Advanced overvoltage protection strategy for wireless power transfer

The invention claimed is: 1. A wireless power receiving circuit, comprising: a transistor based rectifier configured to receive an AC input voltage at first and second nodes, the transistor based rectifier comprising a transistor based single phase full wave rectifier having a first high-side transistor coupled between the first node and a third node, a first low-side transistor coupled between the third node and ground, a second high-side transistor coupled between the second node and the third node, and a second low-side transistor coupled between the third node and ground; control logic configured to receive an overvoltage signal and generate control signals for controlling actuation of the first high-side transistor, the first low-side transistor, the second high-side transistor, and the second low-side transistor so as to cause the transistor based rectifier to produce a rectified output voltage at the third node from the AC input voltage; and a comparator configured to compare the rectified output voltage to a reference voltage and assert the overvoltage signal when the rectified output voltage is greater than the reference voltage; wherein the control logic asserts the control signals to cause the first high-side transistor, the first low-side transistor, the second high-side transistor, and the second high-side transistor to be on simultaneously in response to assertion of the overvoltage signal; and wherein the control logic asserts two of the control signals to switchingly turn on either the first high-side transistor and the second low-side transistor or the second high-side transistor and the first low-side transistor in an absence of assertion of the overvoltage signal. 2. The wireless power receiving circuit of claim 1 , wherein the control signals comprise first, second, third, and fourth control signals; and wherein: the first high-side transistor comprises a first n-channel transistor having a drain coupled to the third node, a source coupled to the first node, and a gate coupled to the first control signal; the first low-side transistor comprises a third n-channel transistor having a drain coupled to the first node, a source coupled to ground, and a gate coupled to the third control signal; the second high-side transistor comprises a second n-channel transistor having a drain coupled to the third node, a source coupled to the second node, and a gate coupled to the second control signal; and the second low-side transistor comprises a fourth n-channel transistor having a drain coupled to the second node, a source coupled to ground, and a gate coupled to the fourth control signal. 3. The wireless power receiving circuit of claim 2 , wherein the control logic is configured to assert the first, second, third, and fourth control signals to turn on the first, second, third, and fourth n-channel transistors in response to assertion of the overvoltage signal. 4. The wireless power receiving circuit of claim 3 , wherein the control logic is configured to switch between asserting the first and fourth control signals, and asserting the second and third control signals, in an absence of assertion of the overvoltage signal. 5. The wireless power receiving circuit of claim 1 , further comprising a power supply circuit generating an output signal from the rectified output voltage. 6. The wireless power receiving circuit of claim 5 , further comprising a load powered by the output signal. 7. The wireless power receiving circuit of claim 6 , wherein the load comprises a battery charging circuit. 8. The wireless power receiving circuit of claim 6 , wherein the load comprises a battery. 9. The wireless power receiving circuit of claim 5 , further comprising a low dropout amplifier generating a low voltage output for powering the control logic. 10. The wireless power receiving circuit of claim 1 , further comprising a power receiving coil wirelessly receiving transmitted power and producing therefrom the AC input voltage. 11. The wireless power receiving circuit of claim 1 , further comprising a low dropout amplifier configured to receive the rectified output voltage as input, a capacitor, and a switch connected between an output of the low dropout amplifier and the capacitor; wherein the switch is configured to connect the output of the low dropout amplifier to the capacitor so that a low voltage output is formed across the capacitor, in an absence of assertion of the overvoltage signal, the low voltage output for powering the control logic. 12. The wireless power receiving circuit of claim 1 , wherein the control logic asserts the control signals to cause the first high-side transistor, the first low-side transistor, the second high-side transistor, and the second low-side transistor to be on simultaneously in response to assertion of the overvoltage signal by progressively asserting different ones of the control signals over time until each control signal is asserted in response to assertion of the overvoltage signal, thereby progressively turning on different ones of the first high-side transistor, the first low-side transistor, the second high-side transistor, and the second low-side transistor over time until each of the first high-side transistor, the first low-side transistor, the second high-side transistor, and the second low-side transistor is simultaneously on. 13. A method, comprising: receiving power wirelessly; rectifying the received power to produce a rectified voltage using a single phase full wave rectifier having two high-side transistors and two low-side transistors by alternating between turning on different pairs of transistors from among the two high-side transistors and the two low-side transistors; and comparing the rectified voltage to a reference voltage, and: a) when the rectified voltage is greater than the reference voltage, causing the two high-side transistors and the two low-side transistors to be turned on simultaneously; and b) when the rectified voltage is less than the reference voltage, continuing to alternate between turning on different pairs of transistors from among the two high-side transistors and the two low-side transistors. 14. The method of claim 13 , further comprising generating a power signal from the rectified voltage and powering a battery charging circuit using the power signal. 15. The method of claim 13 , further comprising generating a logic circuit power signal from the rectified voltage and using the logic circuit power signal to power control logic that performs a) and b). 16. An electronic device, comprising: a battery; a battery charging circuit; a receiver coil receiving wirelessly transmitted power and generating an AC input voltage therefrom; and a wireless power receiving circuit powering the battery charging circuit, the wireless power receiving circuit comprising: a single phase full wave rectifier receiving the AC input voltage at first and second nodes, the single phase full wave rectifier having a first high-side transistor coupled between the first node and a third node, a first low-side transistor coupled between the third node and ground, a second high-side transistor coupled between the second node and the third node, and a second low-side transistor coupled between the third node and ground; control logic receiving an overvoltage signal and generating control signals for controlling actuation of the first high-side transistor, the first low-side transistor, the second high-side transistor, and the second low-side transistor based upon the overvoltage signal to cause the single phase full wave rectifier to produce