Systems and methods for performing shape estimation using sun sensors in large-scale space-based solar power stations

What is claimed is: 1. A space-based solar power station comprising: a plurality of unconnected satellite modules disposed in space in an orbital array formation; a plurality of power generation tiles disposed on and forming an independent array on each of the plurality of satellite modules; at least one photovoltaic cell disposed on each of the power generation tiles; and at least one power transmitter collocated with the at least one photovoltaic cell on each of the power generation tiles and in signal communication therewith such that an electrical current generated by the collection of solar radiation by the at least one photovoltaic cell powers the at least one power transmitter, where each of the at least one power transmitters comprises: an antenna; and separate control electronics that independently control, based on information from other power generation tiles within the independent array, at least the phase of a radio frequency power signal that feeds the antenna so that the power transmitter is coordinated with power transmitters on other power generation tiles on the plurality of unconnected satellite modules to form a phased array; and at least one sun sensor disposed on each of the satellite module that is in signal communication with a microcontroller, where the microcontroller is in signal communication with the control electronics in each of the at least one power transmitter and provides a phase offset signal to the control electronics in each of the at least one power transmitter based upon at least one signal received from the at least one sun sensor. 2. The space-based solar power station of claim 1 , wherein the control electronics further controls the amplitude of the radio frequency power signal that feeds the antenna so that the power transmitter is coordinated with power transmitters on other power generation tiles. 3. The space-based solar power station of claim 1 , wherein: the power transmitter is configured to receive a reference signal; and the control electronics controls the phase of the radio frequency power signal by applying a phase shift with respect to the received reference signal. 4. The space-based solar power station of claim 3 , wherein at least one of the satellite modules comprises a receiver to wirelessly receive the reference signal. 5. The space-based solar power station of claim 4 , wherein the receiver of the at least one satellite module is configured to wirelessly receive the reference signal from an Earth-based transmitter. 6. The space-based solar power station of claim 4 , further comprising: a reference signal transmitter satellite comprising a transmitter that transmits the reference signal; and wherein the receiver of the at least one of the satellite module is configured to wirelessly receive the reference signal from transmitter on the reference signal transmitter satellite. 7. The space-based solar power station of claim 4 , wherein the receiver to wirelessly receive the reference signal comprises an amplifier, and a cleanup phase locked loop. 8. The space-based solar power station of claim 4 , wherein each of the at least one satellite module also includes transmission lines that route the reference signal to at least one power transmitter on a given satellite module. 9. The space-based solar power station of claim 3 , wherein the control electronics determine a phase shift to apply with respect to a received reference signal based upon location information. 10. The space-based solar power station of claim 1 , wherein the at least one signal from the at least one sun sensor comprises signals corresponding to the sensor's relative angle with respect to the sun. 11. The space-based solar power station of claim 10 , further comprising at least one accelerometer disposed on the satellite module that is in signal communication with the microcontroller. 12. The space-based solar power station of claim 10 , further comprising at least one gyroscope disposed on the satellite module that is in signal communication with the microcontroller. 13. The space-based solar power station of claim 10 , wherein the microcontroller is configured to integrate the at least one sun sensor signals to generate a finite model of the power generation tile. 14. The space-based solar power station of claim 13 , wherein the integration of the at least one sun sensor signals includes applying a Kalman filter to the at least one sun sensor signals. 15. The space-based solar power station of claim 13 , wherein the integration of the at least one sun sensor signals includes applying an extended Kalman filter to the at least one sun sensor signals. 16. The space-based solar power station of claim 13 , wherein the microcontroller is further configured to estimate the shape of the power generation tile with respect to the sun. 17. The space-based solar power station of claim 13 , wherein the microcontroller is further configured to estimate the relative position of the antennas in the power transmitters with respect to each other. 18. The space-based solar power station of claim 17 , wherein the microcontroller is further configured to communicate a signal to the control electronics to adjust the reference signal based upon the estimated relative positions of the antennas in the power transmitters with respect to each other. 19. The space-based solar power station of claim 1 , wherein the control electronics is contained within an integrated circuit comprising: an RF synthesizer configured to generate an RF signal based upon a received reference signal; a phase adjuster configured to phase shift an RF signal received from the RF synthesizer by an amount determined by a control signal; a power amplifier configured to amplify a phase shifted RF signal received from the phase adjuster; and a digital signal processor configured by software stored in memory to generate the control signal for the phase adjuster.