TY - GEN
T1 - Concepts and Applications of Aerodynamic Attitude and Orbital Control for Spacecraft in Very Low Earth Orbit
AU - Livadiotti, Sabrina
AU - Crisp, Nicholas H.
AU - Roberts, Peter C.E.
AU - Edmondson, Stephen
AU - Haigh, Sarah J.
AU - Huyton, Claire
AU - Lyons, Rachel
AU - Oiko, Vitor T.A.
AU - Smith, Katharine L.
AU - Sinpetru, Luciana
AU - Straker, Alastair
AU - Worrall, Stephen D
AU - Becedas, Jonathan
AU - Domínguez, Rosa María
AU - Gonzalez, David
AU - Cañas, Valentin
AU - Hanessian, Virginia
AU - Mølgaard, Anders
AU - Nielsen, Jens Cosedis
AU - Bisgaard, Morten
AU - Boxberger, Adam
AU - Chan, Yung An
AU - Herdrich, Georg H.
AU - Romano, Francesco
AU - Fasoulas, Stefanos
AU - Traub, Constantin
AU - Garcia-Almiñana, Daniel
AU - Rodriguez-Donaire, Silvia
AU - Sureda, Miquel
AU - Kataria, Dhiren
AU - Outlaw, Ron
AU - Belkouchi, Badia
AU - Conte, Alexis
AU - Perez, Jose Santiago
AU - Villain, Rachel
AU - Heißerer, Barbara
AU - Schwalber, Ameli
PY - 2019/10/25
Y1 - 2019/10/25
N2 - Spacecraft operations below 450km, namely Very Low Earth Orbit (VLEO), can offer significant advantages over traditional low Earth orbits, for example enhanced ground resolution for Earth observation, improved communications latency and link budget, or improved signal-to-noise ratio. Recently, these lower orbits have begun to be exploited as a result of technology development, particularly component miniaturisation and cost-reduction, and concerns over the increasing debris population in commercially exploited orbits. However, the high cost of orbital launch and challenges associated with atmospheric drag, causing orbital decay and eventually re-entry are still a key barrier to their wider use for large commercial and civil spacecraft. Efforts to address the impact of aerodynamic drag are being sought through the development of novel drag-compensation propulsion systems and identification of materials which can reduce aerodynamic drag by specularly reflecting the incident gas. However, the presence of aerodynamic forces can also be utilised to augment or improve spacecraft operations at these very low altitudes by providing the capability to perform coarse pointing control and trim or internal momentum management for example. This paper presents concepts for the advantageous use of spacecraft aerodynamics developed as part of DISCOVERER, a Horizon 2020 funded project with the aim to revolutionise Earth observation satellite operations in VLEO. The combination of novel spacecraft geometries and use of aerodynamic control methods are explored, demonstrating the potential for a new generation of Earth observation satellites operating at lower altitudes.
AB - Spacecraft operations below 450km, namely Very Low Earth Orbit (VLEO), can offer significant advantages over traditional low Earth orbits, for example enhanced ground resolution for Earth observation, improved communications latency and link budget, or improved signal-to-noise ratio. Recently, these lower orbits have begun to be exploited as a result of technology development, particularly component miniaturisation and cost-reduction, and concerns over the increasing debris population in commercially exploited orbits. However, the high cost of orbital launch and challenges associated with atmospheric drag, causing orbital decay and eventually re-entry are still a key barrier to their wider use for large commercial and civil spacecraft. Efforts to address the impact of aerodynamic drag are being sought through the development of novel drag-compensation propulsion systems and identification of materials which can reduce aerodynamic drag by specularly reflecting the incident gas. However, the presence of aerodynamic forces can also be utilised to augment or improve spacecraft operations at these very low altitudes by providing the capability to perform coarse pointing control and trim or internal momentum management for example. This paper presents concepts for the advantageous use of spacecraft aerodynamics developed as part of DISCOVERER, a Horizon 2020 funded project with the aim to revolutionise Earth observation satellite operations in VLEO. The combination of novel spacecraft geometries and use of aerodynamic control methods are explored, demonstrating the potential for a new generation of Earth observation satellites operating at lower altitudes.
UR - https://iafastro.directory/iac/archive/browse/IAC-19/
M3 - Conference publication
BT - 70th International Astronautical Congress (IAC)
PB - International Astronautical Federation, IAF
T2 - 70th International Astronautical Congress, IAC 2019
Y2 - 21 October 2019 through 25 October 2019
ER -