Optimal low-thrust transfers to lunar L1 halo orbit using variable specific impulse engine

Rui Qi; Shijie Xu

doi:10.1061/(ASCE)AS.1943-5525.0000432

Optimal low-thrust transfers to lunar L1 halo orbit using variable specific impulse engine

Rui Qi^*, Shijie Xu

^*Corresponding author for this work

School of Aerospace Engineering

Beihang University

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

12 Citations (Scopus)

Abstract

Given the advantages of variable specific impulse (VSI) engine, it is very likely that in the future there will be deep space missions that use this thrust as propulsion system. In this study, a design technique for a fuel optimal Earth-to-Halo transfer using VSI is proposed. The calculus of variations approach and direct parameter optimization are combined to formulate the trajectory optimization problem. The classic stable manifold, developed in dynamical systems theory, is employed to further reduce fuel consumption. Adjoint control transformation (ACT) and analytical gradients are incorporated to improve performance of the algorithm. Four transfer examples - direct transfers from 500 km low Earth orbit (LEO) and 3,629 km medium Earth orbit (MEO) to lunar L1 halo orbit - and indirect transfers with lunar flybys, are presented.

Original language	English
Article number	4014096
Journal	Journal of Aerospace Engineering
Volume	28
Issue number	4
DOIs	https://doi.org/10.1061/(ASCE)AS.1943-5525.0000432
Publication status	Published - 1 Jul 2015

Keywords

Halo orbit
Invariant manifold
Low-thrust transfer
Variable specific impulse

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10.1061/(ASCE)AS.1943-5525.0000432

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abstract = "Given the advantages of variable specific impulse (VSI) engine, it is very likely that in the future there will be deep space missions that use this thrust as propulsion system. In this study, a design technique for a fuel optimal Earth-to-Halo transfer using VSI is proposed. The calculus of variations approach and direct parameter optimization are combined to formulate the trajectory optimization problem. The classic stable manifold, developed in dynamical systems theory, is employed to further reduce fuel consumption. Adjoint control transformation (ACT) and analytical gradients are incorporated to improve performance of the algorithm. Four transfer examples - direct transfers from 500 km low Earth orbit (LEO) and 3,629 km medium Earth orbit (MEO) to lunar L1 halo orbit - and indirect transfers with lunar flybys, are presented.",

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AU - Qi, Rui

AU - Xu, Shijie

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AB - Given the advantages of variable specific impulse (VSI) engine, it is very likely that in the future there will be deep space missions that use this thrust as propulsion system. In this study, a design technique for a fuel optimal Earth-to-Halo transfer using VSI is proposed. The calculus of variations approach and direct parameter optimization are combined to formulate the trajectory optimization problem. The classic stable manifold, developed in dynamical systems theory, is employed to further reduce fuel consumption. Adjoint control transformation (ACT) and analytical gradients are incorporated to improve performance of the algorithm. Four transfer examples - direct transfers from 500 km low Earth orbit (LEO) and 3,629 km medium Earth orbit (MEO) to lunar L1 halo orbit - and indirect transfers with lunar flybys, are presented.

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Optimal low-thrust transfers to lunar L1 halo orbit using variable specific impulse engine

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Keywords

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