A wheel speed sensor for a motor vehicle can be supplied with an operating voltage by a control device. The control device has a load resistance with a load resistance value. An operating voltage can be at a voltage input by the control device. An electrical circuit is designed to determine a turn-on or a turn-off voltage value according to the load resistance value. An operation control is designed to transfer the wheel speed sensor into a normal operation using the operating voltage, when the turn-on voltage value is exceeded, and to transfer the wheel speed sensor into an emergency operation using the operating voltage, when a turn-off voltage value is not met. In emergency operation only a low constant signal level is emitted.

A wheel speed sensor for a motor vehicle can be supplied with an operating voltage by a control device. The control device has a load resistance with a load resistance value. An operating voltage can be at a voltage input by the control device. An electrical circuit is designed to determine a turn-on or a turn-off voltage value according to the load resistance value. An operation control is designed to transfer the wheel speed sensor into a normal operation using the operating voltage, when the turn-on voltage value is exceeded, and to transfer the wheel speed sensor into an emergency operation using the operating voltage, when a turn-off voltage value is not met. In emergency operation only a low constant signal level is emitted.

A circuit for activating a capacitive MEMS structure is provided, with the capacitive MEMS structure having an oscillator element and an electrostatic excitation unit with a first input connection and a second input connection. The circuit includes a high voltage generator, a first pump capacitor, a second pump capacitor, a control unit, and a low voltage operation amplifier. The high voltage generator generates a high voltage and connects to the first input connection and the second input connection. The first pump capacitor is connected to the high voltage generator and includes a first connection connected to the first input connection. The second pump capacitor connects to the high voltage generator and includes a first connection connected to the second input connection. The control unit connects to a second connection of the first pump capacitor and a second connection of the second pump capacitor. The low voltage operation amplifier connects to the control unit.

A circuit for activating a capacitive MEMS structure is provided, with the capacitive MEMS structure having an oscillator element and an electrostatic excitation unit with a first input connection and a second input connection. The circuit includes a high voltage generator, a first pump capacitor, a second pump capacitor, a control unit, and a low voltage operation amplifier. The high voltage generator generates a high voltage and connects to the first input connection and the second input connection. The first pump capacitor is connected to the high voltage generator and includes a first connection connected to the first input connection. The second pump capacitor connects to the high voltage generator and includes a first connection connected to the second input connection. The control unit connects to a second connection of the first pump capacitor and a second connection of the second pump capacitor. The low voltage operation amplifier connects to the control unit.

Hemispherical protrusions are protrudingly provided in end surfaces of a rotor gear and a tooth portion of a small gear having the smaller number of gear teeth between the rotor gear and a large gear of an intermediate gear, and between the small gear of the intermediate gear and an output gear, which are meshed with each other in a transmission gear train. Thus, in a case where the large gear rides on the rotor gear or the small gear rides on the output gear when the intermediate gear is accommodated in a housing after the rotor gear and the output gear are accommodated, it is possible to cancel the riding state thereof only by applying a slight vibration to the housing.

Hemispherical protrusions are protrudingly provided in end surfaces of a rotor gear and a tooth portion of a small gear having the smaller number of gear teeth between the rotor gear and a large gear of an intermediate gear, and between the small gear of the intermediate gear and an output gear, which are meshed with each other in a transmission gear train. Thus, in a case where the large gear rides on the rotor gear or the small gear rides on the output gear when the intermediate gear is accommodated in a housing after the rotor gear and the output gear are accommodated, it is possible to cancel the riding state thereof only by applying a slight vibration to the housing.

A sensor data acquisition unit 214 acquires sensor data indicating an acceleration of a device including a vibrator. A second estimation processing unit 250 estimates a speed of the device on the basis of the sensor data. A vibration determination unit 262 determines whether or not the vibrator is vibrating on the basis of the sensor data. A stationary determination unit 264 determines whether or not the device is stationary on the basis of the sensor data. A second estimation processing unit 250 reduces the estimated speed of the device in a case where it is determined that the vibrator is vibrating and the device is stationary.

A measurement apparatus for the detection of the feed movement of a workpiece to be processed, which has a belt or chain, which is guided on a carrier via deflection disks, a pressure device, which is moved along in its movement direction with the belt or the chain for the pressing of the belt or the chain against the workpiece, and a sensor for the detection of the movement of the belt or the chain. An accurate measurement can be attained in that the carrier on a holder can be rotated around a swivel axis, which is at a right angle to the direction of movement of the belt or the chain.

A measurement apparatus for the detection of the feed movement of a workpiece to be processed, which has a belt or chain, which is guided on a carrier via deflection disks, a pressure device, which is moved along in its movement direction with the belt or the chain for the pressing of the belt or the chain against the workpiece, and a sensor for the detection of the movement of the belt or the chain. An accurate measurement can be attained in that the carrier on a holder can be rotated around a swivel axis, which is at a right angle to the direction of movement of the belt or the chain.

An accelerometer system includes a magnet having a first end and a second end opposite the first end. The magnet is configured to generate a magnetic flux that flows through the magnet from the second end of the magnet to the first end of the magnet a proof mass extending through the magnet. The accelerometer system also includes a first coil disposed around a first portion of the magnet, a second coil disposed around a second portion of the magnet, and processing circuitry. The processing circuitry is configured to receive a signal corresponding to a capacitance of an interface between the magnet and the proof mass, cause a first current to flow through the first coil, and cause a second current to flow through the second coil. A first Lorentz force and a second Lorentz force maintain the proof mass in a null position.