Inductance-based estimation of rotor magnet temperature

What is claimed is: 1. A method for estimating a magnet temperature of a rotor magnet within a rotary electric machine having a rotor that includes the rotor magnet, the method comprising: while the rotor is stationary: measuring an angular position of the rotor using a position sensor; injecting a high-frequency voltage component onto a control voltage of the electric machine, via a controller, to thereby generate an adjusted voltage command; extracting a high-frequency component of a resulting current as an extracted high-frequency component, wherein the resulting current corresponds to the adjusted voltage command; calculating an inductance value of the electric machine using the extracted high-frequency component of the resulting current; and estimating a temperature of the rotor magnet using the calculated inductance value and the angular position to thereby generate an estimated magnet temperature; and when the rotor is no longer stationary, controlling an operation of the electric machine using the estimated magnet temperature. 2. The method of claim 1 , wherein extracting the high-frequency component of the resulting current includes using a band pass filter. 3. The method of claim 1 , wherein the position sensor is a resolver, the method further comprising: executing an offset learning process of the resolver via the controller when the rotor is stationary. 4. The method of claim 1 , the method further comprising: receiving a torque command for the electric machine via the controller; converting the torque command into d-axis and q-axis current commands via the controller; and converting the d-axis and q-axis current commands into d-axis and q-axis voltage commands prior to injecting the high-frequency voltage component, wherein the d-axis and q-axis voltage commands form the control voltage. 5. The method of claim 1 , wherein the high-frequency voltage component has a calibrated amplitude and a calibrated frequency, and is a square wave or a sinusoidal wave. 6. The method of claim 5 , wherein the calibrated amplitude is in a range of 20V to 50V, and the calibrated frequency is in a range of 500Hz to 2kHz. 7. The method of claim 5 , wherein the electric machine is connected to a power inverter module (“PIM”) having a switching frequency, and wherein the calibrated frequency of the high-frequency voltage component is less than half of the switching frequency of the PIM. 8. The method of claim 1 , wherein the electric machine is connected to a load, and wherein the operation of the electric machine includes delivering motor torque to the load via the rotor. 9. The method of claim 1 , wherein the electric machine is connected to a load, and wherein the operation of the electric machine includes diagnosing a condition of the electric machine and/or regulating a temperature of the electric machine. 10. The method of claim 9 , wherein the load is a road wheel of a motor vehicle. 11. An electric powertrain comprising: a power inverter module (“PIM”); a rotary electric machine connected to the PIM, and having a rotor with a plurality of rotor magnets; a load coupled to the rotary electric machine; a position sensor configured to measure an angular position of the rotor; and a controller in communication with the PIM and the rotary electric machine, wherein the controller is configured to: when the rotor is stationary: inject a high-frequency voltage component onto a control voltage of the electric machine to thereby generate an adjusted voltage command; extract a high-frequency component of a resulting current as an extracted high-frequency component, wherein the resulting current corresponds to the adjusted voltage command; calculate an inductance value of the electric machine using the extracted high-frequency component of the resulting current; and estimate a temperature of the rotor magnets using the calculated inductance value and the angular position to thereby generate an estimated magnet temperature; and when the rotor is no longer stationary, to control an operation of the electric machine using the estimated magnet temperature. 12. The electric powertrain of claim 11 , wherein the controller is configured to extract the high-frequency component of the resulting current using a band pass filter. 13. The electric powertrain of claim 12 , wherein the position sensor is a resolver, and wherein the controller is configured to execute a resolver offset learning process when the rotor is stationary. 14. The electric powertrain of claim 11 , wherein the controller is configured to: receive a torque command for the electric machine; convert the torque command into d-axis and q-axis current commands via the controller; and convert the d-axis and q-axis current commands into d-axis and q-axis voltage commands prior to injecting the high-frequency voltage component, wherein the d-axis and q-axis voltage commands form the control voltage. 15. The electric powertrain of claim 11 , wherein the high-frequency voltage component has a calibrated amplitude and a calibrated frequency, and is a square wave or a sinusoidal wave. 16. The electric powertrain of claim 15 , wherein the calibrated amplitude is in a range of 20V to 50V and the calibrated frequency is in a range of 500Hz to 2kHz. 17. The electric powertrain of claim 11 , wherein the PIM has a switching frequency, and wherein the calibrated frequency of the high-frequency voltage component is less than half of the switching frequency of the PIM. 18. The electric powertrain of claim 11 , wherein the load is a road wheel of a motor vehicle, the rotor is connected to the road wheel, and the operation of the electric machine includes delivering motor torque to the road wheel via the rotor. 19. The electric powertrain of claim 11 , wherein the operation of the electric machine includes diagnosing a condition of the electric machine. 20. The electric powertrain if claim 11 , wherein the operation of the electric machine includes regulating a temperature of the electric machine.