Scalable hierarchical energy distribution grid utilizing homogeneous control logic

What is claimed is: 1. A distributed electrical grid system, comprising: a plurality of control modules arranged in a hierarchy and associated with a corresponding plurality of sites, wherein each control module of the plurality of control modules implements a same optimization scheme logic, having an energy goal, using a set of locally-determined input values to control one or more devices at a site according to the energy goal, the plurality of control modules including at least: a first control module configured as a child in the hierarchy, the first control module being associated with a first site and configured to determine a first set of input values comprising an energy generation value of the first site, an energy storage value of the first site, and a load value of the first site, the first control module further configured to provide the first set of input values to the optimization scheme logic of the first control module, wherein the first control module communicates with one or more devices at the first site to adjust an energy profile of the first site according to the energy goal; and a second control module configured as a parent in the hierarchy to a set of child control modules including the first control module, the second control module configured to determine a second set of input values comprising an aggregate energy generation value of a set of sites associated with the set of child control modules, an aggregate energy storage value of the set of sites, and an aggregate load value of the set of sites, the second control module further configured to provide the second set of input values to the optimization scheme logic of the second control module, wherein the second control module interacts with the first control module to adjust the energy profile of the first site according to the energy goal. 2. The distributed electrical grid system of claim 1 , wherein the energy goal comprises minimizing deviations of a net flow of energy between the first site and an external energy system. 3. The distributed electrical grid system of claim 1 , wherein the energy goal comprises minimizing a net flow of energy between the first site and an external energy system and deviations of the net flow of energy between the first site and the external energy system. 4. The distributed electrical grid system of claim 1 , wherein: the first control module is further configured to determine a plurality of energy cost values associated with exchanging energy with an external energy source at a corresponding plurality of times; the plurality of energy cost values are used in the first set of input values of the optimization scheme logic; and the energy goal comprises minimizing a cost of energy provided to the first site from the external energy source over a period of time. 5. The distributed electrical grid system of claim 1 , wherein the second control module is associated with a second site including at least one of an energy generator device and an energy storage device, and wherein the second control module is further configured to: determine that the set of sites associated with the set of child control modules are utilizing, or will utilize, an increase in a net flow of energy into the set of sites; and in response to the determination, provide energy from the energy generator device or energy storage device of the second site to at least some of the set of sites. 6. The distributed electrical grid system of claim 1 , wherein the one or more devices of the first site comprise a photo-voltaic (PV) device and an energy storage device. 7. The distributed electrical grid system of claim 1 , wherein the first control module comprises a site gateway device communicatively coupled with the one or more devices of the first site using wireless communications.