Apparatus and methods for protecting radio frequency amplifiers from overdrive

What is claimed is: 1. A radio frequency amplification system comprising: a plurality of radio frequency amplification stages configured to amplify a radio frequency input signal and including a first amplification stage and a second amplification stage that is subsequent to the first amplification stage in a signal path, the first amplification stage including a first stage field-effect transistor, and the second amplification stage including a second stage field-effect transistor and a gate-to-drain feedback circuit electrically connected between a gate and a drain of the second stage field-effect transistor; and an overdrive detection circuit configured to sense a drain current of the first stage field-effect transistor to detect when an overdrive condition is present, and to decrease an impedance of the gate-to-drain feedback circuit in response to detection of the overdrive condition such that a gain of the second stage field-effect transistor is reduced. 2. The radio frequency amplification system of claim 1 further including a sense resistor configured to receive the drain current. 3. The radio frequency amplification system of claim 2 wherein the overdrive detection circuit includes a comparator configured to compare a voltage across the sense resistor to a reference voltage, and to control the impedance of the gate-to-drain feedback circuit based on the comparison. 4. The radio frequency amplification system of claim 1 wherein the plurality of radio frequency amplification stages further includes one or more intermediate amplification stages arranged between an output of the first amplification stage and an input of the second amplification stage. 5. The radio frequency amplification system of claim 1 wherein the gate-to-drain feedback circuit includes a feedback field-effect transistor electrically connected in parallel with a first resistor, the overdrive detection circuit further configured to control a gate voltage of the feedback field-effect transistor. 6. The radio frequency amplification system of claim 5 wherein the overdrive detection circuit is further configured to control the gate voltage of the feedback field-effect transistor to either turn on the feedback field-effect transistor or to turn off the field-effect transistor. 7. The radio frequency amplification system of claim 5 wherein the overdrive detection circuit is further configured to control the gate voltage of the feedback field-effect transistor with an analog voltage that is based on a magnitude of the drain current. 8. The radio frequency amplification system of claim 1 wherein the plurality of radio frequency amplification stages includes a plurality of power amplifier stages. 9. The radio frequency amplification system of claim 1 wherein the plurality of radio frequency amplification stages includes a plurality of low noise amplifier stages. 10. The radio frequency amplification system of claim 1 wherein the plurality of radio frequency amplification stages includes a plurality of driver amplifier stages. 11. A method of overdrive protection of a radio frequency amplifier, the method comprising: providing amplification to a radio frequency signal using a first amplification stage and a second amplification stage that is subsequent to the first amplification stage in a signal path, the first amplification stage including a first stage field-effect transistor, and the second amplification stage including a second stage field-effect transistor and a gate-to-drain feedback circuit electrically connected between a gate and a drain of the second stage field-effect transistor; detecting an overdrive condition of the radio frequency amplifier based on sensing a drain current of the first stage field-effect transistor; and decreasing an impedance of the gate-to-drain feedback circuit in response to detecting the overdrive condition such that a gain of the second stage field-effect transistor is reduced. 12. The method of claim 11 wherein detecting the overdrive condition includes providing the drain current to a sense resistor and comparing a voltage across the sense resistor to a reference voltage. 13. The method of claim 11 wherein decreasing the impedance of the gate-to-drain feedback circuit includes gradually decreasing the impedance of the gate-to-drain feedback circuit to inhibit to a sudden change in the gain of the second stage field-effect transistor. 14. The method of claim 13 further comprising generating an analog voltage based on a magnitude of the drain current and controlling a gate voltage of a feedback field-effect transistor of the gate-to-drain feedback circuit using the analog voltage. 15. A wireless device comprising: a transceiver configured to generate a radio frequency signal; a power amplifier including a plurality of power amplifier stages arranged in a cascade, the plurality of power amplifier stages configured to amplify the radio frequency signal and including a first amplification stage and a second amplification stage that is subsequent to the first amplification stage in a signal path, the first amplification stage including a first stage field-effect transistor, and the second amplification stage including a second stage field-effect transistor and a gate-to-drain feedback circuit electrically connected between a gate and a drain of the second stage field-effect transistor; and an overdrive detection circuit configured to sense a drain current of the first stage field-effect transistor to detect when an overdrive condition is present, the overdrive detection circuit further configured to decrease an impedance of the gate-to-drain feedback circuit in response to detection of the overdrive condition such that a gain of the second stage field-effect transistor is reduced. 16. The wireless device of claim 15 further including a sense resistor configured to receive the drain current. 17. The wireless device of claim 16 wherein the overdrive detection circuit includes a comparator configured to compare a voltage across the sense resistor to a reference voltage, and to control the impedance of the gate-to-drain feedback circuit based on the comparison. 18. The wireless device of claim 15 wherein the gate-to-drain feedback circuit includes a feedback field-effect transistor electrically connected in parallel with a first resistor, the overdrive detection circuit further configured to control a gate voltage of the feedback field-effect transistor. 19. The wireless device of claim 18 wherein the overdrive detection circuit is further configured to control the gate voltage of the feedback field-effect transistor to either turn on the feedback field-effect transistor or to turn off the field-effect transistor. 20. The wireless device of claim 18 wherein the overdrive detection circuit is further configured to control the gate voltage of the feedback field-effect transistor with an analog voltage that is based on a magnitude of the drain current.