Abstract: A method and apparatus for use with a controller that supplies voltages to an induction machine via supply lines, the voltages including a fundamental voltage component and an injected voltage component, the line voltages also including harmonic voltage components where the harmonic voltage components include at least a high frequency first harmonic component having a frequency substantially equal to the sum of the fundamental component frequency and the injected component frequencies, the method for identifying the high frequency first harmonic component and comprising the steps of sensing the line voltages, identifying a zero sequence voltage component of the line voltages, rectifying the zero sequence voltage component to generate a rectified signal and using the rectified signal to identify the high frequency first harmonic component.

Abstract: A method and apparatus for use with a controller that uses a flux angle position value to control a three phase induction machine, the method for determining an instantaneous flux angle position value in the machine where the machine is characterized by a system specific dominant harmonic frequency number DH that is at least two, the method comprising the steps of injecting a high frequency voltage signal having a high frequency value into the machine thereby generating a high frequency current within the stator windings, obtaining a high frequency feedback signal from the machine, mathematically combining the high frequency value and the dominant harmonic number DH to provide an instantaneous modified angle, using the feedback signal to identify X consecutive calculating instances during each Y consecutive feedback signal cycles where Y is at least two, at each of the X different calculating instances, identifying an instantaneous flux angle position value by mathematically combining a shift angle with the i

Abstract: A method and apparatus for use with a controller that uses a flux angle position value to control a three phase induction machine, the method for determining an instantaneous flux angle position value in the machine where the machine is characterized by a system specific dominant harmonic frequency number DH that is at least two, the method comprising the steps of injecting a high frequency voltage signal having a high frequency value into the machine thereby generating a high frequency current within the stator windings, obtaining a high frequency feedback signal from the machine, mathematically combining the high frequency value and the dominant harmonic number DH to provide an instantaneous modified angle, using the feedback signal to identify X consecutive calculating instances during each Y consecutive feedback signal cycles where Y is at least two, at each of the X different calculating instances, identifying an instantaneous flux angle position value by mathematically combining a shift angle with the i

Abstract: A method and apparatus for estimating flux angle position in an induction machine, the method including the steps of providing high frequency injection voltage signals to a three-phase motor, obtaining frequency feedback signals from machine supply lines, converting the feedback signals to two-phase stationary high frequency signals, converting the stationary signals to synchronous signals using a high frequency angle estimate, negating one of the resulting synchronous signals, stepping up the negated signal to generate a low frequency spectrum signal, adding the low frequency spectrum signal and the high frequency injection signal to generate a combined spectrum signal and integrating the combined spectrum signal to generate the high frequency angle estimate, dividing the low frequency spectrum by a system specific DHN to generate a stator frequency estimate and integrating the stator frequency estimate to generate the flux angle estimate.

Abstract: A method and apparatus for generating stator and rotor resistance estimate, the method including the steps of providing high frequency injection voltage signals to a three phase motor, rotating three phase feedback current therefrom, converting the feedback currents to two phase currents that represent the high frequency component of the current vector wherein the d and q axis components are within a two phase voltage coordinate system and driving a regulator via one of the current components to generate a lag angle estimate, the lag angle estimate used to solve any of several different equations to calculate the stator and rotor resistance estimates.

Abstract: A method and apparatus for estimating flux angle position in an induction machine, the method including the steps of providing high frequency injection voltage signals to a three-phase motor, obtaining frequency feedback signals from machine supply lines, converting the feedback signals to two-phase stationary high frequency signals, converting the stationary signals to synchronous signals using a high frequency angle estimate, negating one of the resulting synchronous signals, stepping up the negated signal to generate a low frequency spectrum signal, adding the low frequency spectrum signal and the high frequency injection signal to generate a combined spectrum signal and integrating the combined spectrum signal to generate the high frequency angle estimate, dividing the low frequency spectrum by a system specific DHN to generate a stator frequency estimate and integrating the stator frequency estimate to generate the flux angle estimate.

Abstract: A method and apparatus for generating stator and rotor resistance estimate, the method including the steps of providing high frequency injection voltage signals to a three phase motor, rotating three phase feedback current therefrom, converting the feedback currents to two phase currents that represent the high frequency component of the current vector wherein the d and q axis components are within a two phase voltage coordinate system and driving a regulator via one of the current components to generate a lag angle estimate, the lag angle estimate used to solve any of several different equations to calculate the stator and rotor resistance estimates.

Abstract: A system for accurately determining a slip frequency for use in controlling an induction motor. The system includes two tables for determining ideal flux and flux current levels as a function of rotor speed and uses values from those tables to determine an actual rotor inductance required for calculating the slip. The system also generates a slip multiplier which is used to increase or decrease the slip as a function of the flux current to compensate for changing rotor resistance.