a common spatial region in accordance with a first spatial region partially superimposed upon an at least a second spatial region, the first and at least a second spatial regions associated with a first and an at least a second magnetic signatures respectively; and generating, based at least in part on the first and at least a second magnetic signatures, a re-purposed magnetic signature associated with the common spatial region.

A method of manufacturing a magnetic sensor (1) which method includes: forming a hard magnetic material layer (103) to be processed to a thin film magnet (20) on a disk-shaped nonmagnetic substrate (10); forming a soft magnetic material layer (105) laminated on the hard magnetic material layer (103) on the substrate (10), the soft magnetic material layer (105) being processed into a sensitive element sensing a magnetic field; and magnetizing the hard magnetic material layer (103) in the circumferential direction of the disk-shaped substrate 10. Also disclosed is a magnetic sensor assembly.