A new analysis of debris mitigation and removal using networks
A new analysis of debris mitigation and removal using networks
Modelling studies have shown that the implementation of mitigation guidelines, which aim to reduce the amount of new debris generated on-orbit, is an important requirement of future space activities but may be insufficient to stabilise the near-Earth debris environment. The role of a variety of mitigation practices in stabilising the environment has been investigated over the last decade, as has the potential of active debris removal (ADR) methods in recent work. We present a theoretical approach to the analysis of the debris environment that is based on the study of networks, composed of vertices and edges, which describe the dynamic relationships between Earth satellites in the debris system. Future projections of the 10 cm and larger satellite population in a non-mitigation scenario, conducted with the DAMAGE model, are used to illustrate key aspects of this approach. Information from the DAMAGE projections are used to reconstruct a network in which vertices represent satellites and edges encapsulate conjunctions between collision pairs. The network structure is then quantified using statistical measures, providing a numerical baseline for this future projection scenario. Finally, the impact of mitigation strategies and active debris removal, which can be mapped onto the network by altering or removing edges and vertices, can be assessed in terms of the changes from this baseline. The paper introduces the network methodology, highlights the ways in which this approach can be used to formalise criteria for debris mitigation and removal. It then summarises changes to the adopted network that correspond to an increasing stability and changes that represent a decreasing stability of the future debris environment.
space debris, active debris removal, complexity science, networks, network theory
257-268
Lewis, Hugh G.
e9048cd8-c188-49cb-8e2a-45f6b316336a
Newland, Rebecca J.
af539f77-a9c9-4c3d-91b6-cd48c6c32219
Swinerd, Graham G.
4aa174ec-d08c-4972-9986-966e17e072a0
Saunders, Arrun
97e80137-ddf8-4cde-9501-842de95f86a8
2010
Lewis, Hugh G.
e9048cd8-c188-49cb-8e2a-45f6b316336a
Newland, Rebecca J.
af539f77-a9c9-4c3d-91b6-cd48c6c32219
Swinerd, Graham G.
4aa174ec-d08c-4972-9986-966e17e072a0
Saunders, Arrun
97e80137-ddf8-4cde-9501-842de95f86a8
Lewis, Hugh G., Newland, Rebecca J., Swinerd, Graham G. and Saunders, Arrun
(2010)
A new analysis of debris mitigation and removal using networks.
Acta Astronautica, 66, .
(doi:10.1016/j.actaastro.2009.05.010).
Abstract
Modelling studies have shown that the implementation of mitigation guidelines, which aim to reduce the amount of new debris generated on-orbit, is an important requirement of future space activities but may be insufficient to stabilise the near-Earth debris environment. The role of a variety of mitigation practices in stabilising the environment has been investigated over the last decade, as has the potential of active debris removal (ADR) methods in recent work. We present a theoretical approach to the analysis of the debris environment that is based on the study of networks, composed of vertices and edges, which describe the dynamic relationships between Earth satellites in the debris system. Future projections of the 10 cm and larger satellite population in a non-mitigation scenario, conducted with the DAMAGE model, are used to illustrate key aspects of this approach. Information from the DAMAGE projections are used to reconstruct a network in which vertices represent satellites and edges encapsulate conjunctions between collision pairs. The network structure is then quantified using statistical measures, providing a numerical baseline for this future projection scenario. Finally, the impact of mitigation strategies and active debris removal, which can be mapped onto the network by altering or removing edges and vertices, can be assessed in terms of the changes from this baseline. The paper introduces the network methodology, highlights the ways in which this approach can be used to formalise criteria for debris mitigation and removal. It then summarises changes to the adopted network that correspond to an increasing stability and changes that represent a decreasing stability of the future debris environment.
Text
IAC-08-A6-4-9-ACTA-ASTRONAUTICA-TEXT.pdf
- Accepted Manuscript
Archive
AA-D-09-00153-FIGURES.zip
- Accepted Manuscript
More information
Submitted date: May 2009
Accepted/In Press date: May 2009
Published date: 2010
Keywords:
space debris, active debris removal, complexity science, networks, network theory
Organisations:
Astronautics Group
Identifiers
Local EPrints ID: 68965
URI: http://eprints.soton.ac.uk/id/eprint/68965
ISSN: 0094-5765
PURE UUID: 220bd7bc-f82f-4ae4-99d2-f697ecabe56f
Catalogue record
Date deposited: 13 Oct 2009
Last modified: 14 Mar 2024 02:40
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Contributors
Author:
Rebecca J. Newland
Author:
Arrun Saunders
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