Device for transferring power from a first circuit to a second circuit

What is claimed is: 1. A system for transferring power from a first circuit to a second circuit by a differential signal generated in the first circuit, the system comprising: a first isolation element for transmitting a first component of the differential signal between the first and second circuits; a second isolation element for transmitting a second component of the differential signal between the first and second circuits, the second component being a complement of the first component; a digital rectifier coupled to the first and second isolation elements for generating a rectified voltage in response to the first and second components of the differential signal; circuitry for monitoring the rectified voltage and generating a signal representative of the rectified voltage; a controller for changing the rectified voltage in response to the signal representative of the rectified voltage; and a switch coupled to the output of the digital rectifier, wherein the state of the switch is controlled by the controller in response to the signal representative of the rectified voltage. 2. The system of claim 1 wherein the first and second isolation elements are capacitors. 3. The system of claim 1 further comprising a variable resistance coupled to the output of the digital rectifier, wherein the controller controls the variable resistance. 4. The system of claim 1 further comprising a plurality of rectification modules that are able to be coupled in parallel, each rectification module having a resistance associated therewith, wherein the controller couples and decouples at least one of the rectification modules in response to the signal representative of the rectified voltage. 5. The system of claim 1 wherein the circuitry for monitoring includes a power on reset device for monitoring the rectified voltage and for enabling other devices in the circuitry for monitoring. 6. The system of claim 1 wherein the circuitry for monitoring includes a bandgap generator for generating a reference voltage and a comparator for comparing the reference voltage to the rectified voltage, wherein the signal representative of the rectified voltage is generated by the comparator. 7. The system of claim 1 wherein the differential signal has a first state in response to the voltage at the first isolation element being greater than the voltage at the second isolation element, and a second state in response to the voltage at the second isolation element being greater than the voltage at the first isolation element, and wherein the digital rectifier includes: a first switch coupled between the first isolation element and a node, the first switch for passing current in response to the differential signal being in the first state and for blocking current in response to the differential signal being in the second state; a second switch coupled between the second isolation element and the node, the second switch for blocking current in response to the differential signal being in the first state and for passing current in response to the differential signal being in the second state; a third switch coupled between the first isolation element and a ground, the third switch for blocking current in response to the differential signal being in the first state and for passing current in response to the differential signal being in the second state; and a fourth switch coupled between the second isolation element and the ground, the second switch for passing current in response to the differential signal being in the first state and for blocking current in response to the differential signal being in the second state. 8. The system of claim 7 further comprising: a first resistance coupled between the first switch and the first isolation element; a second resistance coupled between the second switch and the second isolation element; a third resistance coupled between the third switch and the first isolation element; and a fourth resistance coupled between the fourth switch and the second isolation element; the first, second, third, and fourth resistances for isolating the isolation elements from at least one capacitance in the system. 9. The system of claim 8 wherein the value of the first resistance is approximately equal to four times a high voltage at the first isolation element divided by the maximum current flow through the first isolation element. 10. The system of claim 1 wherein the first circuit includes a first ground, and the second circuit includes a second ground electrically isolated from the first ground. 11. A system for transferring power from a first circuit to a second circuit by a differential signal generated in the first circuit, the system comprising: a first isolation element for transmitting a first component of the differential signal between the first and second circuits; a second isolation element for transmitting a second component of the differential signal between the first and second circuits, the second component being a complement of the first component, the differential signal having a first state in response to a voltage at the first isolation element being greater than a voltage at the second isolation element, and having a second state in response to the voltage at the second isolation element being greater than the voltage at the first isolation element; a digital rectifier coupled to the first and second isolation elements for passing current through a load in a predetermined direction, the load being coupled between the rectifier and a ground, wherein the rectifier includes: a first switch coupled between the first isolation element and the load, the first switch for passing current in response to the differential signal being in the first state and for blocking current in response to the differential signal being in the second state; a second switch coupled between the second isolation element and the load, the second switch for blocking current in response to the differential signal being in the first state and for passing current in response to the differential signal being in the second state; a third switch coupled between the first isolation element and the ground, the third switch for blocking current in response to the differential signal being in the first state and for passing current in response to the differential signal being in the second state; and a fourth switch coupled between the second isolation element and the ground, the second switch for passing current in response to the differential signal being in the first state and for blocking current in response to the differential signal being in the second state. 12. The system of claim 11 wherein the first and second isolation elements are capacitors. 13. The system of claim 11 wherein at least one of the first switch, the second, the third switch, or the fourth switch is a field effect transistor (FET). 14. The system of claim 11 wherein the first and second switches are P-channel FETs, and wherein the third and fourth switches are N-channel FETs. 15. The system of claim 11 wherein the first and second switches are N-channel FETs, and wherein the third and fourth switches are P-channel FETs. 16. The system of claim 11 wherein: the first switch is a first FET having a gate coupled to the second isolation element; the second switch is a second FET having a gate coupled to the first isolation element; the third switch is a third FET having a gate coupled to the second isolation element; and the fourth switch is a fourth FET having a gate coupled to the first isolation element.