Sensorless control of AC induction motor method and apparatus

What is claimed is: 1. A method for controlling a sensorless alternating current induction motor (ACIM) comprising a rotor and a stator comprising a plurality of stator windings, comprising: applying a plurality of phase shifted voltages to the plurality of stator windings in the ACIM such that two energized stator windings are connected to first and second phase shifted voltages to cause rotation of the rotor relative to the stator while a third unconnected stator winding is floating; measuring a DC bus current and an inducted voltage from the ACIM while the third unconnected stator winding is floating; and computing an estimated rotor speed from the DC bus current and the inducted voltage, where measuring the DC bus current and the inducted voltage comprises sampling the inducted voltage after expiration of a freewheeling interval in a third phase shifted voltage. 2. The method of claim 1 , where applying a plurality of phase shifted voltages comprises applying three phase shifted voltages to three stator windings, where the three phase shifted voltages are shifted from one another by 120 degrees. 3. The method of claim 1 , further comprising applying a plurality of pulse width modulated drive voltages to a full bridge inverter circuit to generate the plurality of phase shifted voltages such that the first and second phase shifted voltages have opposite polarity. 4. The method of claim 1 , where computing the estimated rotor speed comprises integrating samples of an inducted voltage after expiration of the freewheeling interval until a commutation threshold is reached to determine a commutation event. 5. The method of claim 4 , further comprising computing a commutation period from a plurality of commutation events and the computing an estimated stator speed from the commutation period. 6. The method of claim 5 , further comprising computing an estimated slip between a stator speed and rotor speed based on the measured DC bus current. 7. The method of claim 6 , further comprising computing the estimated rotor speed as a product of the estimated slip and the estimated stator speed. 8. A sensorless alternating current induction motor (ACIM) controller, comprising: a driver power stage hardware circuit comprising a plurality of power transistors for selectively connecting first and second reference voltages to generate a plurality of phase shifted voltages under control of a plurality of PWM gate control signals, where the plurality of phase shifted voltages are connected to a corresponding plurality of stator windings in an alternating current induction motor such that a plurality of energized stator windings are energized to cause rotation of the rotor relative to the stator while at least one stator winding is disconnected and floating; a processor coupled to receive the plurality of phase shifted voltages and a DC bus current measurement and to calculate: an estimated slip based on a DC bus current value measured from the DC bus current measurement; a plurality of commutation events based on integration of an inducted voltage from the alternating current induction motor while the at least one stator winding is disconnected and floating; and a rotor speed based on at least the estimated slip and stator speed derived from the plurality of calculated commutation events; and a pulse width modulator (PWM) hardware circuit for generating the PWM gate control signals so that the driver power stage hardware circuit energizes only the plurality of energized stator windings concurrently while leaving the at least one stator winding unpowered. 9. The sensorless ACIM controller of claim 8 , where the plurality of phase shifted voltages comprises three phase shifted voltages that are connected to three stator windings of the alternating current induction motor, where the three phase shifted voltages are shifted from one another by 120 degrees. 10. The sensorless ACIM controller of claim 8 , where the driver power stage hardware circuit comprises a full bridge inverter circuit which generates the plurality of phase shifted voltages such that the first and second phase shifted voltages have opposite polarity. 11. The sensorless ACIM controller of claim 8 , further comprising analog-to-digital converter circuit for integrating the inducted voltage by sampling the inducted voltage after expiration of a freewheeling interval in a third phase shifted voltage. 12. The sensorless ACIM controller of claim 11 , where the processor is configured to determine a commutation event by integrating samples of an inducted voltage after expiration of the freewheeling interval until a commutation threshold is reached. 13. The sensorless ACIM controller of claim 12 , where the processor is configured to calculate a commutation period from a plurality of commutation events and to compute the stator speed from the commutation period. 14. The sensorless ACIM controller of claim 13 , where the processor is configured to calculate the estimated slip as a product of a motor construction constant k and the DC bus current measurement. 15. The sensorless ACIM controller of claim 14 , where the processor is configured to calculate the rotor speed as a product of the estimated slip and the stator speed. 16. A system for controlling a sensorless alternating current induction motor (ACIM) comprising a rotor and a stator comprising a plurality of stator windings, comprising: a full bridge inverter circuit for generating a plurality of phase shifted voltages under control of a plurality of PWM control signals, where the plurality of phase shifted voltages are connected to a corresponding plurality of stator windings in an alternating current induction motor such that a plurality of energized stator windings are energized in a connected phase to cause rotation of the rotor relative to the stator while at least one stator winding is floating in a disconnected phase; a phase voltage observer coupled to receive the plurality of phase shifted voltages from the full bridge inverter circuit for generating a plurality of commutation events for each of the plurality of phase shifted voltages by integrating an inducted phase voltage during the disconnected phase and producing a stator period measure based on the plurality of commutation events; a slip compensation block coupled to receive a DC bus current measurement value from the full bridge inverter circuit for computing an estimated slip as function of the DC bus current measurement value; a speed measurement hardware circuit for producing an estimated rotor speed based on the estimated slip and stator period measure; a pulse width modulator (PWM) hardware circuit for generating the PWM control signals in response to the estimated rotor speed so that the full bridge inverter circuit energizes only the plurality of energized stator windings concurrently while leaving the at least one stator winding unpowered. 17. The system of claim 16 , where the phase voltage observer generates the commutation event by sampling the inducted phase voltage from the at least one stator winding after expiration of a freewheeling interval in the disconnected phase until a commutation threshold is reached. 18. The system of claim 17 , where the phase voltage observer further computes stator period measure from a commutation period that is derived from the plurality of commutation events. 19. The system of claim 18 , where the speed measurement hardware circuit computes the estimated rotor speed as a product of the estimated slip and stator period measure.