A computer-implemented method includes, by one or more processors in electronic communication with a tunneling magnetoresistive sensor, wherein the tunneling magnetoresistive sensor is a component of a magnetic storage drive configured to read magnetic data from a magnetic storage medium, detecting a short across the tunneling magnetoresistive sensor, measuring a change in resistance of the tunneling magnetoresistive sensor, measuring a change in voltage amplitude for the tunneling magnetoresistive sensor, and dividing said change in voltage amplitude by said change in resistance to yield a ratio. The computer-implemented method further includes, responsive to the ratio being greater than a predetermined ratio threshold, determining that the short is caused by a magnetic shunt. A corresponding computer program product and computer system are also disclosed.

A marker detection device which detects a magnetic marker laid in a road by using a sensor unit in which a plurality of combinations of a magnetic sensor and a magnetic-field generation coil are arranged includes a storage part which stores characteristic information of each magnetic-field generation coil, an estimation part which estimates a magnetic differential value acting on the magnetic sensor due to a current differential value acting on the magnetic-field generation coil by referring to the characteristic information of each magnetic-field generation coil, and a calibration part which calibrates each magnetic sensor so as to enhance uniformity in sensitivity, which is a ratio between an output differential value of the magnetic sensor in accordance with a change of a current by the current differential value acting on the magnetic-field generation coil and the estimated magnetic differential value.

A method for scanning artificial structure, wherein a scanning artificial structure apparatus comprises four magnetic-field sensors, the four magnetic-field sensors are non-coplanar configured, the method comprises following steps of: moving the scanning artificial structure apparatus along a scanning path within a to-be-tested area, in the meantime, measuring magnetic field by the four magnetic-field sensors, and recording a position sequence when measuring magnetic field, wherein four magnetic-field measurement sequences are measured by the four magnetic-field sensors; and calculating a magnetic-field variation distribution from the four magnetic-field measurement sequences and the position sequence, wherein the magnetic-field variation distribution is corresponding to at least one artificial structure distribution.

Described is a system for adaptive calibration of a sensor of an inertial measurement unit. Following each sensor measurement, the system performs automatic calibration of a multi-axis sensor. A reliability of a current calibration is assessed. If the current calibration is reliable, then bias and scale factor values are updated according to the most recent sensor measurement, resulting in updated bias and scale factor values. If the current calibration is not reliable, then previous bias and scale factor values are used. The system causes automatic calibration of the multi-axis sensor using either the updated or previous bias and scale factor values.

An apparatus (10) for checking a component (30) is disclosed. The apparatus (10) comprises a sample holder (20) with a module (28) for receiving at least one component (30), at least one magnetic field generator (60a, 60b, 60c) for generating a magnetic field around the module (28), an inlet (40) for feeding a tempered medium into the module (25), and an outlet (45) for discharging a tempered medium from the module (28).

A field-sensor device comprises first and second field sensors disposed in corresponding different first and second orientations, each responsive to an external field to produce corresponding first and second sensor signals. One of or both the first and second sensor signals are converted to equivalent comparable sensor signals in a common orientation and compared to determine a faulty field sensor. If a faulty field sensor is determined, a faulty sensor signal is produced or, if a faulty sensor is not determined, an output sensor signal responsive to the first, second or comparable sensor signals is produced. Evaluation of the direction of differences between the comparable sensor signals can determine which of the first and second field sensors is faulty.

A semiconductor device includes a semiconductor substrate 10 of a first conductivity type, a vertical Hall element 100 provided on the semiconductor substrate 10, and an excitation conductor 200 provided directly above the vertical Hall element 100 with an intermediation of an insulating film 30. The vertical Hall element 100 includes a semiconductor layer 101 of a second conductivity type provided on the semiconductor substrate 10, and a plurality of electrodes 111 through 115 each constituted from a high-concentration second conductivity type impurity region and provided on the surface of the semiconductor layer 101 along a straight line. A ratio W.sub.C/W.sub.H between a width W.sub.C of the excitation conductor 200 and a width W.sub.H of each of the plurality of electrodes 111 through 115 satisfies 0.3≤W.sub.C/W.sub.H≤1.0.

A magnetic field sensor apparatus includes a sensor signal generator generating a sensor signal responsive to a magnetic field. A switching level provider provides during a power up mode a switching level based on a most recently updated valid one of a first and a second value of a default switching level. If an update triggering condition occurs, the not most recently updated one of the first and second values of the default switching level is updated and the most recently updated one of the first and second values of the default switching level is maintained unchanged until a next update triggering condition occurs, so that the first and second values of the default switching level are updated alternately on consecutive triggering conditions.

An autocalibration method includes generating at least one sensor signal in response to measuring a physical quantity; compensating the at least one sensor signal based on at least one compensation parameter to generate at least one compensated sensor signal; generating the at least one compensation parameter based on the at least one sensor signal or the at least one compensated sensor signal; comparing each of the at least one compensation parameter to a respective tolerance range; on a condition that each of the at least one compensation parameter is within its respective tolerance range, transmitting the at least one compensation parameter as at least one validated compensation parameter to be used for compensating the at least one sensor signal; and on a condition that at least one of the at least one compensation parameter is not within its respective tolerance range, generating a fault detection signal.

The present invention provides device for generating magnetic field of calibration and built-in self-calibration (BISC) magnetic sensor and calibration method, in which a novelty structure utilized for generating a uniform, predetermined magnitude, and three-dimensional orthogonal or approximately orthogonal magnetic field of calibration is arranged in the magnetic sensor such that the magnetic sensor can perform BISC function for obtaining a calibrating information with respect to the magnetic field of calibration anytime and anywhere. The magnetic sensor can be arranged in the application device for measuring magnetic field under the real environment where the magnetic sensor is located and the calibrating information are utilized for calibrating the measuring result thereby improving and advancing the accuracy of measuring three-dimensional magnetic field.