Electrochromic orbit control for smart-dust devices
Electrochromic orbit control for smart-dust devices
Recent advances in MEMS (micro electromechanical systems) technology are leading to spacecraft which are the shape and size of computer chips, so-called SpaceChips, or ‘smart dust devices’. These devices can offer highly distributed sensing when used in future swarm applications. However, they currently lack a feasible strategy for active orbit control. This paper proposes an orbit control methodology for future SpaceChip devices which is based on exploiting the effects of solar radiation pressure using electrochromic coatings. The concept presented makes use of the high area-to-mass ratio of these devices, and consequently the large force exerted upon them by solar radiation pressure, to control their orbit evolution by altering their surface optical properties. The orbital evolution of Space Chips due to solar radiation pressure can be represented by a Hamiltonian system, allowing an analytic development of the control methodology. The motion in the orbital element phase space resembles that of a linear oscillator, which is used to formulate a switching control law. Additional perturbations and the effect of eclipses are accounted for by modifying the linearized equations of the secular change in orbital elements around an equilibrium point in the phase space of the problem. Finally, the effectiveness of the method is demonstrated in a test case scenario
Lücking, Charlotte
fd25bf1e-2dd3-4cdf-bee4-92c21d3a5ef2
Colombo, Camilla
595ced96-9494-40f2-9763-ad4a0f96bc86
McInnes, Colin
58a93321-a76d-42f9-9c2f-bfb659124b78
Lücking, Charlotte
fd25bf1e-2dd3-4cdf-bee4-92c21d3a5ef2
Colombo, Camilla
595ced96-9494-40f2-9763-ad4a0f96bc86
McInnes, Colin
58a93321-a76d-42f9-9c2f-bfb659124b78
Lücking, Charlotte, Colombo, Camilla and McInnes, Colin
(2012)
Electrochromic orbit control for smart-dust devices.
Journal of Guidance Control and Dynamics.
(doi:10.2514/1.55488).
(In Press)
Abstract
Recent advances in MEMS (micro electromechanical systems) technology are leading to spacecraft which are the shape and size of computer chips, so-called SpaceChips, or ‘smart dust devices’. These devices can offer highly distributed sensing when used in future swarm applications. However, they currently lack a feasible strategy for active orbit control. This paper proposes an orbit control methodology for future SpaceChip devices which is based on exploiting the effects of solar radiation pressure using electrochromic coatings. The concept presented makes use of the high area-to-mass ratio of these devices, and consequently the large force exerted upon them by solar radiation pressure, to control their orbit evolution by altering their surface optical properties. The orbital evolution of Space Chips due to solar radiation pressure can be represented by a Hamiltonian system, allowing an analytic development of the control methodology. The motion in the orbital element phase space resembles that of a linear oscillator, which is used to formulate a switching control law. Additional perturbations and the effect of eclipses are accounted for by modifying the linearized equations of the secular change in orbital elements around an equilibrium point in the phase space of the problem. Finally, the effectiveness of the method is demonstrated in a test case scenario
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Accepted/In Press date: 2012
Organisations:
Astronautics Group
Identifiers
Local EPrints ID: 342366
URI: http://eprints.soton.ac.uk/id/eprint/342366
ISSN: 0731-5090
PURE UUID: f9925cf7-0bed-4120-a634-0cf2f3586401
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Date deposited: 24 Aug 2012 08:25
Last modified: 14 Mar 2024 11:50
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Author:
Charlotte Lücking
Author:
Camilla Colombo
Author:
Colin McInnes
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