Rapid slew and settle systems for small satellites
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B64G-001/28
B64G-001/24
G05D-001/08
출원번호
US-0140065
(2016-04-27)
등록번호
US-9745082
(2017-08-29)
발명자
/ 주소
Lim, Sungyung
Tuohy, Seamus
Dionne, Daniel
Duchesne, Laurent
Breger, Louis
출원인 / 주소
The Charles Stark Draper Laboratory, Inc.
대리인 / 주소
Sunstein Kann Murphy & Timbers LLP
인용정보
피인용 횟수 :
0인용 특허 :
5
초록▼
A new approach for rapid slew and settle of small satellites is based on four single degree-of-freedom control moment gyroscopes with variable speed flywheels (or reaction wheels) in a pyramid configuration, combined with path and endpoint constraint time-optimal control. The path and endpoint const
A new approach for rapid slew and settle of small satellites is based on four single degree-of-freedom control moment gyroscopes with variable speed flywheels (or reaction wheels) in a pyramid configuration, combined with path and endpoint constraint time-optimal control. The path and endpoint constrained time-optimal control can be augmented with momentum management without the use of additional actuators.
대표청구항▼
1. A satellite attitude control system for a satellite, the satellite attitude control system comprising: four hybrid control moment gyroscopes arranged in a pyramid configuration, each hybrid control moment gyroscope including a control moment gyroscope actuator and a reaction wheel actuator; anda
1. A satellite attitude control system for a satellite, the satellite attitude control system comprising: four hybrid control moment gyroscopes arranged in a pyramid configuration, each hybrid control moment gyroscope including a control moment gyroscope actuator and a reaction wheel actuator; anda retargeting controller for retargeting the satellite from an initial state through a desired slew and settle maneuver to a desired final state using path and endpoint constrained time-optimal control, the retargeting controller configured to determine a set of gimbal angular rate vectors based on the initial state, the desired final state, and a predetermined set of path and endpoint constraints selected to avoid control moment gyroscope actuator singularities and reaction wheel actuator singularities and to ensure that the hybrid control moment gyroscopes will complete the slew maneuver in a configuration capable of performing the settle maneuver using the reaction wheel actuators and to produce retargeting commands for the hybrid control moment gyroscopes based on the set of gimbal angular rate vectors. 2. A satellite attitude control system according to claim 1, wherein the gimbal angles of each hybrid control moment gyroscope k are constrained by an endpoint constraint: CLE≦|sin(δk(tf))|≧CUE where δk is the k-th gimbal angle tf is the total slew and settle time, CLE is a lower bound and CUE is an upper bound. 3. A satellite attitude control system according to claim 2, wherein the gimbal angles at the end of the slew maneuver are constrained to be between 10 and 20 degrees, and wherein CLE=sin(10°) and CUE=sin(20°). 4. A satellite attitude control system according to claim 1, wherein the retargeting controller comprises: a PEC-TOC control problem formulator configured to formulate a control problem based on the initial state, the desired final state, and the predetermined set of path and endpoint constraints;a PEC-TOC control problem solver configured to solve the formulated control problem to determine the set of gimbal angular rate vectors; anda steering controller configured to produce the retargeting commands based on the set of gimbal angular rate vectors. 5. A satellite attitude control system according to claim 4, wherein the PEC-TOC control problem solver includes an embedded optimizer configured to use, as the initial state, one of: final state information from a prior control problem solution;a previous slew profile with similar beginning and ending conditions; orinformation from a lookup table that contains a set of pre-computed initialization states. 6. A satellite attitude control system according to claim 1, wherein the retargeting controller is further configured to determine a set of reaction wheel angular rate vectors for controlling flywheel spin rates of the reaction wheel actuators for performing momentum management during slew without the use of external actuators and to produce the retargeting commands based on the set of gimbal angular rate vectors and the set of reaction wheel angular rate vectors. 7. A satellite attitude control system according to claim 6, wherein the flywheel acceleration for each hybrid control moment gyroscope k is formulated as a constraint on desired final flywheel spin rate and is modeled as: Ω.=1τRW(uRW-Ω)where Ω is the reaction wheel spin rate, {dot over (Ω)} is the derivative of the reaction wheel spin rate, TRW is the reaction wheel actuator motor time constant and uRW is the reaction wheel actuator acceleration. 8. A retargeting controller for retargeting a satellite from an initial state through a desired slew and settle maneuver to a desired final state using path and endpoint constrained time-optimal control, the satellite having four hybrid control moment gyroscopes arranged in a pyramid configuration, each hybrid control moment gyroscope including a control moment gyroscope actuator and a reaction wheel actuator, the retargeting controller comprising: a PEC-TOC control problem formulator configured to formulate a control problem based on the initial state, the desired final state, and a predetermined set of path and endpoint constraints selected to avoid control moment gyroscope actuator singularities and reaction wheel actuator singularities and to ensure that the hybrid control moment gyroscopes will complete the slew maneuver in a configuration capable of performing the settle maneuver using the reaction wheel actuators; anda PEC-TOC control problem solver configured to solve the formulated control problem to determine a set of gimbal angular rate vectors for the hybrid control moment gyroscopes. 9. A retargeting controller according to claim 8, further comprising: a steering controller configured to produce retargeting commands for the hybrid control moment gyroscopes based on the set of gimbal angular rate vectors. 10. A retargeting controller according to claim 8, wherein the PEC-TOC control problem solver includes an embedded optimizer configured to use, as the initial state, one of: final state information from a prior control problem solution;a previous slew profile with similar beginning and ending conditions; orinformation from a lookup table that contains a set of pre-computed initialization states. 11. A retargeting controller according to claim 8, wherein the gimbal angles of each hybrid control moment gyroscope k are constrained by an endpoint constraint: CLE≦|sin(δk(tf))|≧CUE where δk is the k-th gimbal angle, tf is the total slew and settle time, CLE is a lower bound and CUE is an upper bound. 12. A retargeting controller according to claim 11, wherein the gimbal angles at the end of the slew maneuver are constrained to be between 10 and 20 degrees, and wherein CLE=sin(10°) and CUE=sin(20°). 13. A retargeting controller according to claim 8, wherein the retargeting controller is further configured to determine a set of reaction wheel angular rate vectors for controlling flywheel spin rates of the reaction wheel actuators for performing momentum management during slew without the use of external actuators and to produce the retargeting commands based on the set of gimbal angular rate vectors and the set of reaction wheel angular rate vectors. 14. A retargeting controller system according to claim 13, wherein the flywheel acceleration for each hybrid control moment gyroscope k is formulated as a constraint on desired final flywheel spin rate and is modeled as: Ω.=1τRW(uRW-Ω)where Ω is the reaction wheel spin rate, {dot over (Ω)} is the derivative of the reaction wheel spin rate, TRW is the reaction wheel actuator motor time constant and uRW is the reaction wheel actuator acceleration. 15. A method for retargeting a satellite from an initial state through a desired slew and settle maneuver to a desired final state using path and endpoint constrained time-optimal control, the satellite having four hybrid control moment gyroscopes arranged in a pyramid configuration, each hybrid control moment gyroscope including a control moment gyroscope actuator and a reaction wheel actuator, the method comprising: using at least one processor, determining a set of gimbal angular rate vectors based on the initial state, the desired final state, and a predetermined set of path and endpoint constraints selected to avoid control moment gyroscope actuator singularities and reaction wheel actuator singularities and to ensure that the hybrid control moment gyroscopes will complete the slew maneuver in a configuration capable of performing the settle maneuver using the reaction wheel actuators;producing retargeting commands for the hybrid control moment gyroscopes based on the set of gimbal angular rate vectors; andproviding the retargeting commands to the hybrid control moment gyroscopes. 16. A method according to claim 15, wherein determining the set of gimbal angular rate vectors comprises: formulating a control problem based on the initial state, the desired final state, and the predetermined set of path and endpoint constraints; andsolving the formulated control problem to determine the set of gimbal angular rate vectors. 17. A method according to claim 15, wherein the gimbal angles of each hybrid control moment gyroscope k are constrained by an endpoint constraint: CLE≦|sin(δk(tf))|≧CUE where δk is the k-th gimbal angle, tf is the total slew settle time, CLE is a lower bound and CUE is an upper bound. 18. A method according to claim 17, wherein the gimbal angles at the end of the slew maneuver are constrained to be between 10 and 20 degrees, and wherein CLE=sin(10°) and CUE=sin(20°). 19. A method according to claim 15, wherein determining the set of gimbal angular rate vectors comprises one of: using, as the initial state, final state information from a prior control problem solution;using, as the initial state, a previous slew profile with similar beginning and ending conditions; orusing, as the initial state, information from a lookup table that contains a set of pre-computed initialization states. 20. A method according to claim 15, wherein determining the set of gimbal angular rate vectors further comprises determining a set of reaction wheel angular rate vectors for controlling flywheel spin rates of the reaction wheel actuators for performing momentum management during slew without the use of external actuators, and wherein producing the retargeting commands for the hybrid control moment gyroscopes further comprises producing the retargeting commands based on the set of gimbal angular rate vectors and the set of reaction wheel angular rate vectors. 21. A method according to claim 20, wherein the flywheel acceleration for each hybrid control moment gyroscope k is modeled as: Ω.=1τRW(uRW-Ω)where Ω is the reaction wheel spin rate, {dot over (Ω)} is the derivative of the reaction wheel spin rate, TRW is the reaction wheel actuator motor time constant and uRW is the reaction wheel actuator acceleration. 22. A method according to claim 15, wherein the gimbal angular rate vectors are determined by at least one processor in the satellite. 23. A method according to claim 15, wherein the gimbal angular rate vectors are determined by a ground station and transmitted to the satellite.
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이 특허에 인용된 특허 (5)
Maute P. A. Alexandre (Valbonne FRX), Active three-axis attitude control system for a geostationary satellite.
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