Methods, systems and apparatus for adjusting modulation index to improve linearity of phase voltage commands

What is claimed is: 1. A method for adjusting voltage command signals from a current regulator in an electric motor drive system that further comprises a multi-phase machine having machine terminals, the method comprising: computing a modulation index and a voltage angle based on voltage command signals provided from the current regulator and a DC input voltage, wherein the voltage angle is computed as a function of the voltage command signals; generating, via a lookup table, an adjusted modulation index using inputs comprising the modulation index and a phase current that is a function of a d-axis current command and a q-axis current command; and computing adjusted voltage command signals using the adjusted modulation index, the voltage angle and the DC input voltage, wherein the adjusted voltage command signals cause magnitudes of phase voltage command signals to be adjusted to substantially match applied machine terminal voltages V AN , V BN , V CN that are applied at the machine terminals. 2. A method according to claim 1 , wherein the modulation index is a normalized fundamental reference voltage that is a ratio of a peak fundamental phase voltage (Vph) to a maximum available voltage. 3. A method according to claim 1 , wherein the step of computing adjusted voltage command signals using the adjusted modulation index, comprises: computing adjusted voltage command signals using inputs comprising the adjusted modulation index, the voltage angle and the DC input voltage. 4. A method according to claim 1 , wherein the lookup table is a two-dimensional lookup table that receives the modulation index and the phase current, and wherein the adjusted modulation index is a function of both the modulation index and the phase current. 5. A method according to claim 1 , the method further comprising: generating stationary reference frame voltage command signals by performing a dq-to-αβ transformation on the adjusted voltage command signals; generating the phase voltage command signals based on the stationary reference frame voltage command signals; generating switching vector signals based on the phase voltage command signals; generating three-phase alternating current voltage signal waveforms based on switching vector signals and a DC input voltage; and applying the three-phase alternating current voltage signal waveforms to the machine terminals, wherein the adjusted voltage command signals cause magnitudes of the phase voltage command signals to be adjusted to substantially match applied machine terminal voltages V AN , V BN , V CN despite non-linearities in the electric motor drive system. 6. A method according to claim 1 , wherein the voltage command signals comprise a synchronous reference frame d-axis voltage command signal and a synchronous reference frame q-axis voltage command signal, and wherein the adjusted voltage command signals comprise an adjusted synchronous reference frame d-axis voltage command signal and an adjusted synchronous reference frame q-axis voltage command signal. 7. A method according to claim 1 , wherein the adjusted modulation index is used to adjust the voltage command signals and generate the adjusted voltage command signals so that the applied machine terminal voltages V AN , V BN , V CN substantially match the phase voltage command signals. 8. An electric motor drive system, comprising: a DC input voltage; a multi-phase machine having machine terminals; a current regulator; and a voltage command adjustment processor comprising a lookup table, wherein the voltage command processor is designed to: receive voltage command signals from the current regulator; compute a modulation index and a voltage angle based on voltage command signals and the DC input voltage, wherein the voltage angle is computed as a function of the voltage command signals; generate, via the lookup table, an adjusted modulation index using inputs comprising the modulation index and a phase current that is a function of a d-axis current command and a q-axis current command; and compute adjusted voltage command signals using inputs comprising the adjusted modulation index, the voltage angle and the DC input voltage, wherein the adjusted voltage command signals cause magnitudes of phase voltage command signals to be adjusted to substantially match applied machine terminal voltages V AN , V BN , V CN that are applied at the machine terminals. 9. An electric motor drive system according to claim 8 , wherein the voltage command adjustment processor comprises: a modulation index computation module designed to receive the voltage command signals from the current regulator, and to compute the modulation index based on the voltage command signals; and a voltage command adjustment module designed to compute the adjusted voltage command signals based on the adjusted modulation index. 10. An electric motor drive system according to claim 9 , wherein the modulation index is a normalized fundamental reference voltage that is a ratio of a peak fundamental phase voltage (Vph) to a maximum available voltage. 11. An electric motor drive system according to claim 9 , wherein the lookup table is a two-dimensional lookup table that receives the modulation index and the phase current, and wherein the adjusted modulation index is a function of both the modulation index and the phase current. 12. An electric motor drive system according to claim 8 , further comprising: a synchronous-to-stationary transformation module that generates stationary reference frame voltage command signals by performing a dq-to-αβ transformation on the adjusted voltage command signals; an αβ-to-abc transformation module that receives the stationary reference frame voltage command signals, and generates phase voltage command signals; a pulse width modulation module that generates switching vector signals based on the phase voltage command signals; an inverter module that generates three-phase alternating current voltage signal waveforms based on switching vector signals and a DC input, wherein the multi-phase machine is coupled to the inverter module and the three-phase alternating current voltage signal waveforms are applied to the machine terminals, wherein the adjusted voltage command signals cause magnitudes of the phase voltage command signals to be adjusted to substantially match applied machine terminal voltage V AN , V BN , V CN despite non-linearities in the multi-phase machine and the inverter module. 13. An electric motor drive system according to claim 8 , wherein the voltage command signals comprise a synchronous reference frame d-axis voltage command signal and a synchronous reference frame q-axis voltage command signal, and wherein the adjusted voltage command signals comprise an adjusted synchronous reference frame d-axis voltage command signal and an adjusted synchronous reference frame q-axis voltage command signal. 14. An electric motor drive system according to claim 8 , wherein the adjusted modulation index is used to adjust the voltage command signals and generate the adjusted voltage command signals so that the applied machine terminal voltages V AN , V BN , V CN substantially match the phase voltage command signals. 15. In a system comprising an electric motor drive system that comprises a current regulator and a multi-phase electric machine having machine terminals, a method for controlling the multi-phase electric machine, the method comprising: computing a modulation index and a voltage angle based on voltage command signals provided from the current regulator and a DC input voltage, wherein the voltage angle is