Systems and methods for power transfer based on resonance coupling of inductors

What is claimed is: 1. An integrated circuit (IC), comprising: a first resonator circuit that receives a supply voltage at a first node and that includes: a switching device connected between the first node and a first ground potential; a first inductor that is connected between the first node and the first ground potential; a second inductor that is connected between the first node and the first ground potential; a first inductor capacitor (LC) tank; and first and second resistors connected between the switching device and the LC tank; a second resonator circuit that outputs power to a load and that includes: a third inductor that is inductively coupled to the first inductor across an isolation barrier and that is connected to a second ground potential, wherein the second ground potential is different than the first ground potential; a fourth inductor that is inductively coupled to the second inductor across the isolation barrier and that is connected to the second ground potential, wherein the load draws power from a second node between the third and fourth inductors; and a second LC tank including a plurality of switches; a voltage divider that is connected to the second node; and a regulator circuit that generates a signal based on a comparison of an output voltage of the voltage divider with a reference voltage, wherein the plurality of switches of the second LC tank switch based on a state of the signal. 2. The IC of claim 1 further comprising two diodes that are connected in parallel with the third and fourth inductors, wherein the load draws power from a second node between the two diodes. 3. The IC of claim 1 further comprising: a transmitter that transmits the signal across the isolation barrier; and a receiver that receives the signal across the isolation barrier from the transmitter and that outputs a second signal based on the received signal, wherein the switching device switches based on a state of the second signal. 4. The IC of claim 3 wherein switches of the first LC tank switch based on a complement of the second signal. 5. The IC of claim 1 further comprising a resistor and a capacitor that are connected to the second node between the third and fourth inductors. 6. The IC of claim 1 wherein a voltage output to the load has a magnitude that is less than or equal to the supply voltage. 7. The IC of claim 1 wherein: the first inductor is implemented on a first layer of the IC; the third inductor is implemented on a second layer of the IC; and the first and second layers are different. 8. The IC of claim 1 wherein: the first and third inductors are implemented on one layer of the IC; and the IC includes a dielectric disposed between windings of the first and third inductors. 9. The IC of claim 1 further comprising the isolation barrier. 10. The IC of claim 1 wherein the second resonator circuit further includes a bypass capacitor that is connected between (i) the second ground potential and (ii) a second node between the third and fourth inductors. 11. The IC of claim 1 wherein: the first LC tank comprises: first and second capacitors; and a plurality of switches that control a frequency of charging and discharging of the first LC tank; and the first resonator circuit further includes a variable capacitor array connected in series with one of the first and second capacitors and in parallel with the plurality of switches. 12. The IC of claim 11 wherein the variable capacitor array is configured to adjust a first capacitance of the first resonator circuit to a value that is greater than a second capacitance of the first and second capacitors. 13. The IC of claim 11 wherein the variable capacitor array is configured to adjust a first capacitance of the first resonator circuit to a value that is less than a second capacitance of the first and second capacitors. 14. The IC of claim 11 wherein the IC further includes: a transmitter that transmits the signal across the isolation barrier; a receiver that receives the signal from the transmitter across the isolation barrier and that outputs a second signal based on the signal; and a control module that, based on a clock signal and the second signal from the receiver, selectively adjusts a capacitance of the first resonator circuit. 15. The IC of claim 14 wherein the control module is configured to adjust the capacitance of the first resonator circuit to one of: greater than a second capacitance of the first and second capacitors; and less than the second capacitance of the first and second capacitors. 16. The IC of claim 1 wherein the IC further includes: a transmitter that transmits the signal across the isolation barrier; a receiver that receives the signal from the transmitter across the isolation barrier and that outputs a second signal based on the first signal; and a control module that, based on a clock signal and the second signal from the receiver, controls switching of the first resonator circuit. 17. The IC of claim 15 wherein the regulator circuit includes a hysteretic comparator. 18. An integrated circuit (IC), comprising: a first resonator circuit that receives a supply voltage at a first node and that includes: a switching device connected directly to the first node and connected to a first ground potential; a first inductor that is connected between the first node and the first ground potential; a second inductor that is connected between the first node and the first ground potential; a first inductor capacitor (LC) tank; and first and second resistors connected between the switching device and the LC tank; a second resonator circuit that outputs power to a load and that includes: a third inductor that is inductively coupled to the first inductor across an isolation barrier and that is connected to a second ground potential, wherein the second ground potential is different than the first ground potential; and a fourth inductor that is inductively coupled to the second inductor across the isolation barrier and that is connected to the second ground potential, wherein the load draws power from a second node between the third and fourth inductors; and a second LC tank including a plurality of switches; a voltage divider that is connected to the second node; and a regulator circuit that generates a signal based on a comparison of an output voltage of the voltage divider with a reference voltage, wherein the plurality of switches of the second LC tank switch based on a state of the signal. 19. An integrated circuit (IC), comprising: a first resonator circuit that receives a supply voltage at a first node and that includes: a switching device connected between the first node and a first ground potential; a first inductor that is connected between the first node and the first ground potential; a second inductor that is connected between the first node and the first ground potential; a first inductor capacitor (LC) tank comprising: first and second capacitors; and a plurality of switches that control a frequency of charging and discharging of the first LC tank; and a variable capacitor array connected in series with one of the first and second capacitors and in parallel with the plurality of switches; a second resonator circuit that outputs power to a load and that includes: a third inductor that is inductively coupled to the first inductor across an isolation barrier and that is connected to a second ground potential, wherein the second ground potential is