Switching converter for power domain separation

What is claimed is: 1. A power domain isolation system without requiring a transformer, the system configured for bidirectional power signal communication between first and second power domains, the system comprising: a reactive circuit; an input network coupled to the first power domain and having first and second input nodes that are coupled in parallel with the reactive circuit via respective first and second current control circuits; and an output network coupled to the second power domain and having first and second output nodes that are coupled in parallel with the reactive circuit via respective third and fourth current control circuits; wherein the first and second current control circuits are configured to couple the reactive circuit to the input nodes when the third and fourth current control circuits are configured to electrically isolate the reactive circuit from the output nodes; wherein the first and second current control circuits are configured to electrically isolate the reactive circuit from the input nodes when the third and fourth current control circuits are configured to couple the reactive circuit to the output nodes; and wherein at least one of the first, second, third, and fourth current control circuits comprises back-to-back first and second FET devices, wherein the first FET device has a body diode cathode coupled to the first input node and a body diode anode coupled to a first intermediate node, and the second FET device has a body diode cathode coupled to a terminal of the reactive circuit and a body diode anode coupled to the first intermediate node. 2. The system of claim 1 , wherein the first and second current control circuits are configured to couple the reactive circuit to the input nodes during a first phase, wherein the first and second current control circuits are configured to electrically isolate the reactive circuit from the input nodes during a second phase, and wherein the first and second phases are non-overlapping in time. 3. The system of claim 1 , further comprising a processor circuit configured to provide respective control signals to each of the first, second, third, and fourth current control circuits to selectively enable or disable current flow therethrough. 4. The system of claim 1 , wherein each of the first, second, third, and fourth current control circuits comprises a respective pair of back-to-back FET devices. 5. The system of claim 4 , wherein each of the first, second, third, and fourth current control circuits comprises a respective different instance of first and second FET devices, wherein an anode terminal of a body diode of the first FET device is coupled to an anode terminal of a body diode of the second FET device. 6. The system of claim 4 , further comprising a processor circuit configured to provide substantially a same first PWM control signals to each of the FET devices in the first and second current control circuits, and to provide second PWM control signals to each of the FET devices in the third and fourth current control circuits. 7. The system of claim 6 , wherein the processor circuit is configured to provide a blanking period between transitions in the first and second PWM control signals, wherein during the blanking period the control signals command all of the FET devices to be in a high impedance state. 8. The system of claim 1 , wherein the reactive network comprises a capacitor. 9. The system of claim 8 , wherein the reactive network comprises the capacitor coupled in series with at least one of an inductor and a parallel inductor-capacitor (LC) circuit. 10. The system of claim 1 , wherein the input nodes are configured to receive a source signal having a first reference voltage level and the output nodes are configured to provide an output signal at a different second reference voltage level. 11. The system of claim 10 , wherein a magnitude difference between the source signal and the output signal is less than about 10 volts. 12. The system of claim 11 , wherein: the reactive circuit comprises a flying capacitor coupled between the first and second terminals; and switches in the first, second, third, and fourth current control circuits have a switching frequency between about 300 kHz to 400 kHz and a duty cycle of about 50%. 13. A power domain switching module for decoupling a first power signal having a first reference level from a second power signal having a second reference level, wherein a difference between the first and second reference levels is between about 1 and 10 volts, the module comprising: a bidirectional signal-side isolation path comprising at least first and second back-to-back FET assemblies coupled in series between a signal-side first node and a signal-side second node, wherein a first FET of the first back-to-back FET assembly has a body diode cathode coupled to the signal-side first node and a body diode anode coupled to a first intermediate node and a second FET of the first back-to-back FET assembly has a body diode anode coupled to the first intermediate node; a bidirectional reference-side isolation path comprising at least third and fourth back-to-back FET assemblies coupled in series between a reference-side first node and a reference-side second node; and an energy storage circuit coupled to a first intermediate node in the signal-side isolation path between the first and second FET assemblies, and coupled to a second intermediate node in the reference-side isolation path between the third and fourth FET assemblies. 14. The module of claim 13 , wherein: in a first operating mode, the first and third back-to-back FET assemblies are configured in a low impedance state and the second and fourth back-to-back FET assemblies are configured in a high impedance state, and in a second operating mode that is mutually exclusive with the first operating mode, the first and third back-to-back FET assemblies are configured in a high impedance state and the second and fourth back-to-back FET assemblies are configured in a low impedance state. 15. The module of claim 13 , wherein each of the back-to-back FET assemblies comprises first and second FET devices coupled in series and having oppositely oriented body diodes. 16. The module of claim 15 , further comprising a processor circuit configured to provide first PWM control signals to the FET devices in the first and third FET assemblies, and to provide second PWM control signals to the FET devices in the second and fourth FET assemblies, wherein the PWM control signals have a duty cycle of about 50%. 17. The module of claim 16 , wherein the processor circuit is configured to provide the first and second PWM signals with a blanking period between adjacent pulses. 18. An integrated circuit for use in a power domain isolation device without requiring a transformer, the power domain isolation device comprising a power signal input and a power signal output, wherein the power signal input is configured to receive an input signal referenced to a first voltage level and the power signal output is configured to provide an output signal referenced to a different voltage level, the integrated circuit comprising: a first pair of series-coupled FET devices coupled between a first terminal of the power signal input and an intermediate node, wherein a first FET of the first pair of series-coupled FET devices has a body diode cathode coupled to the first input node and a body diode anode coupled to a first intermediate node and a second FET of the first pair of series-coupled FET devices has a body diode cathode coup