Abstract: Voltage balancing and extracted output power circuit topologies use maximum power point and maximum power point tracking to provide voltage balancing and voltage and current adjustment to optimize extracted output power for corresponding DC voltage source strings (120a, 130a). The topologies used to control power generation include one or more voltage balancing circuits and/or power system optimizer circuits (102a) to reduce decreased power utilization and enable independent operating voltages of DC voltage source strings (120a, 130a) to provide voltage balancing and to deliver a maximum power independent of the voltage and current of other DC voltage source strings (120a, 130a). The current flowing in each DC voltage source string is controlled by the duty ratio of the corresponding switch (101a, 108a). The circuit topologies can include a plurality of voltage balancing/power system optimizer circuits (102a).

Abstract: The method of converting high voltage AC lines into bipolar high voltage DC systems makes use of the three transmission lines (referred to as the positive pole, the negative pole, and the modulating pole) in an existing high voltage AC system as transmission lines in a bipolar high voltage DC system. When current from the power source is up to the thermal current limit of the transmission lines, the transmission lines operate in two-wire mode, where current is delivered in the positive pole and returned in the negative pole, the modulating pole being open. When power source current exceeds the thermal current limit, operation is in three-wire mode, alternating for predetermined periods between parallel configuration of the positive pole and the modulating pole to divide current for delivery to the load, and parallel configuration of the negative pole and the modulating pole, dividing the return current.

Abstract: Voltage balancing and extracted output power circuit topologies use maximum power point and maximum power point tracking to provide voltage balancing and voltage and current adjustment to optimize extracted output power for corresponding DC voltage source strings (120a, 130a). The topologies used to control power generation include one or more voltage balancing circuits and/or power system optimizer circuits (102a) to reduce decreased power utilization and enable independent operating voltages of DC voltage source strings (120a, 130a) to provide voltage balancing and to deliver a maximum power independent of the voltage and current of other DC voltage source strings (120a, 130a). The current flowing in each DC voltage source string is controlled by the duty ratio of the corresponding switch (101a, 108a). The circuit topologies can include a plurality of voltage balancing/power system optimizer circuits (102a).

Abstract: The method of converting high voltage AC lines into bipolar high voltage DC systems makes use of the three transmission lines (referred to as the positive pole, the negative pole, and the modulating pole) in an existing high voltage AC system as transmission lines in a bipolar high voltage DC system. When current from the power source is up to the thermal current limit of the transmission lines, the transmission lines operate in two-wire mode, where current is delivered in the positive pole and returned in the negative pole, the modulating pole being open. When power source current exceeds the thermal current limit, operation is in three-wire mode, alternating for predetermined periods between parallel configuration of the positive pole and the modulating pole to divide current for delivery to the load, and parallel configuration of the negative pole and the modulating pole, dividing the return current.