A method for identifying a position of a multi-phase brushless motor includes applying a plurality of detection voltage pulses to the motor, each detection voltage pulse corresponding to a respective driving phase of the motor, measuring a time period associated with a current reaching a predetermined current limit for each applied detection voltage pulse, and identifying a driving phase associated with a shortest time period for the current to reach the predetermined current limit.

Embodiments of the present invention relate to an industrial wireless sensor system and aim to provide an industrial wireless sensor system in which three types of sensors (e.g., magnetic field detection sensor, limit sensor, proximity sensor), which are conventionally provided only as wired sensors, are replaced with wireless sensors. To that end, according to the present invention, there is disclosed an industrial wireless sensor system, comprising a sensor sensing an external physical state and outputting a sensing signal, a sensor controller converting the sensing signal from the sensor, converting the sensing signal into a digital signal, and outputting the digital signal, a wireless communication unit receiving the digital signal from the sensor controller, converting the digital signal into a wireless signal, and outputting the wireless signal to a factory controller, a power source supplying power to each of the sensor and the sensor controller, and a battery connected to the power source.

Embodiments of the present invention relate to an industrial wireless sensor system and aim to provide an industrial wireless sensor system in which three types of sensors (e.g., magnetic field detection sensor, limit sensor, proximity sensor), which are conventionally provided only as wired sensors, are replaced with wireless sensors. To that end, according to the present invention, there is disclosed an industrial wireless sensor system, comprising a sensor sensing an external physical state and outputting a sensing signal, a sensor controller converting the sensing signal from the sensor, converting the sensing signal into a digital signal, and outputting the digital signal, a wireless communication unit receiving the digital signal from the sensor controller, converting the digital signal into a wireless signal, and outputting the wireless signal to a factory controller, a power source supplying power to each of the sensor and the sensor controller, and a battery connected to the power source.

A sensing system adapted to determine changes in phase when a capacitive object enters into the phase detection zone created by a pair of transmitting conductors. One of the transmitting conductors has a receiving conductor located proximate to it and transmits a signal at a certain frequency. The other transmitting conductor transmits a signal that is phase shifted from the signal transmitted by the other transmitting conductor. Capacitive objects entering the space between the two transmitting conductors impacts the phase. Measurements of the change in phase are used to determine the position of an object between the two transmitting conductors.

A sensing system adapted to determine changes in phase when a capacitive object enters into the phase detection zone created by a pair of transmitting conductors. One of the transmitting conductors has a receiving conductor located proximate to it and transmits a signal at a certain frequency. The other transmitting conductor transmits a signal that is phase shifted from the signal transmitted by the other transmitting conductor. Capacitive objects entering the space between the two transmitting conductors impacts the phase. Measurements of the change in phase are used to determine the position of an object between the two transmitting conductors.

A device disclosed herein includes a feedback measuring circuit to measure a signal flowing through a movable MEMS mirror. Processing circuitry determines a time at which the signal indicates that a capacitance of the movable MEMS mirror is substantially at a maximum capacitance. The processing circuitry also determines, over a window of time extending from the time at which the signal indicates that the capacitance of the movable MEMS mirror is substantially at the maximum to a given time, a total change in capacitance of the movable MEMS mirror compared to the maximum capacitance. The processor further determines the capacitance at the given time as a function of the total change in capacitance, and determines an opening angle of the movable MEMS mirror as a function of the capacitance at the given time.

The present disclosure describes a two-stage method for estimating an angle offset of an angle sensor in a system comprising a permanent-magnet synchronous motor. An initial value for the estimated angle offset is first determined with a short circuit test. Next, a torque of the motor may be controlled so that the motor is maintained at a zero speed. Minor adjustments are made to the value of the angle offset to find a minimum magnitude of stator current. A value at which the stator current is at its minimum is used as a final angle offset.

The present disclosure describes a two-stage method for estimating an angle offset of an angle sensor in a system comprising a permanent-magnet synchronous motor. An initial value for the estimated angle offset is first determined with a short circuit test. Next, a torque of the motor may be controlled so that the motor is maintained at a zero speed. Minor adjustments are made to the value of the angle offset to find a minimum magnitude of stator current. A value at which the stator current is at its minimum is used as a final angle offset.

A position sensing device for measuring a position, comprises a position sensing device for measuring a position; a plurality of sensors arranged to produce sense signals each being a function of an input phase representative of a position to be measured; a combiner circuit arranged to generate an error signal by combining the sense signals according to an array of weight factors; a processing block including a loop filter to filter the error signal and arranged to output a phase value representative of the position; and a feedback loop comprising a feedback signal unit arranged for receiving the output phase value and for adjusting based on the received output phase value of the array of weight factors.

A position sensing device for measuring a position, comprises a position sensing device for measuring a position; a plurality of sensors arranged to produce sense signals each being a function of an input phase representative of a position to be measured; a combiner circuit arranged to generate an error signal by combining the sense signals according to an array of weight factors; a processing block including a loop filter to filter the error signal and arranged to output a phase value representative of the position; and a feedback loop comprising a feedback signal unit arranged for receiving the output phase value and for adjusting based on the received output phase value of the array of weight factors.