Gate drive circuit and method of operating same

What is claimed is: 1. A gate drive circuit for applying a gate voltage to a gate of a semiconductor switching device, the gate drive circuit comprising: a gate drive controller providing one or more voltage commands for operating the semiconductor switching device; a plurality of primary gate resistors coupled between the gate drive controller and the semiconductor switching device; a plurality of secondary gate resistors connected in parallel with the primary gate resistors; a primary transistor connected in series with each of the primary gate resistors; and, one or more secondary transistors connected in parallel with the primary gate resistors, wherein one of the primary or secondary transistors receives the one or more voltage commands from the gate drive controller and provides one or more corresponding voltage levels to the semiconductor switching device so as to control the on-off behavior of the semiconductor switching device. 2. The gate drive circuit of claim 1 , wherein at least one secondary transistor is connected in series with each of the secondary gate resistors. 3. The gate drive circuit of claim 1 , wherein the semiconductor switching device comprises an insulated gate bipolar transistor (IGBT). 4. The gate drive circuit of claim 3 , wherein the IGBT is configured with a bridge circuit of a power converter of a wind-drive power generation system. 5. The gate drive circuit of claim 1 ., wherein the primary and secondary transistors comprise a metal-oxide-semiconductor field-effect transistor (MOSFET). 6. The gate drive circuit of claim 5 , further comprising at least one diode connected in series with the secondary MOSFETs. 7. The gate drive circuit of claim 1 , wherein the corresponding voltage levels comprise at least a first voltage and a second voltage, the first voltage being configured to turn on the semiconductor switching device via a first primary gate resistor, the first voltage being greater than a threshold voltage for the semiconductor switching device, the second voltage being configured to turn off the semiconductor switching device via a second primary gate resistor, the second voltage being less than the threshold voltage. 8. The gate drive circuit of claim 7 , wherein during turn off of the semiconductor switching device, the gate drive controller is further configured to apply a third voltage to the gate of the semiconductor switching device via a second secondary gate resistor for a first turn off period, the third voltage being less than the first voltage but greater than the second voltage. 9. The gate drive circuit of claim 8 , wherein the gate drive controller is further configured to apply a fourth voltage to the gate of the semiconductor switching device via a fourth secondary gate resistor for a second turn off period, the fourth voltage being less than the third voltage but greater than the second voltage. 10. The gate drive circuit of claim 9 , wherein during turn on of the semiconductor switching device, the gate drive controller is further configured to apply the fourth voltage to the gate of the semiconductor switching device via a third secondary gate resistor for a first turn on period, the fourth voltage being less than the third voltage but greater than the second voltage. 11. The gate drive circuit of claim 10 , wherein the gate drive controller is further configured to apply the third voltage to the gate of the semiconductor switching device via a first secondary gate resistor for a second turn on period, the third voltage being less than the first voltage but greater than the second voltage. 12. A bridge circuit used in a power converter of a power system, the bridge circuit comprising: a first insulated gate bipolar transistor (IGBT) having a gate, a collector, and an emitter; a second IGBT coupled in series with the first IGBT; a diode coupled in parallel with the first IGBT; a gate drive circuit configured to apply a voltage to the gate of the first IGBT, the gate drive circuit comprising: a gate drive controller providing one or more voltage commands for operating the first IGBT; a plurality of primary gate resistors coupled between the gate drive controller and the first IGBT; a plurality of gate resistors connected in parallel with the primary gate resistors; a primary transistor connected in series with each of the primary gate resistors; and, a secondary transistor connected in series with each of the secondary gate resistors, wherein one of the primary or secondary transistors receives the one or more voltage commands from the gate drive controller and provides one or more corresponding voltage levels to the semiconductor switching device via one of the primary or secondary gate resistors so as to control the on-off behavior of the semiconductor switching device. 13. The gate drive circuit of claim 12 , wherein the primary and secondary transistors comprise a metal-oxide-semiconductor field-effect transistor (MOSFET). 14. The gate drive circuit of claim 13 , further comprising at least one diode connected in series with the secondary MOSFETs. 15. The gate drive circuit of claim 12 , wherein the corresponding voltage levels comprise at least a first voltage and a second voltage, the first voltage configured to turn on the first IGBT via a first primary gate resistor, the first voltage being greater than a threshold voltage for the semiconductor switching device, the second voltage configured to turn off the first IGBT via a second primary gate resistor, the second voltage being less than the threshold voltage. 16. The gate drive circuit of claim 15 , wherein during turn off of the first IGBT, the gate drive controller is further configured to apply a third voltage to the gate of the first IGBT via a second secondary gate resistor for a first turn off period, the third voltage being less than the first voltage but greater than the second voltage. 17. The gate drive circuit of claim 16 , wherein the gate drive controller is further configured to apply a fourth voltage to the gate of the first IGBT via a fourth secondary gate resistor for a second turn off period, the fourth voltage being less than the third voltage but greater than the second voltage. 18. The gate drive circuit of claim 17 , wherein during turn on of the first IGBT, the gate drive controller is further configured to apply the fourth voltage to the gate of the first IGBT via a third secondary gate resistor for a first turn on period, the fourth voltage being less than the third voltage but greater than the second voltage, and wherein the gate drive controller is further configured to apply the third voltage to the gate of the semiconductor switching device via a first secondary gate resistor for a second turn on period, the third voltage being less than the first voltage but greater than the second voltage. 19. A. method of gating an insulated gate bipolar transistor (IGBT) used in a power converter of a wind-driven power generation system, the method. comprising: applying a first voltage via. a first primary gate resistor to a gate of the :IGBT to turn on the IGBT, the first voltage being greater than a threshold voltage for the IGBT; receiving a turn off signal to turn off the IGBT; and, subsequent to receiving the turn off signal, applying a second voltage via a second primary gate resistor to the gate of the IGBT to turn off the IGBT, the second voltage being less than the threshold voltage; wherein during turn off of the IGBT, the method further comprises applying one or more intermediate vol