Method and system for estimating differential inductances in an electric machine

What is claimed is: 1. A self-commissioning method for estimating differential inductances in an electric machine, preferably a synchronous electric machine such as e.g. a synchronous reluctance machine or interior permanent magnet machine and/or an electric machine which has cross-magnetization effects, comprising the steps of: driving the electric machine with PWM voltages to explore a plurality of operating points of the currents in the electric machine while keeping the electric machine at standstill or quasi-standstill; at each of the operating points, using PWM switching transients as a small-signal voltage excitation; measuring currents of the electric machine by means of oversampling to permit the reconstruction of the current waveforms, wherein the current ripple within a PWM period caused by the PWM switching transients is observed; determining direct and quadrature current waveforms from the measured currents of the electric machine while the current ripple within a PWM period is observed; and determining the differential inductances at each of the operating points of the currents based on the determined direct and quadrature current waveforms and on direct and quadrature voltages of the electric machine. 2. The method of claim 1 wherein the differential inductances at each of the operating points are determined based on the determined direct and quadrature current waveforms and voltages by using a recursive algorithm. 3. The method of claim 1 wherein said direct and quadrature voltages are determined from PWM voltages, which are either measured or reconstructed from the bus voltage and inverter switching commands. 4. The method of claim 1 wherein said PWM voltages are provided without using any zero voltage vectors. 5. The method of claim 1 wherein said PWM voltages are provided with a maximum voltage limitation to avoid that the slopes of the ripple of the currents are linearly dependent on one another within a PWM period. 6. The method of claim 1 wherein said PWM voltages are provided to keep one of the direct and quadrature currents at zero to thereby keep the electric machine at standstill. 7. The method of claim 1 wherein said PWM voltages are provided to keep one of the direct and quadrature currents at a constant value and the other one of the direct and quadrature currents alternating to obtain an oscillating torque with a mean value equal to zero and thereby keep the electric machine at quasi-standstill. 8. The method claim 1 wherein the shape of the alternating component keeps the angle displacement resulting from the torque and speed buildup centered on zero, to maintain the quasi-standstill condition. 9. The method of claim 7 wherein said PWM voltages are provided to keep said one of the direct and quadrature currents at a constant value by means of using a PI regulator. 10. The method of claim 7 wherein said PWM voltages are provided to keep said another one of the direct and quadrature currents alternating by means of using a bang-bang regulator. 11. The method of claim 9 wherein a hybrid control scheme is applied, which first calculates the voltage for the PI regulator to hold its current constant, and subsequently use a remaining voltage for the bang-bang regulator. 12. The method of claim 1 , wherein oversampling is defined as sampling the currents faster than the sampling required by the current control itself. 13. A system for estimating differential inductances in an electric machine, preferably a synchronous electric machine such as e.g. a synchronous reluctance machine or interior permanent magnet machine and/or an electric machine having cross-magnetization effects, comprising: a control and drive arrangement for driving the electric machine with PWM voltages to explore a plurality of operating points of the currents in the electric machine while keeping the electric machine at standstill or quasi-standstill, wherein, at each of the operating points, PWM switching voltage transients are used as a small-signal excitation; sensors for measuring currents of the electric machine by means of oversampling to permit the reconstruction of the current waveforms, wherein the current ripple within a PWM period caused by the PWM switching transients is observed; an arrangement for determining direct and quadrature current waveforms from the measured currents of the electric machine while the current ripple within a PWM period is observed; and an arrangement for determining the differential inductances at each operating point of the currents based on the determined direct and quadrature currents and on direct and quadrature voltages of the electric machine. 14. The system of claim 13 wherein the arrangement for determining the differential inductances comprises a recursive algorithm. 15. The system of claim 13 wherein the control and drive arrangement is configured to provide said PWM voltages to keep one of the direct and quadrature currents at zero to thereby keep the electric machine at standstill. 16. The system of claim 13 wherein the control and drive arrangement is configured to provide said PWM voltages to keep one of the direct and quadrature currents at a constant value and the other one of the direct and quadrature currents alternating to obtain an oscillating torque with a mean value equal to zero, to thereby keep the electric machine at quasi-standstill. 17. The system of claim 16 wherein the control and drive arrangement is configured to provide said PWM voltages such that the shape of the alternating current keeps the angle displacement resulting from the torque and speed buildup centered on an initial position, to maintain the quasi-standstill condition with minimal angle displacement. 18. The system of claim 13 wherein the control and drive arrangement is configured to provide said PWM voltages to keep said one of the direct and quadrature currents at a constant value by means of using a PI regulator and to keep said another one of the direct and quadrature currents alternating by means of using a bang-bang regulator. 19. The system of claim 18 wherein the control and drive arrangement is configured to employ a hybrid control scheme, which first calculates the voltage for the PI controller to hold its current constant, and subsequently uses the remaining voltage for the bang-bang controller. 20. The system of claim 13 , wherein oversampling is defined as sampling the currents faster than the sampling required by the current control itself. 21. The method of claim 2 wherein said direct and quadrature voltages are determined from PWM voltages, which are either measured or reconstructed from the bus voltage and inverter switching commands. 22. The method of claim 8 wherein said PWM voltages are provided to keep said one of the direct and quadrature currents at a constant value by means of using a PI regulator. 23. The method of claim 10 wherein a hybrid control scheme is applied, which first calculates the voltage for the PI regulator to hold its current constant, and subsequently use a remaining voltage for the bang-bang regulator. 24. The system of claim 14 wherein the control and drive arrangement is configured to provide said PWM voltages to keep one of the direct and quadrature currents at zero to thereby keep the electric machine at standstill.