Seat power systems and methods

What is claimed is: 1. A power system for providing power within an aircraft, wherein the aircraft includes a source of AC power having a first frequency, the power system comprising: a power supply unit, the power supply unit including a frequency converter subsystem, the frequency converter subsystem being configured to receive power from the source of AC power and to convert the received power having the first frequency into converted power having a second frequency less than the first frequency, the power supply unit being configured to monitor total power consumed by a plurality of seat nodes; each of the plurality of seat nodes comprising a microprocessor and an AC monitor and control element, the AC monitor and control element of each of the plurality of seat nodes being configured to monitor the converted power received from the frequency converter subsystem of the power supply unit and to control the received converted power as output power that is output from each of the plurality of seat nodes, the output power from each of the plurality of seat nodes being individually selectively controlled based on the monitored total power consumed by the plurality of seat nodes; a power network configured to provide the converted power from the frequency converter subsystem of the power supply unit to the plurality of seat nodes, wherein; and a data network configured to communicate data between the power supply unit and each of the plurality of seat nodes. 2. The system of claim 1 , wherein each AC monitor and control element comprises at least ones relay for individually selectively controlling the output power from each of the plurality of seat nodes based on the monitored total power consumed by the plurality of seat nodes. 3. The system of claim 1 , wherein the data network is formed by a bi-directional data-over-power network that operates using the power network. 4. The system of claim 1 , wherein each of the plurality of seat nodes comprises at least one outlet. 5. A method for providing power within an aircraft, wherein the aircraft includes a source of AC power having a first frequency, the power system comprising: supplying power having the first frequency from the source of AC power to a power supply unit having a frequency converter subsystem; converting the received power having the first frequency into converted power having a second frequency less than the first frequency; supplying the converted power from the frequency converter subsystem to a plurality of seat nodes; monitoring by the power supply unit the total power consumed by the plurality of seat nodes; monitoring at each of the plurality of seat nodes the converted power received from the frequency converter subsystem of the power supply unit; and controlling at each of the plurality of seat nodes the received converted power as output power that is output from each of the plurality of seat nodes, the output power from each of the plurality of seat nodes being individually selectively controlled based on the monitored total power consumed by the plurality of seat nodes. 6. The method of claim 5 , wherein the data network is formed by a bi-directional data-over-power network that operates using the power network. 7. The method of claim 5 , further comprising controlling at least one relay for individually selectively controlling the output power from each of the plurality of seat nodes based on the monitored total power consumed by the plurality of seat nodes. 8. The system of claim 3 , wherein each of the plurality of seat nodes includes a AC/DC converter configured to perform as a data-over-power interface between the power supply unit and the seat node. 9. A power system for providing power within an aircraft, wherein the aircraft includes a source of AC power having a first frequency above 60 Hz, the power system comprising: a plurality of seat nodes, each of the plurality of seat nodes comprising a microprocessor and an AC monitor and control element; a power supply unit, the power supply unit including a frequency converter subsystem, the frequency converter subsystem being configured to receive power from the source of AC power and to convert the received power having the first frequency into converted power having a second frequency at essentially 60 Hz; a power network configured to provide the converted power from the frequency converter subsystem of the power supply unit to the plurality of seat nodes, wherein the AC monitor and control element of each of the plurality of seat nodes is configured to monitor the converted power received from the frequency converter subsystem of the power supply unit and to control the received converted power as output power that is output from each of the plurality of seat nodes; and a data network configured to communicate data between the power supply unit and each of the plurality of seat nodes, the data network being a bi-directional data-over-power network that operates using the power network. 10. The power system of claim 9 , wherein each of the plurality of seat nodes includes a AC/DC converter configured to perform as a data-over-power interface between the power supply unit and the seat node.