Effective stability of quasi-satellite orbits in the spatial problem for phobos exploration
Effective stability of quasi-satellite orbits in the spatial problem for phobos exploration
The generation of bounded trajectories complying with operational constraints in the complex dynamic environment surrounding Phobos is not an easy task. The vicinity of Phobos is dominated by the gravity field of Mars; consequently, orbiting on a Keplerian orbit about this moon is not feasible. The quasi-satellite orbit (QSO) is a means to orbit Phobos in the sense of relative motion. In particular, the three-dimensional QSO (3D QSO) has been recently suggested as an approach for better meeting mission objectives, such as global mapping. However, the linear stability of QSOs concluded in the simplified three-body model cannot sufficiently ensure a stability domain for operations. In this context, this paper investigates the strategy for designing bounded orbits with desired stability properties and characteristics for observation. Families of periodic 3D QSOs are first computed in the circular-restricted three-body problem. The sensitivity of the QSOs to the initial epoch and operational errors is analyzed, revealing effective stability levels and region that can guide trajectory and operation design. The stability levels are then validated by a dispersion analysis in the full dynamics. Furthermore, being guided by effective stability, a preliminary attempt to maintain low-altitude and high-inclination QSOs in the full dynamics has proven successful.
2309-2320
Chen, Hongru
8286469d-afe1-46e5-b107-694017de4d97
Canalias, Elisabet
900c6845-45ee-4422-b21b-810d5f27f21d
Hestroffer, Daniel
06b8b68f-3a94-4f2e-b434-ce6822b08c71
Hou, Xiyun
f0b359ce-3eeb-4950-9523-88bc4f16b931
Chen, Hongru
8286469d-afe1-46e5-b107-694017de4d97
Canalias, Elisabet
900c6845-45ee-4422-b21b-810d5f27f21d
Hestroffer, Daniel
06b8b68f-3a94-4f2e-b434-ce6822b08c71
Hou, Xiyun
f0b359ce-3eeb-4950-9523-88bc4f16b931
Chen, Hongru, Canalias, Elisabet, Hestroffer, Daniel and Hou, Xiyun
(2020)
Effective stability of quasi-satellite orbits in the spatial problem for phobos exploration.
Journal of Guidance, Control, and Dynamics, 43 (12), .
(doi:10.2514/1.G004911).
Abstract
The generation of bounded trajectories complying with operational constraints in the complex dynamic environment surrounding Phobos is not an easy task. The vicinity of Phobos is dominated by the gravity field of Mars; consequently, orbiting on a Keplerian orbit about this moon is not feasible. The quasi-satellite orbit (QSO) is a means to orbit Phobos in the sense of relative motion. In particular, the three-dimensional QSO (3D QSO) has been recently suggested as an approach for better meeting mission objectives, such as global mapping. However, the linear stability of QSOs concluded in the simplified three-body model cannot sufficiently ensure a stability domain for operations. In this context, this paper investigates the strategy for designing bounded orbits with desired stability properties and characteristics for observation. Families of periodic 3D QSOs are first computed in the circular-restricted three-body problem. The sensitivity of the QSOs to the initial epoch and operational errors is analyzed, revealing effective stability levels and region that can guide trajectory and operation design. The stability levels are then validated by a dispersion analysis in the full dynamics. Furthermore, being guided by effective stability, a preliminary attempt to maintain low-altitude and high-inclination QSOs in the full dynamics has proven successful.
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Accepted/In Press date: 22 June 2020
e-pub ahead of print date: 9 August 2020
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Local EPrints ID: 490968
URI: http://eprints.soton.ac.uk/id/eprint/490968
ISSN: 0731-5090
PURE UUID: 67d22917-3366-4dc6-bd16-cba3fe0c0211
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Date deposited: 10 Jun 2024 17:01
Last modified: 11 Jun 2024 02:10
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Author:
Hongru Chen
Author:
Elisabet Canalias
Author:
Daniel Hestroffer
Author:
Xiyun Hou
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