According to one embodiment of the invention, a stationkeeping method for a geostationary satellite includes determining a gravitational force of the sun on the satellite at a beginning of a stationkeeping operation and a gravitational force of the moon on the satellite at the beginning of the stati
According to one embodiment of the invention, a stationkeeping method for a geostationary satellite includes determining a gravitational force of the sun on the satellite at a beginning of a stationkeeping operation and a gravitational force of the moon on the satellite at the beginning of the stationkeeping operation. An initial inclination vector of the satellite is determined at the beginning of the stationkeeping operation that accounts for a first set of one or more perturbations affecting the orbit of the satellite. A maneuver strategy is determined to correct for a second set of one or more perturbations affecting the orbit of the satellite without accounting for the first set of one or more perturbations affecting the orbit of the satellite. Finally, a maneuver is performed on the satellite according to the maneuver strategy.
대표청구항▼
What is claimed is: 1. A geostationary stationkeeping method, comprising: determining a gravitational force of the sun on a satellite at a beginning of a stationkeeping operation; determining a gravitational force of the moon on the satellite at the beginning of the stationkeeping operation; determ
What is claimed is: 1. A geostationary stationkeeping method, comprising: determining a gravitational force of the sun on a satellite at a beginning of a stationkeeping operation; determining a gravitational force of the moon on the satellite at the beginning of the stationkeeping operation; determining an initial inclination vector of the satellite that prevents the satellite from exceeding a predefined inclination box while the satellite is in orbit, wherein the initial inclination vector accounts for a first set of one or more perturbations affecting the orbit of the satellite, wherein the first set of one or more perturbations affecting the orbit of the satellite comprises an 18.6 year moon perturbation; determining a guard band for a mean inclination of the satellite, wherein a size of the guard band is calculated based on unmodeled small amplitude short period perturbations, maneuver error, and orbit estimation error, the guard band located within the inclination box; determining a maneuver strategy to correct for a second set of one or more perturbations affecting the orbit of the satellite without accounting for the first set of one or more perturbations affecting the orbit of the satellite and to maintain a mean inclination of the satellite within the guard band to guarantee the inclination of the satellite does not exceed the inclination box; and performing a maneuver on the satellite according to the maneuver strategy. 2. The geostationary stationkeeping method of claim 1, wherein the second set of one or more perturbations affecting the orbit of the satellite comprises a long period perturbation of the moon. 3. The geostationary stationkeeping method of claim 1, wherein the second set of one or more perturbations affecting the orbit of the satellite comprises a long period perturbation of the sun. 4. The geostationary stationkeeping method of claim 1, wherein the maneuver is applied periodically. 5. The geostationary stationkeeping method of claim 1, wherein the maneuver is applied continuously. 6. The geostationary stationkeeping method of claim 1, wherein the maneuver is applied at least once every eight weeks. 7. The geostationary stationkeeping method of claim 1, wherein the inclination vector of the satellite comprises a vector in the direction of the angle of right ascension of the ascending node of the satellite's orbit with a magnitude of the inclination of the orbit. 8. The geostationary stationkeeping method of claim 1, wherein the inclination vector of the satellite does not exceed a first predetermined value while the satellite is in orbit. 9. The geostationary stationkeeping method of claim 8, wherein the mean inclination vector of the satellite does not exceed a second predetermined value that is lower than the first predetermined value while the satellite is in orbit. 10. A geostationary stationkeeping method, comprising: determining a direction of the sun gravitational force on a satellite at a beginning of a stationkeeping operation; determining a direction of the moon gravitational force on a satellite at the beginning of the stationkeeping operation; determining an effect of an 18.6 year moon perturbation on an inclination and a right ascension of the satellite at the beginning of the stationkeeping operation; determining an initial inclination vector of the satellite that prevents the satellite from exceeding a predefined inclination box while the satellite is in orbit, the initial inclination vector accounting for the effect of the 18.6 year moon perturbation and the direction of the sun and moon gravitational forces on the satellite; determining a guard band for a mean inclination of the satellite, wherein a size of the guard band is calculated based on unmodeled small amplitude short period perturbations, maneuver error, and orbit estimation error, the guard band located within the inclination box; determining a maneuver strategy for preventing the inclination vector of the satellite from exceeding a first predetermined value by correcting for only the long period effects of the sun and moon while the satellite is in orbit and to maintain a mean inclination of the satellite within the guard band to guarantee the inclination of the satellite does not exceed the inclination box; and performing periodically a maneuver on the satellite according to the maneuver strategy. 11. The geostationary stationkeeping method of claim 10, wherein the maneuver is applied at least once every eight weeks. 12. The geostationary stationkeeping method of claim 10, wherein the mean inclination vector of the satellite does not exceed a second predetermined value that is lower than the a first predetermined value while the satellite is in orbit. 13. An apparatus comprising: a computer-readable medium; and program code stored on the computer-readable medium and operable, when executed to: determine a gravitational force of the sun on a satellite at a beginning of a stationkeeping operation; determine a gravitational force of the moon on the satellite at the beginning of the stationkeeping operation; determine an initial inclination vector of the satellite that prevents the satellite from exceeding a predefined inclination box while the satellite is in orbit, wherein the initial inclination vector accounts for a first set of one or more perturbations affecting the orbit of the satellite, wherein the first set of one or more perturbations affecting the orbit of the satellite comprises an 18.6 year moon perturbation; determining a guard band for a mean inclination of the satellite, wherein a size of the guard band is calculated based on unmodeled small amplitude short period perturbations, maneuver error, and orbit estimation error, the guard band located within the inclination box; determine a maneuver strategy to correct for a second set of one or more perturbations affecting the orbit of the satellite without accounting for the first set of one or more perturbations affecting the orbit of the satellite and to maintain a mean inclination of the satellite within the guard band to guarantee the inclination of the satellite does not exceed the inclination box; and perform a maneuver on the satellite according to the maneuver strategy. 14. The apparatus of claim 13, wherein the second set of one or more perturbations affecting the orbit of the satellite comprises a long period perturbation of the moon. 15. The apparatus of claim 13, wherein the second set of one or more perturbations affecting the orbit of the satellite comprises a long period perturbation of the sun. 16. The apparatus of claim 13, wherein the maneuver is applied periodically. 17. The apparatus of claim 13, wherein the maneuver is applied at least once every eight weeks. 18. The apparatus of claim 13, wherein the inclination vector of the satellite comprises a vector in the direction of the angle of right ascension of the ascending node of the satellite's orbit with a magnitude of the inclination of the orbit. 19. The apparatus of claim 13, wherein the inclination vector of the satellite does not exceed a first predetermined value while the satellite is in orbit. 20. The apparatus of claim 19, wherein the mean inclination vector of the satellite does not exceed a second predetermined value that is lower than the first predetermined value while the satellite is in orbit.
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