Asteroid rotation and orbit control via laser ablation
Asteroid rotation and orbit control via laser ablation
This paper presents an approach to control the rotational motion of an asteroid while a spacecraft is deflecting its trajectory through laser ablation. During the deflection, the proximity motion of the spacecraft is coupled with the orbital and rotational motion of the asteroid. The combination of the deflection acceleration, solar radiation pressure, gravity field and plume impingement will force the spacecraft to drift away from the asteroid. In turn, a variation of the motion of the spacecraft produces a change in the modulus and direction of the deflection action which modifies the rotational and orbital motion of the asteroid. An on-board state estimation and control algorithm is then presented that simultaneously provides an optimal proximity control and a control of the rotational motion of the asteroid. It will be shown that the simultaneous control of the rotational and proximity motions of asteroid and spacecraft has a significant impact on the required deflection time.
asteroid rotation control, asteroid deflection, proximity operation, spacecraft control, rotational dynamics
1-38
Vetrisano, Massimo
af20d869-732e-4b68-bcca-633ef32badce
Colombo, Camilla
595ced96-9494-40f2-9763-ad4a0f96bc86
Vasile, Massimiliano
de6550cb-82fc-49eb-b90b-dffa9787bf7d
Vetrisano, Massimo
af20d869-732e-4b68-bcca-633ef32badce
Colombo, Camilla
595ced96-9494-40f2-9763-ad4a0f96bc86
Vasile, Massimiliano
de6550cb-82fc-49eb-b90b-dffa9787bf7d
Vetrisano, Massimo, Colombo, Camilla and Vasile, Massimiliano
(2015)
Asteroid rotation and orbit control via laser ablation.
Advances in Space Research, .
(doi:10.1016/j.asr.2015.06.035).
Abstract
This paper presents an approach to control the rotational motion of an asteroid while a spacecraft is deflecting its trajectory through laser ablation. During the deflection, the proximity motion of the spacecraft is coupled with the orbital and rotational motion of the asteroid. The combination of the deflection acceleration, solar radiation pressure, gravity field and plume impingement will force the spacecraft to drift away from the asteroid. In turn, a variation of the motion of the spacecraft produces a change in the modulus and direction of the deflection action which modifies the rotational and orbital motion of the asteroid. An on-board state estimation and control algorithm is then presented that simultaneously provides an optimal proximity control and a control of the rotational motion of the asteroid. It will be shown that the simultaneous control of the rotational and proximity motions of asteroid and spacecraft has a significant impact on the required deflection time.
Text
Vetrisano_Asteroid.pdf
- Accepted Manuscript
More information
Accepted/In Press date: 27 June 2015
e-pub ahead of print date: 3 July 2015
Keywords:
asteroid rotation control, asteroid deflection, proximity operation, spacecraft control, rotational dynamics
Organisations:
Astronautics Group
Identifiers
Local EPrints ID: 378954
URI: http://eprints.soton.ac.uk/id/eprint/378954
ISSN: 0273-1177
PURE UUID: 28424afa-c006-4012-8f7b-035868458acf
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Date deposited: 15 Jul 2015 10:43
Last modified: 14 Mar 2024 20:31
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Contributors
Author:
Massimo Vetrisano
Author:
Camilla Colombo
Author:
Massimiliano Vasile
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