Optimal fuel consumption finite-thrust orbital hopping of aeroassisted spacecraft

Runqi Chai; Al Savvaris; Antonios Tsourdos; Senchun Chai; Yuanqing Xia

doi:10.1016/j.ast.2017.12.026

Optimal fuel consumption finite-thrust orbital hopping of aeroassisted spacecraft

Runqi Chai, Al Savvaris, Antonios Tsourdos, Senchun Chai^*, Yuanqing Xia

^*Corresponding author for this work

School of Automation

Cranfield University

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

26 Citations (Scopus)

Abstract

In the paper, the problem of minimum-fuel aeroassisted spacecraft regional reconnaissance (orbital hopping) is considered. A new nonlinear constrained optimal control formulation is designed and constructed so as to describe this mission scenario. This formulation contains multiple exo-atmospheric and atmospheric flight phases and correspondingly, two sets of flight dynamics. The constructed continuous-time optimal control system is then discretized via a multi-phase global collocation technique. The resulting discrete-time system is optimized using a newly proposed gradient-based optimization algorithm. Several comparative simulations are carried out and the obtained optimal results indicate that it is effective and feasible to use the proposed multi-phase optimal control design for achieving the aeroassisted vehicle orbital hopping mission.

Original language	English
Pages (from-to)	172-182
Number of pages	11
Journal	Aerospace Science and Technology
Volume	75
DOIs	https://doi.org/10.1016/j.ast.2017.12.026
Publication status	Published - Apr 2018

Keywords

Aeroassisted spacecraft
Optimal control
Orbital hopping
Trajectory optimization

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10.1016/j.ast.2017.12.026

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title = "Optimal fuel consumption finite-thrust orbital hopping of aeroassisted spacecraft",

abstract = "In the paper, the problem of minimum-fuel aeroassisted spacecraft regional reconnaissance (orbital hopping) is considered. A new nonlinear constrained optimal control formulation is designed and constructed so as to describe this mission scenario. This formulation contains multiple exo-atmospheric and atmospheric flight phases and correspondingly, two sets of flight dynamics. The constructed continuous-time optimal control system is then discretized via a multi-phase global collocation technique. The resulting discrete-time system is optimized using a newly proposed gradient-based optimization algorithm. Several comparative simulations are carried out and the obtained optimal results indicate that it is effective and feasible to use the proposed multi-phase optimal control design for achieving the aeroassisted vehicle orbital hopping mission.",

keywords = "Aeroassisted spacecraft, Optimal control, Orbital hopping, Trajectory optimization",

author = "Runqi Chai and Al Savvaris and Antonios Tsourdos and Senchun Chai and Yuanqing Xia",

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T1 - Optimal fuel consumption finite-thrust orbital hopping of aeroassisted spacecraft

AU - Chai, Runqi

AU - Savvaris, Al

AU - Tsourdos, Antonios

AU - Chai, Senchun

AU - Xia, Yuanqing

PY - 2018/4

Y1 - 2018/4

N2 - In the paper, the problem of minimum-fuel aeroassisted spacecraft regional reconnaissance (orbital hopping) is considered. A new nonlinear constrained optimal control formulation is designed and constructed so as to describe this mission scenario. This formulation contains multiple exo-atmospheric and atmospheric flight phases and correspondingly, two sets of flight dynamics. The constructed continuous-time optimal control system is then discretized via a multi-phase global collocation technique. The resulting discrete-time system is optimized using a newly proposed gradient-based optimization algorithm. Several comparative simulations are carried out and the obtained optimal results indicate that it is effective and feasible to use the proposed multi-phase optimal control design for achieving the aeroassisted vehicle orbital hopping mission.

AB - In the paper, the problem of minimum-fuel aeroassisted spacecraft regional reconnaissance (orbital hopping) is considered. A new nonlinear constrained optimal control formulation is designed and constructed so as to describe this mission scenario. This formulation contains multiple exo-atmospheric and atmospheric flight phases and correspondingly, two sets of flight dynamics. The constructed continuous-time optimal control system is then discretized via a multi-phase global collocation technique. The resulting discrete-time system is optimized using a newly proposed gradient-based optimization algorithm. Several comparative simulations are carried out and the obtained optimal results indicate that it is effective and feasible to use the proposed multi-phase optimal control design for achieving the aeroassisted vehicle orbital hopping mission.

KW - Aeroassisted spacecraft

KW - Optimal control

KW - Orbital hopping

KW - Trajectory optimization

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DO - 10.1016/j.ast.2017.12.026

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VL - 75

SP - 172

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JO - Aerospace Science and Technology

JF - Aerospace Science and Technology

ER -

Optimal fuel consumption finite-thrust orbital hopping of aeroassisted spacecraft

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Keywords

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