Methods for determining maximum power point tracking in power converters

What is claimed is: 1. A method for determining maximum power point tracking in a power converter, comprising: periodically increasing current from a photovoltaic array connected to a power converter; after increasing the current from the photovoltaic array, detecting whether the power from the photovoltaic array has increased; if, after increasing the current from the photovoltaic array, the power from the photovoltaic array has increased, then continuing to periodically increase the current from the photovoltaic array; else, if after increasing the current from the photovoltaic array, the power from the photovoltaic array has remained the same or decreased, then decreasing the current from the photovoltaic array; wherein said power converter comprises a link reactance connected by parallel pairs of bidirectional switches to a plurality of input and output ports. 2. The method for determining maximum power point tracking in a power converter of claim 1 , wherein the steps of increasing the current from the photovoltaic array are accomplished by increasing the conductance of the photovoltaic array. 3. The method for determining maximum power point tracking in a power converter of claim 1 , further comprising: establishing predetermined thresholds for voltage and current output from the photovoltaic array; periodically detecting the voltage and current output from the photovoltaic array; if, after detecting the voltage and current output from the photovoltaic array, the voltage output and the current output both fail to equal or exceed the respective voltage and current thresholds, shutting down the photovoltaic array. 4. The method for determining maximum power point tracking in a power converter of claim 1 , wherein the method of determining maximum power point tracking in a power converter is an iterative process. 5. The method for determining maximum power point tracking in a power converter of claim 1 , wherein said link reactance comprises an inductor in parallel with a capacitor. 6. The method for determining maximum power point tracking in a power converter of claim 1 , wherein, during normal operation of said power converter, said bidirectional switches repeatedly and intermittently connect said link reactance to two said input and output ports, disconnect said link reactance from outside connections, and connect said link reactance to two other said input and output ports, to thereby transfer power therebetween. 7. A method for determining maximum power point tracking in a power converter, comprising: (a) detecting a power loss from the power converter; (b) storing a first power value representing a current power output of the power converter; (c) increasing a current from the power converter; (d) delaying processing after increasing the current from the power converter for a pre-determined delay time; (e) calculating and storing a second power value representing the power output of the power converter after the step of delaying processing; (f) comparing the first power value to the second power value; and, if the second power value is greater than the first power value, (g) setting the second power value to the first power value and increasing the current from the power converter; else, if the second power value is less than or equal to the first power value, (h) setting the second power value to the first power value and decreasing the conductance of the power converter; wherein said power converter comprises a link reactance connected by parallel pairs of bidirectional switches to a plurality of input and output ports. 8. The method for determining maximum power point tracking in a power converter of claim 7 , wherein said link reactance comprises an inductor in parallel with a capacitor. 9. The method for determining maximum power point tracking in a power converter of claim 7 , wherein at least two said input and output ports are connected to a photovoltaic array. 10. The method for determining maximum power point tracking in a power converter of claim 7 wherein, during normal operation of said power converter, said bidirectional switches intermittently connect said link reactance to two said input and output ports, disconnect said link reactance from outside connections, and connect said link reactance to two other said input and output ports, to thereby transfer power therebetween. 11. The method for determining maximum power point tracking in a power converter of claim 7 , further comprising: after either of steps (g) or (h), returning to step (a). 12. The method for determining maximum power point tracking in a power converter of claim 7 , further comprising: after step (e), storing a voltage value and a current value from the power converter; comparing the stored voltage value to a predetermined voltage threshold; comparing the stored current value to a predetermined current threshold; and, if the stored voltage value and the stored current value both fail to equal or exceed the respective voltage and current thresholds, shutting down the power converter; else, proceeding to step (f). 13. The method for determining maximum power point tracking in a power converter of claim 7 , wherein increasing the current from the power converter comprises changing the conductance of the power converter. 14. The method for determining maximum power point tracking in a power converter of claim 7 , wherein the predetermined delay time is about 40 milliseconds. 15. The method for determining maximum power point tracking in a power converter of claim 7 , wherein the step of setting the second power value to the first power value and decreasing the conductance of the power converter comprises reducing the conductance of the power converter by about one-half. 16. The method for determining maximum power point tracking in a power converter of claim 7 , wherein the method of determining maximum power point tracking in a power converter is an iterative process. 17. A method for determining maximum power point tracking in a photovoltaic inverter, comprising: periodically increasing the current from the photovoltaic inverter; after increasing the current from the photovoltaic inverter, detecting whether the power from the photovoltaic inverter has increased; if, after increasing the current from the photovoltaic inverter, the power from the photovoltaic inverter has increased, then continuing to periodically increase the current from the photovoltaic inverter; else, if after increasing the current from the photovoltaic inverter, the power from the photovoltaic inverter has remained the same or decreased, then decreasing the current from the photovoltaic inverter. 18. The method for determining maximum power point tracking in a photovoltaic inverter of claim 17 , where the steps of increasing the current from the photovoltaic inverter are accomplished by increasing the conductance of the photovoltaic inverter. 19. The method for determining maximum power point tracking in a photovoltaic inverter of claim 17 , further comprising: establishing predetermined thresholds for voltage and current output from the photovoltaic inverter; periodically detecting the voltage and current output from the photovoltaic inverter; if, after detecting the voltage and current output from the photovoltaic inverter, the voltage output and the current output both fail to equal or exceed the respective voltage and current thresholds, shutting down the inverter.