Various embodiments of the present technology comprise a method and apparatus for an encoder. In various embodiments, the encoder is configured to perform offset and gain correction. The encoder includes a first correction circuit to perform offset and gain correction and a second correction circuit to perform additional offset and gain correction.

A device for processing rotation-dependent measured values includes a data converter, a sequencing control, and an output interface. Series of measured values, which are a function of the rotation of a shaft and of which at least one is an angle value that indicates the angular position of the shaft, are conveyable to the data converter at constant time intervals of a measuring interval. The data converter is adapted to subdivide a rotation of the shaft into sectors and, using one of the angle values as a reference angle value, to allocate received measured values to a sector, and per rotation of the shaft, to ascertain for each series of measured values precisely one result value for each sector. The result values are able to be output to the output interface.

Uses a generic sensor to provide a rotary encoder with high accuracy, excellent environmental resistance, and low cost that is equivalent to having a precision sensor. A generic type rotary encoder comprising a generic sensor, a rotation angle detector that outputs information on the rotation angle of the rotary shaft of the motor based on an output signal from the generic sensor, and an encoder control unit, wherein the encoder control unit comprises a function for driving an initial setting motor, an initial setting data acquisition function for acquiring initial setting data unique to the generic sensor, a normal operation data acquisition function that acquires and generates data for normal operation used when the motor to be controlled to which the generic type rotary encoder is mounted is normally operated, and an EEPROM recorded calibration data to calibrate the initial setting data unique to the generic sensor, wherein the calibration data is obtained, by using a standard sensor that guarantees high accuracy of 2 digits or 3 digits higher than the generic sensor, and by simultaneously connecting the generic sensor and the standard sensor to the initial setting motor and driving the initial setting motor at least one forward and reverse rotation, and the calibration data is data for calibration relating to the rotation angle of the rotary shaft.

Various embodiments of the present technology comprise a method and apparatus for an encoder. In various embodiments, the encoder is configured to perform offset and gain correction. The encoder includes a first correction circuit to perform offset and gain correction and a second correction circuit to perform additional offset and gain correction.

Various embodiments of the present technology comprise a method and apparatus for an encoder. In various embodiments, the encoder is configured to remove impairments from the signals produced by a servo motor and compute a phase that is used to determine the rotary position of the servo motor. In various embodiments, the encoder is configured to remove a DC offset, improve amplitude mismatch, and compute a phase offset.

Various embodiments of the present technology comprise a method and apparatus for an encoder. In various embodiments, the encoder is configured to remove impairments from the signals produced by a servo motor and compute a phase that is used to determine the rotary position of the servo motor. In various embodiments, the encoder is configured to remove a DC offset, improve amplitude mismatch, and compute a phase offset.