Active clamp overvoltage protection for switching power device

What is claimed is: 1. A controller circuit for generating a gate drive signal on an output node of the controller circuit for driving a gate terminal of a power switch where the gate terminal controls the current flow between first and second power terminals of the power switch, the controller circuit comprising: a first gate drive circuit configured to receive an input control signal and to generate a first output signal as the gate drive signal to drive the gate terminal of the power switch to fully turn on and off the power switch responsive to the input control signal, the first output signal having a first gate voltage value to drive the gate terminal of the power switch to fully turn on the power switch; a protection circuit configured to receive a first voltage indicative of a voltage at a first power terminal of the power switch and to generate a fault detection indicator signal, the protection circuit asserting the fault detection indicator signal in response to the first voltage exceeding a predetermined voltage level; a second gate drive circuit configured to receive the fault detection indicator signal and to generate a second output signal as the gate drive signal to drive the gate terminal of the power switch responsive to the fault detection indicator signal, the second gate drive circuit comprising an impedance divider circuit having an output terminal coupled to the output node of the controller circuit to generate the second output signal having a slow assertion transition and having a peak voltage value being clamped at a second gate voltage value being a voltage value above a threshold voltage of the power switching device and less than the first gate voltage value, wherein while the power switch is in an off state in response to the input control signal and in response to the fault detection indicator signal being asserted, the second gate drive circuit asserts the second output signal to turn on the power switch at the second gate voltage value for a predetermined time duration. 2. The controller circuit of claim 1 , wherein the protection circuit comprises a hysteresis over-voltage detection circuit having a set voltage level and a reset voltage level, the set voltage level being higher than the reset voltage level, the hysteresis over-voltage detection circuit asserting the fault detection indicator signal in response to the first voltage being at or above the set voltage level and deasserting the fault detection indicator signal in response to the first voltage being at or below the reset voltage level. 3. The controller circuit of claim 2 , wherein in response to the hysteresis over-voltage detection circuit asserting the fault detection indicator signal, the second gate drive circuit asserts the second output signal after a first time period. 4. The controller circuit of claim 1 , wherein the second gate drive circuit asserts the second output signal to turn on the power switch at the second gate voltage value in response to a shorter time duration of the fault detection indicator signal being asserted and a predetermined fixed time duration. 5. The controller circuit of claim 1 , wherein the protection circuit is disabled in response to the input control signal being asserted to turn on the power switch and the protection circuit is enabled a second time period after the input control signal is deasserted to turn off the power switch. 6. The controller circuit of claim 1 , wherein the first gate drive circuit is disabled in response to the fault detection indicator signal being asserted. 7. The controller circuit of claim 1 , wherein: the first gate drive circuit comprises a first transistor, a first impedance, a second impedance and a second transistor connected in series between a positive power supply voltage and a ground voltage, a common node between the first impedance and the second impedance being the output node; and the second gate drive circuit comprises a third transistor, a third impedance, a fourth impedance and a fourth transistor connected in series between the positive power supply voltage and the ground voltage, a common node between the third impedance and the fourth impedance being the output node, wherein the first gate drive circuit turns on the first transistor and turns off the second transistor to assert the first output signal to fully turn on the power switch and the first gate drive circuit turns off the first transistor and turns on the second transistor to deassert the first output signal to fully turn off the power switch; and wherein in response to the fault detection indicator signal being asserted, the second gate drive circuit turns on the third transistor and the fourth transistor to assert the second output signal at the second gate voltage value to turn on the power switch. 8. The controller circuit of claim 7 , wherein the second output signal has a slow assertion transition as a result of the third impedance and the fourth impedance forming the impedance divider in response to the third transistor and the fourth transistor being turned on. 9. The controller circuit of claim 7 , wherein the second output signal is clamped at the second gate voltage value as a result of the third impedance and the fourth impedance forming the impedance divider in response to the third transistor and the fourth transistor being turned on, the second gate voltage value being a divided down voltage of the positive power supply voltage as a function of the third impedance and the fourth impedance. 10. The controller circuit of claim 7 , wherein in response to the fault detection indicator signal being asserted, the first gate drive circuit turns off the second transistor and the second gate drive circuit turns on the third transistor and the fourth transistor. 11. The controller circuit of claim 10 , wherein in response to the fault detection indicator signal being deasserted or the expiration of a fixed time duration, the second gate drive circuit turns off the third transistor and the fourth transistor, the fourth transistor being turned off a third time period after the third transistor is turned off. 12. The controller circuit of claim 11 , wherein in response to the fourth transistor being turned off, the first gate drive circuit turns on the second transistor to drive the first output signal to a voltage level to keep the power switch turned off. 13. The controller circuit of claim 1 , wherein the power switch comprises an insulated gate bipolar transistor (IGBT) device. 14. A method of generating a gate drive signal for driving a gate terminal of a power switch where the gate terminal controls the current flow between first and second power terminals of the power switch, the method comprising: monitoring a feedback voltage indicative of a voltage across the first and second power terminals of the power switch during an off-period of the power switch; determining the feedback voltage exceeding a first voltage level during the off-period of the power switch; in response to the determining, disabling a normal gate drive signal driving the gate terminal of the power switch to turn off the power switch during the off-duration; in response to the determining, enabling a protection gate drive signal; generating a clamped gate drive signal having a clamped gate drive voltage value and applying the clamped gate drive signal to turn on the power switch in response to the determining that the feedback voltage exceeds the first voltage level during the off-period of the power switch; monitoring the feedback voltage to determine if the feedback voltage has decreased below a second voltage level, the