Rotor position and velocity estimation for a permanent magnet synchronous machine at standstill and high speeds

Abstract

This paper addresses self-sensing ("sensorless") control of permanent magnet synchronous motors (PMSMs). The major contribution of this work is the introduction of a simple-to-implement estimation technique that operates over a wide speed range, including zero speed. The technique achieves simplicity by decoupling the inherent cross-coupling in PMSMs. The technique utilizes the dependence of inductance on rotor position in interior permanent magnet machines to produce position and velocity estimates both for field orientation and for all motion control of the drives. The technique functions in a manner similar to a resolver and resolver-to-digital converter sensing system, whereby in the proposed technique the motor acts as the electromagnetic resolver and the power converter applies carrier frequency voltages to the stator which produce high frequency currents that vary with position. The sensed currents are then processed with a heterodyning technique that produces a signal that is approximately proportional to the difference between the actual rotor position and an estimated rotor position. This position error signal and a torque estimate are then used as inputs to a Luenberger style observer to produce parameter, zero lag, position and velocity estimates.