Systems and methods are disclosed for intelligent circuit control for solar panel systems. In one embodiment, an example method may include determining, by a controller, that a first electrical output of a first solar panel configured to charge a plurality of rechargeable batteries is greater than a second electrical output of a second solar panel configured to charge the plurality of rechargeable batteries, and causing the second solar panel to be disconnected from the plurality of rechargeable batteries. Example methods may include determining that a voltage potential of the plurality of rechargeable batteries is greater than a total output voltage, where the total output voltage is a sum of the first electrical output and the second electrical output, and causing a connection between the plurality of rechargeable batteries to be changed from a series connection to a parallel connection based at least in part on the first electrical output.

Systems and methods are disclosed for intelligent circuit control for solar panel systems. In one embodiment, an example method may include determining that a first solar panel has a first voltage output that is less than a voltage potential of a battery system that includes a first battery and a second battery, determining that the first battery is connected to the second battery in a series connection, causing the first battery to be connected to the second battery in a parallel connection, and determining that the voltage potential is less than the first voltage output.

Systems and methods are disclosed for intelligent circuit control for solar panel systems. In one embodiment, an example method may include determining that a first solar panel has a first voltage output that is less than a voltage potential of a battery system that includes a first battery and a second battery, determining that the first battery is connected to the second battery in a series connection, causing the first battery to be connected to the second battery in a parallel connection, and determining that the voltage potential is less than the first voltage output.

A synchronous generator with high frequency AC excitation source.

A synchronous generator with high frequency AC excitation source.

Pairs of unidirectionally magnetic rotor/stator assemblies are mounted for synchronous rotation and complementary, so that one creates pulsating positive current flow and the other creates pulsating negative current flow, as the rotor and stator in each assembly are rotated with respect to each other. The pulsating positive current flow and pulsating negative current flow are combined at a desired phase angle to create alternating current, without power loss due to reversal of current flow.

Pairs of unidirectionally magnetic rotor/stator assemblies are mounted for synchronous rotation and complementary, so that one creates pulsating positive current flow and the other creates pulsating negative current flow, as the rotor and stator in each assembly are rotated with respect to each other. The pulsating positive current flow and pulsating negative current flow are combined at a desired phase angle to create alternating current, without power loss due to reversal of current flow.

A uni-pole rotor for an electrical power generator includes two separate electromagnets formed on rotor laminates and separated by a mu metal shield. The laminates further include two separate winding wire slots on either side of the mu metal shield which slots are wound with magnet wire to serve as rotor coils of the two separate electromagnets. The two separate electromagnets, when excited, create magnetic fluxes of a first polarity and a second polarity such that outer fluxes of the rotor are of the first polarity and the inner fluxes of the rotor are of the second polarity. The uni-pole rotor further includes electrical leads to the rotor coils such that leads are used to excite in an alternating fashion a positive and negative DC current in the rotor coils which allows alternation of 360 north pole with 360 south pole generation on the outer portion of the rotor laminates of the rotor.

A uni-pole rotor for an electrical power generator includes two separate electromagnets formed on rotor laminates and separated by a mu metal shield. The laminates further include two separate winding wire slots on either side of the mu metal shield which slots are wound with magnet wire to serve as rotor coils of the two separate electromagnets. The two separate electromagnets, when excited, create magnetic fluxes of a first polarity and a second polarity such that outer fluxes of the rotor are of the first polarity and the inner fluxes of the rotor are of the second polarity. The uni-pole rotor further includes electrical leads to the rotor coils such that leads are used to excite in an alternating fashion a positive and negative DC current in the rotor coils which allows alternation of 360 north pole with 360 south pole generation on the outer portion of the rotor laminates of the rotor.

Pairs of unidirectionally magnetic rotor/stator assemblies are mounted for synchronous rotation and complementary, so that one creates pulsating positive current flow and the other creates pulsating negative current flow, as the rotor and stator in each assembly are rotated with respect to each other. The pulsating positive current flow and pulsating negative current flow are combined at a desired phase angle to create alternating current, without power loss due to reversal of current flow.