Sensors measure magnetic field components, and the measured fields are used to calculate and estimated transverse position of a longitudinal electric current flowing as an electric discharge across a discharge gap. Based on the estimated position, and according to a selected transverse trajectory or distribution of the estimated discharge position, magnetic fields are applied transversely across the discharge gap so as to control or alter the estimated discharge position. Inventive apparatus and methods can be employed, inter alia, during operation of a vacuum arc furnace.

Examples of systems and methods for calibrating or operating a magnetic sensor for sensor temperature or operating conditions are provided. The magnetic sensor can comprise a dual magnetometer sensor that comprises a first, low-power-consumption magnetometer (e.g., a magneto-inductive magnetometer) and a second higher-power-consumption magnetometer (e.g., a magneto-resistive magnetometer). The second magnetometer can have a lower unit-to-unit variation in temperature calibration parameters and can be used to temperature-correct readings from the first magnetometer. The magnetic sensor can dynamically switch between usage of the first magnetometer and the second magnetometer in order to provide a dynamic sample rate that can depend on conditions within the sensor or external to the sensor.

Systems, methods, and apparatuses for a self-locating compass for use in navigation are disclosed. The self-locating compass is operable to provide position and/or velocity without information from a global positioning system (GPS) device. The self-locating compass includes a direction finder and a Lorentz force detector. The method includes determining orientation with respect to Earth's magnetic field, measuring a Lorentz force proportional to rate of change of location with respect to the field, determining a change in location, and updating location.

A sensor device contains a first magnetic field sensor chip having a first sensor element. The first magnetic field sensor chip is configured to detect a component of a magnetic field at the location of the first sensor element. The sensor device contains a second magnetic field sensor chip having a second sensor element. The second magnetic field sensor chip is configured to detect a component of a magnetic field at the location of the second sensor element. The sensor device contains a current conductor configured to carry a measurement current that induces a magnetic field at the locations of the sensor elements. The magnetic field sensor chips and the current conductor are arranged relative to one another in such a way that an influence of a homogeneous magnetic stray field on the first components is compensated for upon difference formation or summation applied to the first components.

A magnetic sensor comprising: an application specific integrated circuit (ASIC); an insulating protective film formed on a surface of the ASIC; a substrate film formed on the insulating protective film; and a magnetic field detection element formed on the substrate film, the magnetic field detection element including two magnetic wires on the substrate film, a detection coil surrounding the two magnetic wires, two electrodes coupled to the two magnetic wires for wire energization, and two electrodes coupled to the coil for coil voltage detection.

A variety of magnetic field sensor arrangements provide so-called “tooth detectors” using a simple low-cost magnet.

A variety of magnetic field sensor arrangements provide so-called “tooth detectors” using a simple low-cost magnet.

A sensor element based on a magneto-thermoelectric effect and realizing method thereof are provided, the sensor element includes a plurality of thermoelectric elements having an angular structure and are located in a magnetic field; the thermoelectric element is made of magnetic material having a thermoelectric effect, and includes a first side, a second side, and an angular part formed by connecting the two sides; the angular part is provided with a heating device; and the temperature in the region where the other end of the first side and the second side are located are less than or equal to the ambient temperature.

A sensor element based on a magneto-thermoelectric effect and realizing method thereof are provided, the sensor element includes a plurality of thermoelectric elements having an angular structure and are located in a magnetic field; the thermoelectric element is made of magnetic material having a thermoelectric effect, and includes a first side, a second side, and an angular part formed by connecting the two sides; the angular part is provided with a heating device; and the temperature in the region where the other end of the first side and the second side are located are less than or equal to the ambient temperature.

A rotation detection sensor is disposed to face an outer peripheral part of a signal rotor, and outputs a detection signal corresponding to a position of the outer peripheral part with the rotation of the signal rotor. The rotation detection sensor detects a rotation reference position with the detection of switching from projections to a missing tooth part on the basis of a gap to the signal rotor, and detects switching from the missing tooth part to the projections to output a rotation reference position signal indicative of position information on the rotation reference position at timing of the detection. An ECU receives the detection signal and the rotation reference position signal from the rotation detection sensor, and acquires the rotation reference position on the basis of the rotation reference position signal.