A solar sail inverse periodic orbit

Xiangyuan Zeng; Hexi Baoyin; Junfeng Li; Shengping Gong

A solar sail inverse periodic orbit

Xiangyuan Zeng, Hexi Baoyin^*, Junfeng Li, Shengping Gong

^*Corresponding author for this work

Tsinghua University

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

1 Citation (Scopus)

Abstract

Deep space exploration solar sail spacecraft have great potential due to their continuous thrust without propellant. This paper describes an inverse periodic orbit. A two-body frame and an ideal sail model are used to analyze the dynamic conditions needed to produce an inverse orbit and constraints for the inverse periodic orbit. Due to the symmetry in the inverse periodic orbit, the orbital characteristics were introduced based on a semi-periodic orbit. The orbit is located by one side of the sun in the ecliptic plane. However, during each period the sign of the orbital angular momentum changed twice. The particle swarm optimization and differential evolution (PSODE) method was used to optimize control of the sail cone angle. Numerical simulations produced an inverse periodic orbit using a simple control law where the cone angle changed only once in 4.26 years.

Original language	English
Pages (from-to)	118-121
Number of pages	4
Journal	Qinghua Daxue Xuebao/Journal of Tsinghua University
Volume	52
Issue number	1
Publication status	Published - Jan 2012
Externally published	Yes

Keywords

Inverse periodic orbit
Optimal method
Particle swarm optimization and differential evolution
Solar sail

Cite this

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title = "A solar sail inverse periodic orbit",

abstract = "Deep space exploration solar sail spacecraft have great potential due to their continuous thrust without propellant. This paper describes an inverse periodic orbit. A two-body frame and an ideal sail model are used to analyze the dynamic conditions needed to produce an inverse orbit and constraints for the inverse periodic orbit. Due to the symmetry in the inverse periodic orbit, the orbital characteristics were introduced based on a semi-periodic orbit. The orbit is located by one side of the sun in the ecliptic plane. However, during each period the sign of the orbital angular momentum changed twice. The particle swarm optimization and differential evolution (PSODE) method was used to optimize control of the sail cone angle. Numerical simulations produced an inverse periodic orbit using a simple control law where the cone angle changed only once in 4.26 years.",

keywords = "Inverse periodic orbit, Optimal method, Particle swarm optimization and differential evolution, Solar sail",

author = "Xiangyuan Zeng and Hexi Baoyin and Junfeng Li and Shengping Gong",

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T1 - A solar sail inverse periodic orbit

AU - Zeng, Xiangyuan

AU - Baoyin, Hexi

AU - Li, Junfeng

AU - Gong, Shengping

PY - 2012/1

Y1 - 2012/1

N2 - Deep space exploration solar sail spacecraft have great potential due to their continuous thrust without propellant. This paper describes an inverse periodic orbit. A two-body frame and an ideal sail model are used to analyze the dynamic conditions needed to produce an inverse orbit and constraints for the inverse periodic orbit. Due to the symmetry in the inverse periodic orbit, the orbital characteristics were introduced based on a semi-periodic orbit. The orbit is located by one side of the sun in the ecliptic plane. However, during each period the sign of the orbital angular momentum changed twice. The particle swarm optimization and differential evolution (PSODE) method was used to optimize control of the sail cone angle. Numerical simulations produced an inverse periodic orbit using a simple control law where the cone angle changed only once in 4.26 years.

AB - Deep space exploration solar sail spacecraft have great potential due to their continuous thrust without propellant. This paper describes an inverse periodic orbit. A two-body frame and an ideal sail model are used to analyze the dynamic conditions needed to produce an inverse orbit and constraints for the inverse periodic orbit. Due to the symmetry in the inverse periodic orbit, the orbital characteristics were introduced based on a semi-periodic orbit. The orbit is located by one side of the sun in the ecliptic plane. However, during each period the sign of the orbital angular momentum changed twice. The particle swarm optimization and differential evolution (PSODE) method was used to optimize control of the sail cone angle. Numerical simulations produced an inverse periodic orbit using a simple control law where the cone angle changed only once in 4.26 years.

KW - Inverse periodic orbit

KW - Optimal method

KW - Particle swarm optimization and differential evolution

KW - Solar sail

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SN - 1000-0054

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JF - Qinghua Daxue Xuebao/Journal of Tsinghua University

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ER -

A solar sail inverse periodic orbit

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Keywords

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