Abstract: Magnetic sensor arrangement comprising a component board delimited by two opposing main surfaces and having an accommodation hole for accommodating at least part of a magnetic field generating structure, and a magnetic sensor package located at least partially between the two opposing main surfaces and configured for sensing a magnetic field generated by the magnetic field generating structure.

Abstract: A magnetic set-up for use in a rotary encoder is disclosed. The set-up includes a permanent magnet arrangement including at least one permanent magnet, which is rotatable with respect to a rotation axis, and a soft magnetic sleeve encompassing the rotation axis and thus the permanent magnet arrangement for shielding against external magnetic fields. The at least one permanent magnet includes a through-hole, which extends along the rotation axis, so that the permanent magnet fully extends around the rotation axis.

Abstract: A method for correcting the output of a Hall effect device for thermal electromotive force (thermo-EMF) utilizing the steps of: (1) supplying energy to the Hall effect device, (2) measuring a first output of the Hall effect device as a result of the supplying energy, (3) stopping the supply of energy to the Hall effect device, (4) waiting a period of time, (5) measuring a second output of the Hall device in response to a temperature difference between the output measurement location and a reference point, and (6) combining the first and second outputs to determine an output corrected for thermo-EMF.

Abstract: An inductive angle sensor for determining a rotational position of a rotor relative to a stator includes an exciter coil, at least one pickup coil arrangement having an m-fold symmetry and at least one conductive target having an m-fold symmetry. The exciter coil may excite the conductive target which, in turn, may induce an induced signal in the pickup coil arrangement. A signal analysis device may determine the rotational position of the rotor based on the induced signal. The inductive angle sensor may comprise a second pickup coil arrangement having an n-fold symmetry and a second conductive target having an n-fold symmetry. The exciter coil may excite the second conductive target which, in turn, may induce a second induced signal in the second pickup coil arrangement. The signal analysis device may determine the rotational position of the rotor based on the two induced signals according to a Vernier principle.

Abstract: The present disclosure relates to a magnetic sensor arrangement comprising a first rotatable body having a first magnetic quadrupole attached thereto, a first magnetic sensor configured to generate, in response to a rotational angular position of the first magnetic quadrupole, a first sensor signal indicative of a first rotational angle of the first rotatable body, a second rotatable body having a second magnetic quadrupole attached thereto, and a second magnetic sensor configured to generate, in response to a rotational angular position of the second magnetic quadrupole, a second sensor signal indicative of a second rotational angle of the second rotatable body.

Abstract: A magnetic angle sensor device and a method for operating such device is provided. The magnetic angle sensor device includes a shaft rotatable around a rotation axis; a magnetic field source coupled to the shaft; a first magnetic angle sensor configured to generate a first signal that represents a first angle based on a first diametric magnetic field from the magnetic field source applied to the first magnetic angle sensor; a second magnetic angle sensor configured to generate a second signal that represents a second angle based on a second diametric magnetic field from the magnetic field source applied to the second magnetic angle sensor; and a combining circuit configured to determine a combined rotation angle based on the first signal and on the second signal.

Abstract: An off-axis counter is suggested that is arranged to count magnetic poles of a magnetic field source that turns around a rotation axis modulo an integer number. Also, a rotation angle sensing device and a method for determining a rotation angle are provided.

Abstract: A rotation angle sensing device is suggested, said device including: a magnetic field source that is mechanically coupled to a rotatable shaft; at least one conductive target that is mechanically coupled to the rotatable shaft; a magnetic angle sensor that is configured to detect the magnetic field of the magnetic field source; and at least one coil that is configured to excite an eddy current in the at least one conductive target and to receive a signal induced by the eddy current.

Abstract: Magnetic position sensors, systems and methods are disclosed. In an embodiment, a position sensing system includes a magnetic field source; and a sensor module spaced apart from the magnetic field source, at least one of the magnetic field source or the sensor module configured to move relative to the other along a path, the sensor module configured to determine a position of the magnetic field source relative to the sensor module from a nonlinear function of a ratio of a first component of a magnetic field of the magnetic field source to a second component of the magnetic field of the magnetic field source.

Abstract: An embodiment of a magnetic-field sensor includes a magnetic-field sensor arrangement and a magnetic body which has, for example, a non-convex cross-sectional area with regard to a cross-sectional plane running through the magnetic body, the magnetic body having an inhomogeneous magnetization.

Abstract: A sensor cross-talk compensation system includes a semiconductor substrate having a first main surface and a second main surface opposite to the first main surface; a vertical Hall sensor element disposed in the semiconductor substrate, the vertical Hall sensor element is configured to generate a sensor signal in response to a magnetic field impinging thereon; and an asymmetry detector configured to detect an asymmetric characteristic of the vertical Hall sensor element. The asymmetry detector includes a detector main region that vertically extends into the semiconductor substrate from the first main surface towards the second main surface and is of a conductivity type having a first doping concentration; and at least three detector contacts disposed in the detector main region at the first main surface, the at least three detector contacts are ohmic contacts of the conductivity type having a second doping concentration that is higher than the first doping concentration.

Abstract: A magnetic angle sensing system for detecting a rotation angle of a magnetic field source arranged rotatably around a rotation axis, the magnetic angle sensing system including at least two magnetic field sensing elements that are located in/on a plane, are not arranged on a single straight line through the rotation axis, and are configured to provide output signals that are functions of the same magnetic field component which is in parallel to the rotation axis. The system also including a processor that is arranged to determine the rotation angle from an angle between a pointer and a reference direction, wherein the pointer is determined based on the output signals of the at least two magnetic field sensing elements.

Abstract: Magnetic position sensors, systems and methods are disclosed. In an embodiment, a position sensing system includes a magnetic field source; and a sensor module spaced apart from the magnetic field source, at least one of the magnetic field source or the sensor module configured to move relative to the other along a path, the sensor module configured to determine a position of the magnetic field source relative to the sensor module from a nonlinear function of a ratio of a first component of a magnetic field of the magnetic field source to a second component of the magnetic field of the magnetic field source.

Abstract: A discrete magnetic angle sensor device can include a first magnetic field gradiometer and a second magnetic field gradiometer. The first magnetic field gradiometer and the second magnetic field gradiometer can be of different types of a group of gradiometer types. The sensor advantageously improves an accuracy of a determination of a rotation angle.

Abstract: An integrated Hall sensor device for measuring a magnetic field is provided. The integrated Hall sensor device includes: a semiconductor chip; a first Hall sensor for generating a first magnetic field measurement signal dependent on a first component; a second Hall sensor for generating a second magnetic field measurement signal dependent on a second component of the magnetic field; a first stress sensor for generating a shear stress measurement signal dependent on mechanical stresses in the semiconductor chip; and an evaluation device for determining one or more properties of the magnetic field depending on the first magnetic field measurement signal, the second magnetic field measurement signal. and the first shear stress measurement signal.

Abstract: A sensor arrangement, including: a rotatable driving shaft extending along a rotation axis and comprising a bore extending from a first end face of the shaft along the rotation axis; a substantially ring-shaped magnet arranged within the bore and coupled to the driving shaft, the magnet configured to generate a magnetic field within the bore; and a sensor configured to sense a rotation of the magnetic field in response to rotation of the driving shaft.

Abstract: Sensor devices, systems and methods are provided, including a first magnetic sensor configured to measure a first magnetic field in a first frequency range and output a first sensor signal based on the measured first magnetic field, a second magnetic sensor configured to measure a second magnetic field in a second frequency range and output a second sensor signal based on the measured second magnetic field, and a sensor circuit configured to receive the first and the second sensor signals, combine the first and the second sensor signals, and output a combined sensor signal. The first magnetic sensor and the second magnetic sensor are configured to share a cross-over frequency.

Abstract: A magnetic angle sensing system is suggested comprising first, second, and third magnetic sensing devices, a substrate comprising the first, second and third magnetic sensing devices, wherein the first, seconds and third magnetic sensing devices are each arranged such to be responsive to a magnetic field component that is perpendicular to a main surface of the substrate, wherein each or the first, second and third magnetic sensing devices comprises the same number of magnetic sensing elements, wherein the second magnetic sensing device is arranged on the semiconductor surface rotated by 120° in view of the first magnetic sensing device clockwise around a reference point, wherein the third magnetic sensing device is arranged on the semiconductor surface rotated by 120° in view of the first magnetic sensing device counter-clockwise around the reference point.

Abstract: A magnetic-field-sensitive MOSFET (MagFET) is described herein. In accordance with one embodiment, the MagFET comprises a semiconductor body, a first well region arranged in the semiconductor body and being doped with dopants of a first doping type, and a number of N contact regions arranged in the first well region and doped with dopants of a second doping type, which is complementary to the first doping type, wherein N is equal to or greater than three. A gate electrode covers the first well region between the contact regions. The gate electrode is separated from the first well region by an isolation layer and is configured to control a charge carrier density in the first well region between the contact regions dependent on a voltage applied at the gate electrode. The first well region has a center of symmetry and the contact regions are arranged rotationally symmetric with respect to the center of symmetry with a rotational symmetry of order N.

Abstract: A sensing element is provided including a magnetic sensor that detects a first magnetic field component, at least one AC-magnetic field generator that applies at least one additional magnetic field component at a given frequency to the magnetic sensor, where the first magnetic field component and the at least one additional magnetic field component are orthogonal to each other, and at least one demodulator using the given frequency to determine a sensitivity of the sensing element respective to the at least one additional magnetic field component. Also, several methods of operating such sensing element are provided.