System for tracking solar energy

The invention claimed is: 1. An antenna system configured for use in Low Earth Orbit (LEO) around Earth, the antenna system comprising: a plurality of antenna satellites mechanically coupled together to form a phased array, each of the plurality of antenna satellites having an antenna body with an antenna and a solar cell, the solar cells of the plurality of antenna satellites defining an outwardly facing solar side surface of the phased array that are configured to face a Sun and the antennas of the plurality of antenna satellites defining an inwardly facing antenna side surface of the phased array that is configured to face the Earth; actuators mounted to one or more of the plurality of antenna satellites; a sensor configured to sense an orientation and a position of the phased array; and a processing device that is configured to determine a desired orientation of the plurality of antenna satellites and that is configured to control movement of the actuators to move the phased array to the desired orientation, wherein the processing device is configured to determine the desired orientation based on: (a) a positioning of the outwardly facing solar side surface of the phased array with respect to the Sun, (b) a positioning of the inwardly facing antenna side surface with respect to the Earth, and (c) a maintaining of a torque equilibrium of the phased array such that there is zero or near zero torque acting on the phased array; and wherein the processing device is configured to control the actuators to generate rotational motion of the plurality of antenna satellites to move the phased array from a current orientation to the desired orientation and configured to maintain the torque equilibrium of the phased array based on the orientation and the position sensed by the sensor. 2. The antenna system of claim 1 , further comprising a flight computer that is configured to control the processing device to improve solar energy received from the Sun at the solar cells of the plurality of antenna satellites. 3. The antenna system of claim 1 , wherein one or more of the actuators comprises a gyroscopic component that generates the rotational motion with respect to the plurality of antenna satellites to maintain the torque equilibrium of the phased array. 4. The antenna system of claim 3 , wherein the gyroscopic component comprises a momentum wheel. 5. The antenna system of claim 3 , further comprising a flight computer that is configured to control the gyroscopic component. 6. The antenna system of claim 3 , wherein the rotational motion is configured to provide stability against a gravity gradient torque via a gyroscopic effect. 7. The antenna system of claim 1 , wherein the rotational motion is configured to provide stability against a gravity gradient torque via a gyroscopic effect. 8. The antenna system of claim 1 , further comprising a flight computer that is configured to control the actuators. 9. The antenna system of claim 1 , wherein the actuators comprise torque rods. 10. The antenna system of claim 1 , further comprising a control satellite connected to the plurality of antenna satellites, the control satellite comprising the processing device. 11. The antenna system of claim 10 , wherein the control satellite includes at least one of the actuators. 12. The antenna system of claim 11 , wherein an aggregate coordinated control authority of the control satellite and the plurality of antenna satellites controls the orientation and rotation rates of an entirety of the antenna system. 13. The antenna system of claim 11 , wherein one or more of the actuators of the control satellite comprises a momentum wheel that is configured to spin about a normal vector of the antenna system at a specific rate that, in combination with an orbital rotation of the antenna system, brings the antenna system into the torque equilibrium. 14. The antenna system of claim 13 , wherein a gyroscopic torque is generated by a momentum state of the momentum wheel and the orbital rotation of the antenna system, and the gyroscopic torque cancels out a net torque from a gravity gradient and a natural gyroscopic torque of the antenna system. 15. The antenna system of claim 14 , wherein the gyroscopic torque is determined by the formula: τ wheel gyro =L wheel ×ω=I wheel ω wheel ×ω wherein ω is a rotation of the antenna system, I wheel is a moment of inertia of the momentum wheel, ω wheel is a rotation rate of the momentum wheel, and L wheel is an angular momentum of the momentum wheel. 16. The antenna system of claim 1 , wherein the processing device is located at a ground station. 17. The antenna system of claim 1 , wherein one or more of the actuators comprises a gyroscopic component that is configured to generate a gyroscopic torque, wherein the processing device controls the gyroscopic component to position the phased array in the desired orientation and to maintain the torque equilibrium of the phased array. 18. The antenna system of claim 17 , wherein the gyroscopic component is configured to rotate with respect to the antenna body. 19. The antenna system of claim 17 , wherein the gyroscopic component is configured to maintain the torque equilibrium when the desired orientation is offset from a stable orientation by a controlled angle. 20. The antenna system of claim 17 , wherein the gyroscopic component is configured to maintain stability of the plurality of antenna satellites when the desired orientation is unstable. 21. The antenna system of claim 1 , wherein the desired orientation provides the antenna at an angle offset from an orthogonal to a surface of the Earth. 22. The antenna system of claim 1 , wherein the antenna is configured to communicate with wireless devices on Earth. 23. A method for communicating comprising transmitting signals to the antenna system of claim 1 . 24. A method for communicating comprising receiving signals from the antenna system of claim 1 . 25. The antenna system of claim 1 , wherein the inwardly facing antenna side surface of the phased array comprises a communications layer that is configured to transmit and receive data from devices on the Earth. 26. The antenna system of claim 1 , wherein the processing device is configured to control the actuators to generate rotational motion of the plurality of antenna satellites to move the phased array from the current orientation to the desired orientation and to maintain the torque equilibrium of the phased array when the phased array is in LEO. 27. A method of positioning a phased array of a solar energy satellite structure, the method comprising: providing a plurality of antenna satellites mechanically coupled together to form the phased array for use in Low Earth Orbit (LEO) around Earth, each of the plurality of antenna satellites comprising an antenna body with an antenna and a solar cell, the solar cells of the plurality of antenna satellites form an outwardly facing solar side surface of the phased array that faces a Sun and the antennas of the plurality of antenna satellites form an inwardly facing antenna side surface of the phased array that is configured to face the Earth; receiving, at a processing device, an orientation and a position of the phased array from a sensor; positioning the phased array, via actuators mounted to one or more of the plurality of antenna satellites, in a desired o