Ecliptic sun acquisition control mode for satellites

What is claimed is: 1. A method for orienting an earth-orbiting spacecraft, the method comprising: determining, using a star tracker on board the spacecraft, a first vector aligned between an ecliptic pole of the earth and the spacecraft; adjusting attitude of the spacecraft so as to align a first axis of the spacecraft with the first vector; rotating the spacecraft about the first axis until presence of the sun is registered; and reducing rotation rates of the spacecraft such that the sun remains within a field of view of a sun sensor or of a solar array of the spacecraft. 2. The method of claim 1 , wherein the presence of the sun is registered by the sun sensor of the spacecraft. 3. The method of claim 2 , further comprising controlling the spacecraft using sun sensor data for angle determination in one or more axes. 4. The method of claim 1 , wherein the determining step is executed in the absence of knowledge of at least one of spacecraft orbital position, orbit epoch and angular rates. 5. The method of claim 1 , wherein the determining step is executed in the absence of knowledge of each of spacecraft orbital position, orbit epoch and angular rates. 6. The method of claim 1 , wherein the presence of the sun is registered by a solar array of the spacecraft. 7. The method of claim 6 , wherein use of a sun sensor is avoided. 8. The method of claim 1 , wherein the first axis is parallel or substantially co-aligned with an axis of rotation of a solar array of the spacecraft. 9. A spacecraft comprising a spacecraft controller and a star tracker, the spacecraft controller configured to: determine, using the star tracker, a first vector aligned between an ecliptic pole of the earth and the spacecraft; adjust attitude of the spacecraft so as to align a first axis of the spacecraft with the first vector; rotate the spacecraft about the first axis until presence of the sun is registered; and reduce rotation rates of the spacecraft such that the sun remains within a field of view of a sun sensor or of a solar array of the spacecraft. 10. The spacecraft of claim 9 , wherein the presence of the sun is registered by the sun sensor. 11. The spacecraft of claim 9 , wherein the spacecraft controller is configured to determine the first vector in the absence of knowledge of at least one of spacecraft orbital position, orbit epoch and angular rates. 12. The spacecraft of claim 9 , wherein the spacecraft controller is configured to determine the first vector in the absence of knowledge of each of spacecraft orbital position, orbit epoch and angular rates. 13. The spacecraft of claim 9 , wherein the presence of the sun is registered by a solar array of the spacecraft. 14. The spacecraft of claim 13 , wherein use of a sun sensor is avoided. 15. The spacecraft of claim 9 , wherein the first axis is parallel or substantially co-aligned with an axis of rotation of a solar array of the spacecraft. 16. A non-transitory computer readable medium having software stored thereon, the software including instructions for causing a spacecraft controller to: determine, using a star tracker, a first vector aligned between an ecliptic pole of the earth and a spacecraft including the spacecraft controller and the star tracker; adjust attitude of the spacecraft so as to align a first axis of the spacecraft with the first vector; rotate the spacecraft about the first axis until presence of the sun is registered; and reduce rotation rates of the spacecraft such that the sun remains within a field of view of a sun sensor or of a solar array of the spacecraft. 17. The computer readable medium of claim 16 , the software further including instructions for causing the controller to determine the first vector in the absence of knowledge of one or all of spacecraft orbital position, orbit epoch and angular rates.