Series expansion-based state transition matrix for relative motion on eccentric orbits

Yafei Li; Xiangdong Liu

doi:10.1177/0954410013482059

Series expansion-based state transition matrix for relative motion on eccentric orbits

Yafei Li^*, Xiangdong Liu

^*Corresponding author for this work

School of Automation

Beijing Institute of Technology

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

3 Citations (Scopus)

Abstract

This paper considers the formation dynamics with the target satellite in an elliptic orbit. A new state transition matrix for the linearized equations of relative motion is presented by series expansion and some mathematical transformations. The state transition matrix is applicable to any eccentricity elliptic reference orbit. Besides, the state transition matrix is just related to the trigonometric function of the true anomaly of the target satellite, so it is easy to calculate. With the state transition matrix, the contribution of three-order nonlinearity in the differential gravitational acceleration on the relative motion is estimated by a perturbation approach. Numerical simulations are included to evaluate the proposed methods.

Original language	English
Pages (from-to)	869-879
Number of pages	11
Journal	Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering
Volume	228
Issue number	6
DOIs	https://doi.org/10.1177/0954410013482059
Publication status	Published - May 2014

Keywords

Series expansion
perturbation approach
relative orbit estimation
state transition matrix

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10.1177/0954410013482059

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abstract = "This paper considers the formation dynamics with the target satellite in an elliptic orbit. A new state transition matrix for the linearized equations of relative motion is presented by series expansion and some mathematical transformations. The state transition matrix is applicable to any eccentricity elliptic reference orbit. Besides, the state transition matrix is just related to the trigonometric function of the true anomaly of the target satellite, so it is easy to calculate. With the state transition matrix, the contribution of three-order nonlinearity in the differential gravitational acceleration on the relative motion is estimated by a perturbation approach. Numerical simulations are included to evaluate the proposed methods.",

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AU - Li, Yafei

AU - Liu, Xiangdong

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N2 - This paper considers the formation dynamics with the target satellite in an elliptic orbit. A new state transition matrix for the linearized equations of relative motion is presented by series expansion and some mathematical transformations. The state transition matrix is applicable to any eccentricity elliptic reference orbit. Besides, the state transition matrix is just related to the trigonometric function of the true anomaly of the target satellite, so it is easy to calculate. With the state transition matrix, the contribution of three-order nonlinearity in the differential gravitational acceleration on the relative motion is estimated by a perturbation approach. Numerical simulations are included to evaluate the proposed methods.

AB - This paper considers the formation dynamics with the target satellite in an elliptic orbit. A new state transition matrix for the linearized equations of relative motion is presented by series expansion and some mathematical transformations. The state transition matrix is applicable to any eccentricity elliptic reference orbit. Besides, the state transition matrix is just related to the trigonometric function of the true anomaly of the target satellite, so it is easy to calculate. With the state transition matrix, the contribution of three-order nonlinearity in the differential gravitational acceleration on the relative motion is estimated by a perturbation approach. Numerical simulations are included to evaluate the proposed methods.

KW - Series expansion

KW - perturbation approach

KW - relative orbit estimation

KW - state transition matrix

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JO - Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering

JF - Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering

IS - 6

ER -

Series expansion-based state transition matrix for relative motion on eccentric orbits

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Keywords

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