Power distribution switch for a power distribution system

What is claimed is: 1. A power distribution switch, comprising: a controller module communicatively coupled to a power source having a power regulator, and arranged to receive an indication of a zero-crossing of an output current of the power source from the power regulator, and in response to the indication, to provide a first control signal; and a micro electro mechanical system (MEMS) relay comprising a MEMS switch controllably operated by a MEMS driver, the MEMS switch disposed between the power source and an electrical load, the MEMS relay further comprising a resonant voltage limiting circuit, the resonant voltage limiting circuit including a control circuit in signal communication with the controller module and responsive to the first control signal to provide a second control signal to the MEMS driver to operate the MEMS switch between a conducting and a non-conducting state, the resonant voltage limiting circuit further including a first solid state switch and a second solid state switch electrically in parallel with the MEMS switch, and an inductance and capacitance in series with the second solid state switch, and a charge circuit disposed across the capacitance. 2. The power distribution switch of claim 1 wherein the power source is a variable power source. 3. The power distribution switch of claim 1 wherein the power source is a set of power sources. 4. The power distribution switch of claim 1 , wherein the control circuit is configured to receive a third signal indicative of a current flow from a current sensor disposed downstream from the MEMS switch, and wherein the control circuit is further configured to provide the second control signal responsive to at least one of the first control signal from the control module and the third signal from the current sensor. 5. The power distribution switch of claim 4 , wherein the resonant voltage limiting circuit is further responsive to the at least one of the first control signal from the control module and the third signal from the current sensor to selectively provide a fourth control signal to the first solid state switch, and a fifth control signal to the second solid state switch. 6. The power distribution switch of claim 5 , wherein the control circuit is configured to reroute a current through at least one of the first solid state switch based on the second control signal and the second solid state switch based on the fifth control signal. 7. A power distribution system, comprising: a set of regulated power sources; a set of electrical loads; a controller module communicatively coupled to the set of power sources, and arranged to receive an indication of a zero-crossing of an output current of the set of regulated power source from a regulator of the set of regulated power sources, and in response to the indication, provide a first control signal; and a set of micro electro mechanical system (MEMS) relays disposed between the set of regulated power sources and the set of electrical loads, each relay comprising a respective MEMS switch controllably operated by a MEMS driver, each MEMS relay further comprising a resonant voltage limiting circuit, the resonant voltage limiting circuit including a control circuit in signal communication with the controller module and responsive to the first control signal to provide a second control signal to the MEMS driver to operate the MEMS switch between a conducting and a non-conducting state, the resonant voltage limiting circuit further including a first solid state switch and a second solid state switch electrically in parallel with the MEMS switch, and an inductance and capacitance in series with the second solid state switch, and a charge circuit disposed across the capacitance. 8. The power distribution system of claim 7 wherein the set of regulated power source includes an unregulated power source and a power regulator, wherein the power regulator provides the regulated power source. 9. The power distribution system of claim 8 wherein the unregulated power source is a variable power source. 10. The power distribution system of claim 9 wherein the unregulated power source is a solar power system. 11. The power distribution system of claim 7 wherein the set of regulated power sources includes at least one of a pure sine wave alternating current (AC) source. 12. The power distribution system of claim 7 wherein the set of power sources includes at least one regulated power source and at least one variable power source connected with a power regulator. 13. The power distribution system of claim 7 , further comprising a transmission line matrix conductively connecting the set of regulated power sources with the set of MEMS relay switches. 14. The power distribution system of claim 13 wherein the set of regulated power sources includes at least power sources supplying two phases of AC power. 15. A method for operating a power distribution system, comprising: determining, in a controller module, a desired switch state for a micro electro mechanical system (MEMS) relay comprising a MEMS switch controllably operated by a MEMS driver, the MEMS switch disposed between a regulated power source and an electrical load, the MEMS relay comprising a resonant voltage limiting circuit, the resonant voltage limiting circuit including a control circuit, the control circuit being in signal communication with the controller module, the resonant voltage limiting circuit further including a first solid state switch and a second solid state switch electrically in parallel with the MEMS switch, and an inductance and capacitance in series with the second solid state switch, and a charge circuit disposed across the capacitance; obtaining, by the controller module, from a regulator of the regulated power source, an indication of a zero-crossing of a current of the regulated power source; providing a first control signal, by the controller module, to the control circuit of the resonant voltage limiting circuit, the control circuit being responsive to the first control signal; and providing a second control signal, by the control circuit, to the MEMS driver to operate the MEMS switch between a conducting and a non-conducting state; wherein controllably operating the MEMS switch includes anticipating a zero-crossing of the current of the regulated power source, and controllably operating the MEMS switch based on the anticipated zero-crossing of the current.