Optimal sun safe attitude for satellite ground tracking
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B64G-001/24
F02K-001/00
F02K-003/00
F02K-005/00
F02K-007/00
F02K-009/00
F03H-001/00
F03H-003/00
출원번호
UP-0633268
(2006-12-04)
등록번호
US-7823836
(2010-11-22)
발명자
/ 주소
Ho, Yiu-Hung M.
Liu, John Y.
출원인 / 주소
The Boeing Company
대리인 / 주소
Gates & Cooper LLP
인용정보
피인용 횟수 :
2인용 특허 :
6
초록▼
A method and apparatus for maneuvering a satellite in orbit to alternately optimize the collection of solar energy and to take sensor data of terrestrial objects is disclosed The longitudinal axis of a large payload package is oriented perpendicular to the orbital plane to minimize the disturbance t
A method and apparatus for maneuvering a satellite in orbit to alternately optimize the collection of solar energy and to take sensor data of terrestrial objects is disclosed The longitudinal axis of a large payload package is oriented perpendicular to the orbital plane to minimize the disturbance torque due to gravity gradient, and to allow simple rotation about the axis for attitude change between optimal Sun and optimal ground coverage.
대표청구항▼
What is claimed is: 1. A method of maneuvering a satellite in an orbit, the satellite having a payload disposed longitudinally along a first (x) axis and rotatable solar panels disposed longitudinally along a second (y) axis perpendicular to the first axis (x), the satellite having a moment of iner
What is claimed is: 1. A method of maneuvering a satellite in an orbit, the satellite having a payload disposed longitudinally along a first (x) axis and rotatable solar panels disposed longitudinally along a second (y) axis perpendicular to the first axis (x), the satellite having a moment of inertia about the first axis IXX and about the second axis IYY and a moment of inertia IZZ about a third (z) axis perpendicular to the first axis (x) and the second (y) axis such that IXX<IYY and IXX<IZZ the method comprising the steps of: when the satellite is not in a payload data collection mode, performing steps comprising the steps of: orienting the satellite to align the first (x) axis normal to the plane of the orbit; rotating the satellite about the first (x) axis such that the second (y) axis is perpendicular to a Sun line of sight; rotating the solar panels about the second (y) axis at a first angle (θ) from the satellite orbital plane to orient the solar panels towards the Sun; and maintaining the alignment of the first (x) axis normal to the satellite orbital plane during the non-payload data collection mode; when the satellite is in a payload data collection mode, performing steps comprising the steps of: rotating the satellite about only the first (x) axis to direct the payload at a terrestrial target; and collecting payload data. 2. The method of claim 1, wherein the step of orienting the satellite to align the first (x) axis normal to the plane of the orbit comprises orienting the satellite to align the first axis (x) to be perpendicular to the Earth nadir and a satellite velocity vector. 3. The method of claim 1, wherein the step of maintaining the alignment of the first (x) axis normal to the satellite orbital plane during the non-payload data collection mode comprises the step of rotating the satellite about the first (x) axis to maintain the alignment of the first (x) axis normal to the satellite orbital plane and to direct the second (y) axis perpendicular to the Sun line of sight. 4. The method of claim 1, wherein the step of maintaining the alignment of the first (x) axis normal to the satellite orbital plane during the non-payload data collection mode comprises the step of rotating the first (x) axis about the same axis and at the same rate as a nodal precession of the orbital plane. 5. The method of claim 1, wherein the payload comprises a sensor array longitudinally disposed along the first (x) axis. 6. An apparatus for maneuvering a satellite in an orbit, the satellite having a payload disposed longitudinally along a first (x) axis and rotatable solar panels disposed longitudinally along a second (y) axis perpendicular to the first axis (x), the satellite having a moment of inertia about the first axis IXX and about the second axis IYY and a moment of inertia IZZ about a third axis (z) perpendicular to the first axis (x) and the second (y) axis such that IXX <IYY and IXX<IZZ, comprising an attitude control system, comprising a plurality of attitude motive elements, the plurality of attitude motive elements for changing the attitude of the satellite in the first (x) axis, the second (y) axis, and the third (z) axis; a processor, communicatively coupled to the attitude motive elements, the processor also communicatively coupled to a memory storing instructions comprising instructions for: when the satellite is not in a payload data collection mode, maneuvering the satellite to a first orientation by orienting the satellite to align the first (x) axis normal to the plane of the orbit, rotating the satellite about the first (x) axis such that the second (y) axis is perpendicular to a Sun line of sight, and rotating the solar panels about the second (y) axis at a first angle (θ) from the satellite orbital plane to orient the solar panels towards the Sun, and maintaining the alignment of the first (x) axis normal to the satellite orbital plane during the non-payload data collection mode; and when the satellite is in a payload data collection mode, maneuvering the satellite to a second orientation by rotating the satellite only about the first (x) axis to direct the payload at a terrestrial target to collect the payload data. 7. The apparatus of claim 6, wherein the instructions for orienting the satellite to align the first (x) axis normal to the plane of the orbit comprise instructions for orienting the satellite to align the first axis (x) to be perpendicular to the Earth nadir and a satellite velocity vector. 8. The apparatus of claim 6, wherein the instructions for maintaining the alignment of the first (x) axis normal to the satellite orbital plane during the non-payload data collection mode comprises instructions for rotating the satellite about the first (x) axis to maintain the alignment of the first (x) axis normal to the satellite orbital plane and to direct the second (y) axis perpendicular to the Sun line of sight. 9. The apparatus of claim 6, wherein the instructions for maintaining the alignment of the first (x) axis normal to the satellite orbital plane during the non-payload data collection mode comprise instructions for rotating the first (x) axis about the same axis and at the same rate as a nodal precession of the orbital plane. 10. The apparatus of claim 6, wherein the payload comprises a sensor array longitudinally disposed along the first (x) axis. 11. A apparatus for maneuvering a satellite in an orbit, the satellite having a payload disposed longitudinally along a first (x) axis and rotatable solar panels disposed longitudinally along a second (y) axis perpendicular to the first axis (x), the satellite having a moment of inertia about the first axis IXX and about the second axis IYY, and a moment of inertia IZZ about a third axis (z) perpendicular to the first axis (x) and the second (y) axis such that IXX<IYY and IXX<IZZ the apparatus comprising: means for orienting the satellite to align the first (x) axis normal to the plane of the orbit, maintaining the alignment of the first (x) axis normal to the satellite orbital plane during the non-payload data collection mode, and rotating the satellite about the first (x) axis such that the second (y) axis is perpendicular to a Sun line of sight, and rotating the solar panels about the second (y) axis at a first angle (θ) from the satellite orbital plane to orient the solar panels towards the Sun when the satellite is not in a payload data collection mode, maneuvering the satellite to a first orientation; and means for rotating the satellite only about the first (x) axis to direct the payload at a terrestrial target and collecting payload data when the satellite is in a payload data collection mode, maneuvering the satellite to a second orientation. 12. The apparatus of claim 11, wherein the means for orienting the satellite to align the first (x) axis normal to the plane of the orbit comprise means for orienting the satellite to align the first axis (x) to be perpendicular to the Earth nadir and a satellite velocity vector. 13. The apparatus of claim 11, wherein the means for maintaining the alignment of the first (x) axis normal to the satellite orbital plane during the non-payload data collection mode comprises means for rotating the satellite about the first (x) axis to maintain the alignment of the first (x) axis normal to the satellite orbital plane and to direct the second (y) axis perpendicular to the Sun line of sight. 14. The apparatus of claim 11, wherein the means for maintaining the alignment of the first (x) axis normal to the satellite orbital plane during the non-payload data collection mode comprises the means for rotating the first (x) axis about the same axis and at the same rate as a nodal precession of the orbital plane. 15. The apparatus of claim 11, wherein the satellite comprises a payload array longitudinally disposed along the first (x) axis.
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이 특허에 인용된 특허 (6)
Salkeld Robert J. (266 Blood\s Ridge Rd. Bear Valley CA 95223) Sklarew Ralph C. (963 Dunlin Westlake Village CA 91366), Closed space structures.
Johnson Caldwell C. (Dickinson TX) Faget Maxime A. (Dickinson TX) Bergeron ; III David J. (Houston TX), Spacecraft operable in two alternative flight modes.
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