Systems and methods for energy harvest

What is claimed is: 1. A power generation system, comprising: a plurality of power generation units, wherein each of the plurality of power generation units is configured to generate electrical power from movement of a fluid within a body of water; an electrical power storage unit configured to store the electrical power generated by the power generation units, wherein the power generation units are operable to supply the electrical power to the electrical power storage unit and to an electrical energy transmission system; one or more switching devices connected between the plurality of power generation units and the electrical energy transmission system and between the electrical power storage unit and the electrical energy transmission system; a control system operable to control the one or more switching devices, wherein the control system is configured to: communicate with the plurality of power generation units, with the electrical power storage unit, and with the electrical energy transmission system, receive power specifications of the electrical energy transmission system and at least one of weather and environmental data, determine a percentage of the electrical power supplied by the plurality of power generation units to be directed to one or both of the electrical power storage unit and the electrical energy transmission system based on the power specifications of the electrical energy transmission system and the at least one of weather and environmental data, and switch the one or more switching devices for selectively directing the determined percentage of the electrical power supplied by the plurality of power generation units to one or both of the electrical power storage unit and the electrical energy transmission system. 2. The power generation system of claim 1 , wherein the power generation units are tethered together to a common weight, and wherein the common weight is fixedly positioned to a floor of the body of water. 3. The power generation system of claim 1 , wherein the power generation units are tethered together via an output power line, and wherein the output power line is fixedly positioned to a floor of the body of water. 4. The power generation system of claim 1 , wherein each of the plurality of power generation units comprises: a controller, wherein the controller is configured to manage an electrical power output of the respective power generation unit; and a generator, wherein the generator is configured to generate electrical power from movement of the fluid within the body of water. 5. The power generation system of claim 4 , further comprising: a piling coupled to a base fixedly positioned to a floor of the body of water; one or more magnets, wherein the one or more magnets are positioned within the piling; a cap, wherein the cap includes a plurality of windings; a buoy coupled to the cap, wherein the buoy is configured to move the windings relative to the one or more magnets upon the movement of the fluid, and wherein the movement of the windings relative to the one or more magnets causes the generator to generate the electrical power. 6. The power generation system of claim 4 , further comprising: a piling coupled to a base fixedly positioned to a floor of the body of water; an electromagnetic core, wherein the electromagnetic core is positioned within the piling, and wherein the electromagnetic core comprises a plurality of windings; a cap, wherein the cap includes at least two magnetic assemblies, wherein each magnetic assembly includes a plurality of magnets positioned on each other with opposite polarities; and a buoy coupled to the cap, wherein the buoy is configured to move the magnetic assemblies relative to the plurality of windings within the electromagnetic core upon movement of the fluid, and wherein the movement of the magnetic assemblies relative to the plurality of windings causes the generator to generate the electrical power. 7. The power generation system of claim 4 , further comprising: a piling coupled to a base fixedly positioned to a floor of the body of water; a divider coupled to the piling, wherein the divider defines a fluid chamber and an electronics chamber within the piling; a fluid intake valve, wherein the fluid intake valve is coupled to the piling and configured to enable intake of the fluid into the fluid chamber of the piling caused by the movement of the fluid within the body of water; one or more vents on the fluid chamber of the piling configured to enable the fluid in the fluid chamber to exit the fluid chamber; an electromagnetic core, wherein the electromagnetic core is positioned within the electronics chamber of the piling, and wherein the electromagnetic core comprises a plurality of windings; an impeller operatively coupled to the electromagnetic core, wherein the impeller is positioned within the fluid chamber of the piling; and a plurality of magnets fixedly coupled to the piling adjacent to the electromagnetic core, wherein a force of the fluid entering the fluid chamber of the piling through the fluid intake valve and exiting the fluid chamber through the one or more vents causes the impeller to rotate thereby causing the electromagnetic core to rotate, and wherein the rotation of the electromagnetic core causes the generator to generate the electrical power. 8. A power generation unit operable to supply an electrical power output, comprising: a controller, wherein the controller is configured to manage the electrical power output of the power generation unit; a generator, wherein the generator is configured to generate electrical power from movement of a fluid within a body of water; an electrical power storage unit configured to store the electrical power generated by the generator, wherein the generator is operable to supply the electrical power to the electrical power storage unit and to an electrical energy transmission system; at least one sensor configured to sense an operating condition of the power generation unit, wherein the controller is communicatively coupled to the at least one sensor; and one or more switching devices connected between the generator and the electrical energy transmission system and between the electrical power storage unit and the electrical energy transmission system, wherein the controller is operable to control the one or more switching devices and configured to: control the electrical power output of the power generation unit, receive a sensor signal from the at least one sensor indicative of the sensed operating condition of the power generation unit, determine a percentage of the electrical power supplied by the generator to be directed to one or both of the electrical power storage unit and the electrical energy transmission system based on the received sensor signal, and switch the one or more switching devices for selectively directing the determined percentage of the electrical power from the generator to one or both of the electrical power storage unit and the electrical energy transmission system. 9. A power generation unit operable to supply an electrical power output, comprising: a controller, wherein the controller is configured to manage the electrical power output of the power generation unit; a generator, wherein the generator is configured to generate electrical power from movement of a fluid within a body of water; and an electrical power storage unit configured to store the electrical power generated by the generator; a piling coupled to a base fixedly positioned to a floor of the body of water; a divider coupled to the piling, wherein the divider defines a fluid chamber and an electronics chamber within the piling; a fluid intake valve, where