Apparatus and associated methods relate to monitoring health of a system for sensing rotational frequency of a rotatable member. A plurality of magnetic speed probes, each of which is configured to sense the rotational frequency of the rotatable member, are arranged in transmissive proximity with one another. A transmitter-configured one of the plurality of magnetic speed probes includes a signal coupler that couples an electrical signal generated by a radio-frequency signal generator into the inductive coil of the transmitter-configured magnetic speed probe, thereby radiatively transmitting an electromagnetic signal. A speed-probe monitor electrically coupled to each of the plurality of magnetic speed probes determines, based on the coil current sensed by each of the plurality of magnetic speed probes in response to the electromagnetic signal radiatively transmitted, health of the system.

A system for determining vehicle direction includes an active wheel speed sensor (aWSS), an exciter ring for inducing a change in a signal from the aWSS and a controller. The controller receives a first series of signals from the aWSS, compares them to an array of predefined signals and determines the direction of travel based on the first series of signals matching the array. The controller receives a second series of signals and determines the exciter ring has an anomaly in response to at least one signal in the second series of signals having a first variance. The controller updates the array of predefined signals to include a representation of the first variance to create an array of updated signals. The controller determines the direction of travel based on a subsequent series of signals matching one of the array of predefined signals and the array of updated signals.

In one aspect, an integrated circuit (IC) includes a magnetic-field sensor. The magnetic field sensor includes a first and second magnetoresistance circuitries configured to receive a magnetic field signal from a target and convert the magnetic field signal received to a first signal and second signal; analog circuitry configured to receive the first and second signals; digital circuitry configured to receive a first and second analog output signals from analog circuitry and to convert the first and second analog output signals to a first and second digital signals representing a first and second channel output signals; and diagnostic circuitry configured to receive, from the digital circuitry, an input signal related to a separation of the first and second channel output signals, and configured to provide a test signal at a pin of the IC indicating whether a distance between the IC and the target complies with at least one rule.

The present invention proposes a device for positioning a wheel speed sensor relative to a pole wheel, comprising a fastening mechanism for attaching the device to an axle body part, a receiving region for receiving the wheel speed sensor, and a positioning mechanism for the controlled setting of a distance between the receiving region and the pole wheel.

A method of inspecting an air data probe for damage or misalignment on a mounting surface includes retrieving reference data for the air data probe from a database, capturing images of the air data probe via a camera and generating dimensions from the captured images of the air data probe via a feature extractor. An alignment calculator analyzes the generated dimensions from the captured images of the air data probe and the reference data for the air data probe from the database to identify misalignment of the air data probe, and analyzes the generated dimensions from the captured images of the air data probe and the reference data for the air data probe from the database to identify damage of the air data probe. A maintenance recommendation for the air data probe is generated and outputted, based on the identified misalignment or damage of the air data probe.

Systems, methods, and apparatuses for magnetic field sensors with self-test include a detection circuit to detect speed and direction of a target. One or more circuits to test accuracy of the detected speed and direction may be included. One or more circuits to test accuracy of an oscillator may also be included. One or more circuits to test the accuracy of an analog-to-digital converter may also be included. Additionally, one or more IDDQ and/or built-in-self test (BIST) circuits may be included.

Systems, methods, and apparatuses for magnetic field sensors with self-test include a detection circuit to detect speed and direction of a target. One or more circuits to test accuracy of the detected speed and direction may be included. One or more circuits to test accuracy of an oscillator may also be included. One or more circuits to test the accuracy of an analog-to-digital converter may also be included. Additionally, one or more IDDQ and/or built-in-self test (BIST) circuits may be included.

Disclosed are a parameter estimating method based on correction of independence of an error term, a computer program implementing the method, and a system configured to perform the method. The method includes: acquiring a measured velocity, which is a velocity of a moving object measured with a speedometer being operated by an observer and having a specific measurement unit, and an actual velocity of the moving object with respect to the observer; performing modeling of a linear regression model with the measured velocity as a dependent variable and the actual velocity of the moving object with respect to the observer as an independent variable; and estimating parameters of a linear regression equation after correcting the independence of the error term based on Lorentz velocity transformation.

Disclosed are a parameter estimating method based on correction of independence of an error term, a computer program implementing the method, and a system configured to perform the method. The method includes: acquiring a measured velocity, which is a velocity of a moving object measured with a speedometer being operated by an observer and having a specific measurement unit, and an actual velocity of the moving object with respect to the observer; performing modeling of a linear regression model with the measured velocity as a dependent variable and the actual velocity of the moving object with respect to the observer as an independent variable; and estimating parameters of a linear regression equation after correcting the independence of the error term based on Lorentz velocity transformation.

A method for monitoring the travel speed of a bicycle, in particular a pedelec. The method includes: providing a power supply for a speed signal transmitter, ascertaining a first speed for the bicycle, interrupting the power supply for the speed signal transmitter for a specifiable interruption time span, while the power supply is switched off, ascertaining a second speed, ascertaining a comparison result by comparing the ascertained first and second speed, and recognizing a faulty speed signal transmitter as a function of the result of the comparison.