Serially connected micro-inverter system having concertina output voltage control

The invention claimed is: 1. A serially connected micro-inverter (SCMI) system comprising: a plurality of power sources for producing DC power; a plurality of micro-inverters, where each micro-inverter is coupled to at least one power source of the plurality of power sources, for converting the DC power into AC power; an AC bus for coupling the plurality of micro-inverters in series to form a string and for coupling the AC power to an AC line, wherein each of the micro-inverters comprises (i) an AC bus coupler for coupling the micro-inverter to the AC bus, wherein the AC bus coupler decouples the micro-inverter from the AC bus when a fault is detected with the micro-inverter, and (ii) a DC to AC inverter for converting DC input power from a coupled power source to AC output power; and a controller, coupled to the string, for: measuring an output voltage of the string; comparing the measured output voltage to a desired voltage for the string; and adjusting a phase angle of an output from each micro-inverter in the string until a difference between the measured output voltage and the desired voltage is less than a predetermined threshold value. 2. The SCMI system of claim 1 , wherein each of the micro-inverters further comprises: a current-voltage monitoring circuit for monitoring current and voltage from a corresponding power source; and a maximum power point tracking controller for maintaining maximum power output from the micro-inverter. 3. The SCMI system of claim 2 , wherein each of the micro-inverters further comprises: a local controller that synchronizes phase of an AC output from the micro-inverter and voltage phase of the AC line; and a control bus coupler for receiving information regarding the micro-inverter from the local controller. 4. The SCMI system of claim 3 , wherein the local controller further comprises: an inverter controller for controlling parameters of the DC to AC inverter. 5. The SCMI system of claim 1 , wherein each micro-inverter of the plurality of micro-inverters is a voltage source inverter (VSI). 6. The SCMI system of claim 5 , wherein the VSI comprises: an input capacitor; an H-bridge, coupled to the input capacitor; and a plurality of output inductors to generate an AC output voltage. 7. The SCMI system of claim 1 , wherein each micro-inverter of the plurality of micro-inverters is a current source inverter (CSI). 8. The SCMI system of claim 7 , wherein the CSI comprises: a plurality of inductors; an H-bridge, coupled to the plurality of inductors; and an output capacitor, coupled to the H-Bridge, to generate a pulsed AC current signal. 9. The SCMI system of claim 1 wherein the plurality of power sources comprises a plurality of photovoltaic (PV) modules that generate power when exposed to solar irradiance. 10. The SCMI system of claim 1 , wherein the controller is coupled to the Internet for remote monitoring and control. 11. The SCMI system of claim 1 , wherein a plurality of strings are coupled in parallel to generate an output power represented by the equation: P o (t)=Σ m (i m (t)·Σ m v n (t)) where P o (t) is the output power generated by the SCMI system, I m (t) is current in a given string from the plurality of strings and V n (t) is voltage produced by an individual micro-inverter. 12. The SCMI system of claim 11 , wherein power generated by a string is represented P ⁡ ( t ) = i m ⁡ ( t ) ⁢ ⁢ • ⁢ ⁢ ∑ n ⁢ v n ⁡ ( t ) by the equation: where I m (t) is the current in the string and V n (t) is the voltage produced by an individual micro-inverter. 13. A method for controlling output voltage of a serially connected micro-inverter system comprising: measuring an output voltage of a string of series coupled micro-inverters coupled to an AC bus, wherein each of the micro-inverters comprises (i) an AC bus coupler for coupling the micro-inverter to the AC bus, wherein the AC bus coupler decouples the micro-inverter from the AC bus when a fault is detected with the micro-inverter, and (ii) a DC to AC inverter for converting DC input power from a coupled power source to AC output power that is coupled to the AC bus; comparing the measured output voltage to a desired voltage for the string; and adjusting a phase angle of an output from each micro-inverter in the string until a difference between the measured output voltage and the desired voltage is less than a predetermined threshold value. 14. The method of claim 13 further comprising: waiting, according to a sampling rate, a period of time until measuring the output voltage again to determine the difference between the measured output voltage and the desired voltage. 15. The method of claim 14 , wherein the period of time is once per grid cycle. 16. The method of claim 13 , wherein the desired voltage is one of 120 volts, 220 volts, or 240 volts. 17. The method of claim 13 , wherein adjusting the phase angle of the output from the string drives a sum of real signal components over the string towards the desired voltage.