Provided is an apparatus configured to detect a car position by performing threshold processing on a voltage caused by an AC magnetic response through use of an identification plate in which a slit pattern is formed and a plurality of coils, the apparatus including a circuit configuration capable of switching between a normal operation for detecting the car position based on an on/off detection operation using the plurality of coils and a self-diagnosis operation capable of verifying the on/off detection operation irrespective of the presence or absence of the identification plate with a car in a stopped state by forcedly applying a magnetic field to the coils.

Embodiments herein relate to a system and method for detecting an open circuit in a sensor measurement system. The system including a sensor having a direct current (DC) output, operably connected to a wiring harness and configured to transmit a sensor signal, and a controller, the controller operably connected to the wiring harness. The controller is configured execute a method including receiving a sensor signal from the sensor, AC coupling an AC signal with the sensor signal to form a coupled signal, measuring the coupled signal, determining if an open circuit is present based on the coupled signal and characterizing the sensor as failed if the open circuit is detected.

A magnetic sensor may detect a system-level error, associated with a sensor system that includes the magnetic sensor, based on one or more physical parameters as determined at the magnetic sensor. The magnetic sensor may provide an indication of the system-level error in an output signal. The one or more physical parameters may include a temperature at the magnetic sensor, a temperature drift of the magnetic sensor, a supply voltage at the magnetic sensor, an amount of humidity at the magnetic sensor, or an amount of pressure at the magnetic sensor.

In a method and device for monitoring the track signals of a position change sensor, a resource-optimized diagnosis of errors of track signals of a position change sensor is performed.

The disclosure relates to a method of determining the initialization state of a multi-turn sensor based on the sensor outputs. The method takes a reading of the sensor outputs, and then determines whether the sensor outputs are feasible based on an assumption that the sensor is initialised in one of two states. If the sensor outputs are correct, this initial assumption is taken to also be correct. However, if an incorrect sensor output is read, then it is taken that the assumed initialization state is incorrect. The sensor is therefore taken to be initialised in the alternative state. The method will then determine whether the sensor outputs are feasible based on this second assumption, and if an incorrect sensor output is still being read, then there is a fault in the multi-turn sensor.

A one dimensional measuring machine includes a scale having graduations, a mover that has a light source configured to emit light to the graduations of the scale and a light receiving element configured to receive the light having passed through the scale from the light source, and can move along the scale, a light amount information detector that detects information regarding a light amount of the light emitted to the scale from the light source while the mover moves along the scale, and a contamination detector that detects a degree of contamination of the scale, based the information regarding the light amount of the light detected by the light amount information detector.

A method for diagnosing errors in the correct operation of a sensor system. A positive signal amplifier saturation threshold value and a negative signal amplifier saturation threshold value less than the positive signal amplifier saturation threshold value are provided, and at least one signal comparator threshold value. A current value of a first amplified input signal at a first time is provided and a current value of a second amplified input signal obtained at a second time later than the first time, but in the same measurement cycle. The measured values of the first and second amplified input signal are compared to the current signal comparator threshold value. A new output state is determined via the measured first and second amplified input signals. From a previous comparison of the first and second amplified input signal a current output state is provided, from which an expected new output state is determined.

A position measuring device includes a scale carrier with a measuring scale. A scanner is configured to generate position signals by scanning the measuring scale. A processor is configured to process the position signals into a digital position value. An interface is configured to communicate with downstream electronics. At least one collision sensor is assigned to the position measuring device, and is configured to generate analog or digital measured values from a time characteristic of which collision events are determinable. The measured values are fed to an evaluator configured to determine the collision events by evaluating the time characteristic of the measured values in a controller.

An object of the present invention is to provide an electrically operated valve capable of more accurately detecting the position of a valve body. In order to achieve the above object, the electrically operated valve of the present invention comprises a valve body, a driver configured to move the valve body along a first axis, a rotation shaft configured to rotate the driver around the first axis, a permanent magnet member, and an angle sensor. The permanent magnet member is disposed on the rotation shaft and configured to rotate with the rotation shaft. The angle sensor is configured to detect a rotation angle of a permanent magnet included in the permanent magnet member. The angle sensor is disposed above the permanent magnet.

An absolute encoder that receives a current from an electronic power supply includes: a plurality of regulators connected in parallel with one another that receive a drive current from an electronic power supply in which a magnitude of a constant voltage output to the absolute encoder and a magnitude of a drive current needed for outputting the constant voltage are different; a voltage detection unit configured to detect an output voltage of at least one regulator of the plurality of regulators; and an abnormality detection unit for detecting an abnormality of a current from an electronic power supply consumed when the absolute encoder is driven based on the output voltage detected by the voltage detection unit.