초록 ▼

A system and a method for commanding a spacecraft to perform a three-axis maneuver purely based on “position” (i.e., attitude) measurements. Using an “inertial gimbal concept”, a set of formulae are derived that can map a set of “inertial” motion to the spacecraft body frame based on position inform

A system and a method for commanding a spacecraft to perform a three-axis maneuver purely based on “position” (i.e., attitude) measurements. Using an “inertial gimbal concept”, a set of formulae are derived that can map a set of “inertial” motion to the spacecraft body frame based on position information so that the spacecraft can perform/follow according to the desired inertial position maneuvers commands. Also, the system and method disclosed herein employ an intrusion steering law to protect the spacecraft from acquisition failure when a long sensor intrusion occurs.

대표청구항 ▼

1. A system for a spacecraft having a plurality of star trackers, the system comprising a control processor configured to: move the star trackers to create a three-dimensional spiral acquisition pattern;use attitude measurements from the acquisition pattern to generate spacecraft position estimates;

1. A system for a spacecraft having a plurality of star trackers, the system comprising a control processor configured to: move the star trackers to create a three-dimensional spiral acquisition pattern;use attitude measurements from the acquisition pattern to generate spacecraft position estimates;generate attitude commands; anduse a position-only control on the position estimates and the attitude commands to generate actuator torque commands. 2. The system of claim 1, wherein the position-only control includes a 1-2-3 Euler sequence of rotation to command spacecraft attitude relative to a local inertial reference frame. 3. The system of claim 2, wherein Euler angles are represented by elevation, azimuth, and rotation of boresight. 4. The system of claim 2, wherein the inertial reference frame is an Earth-centered inertial frame of reference. 5. The system of claim 1, wherein the control processor is further configured with a phase sequencer for generating the attitude commands for at least one of sun acquisition and safe hold. 6. A system for a spacecraft having a plurality of star trackers, the system comprising an attitude control processor configured to: use attitude measurements from the star trackers to provide an attitude reference estimate for the spacecraft;use the attitude reference estimate to generate spacecraft position estimates;generate attitude commands;use a position-only control on the position estimates and the attitude commands to generate actuator torque commands; andcontinuously update the attitude reference estimate with the attitude measurements unless a sensor intrusion occurs. 7. A system for a spacecraft having a plurality of star trackers, the system comprising an attitude control processor configured to: use attitude measurements from the star trackers to provide an attitude reference estimate for the spacecraft;use the attitude reference estimate to generate spacecraft position estimates;generate attitude commands; anduse a position-only control including a two-state H-infinity control on the position estimates and the attitude commands to generate actuator for torque commands. 8. The system of claim 1, wherein the position-only control generates the actuator torque commands for roll, pitch and yaw without utilizing gyro information. 9. A spacecraft comprising: a plurality of star trackers;torque actuators; andthe control processor of claim 1. 10. A method in a spacecraft, the method comprising: generating an attitude reference estimate from star tracker attitude measurements;generating spacecraft position estimates from the attitude reference;generating attitude commands; andusing the position estimates and the attitude commands to cause actuators of the spacecraft to bring the spacecraft to a commanded attitude without utilizing gyro information;wherein a 1-2-3 Euler sequence of rotation is used to command spacecraft attitude relative to a local inertial reference frame, and Euler angles are represented by elevation, azimuth, and rotation of boresight. 11. The method of claim 10, wherein the inertial reference frame is an Earth-centered inertial frame of reference. 12. The method of claim 10, wherein the attitude commands cause the spacecraft to perform at least one of sun acquisition and safe hold maneuver. 13. The method of claim 10, wherein the attitude reference estimate is continuously updated with the attitude measurements unless a sensor intrusion occurs. 14. The method of claim 10, wherein reaction wheels of the spacecraft are commanded to bring the spacecraft to the commanded attitude. 15. A method in a spacecraft, the method comprising: generating an attitude reference estimate from star tracker attitude measurements;generating spacecraft position estimates from the attitude reference;generating attitude commands; andusing the position estimates and the attitude commands to cause actuators of the spacecraft to bring the spacecraft to a commanded attitude without utilizing gyro information;wherein gyroscopes aboard the spacecraft are kept in backup mode while the actuators are being commanded. 16. A spacecraft comprising: a plurality of star trackers;a plurality of torque actuators; andan attitude control processor for generating an attitude reference estimate from attitude measurements from the star trackers, generating spacecraft position estimates from the attitude reference, generating attitude commands including commands for at least one of sun acquisition and safe hold, and using the position estimates and the attitude commands to cause the actuators to bring the spacecraft to a commanded attitude without utilizing gyro information. 17. The spacecraft of claim 16, further comprising an inertial reference unit; wherein the control processor uses the attitude measurements from the star trackers instead of gyro information from the inertial reference unit to command the actuators. 18. The system of claim 1, wherein moving the star trackers includes rotating gimbals about Azimuth and Elevation at rates that create the spiral acquisition pattern.