On the predictability and robustness of Galileo disposal orbits
On the predictability and robustness of Galileo disposal orbits
The end-of-life disposal of Galileo satellites is needed to avoid collisions with operational spacecraft and to prevent the generation of space debris. Either disposal into stable graveyard orbits or disposal into the atmosphere exploiting eccentricity growth caused by lunisolar resonances is possible. However, there is a concern about the predictability of medium Earth orbits because of possible chaotic behaviour caused by the overlap of resonances. In this work, we investigate if Galileo disposal orbits are predictable and robust, that is, if safe disposal is possible under uncertainties. For this, we employ finite-time Lyapunov exponents (FTLEs) to study the chaoticity of orbits. In addition, sensitivity analysis is used to quantify the effect of uncertainties on the orbital evolution and to determine if safe disposal is possible. Whether the disposal orbits are chaotic or not could not be concluded from the FTLE analysis, because the observed divergence between neighbouring orbits can also be caused by hyperbolicity of the dynamics. Nevertheless, because the resonance dynamics are perturbed and resonances may overlap, all disposal orbits are expected to be chaotic. Regarding robustness, we found that the majority of the investigated re-entry disposal trajectories (including low ΔV solutions) is robust. On the other hand, we find that the investigated graveyard orbits and a small portion of the assessed re-entry orbits are not robust under uncertainties in the disposal manoeuvre and in the dynamical model. Therefore, it is mandatory to assess the sensitivity of a disposal orbit to uncertainties to ensure safe disposal.
Gondelach, David
693aa9ad-3625-4ec6-867c-101fa9c98b00
Armellin, Roberto
fb6044e3-c3fd-4a3d-a150-592efb2c0365
Wittig, Alexander Nicolaus
3a140128-b118-4b8c-9856-a0d4f390b201
29 November 2019
Gondelach, David
693aa9ad-3625-4ec6-867c-101fa9c98b00
Armellin, Roberto
fb6044e3-c3fd-4a3d-a150-592efb2c0365
Wittig, Alexander Nicolaus
3a140128-b118-4b8c-9856-a0d4f390b201
Gondelach, David, Armellin, Roberto and Wittig, Alexander Nicolaus
(2019)
On the predictability and robustness of Galileo disposal orbits.
Celestial Mechanics and Dynamical Astronomy, 131 (60).
(doi:10.1007/s10569-019-9938-9).
Abstract
The end-of-life disposal of Galileo satellites is needed to avoid collisions with operational spacecraft and to prevent the generation of space debris. Either disposal into stable graveyard orbits or disposal into the atmosphere exploiting eccentricity growth caused by lunisolar resonances is possible. However, there is a concern about the predictability of medium Earth orbits because of possible chaotic behaviour caused by the overlap of resonances. In this work, we investigate if Galileo disposal orbits are predictable and robust, that is, if safe disposal is possible under uncertainties. For this, we employ finite-time Lyapunov exponents (FTLEs) to study the chaoticity of orbits. In addition, sensitivity analysis is used to quantify the effect of uncertainties on the orbital evolution and to determine if safe disposal is possible. Whether the disposal orbits are chaotic or not could not be concluded from the FTLE analysis, because the observed divergence between neighbouring orbits can also be caused by hyperbolicity of the dynamics. Nevertheless, because the resonance dynamics are perturbed and resonances may overlap, all disposal orbits are expected to be chaotic. Regarding robustness, we found that the majority of the investigated re-entry disposal trajectories (including low ΔV solutions) is robust. On the other hand, we find that the investigated graveyard orbits and a small portion of the assessed re-entry orbits are not robust under uncertainties in the disposal manoeuvre and in the dynamical model. Therefore, it is mandatory to assess the sensitivity of a disposal orbit to uncertainties to ensure safe disposal.
Text
1901.06947
- Accepted Manuscript
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Published date: 29 November 2019
Identifiers
Local EPrints ID: 452542
URI: http://eprints.soton.ac.uk/id/eprint/452542
ISSN: 0923-2958
PURE UUID: 8c536cb9-59b2-476f-a3a2-88f32a404666
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Date deposited: 11 Dec 2021 11:26
Last modified: 17 Mar 2024 06:54
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Author:
David Gondelach
Author:
Roberto Armellin
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