Provided is a pseudo force sensation providing device that can accurately measure an external magnetic field despite a small size thereof. Provided is a pseudo force sensation providing device including: an electrical actuator that performs physical movement based on a control signal supplied thereto; a contact mechanism that performs periodic asymmetric movement that causes a user to perceive pseudo force sensation, based on physical movement of the actuator; a magnetic sensor that measures an external magnetic field; and a shielding member that is provided between the actuator and the magnetic sensor, and surrounds a portion of the actuator on the side of the magnetic sensor, to block a magnetic field on the side of the magnetic sensor generated by the actuator.

A magnetic field sensor for measuring a variable magnetic field, in particular for a movement sensor or position sensor, has a magnetoresistive sensor chip and a flat sensor carrier carrying the sensor chip. The carrier has an upper side from which the sensor chip is electrically contactable, the upper side of the sensor carrier having a recess or depression in which the sensor chip is arranged. The sensor chip is electrically contactable from the upper side and that the sensor chip receives a magnetic field to be measured via an underside of the sensor carrier. A manufacturing method for manufacturing an above magnetic field sensor and a measuring method are proposed.

An assembly includes a permanent magnet generating a magnetic field. The permanent magnet is arranged on the rotary member and generates a magnetic field perpendicular to an axis of rotation. A first channel has a first magnetic sensing element centered on the axis of rotation, the first channel providing a first angular data. A second channel has a second magnetic sensing element centered on the axis of rotation, the second channel providing a second angular data. The second magnetic sensing element is spaced from the first magnetic sensing element. Each of the first magnetic sensing element and the second magnetic sensing element have three voltage dividers. A processor computes a magnetic stray field component orthogonal to the magnetic field by comparing a first field strength based on the first angular data with the second field strength based on the second angular data.

A sensor device includes a silicon substrate having an active surface; a first sensing area disposed near a first edge of the active surface of the silicon substrate such that the first sensing area has at least one first magnetic sensing element is made of a first compound semiconductor material and contact pads; and a second sensing area disposed near a second edge of the active surface of the silicon substrate, such that the second edge is substantially opposite to the first edge, such that the second sensing area has at least one second magnetic sensing element made of a second compound semiconductor material and contact pads. A processing circuit is disposed of in the silicon substrate and is electrically connected via wire bonds and/or a redistribution layer with the contact pads of the first and second sensing areas.

A magnetic field measurement system for measurement of weak magnetic field signals or a wearable assembly includes at least one magnetometer and a shield disposed around the magnetometer. The shield includes a first portion configured for positioning between the at least one magnetometer and a source of the weak magnetic field signals. The first portion is made of an amplitude-selective magnetic shield (ASMS) that preferentially passes magnetic fields having a magnetic field amplitude below a threshold (for example, 500 nT or less) and shields magnetic fields having a larger magnetic field amplitude.

A magnetic sensor is disclosed. The magnetic sensor can include a sensing element and a magnetic shield. The sensing element and the magnetic shield can be vertically stacked with one another. The magnetic shield can be a magnetic shield plate that includes ferromagnetic portions spaced laterally by a non-ferromagnetic material. The sensing element can have a first side and a second side opposite the first side. The magnetic shield that can be vertically stacked over the first side of the sensing element. The magnetic shield can be spaced apart from the sensing element by an isolation layer. A passivation layer can cover at least a portion of the sensing element or the magnetic shield. The sensing element can be configured to sense a magnetic field property of a magnetic field source that is positioned on the second side of the sensing element.

A device with position detection includes: a first hall element; a second hall element; a differential amplifier configured to generate a subtraction voltage by differentially amplifying a first hall voltage generated by the first hall element and a second hall voltage generated by the second hall element; a summing amplifier configured to generate a sum voltage by summatively amplifying the first and second hall voltages; a comparer configured to compare a reference voltage with the subtraction voltage to generate an error voltage; and a current converter configured to generate a bias current provided to the first and second hall elements, based on the error voltage, wherein the device is configured to detect a position of a detection object based on the sum voltage.

A non-local spin valve (NLSV) sensor includes a bearing surface and a detector located proximate to the bearing surface. The NLSV sensor also includes a channel layer located behind the detector relative to the bearing surface, and in a substantially same plane as the detector. The channel layer has a front end that is proximate to the detector and a rear end that is distal to the detector. The NLSV sensor further includes first and second spin injectors, with the first spin injector located proximate to the rear end of the channel layer and positioned above the channel layer, and the second spin injector located proximate the rear end of the channel layer and positioned below the channel layer.

A magnetic localization system including a magnetic field generator that generates an alternating magnetic field with a maintained frequency; and a receiver comprising: a DC magnetometer to sense a local magnetic field, at least in part due to the generated magnetic field; and at least one processor that calculates a six-degrees-of-freedom (6DOF) position and orientation of the receiver relative to the generator, based on the sensed magnetic field and the maintained frequency, and optionally based on the momentary phase of the generated field. Optionally, the generator includes an actuator that applies a rotational motion; at least one magnet rotating about a first axis by the actuator; a magnetometer to sense a momentary rotation phase of the at least one magnet; and a controller to maintain a desired rotation frequency of the at least one magnet. Optionally, the generator communicates the maintained rotation frequency and optionally the sensed momentary phase.

A magnetometer includes a sample signal device; a reference signal device; a microwave field generator operable to apply a microwave field to the sample signal device and the reference signal device; an optical source configured to emit light including light of a first wavelength that interacts optically with the sample signal device and with the reference signal device; at least one photodetector arranged to detect a sample photoluminescence signal including light of a second wavelength emitted from the sample signal device and a reference photoluminescence signal including light of the second wavelength emitted from the reference signal device, in which the first wavelength is different from the second wavelength; and a magnet arranged adjacent to the sample signal device and the reference signal device.