On target for Venus - Set oriented computation of energy efficient low thrust trajectories

Michael Dellnitz; Oliver Junge; Marcus Post; Bianca Thiere

doi:10.1007/s10569-006-9008-y

On target for Venus - Set oriented computation of energy efficient low thrust trajectories

Michael Dellnitz, Oliver Junge, Marcus Post, Bianca Thiere

Associate Professorship of Numerics of Complex Systems

Universität Paderborn

Research output: Contribution to journal › Article › peer-review

60 Scopus citations

Abstract

Recently new techniques for the design of energy efficient trajectories for space missions have been proposed that are based on the circular restricted three body problem as the underlying mathematical model. These techniques exploit the structure and geometry of certain invariant sets and associated invariant manifolds in phase space to systematically construct energy efficient flight paths. In this paper, we extend this model in order to account for a continuously applied control force on the spacecraft as realized by certain low thrust propulsion systems. We show how the techniques for the trajectory design can be suitably augmented and compute approximations to trajectories for a mission to Venus.

Original language	English
Pages (from-to)	357-370
Number of pages	14
Journal	Celestial Mechanics and Dynamical Astronomy
Volume	95
Issue number	1-4
DOIs	https://doi.org/10.1007/s10569-006-9008-y
State	Published - May 2006

Keywords

Dynamical system
Earth venus transfer
Invariant manifold
Low thrust trajectory
Reachable set
Set oriented numerics
Space mission design
Three body problem

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10.1007/s10569-006-9008-y

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title = "On target for Venus - Set oriented computation of energy efficient low thrust trajectories",

abstract = "Recently new techniques for the design of energy efficient trajectories for space missions have been proposed that are based on the circular restricted three body problem as the underlying mathematical model. These techniques exploit the structure and geometry of certain invariant sets and associated invariant manifolds in phase space to systematically construct energy efficient flight paths. In this paper, we extend this model in order to account for a continuously applied control force on the spacecraft as realized by certain low thrust propulsion systems. We show how the techniques for the trajectory design can be suitably augmented and compute approximations to trajectories for a mission to Venus.",

keywords = "Dynamical system, Earth venus transfer, Invariant manifold, Low thrust trajectory, Reachable set, Set oriented numerics, Space mission design, Three body problem",

author = "Michael Dellnitz and Oliver Junge and Marcus Post and Bianca Thiere",

note = "Funding Information: Acknowledgements We thank Shane Ross and Albert Seifried for helpful discussions on the contents of this paper. We also gratefully acknowledge support by Marc Steckling (EADS Astrium GmbH). Finally, we are much obliged to one of the referees for a very careful review of this paper. The research is (partly) supported by the DFG Research Training Group GK-693 of the Paderborn Institute for Scientific Computation (PaSCo).",

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doi = "10.1007/s10569-006-9008-y",

language = "English",

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AU - Junge, Oliver

AU - Post, Marcus

AU - Thiere, Bianca

N1 - Funding Information: Acknowledgements We thank Shane Ross and Albert Seifried for helpful discussions on the contents of this paper. We also gratefully acknowledge support by Marc Steckling (EADS Astrium GmbH). Finally, we are much obliged to one of the referees for a very careful review of this paper. The research is (partly) supported by the DFG Research Training Group GK-693 of the Paderborn Institute for Scientific Computation (PaSCo).

PY - 2006/5

Y1 - 2006/5

N2 - Recently new techniques for the design of energy efficient trajectories for space missions have been proposed that are based on the circular restricted three body problem as the underlying mathematical model. These techniques exploit the structure and geometry of certain invariant sets and associated invariant manifolds in phase space to systematically construct energy efficient flight paths. In this paper, we extend this model in order to account for a continuously applied control force on the spacecraft as realized by certain low thrust propulsion systems. We show how the techniques for the trajectory design can be suitably augmented and compute approximations to trajectories for a mission to Venus.

AB - Recently new techniques for the design of energy efficient trajectories for space missions have been proposed that are based on the circular restricted three body problem as the underlying mathematical model. These techniques exploit the structure and geometry of certain invariant sets and associated invariant manifolds in phase space to systematically construct energy efficient flight paths. In this paper, we extend this model in order to account for a continuously applied control force on the spacecraft as realized by certain low thrust propulsion systems. We show how the techniques for the trajectory design can be suitably augmented and compute approximations to trajectories for a mission to Venus.

KW - Dynamical system

KW - Earth venus transfer

KW - Invariant manifold

KW - Low thrust trajectory

KW - Reachable set

KW - Set oriented numerics

KW - Space mission design

KW - Three body problem

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JO - Celestial Mechanics and Dynamical Astronomy

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IS - 1-4

ER -

On target for Venus - Set oriented computation of energy efficient low thrust trajectories

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Keywords

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