Control system for executing a safing mode sequence in a spacecraft

What is claimed is: 1. A control system configured to execute a safing mode sequence for a spacecraft, the control system comprising: one or more star trackers that each include a field of view to capture light from a plurality of space objects surrounding a celestial body; one or more actuators; one or more processors in electronic communication with the one or more actuators and the one or more star trackers; and a memory coupled to the one or more processors, the memory storing data into a database and program code that, when executed by the one or more processors, causes the control system to: instruct the spacecraft to enter a safing mode, wherein the spacecraft revolves in an orbit around the celestial body; in response to entering the safing mode, determine a current attitude of the spacecraft is unknown and instruct the one or more actuators to rotate the spacecraft about a rotational axis, wherein the one or more star trackers capture the light from the plurality of space objects surrounding the celestial body as the spacecraft rotates about the rotational axis to create measurements that represent a current attitude of the spacecraft; determine the current attitude of the spacecraft based on the measurements created by the one or more star trackers; and in response to determining the current attitude, instruct the one or more actuators to re-orient the spacecraft from the current attitude into a momentum neutral attitude. 2. The control system of claim 1 , wherein the one or more processors execute instructions to: instruct the one or more actuators to substantially align a principal axis of the spacecraft with a vector that is normal to the orbit around the celestial body as the spacecraft is re-oriented into the momentum neutral attitude. 3. The control system of claim 1 , wherein the one or more actuators that rotate the spacecraft about the rotational axis include one or more reaction wheels that are in electronic communication with the one or more processors. 4. The control system of claim 1 , wherein the one or more processors execute instructions to: determine the rotational axis that the spacecraft rotates about, wherein the rotational axis is substantially perpendicular to the field of view of the one or more star trackers. 5. The control system of claim 1 , further comprising: one or more solar wings rotatably coupled to a main body of the spacecraft, wherein the one or more solar wings include a plurality of photovoltaic cells that generate electrical current from light. 6. The control system of claim 5 , wherein the one or more processors further execute instructions to: instruct the one or more solar wings to rotate about a solar axis as the spacecraft rotates about the rotational axis; and monitor the electrical current generated by the plurality of photovoltaic cells as the one or more solar wings rotate about the solar axis. 7. The control system of claim 6 , wherein the one or more processors further execute instructions to: determine a maximum local value of the electrical current as the one or more solar wings rotate about the solar axis; and determine an angular position of the one or more solar wings relative to the solar axis when the electrical current is at the maximum local value. 8. A spacecraft configured to orbit a celestial body, the spacecraft comprising: a main body defining a rotational axis; one or more star trackers that each include a field of view to capture light from a plurality of space objects surrounding the celestial body; one or more actuators; one or more processors in electronic communication with the one or more actuators; and a memory coupled to the one or more processors, the memory storing data into a database and program code that, when executed by the one or more processors, causes the spacecraft to: instruct the spacecraft to enter a safing mode, wherein the spacecraft revolves in an orbit around the celestial body; in response to entering the safing mode, determine a current attitude of the spacecraft is unknown and instruct the one or more actuators to rotate the spacecraft about the rotational axis, wherein the one or more star trackers capture the light from the plurality of space objects surrounding the celestial body as the spacecraft rotates about the rotational axis to create measurements that represent a current attitude of the spacecraft; determine the current attitude of the spacecraft based on the measurements created the one or more star trackers; and in response to determining the current attitude, instruct the one or more actuators to re-orient the spacecraft from the current attitude into a momentum neutral attitude. 9. The spacecraft of claim 8 , wherein the one or more processors execute instructions to: instruct the one or more actuators to substantially align a principal axis of the spacecraft with a vector that is normal to the orbit around the celestial body as the spacecraft is re-oriented into the momentum neutral attitude. 10. The spacecraft of claim 8 , wherein the one or more actuators that rotate the spacecraft about the rotational axis include one or more reaction wheels that are in electronic communication with the one or more processors. 11. The spacecraft of claim 8 , wherein the one or more processors execute instructions to: determine the rotational axis that the spacecraft rotates about, wherein the rotational axis is substantially perpendicular to the field of view of the one or more star trackers. 12. The spacecraft of claim 8 , further comprising: one or more solar wings rotatably coupled to the main body of the spacecraft, wherein the solar wings include a plurality of photovoltaic cells that generate electrical current from light. 13. The spacecraft of claim 12 , wherein the one or more processors further execute instructions to: instruct the one or more solar wings to rotate about a solar axis as the spacecraft rotates about the rotational axis; and monitor the electrical current generated by the plurality of photovoltaic cells as the one or more solar wings rotate about the solar axis. 14. The spacecraft of claim 13 , wherein the one or more processors further execute instructions to: determine a maximum local value of the electrical current as the one or more solar wings rotate about the solar axis; and determine an angular position of the one or more solar wings relative to the solar axis when the electrical current is at the maximum local value. 15. A method for executing a safing mode sequence for a spacecraft, the method comprising: instructing, by a computer, the spacecraft to enter a safing mode, wherein the spacecraft revolves in an orbit around a celestial body; in response to entering the safing mode, determining a current attitude of the spacecraft is unknown and instructing one or more actuators to rotate the spacecraft about a rotational axis, wherein one or more star trackers capture light from a plurality of space objects surrounding the celestial body as the spacecraft rotates about the rotational axis to create measurements that represent a current attitude of the spacecraft; determining, by the computer, the current attitude based on the measurements received from the one or more star trackers; and in response to determining the current attitude, instructing the one or more actuators to re-orient the spacecraft from the current attitude into a momentum neutral attitude. 16. The method of claim 15 , further comprising: instructing, by the computer, the one or more actuators to substantially align a principal axis of the spac