Safe-trajectory optimization and tracking control in ultra-close proximity to a failed satellite

Jingrui Zhang; Xiaoyu Chu; Yao Zhang; Quan Hu; Guang Zhai; Yanyan Li

doi:10.1016/j.actaastro.2017.12.047

Safe-trajectory optimization and tracking control in ultra-close proximity to a failed satellite

Jingrui Zhang, Xiaoyu Chu, Yao Zhang^*, Quan Hu, Guang Zhai, Yanyan Li

^*Corresponding author for this work

School of Aerospace Engineering

Beijing Institute of Technology

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

17 Citations (Scopus)

Abstract

This paper presents a trajectory-optimization method for a chaser spacecraft operating in ultra-close proximity to a failed satellite. Based on the combination of active and passive trajectory protection, the constraints in the optimization framework are formulated for collision avoidance and successful docking in the presence of any thruster failure. The constraints are then handled by an adaptive Gauss pseudospectral method, in which the dynamic residuals are used as the metric to determine the distribution of collocation points. A finite-time feedback control is further employed in tracking the optimized trajectory. In particular, the stability and convergence of the controller are proved. Numerical results are given to demonstrate the effectiveness of the proposed methods.

Original language	English
Pages (from-to)	339-352
Number of pages	14
Journal	Acta Astronautica
Volume	144
DOIs	https://doi.org/10.1016/j.actaastro.2017.12.047
Publication status	Published - Mar 2018

Keywords

Active and passive trajectory protection
Adaptive Gauss pseudospectral method
Collision avoidance
Finite-time control
Trajectory optimization

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10.1016/j.actaastro.2017.12.047

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title = "Safe-trajectory optimization and tracking control in ultra-close proximity to a failed satellite",

abstract = "This paper presents a trajectory-optimization method for a chaser spacecraft operating in ultra-close proximity to a failed satellite. Based on the combination of active and passive trajectory protection, the constraints in the optimization framework are formulated for collision avoidance and successful docking in the presence of any thruster failure. The constraints are then handled by an adaptive Gauss pseudospectral method, in which the dynamic residuals are used as the metric to determine the distribution of collocation points. A finite-time feedback control is further employed in tracking the optimized trajectory. In particular, the stability and convergence of the controller are proved. Numerical results are given to demonstrate the effectiveness of the proposed methods.",

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author = "Jingrui Zhang and Xiaoyu Chu and Yao Zhang and Quan Hu and Guang Zhai and Yanyan Li",

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AU - Zhang, Jingrui

AU - Chu, Xiaoyu

AU - Zhang, Yao

AU - Hu, Quan

AU - Zhai, Guang

AU - Li, Yanyan

PY - 2018/3

Y1 - 2018/3

N2 - This paper presents a trajectory-optimization method for a chaser spacecraft operating in ultra-close proximity to a failed satellite. Based on the combination of active and passive trajectory protection, the constraints in the optimization framework are formulated for collision avoidance and successful docking in the presence of any thruster failure. The constraints are then handled by an adaptive Gauss pseudospectral method, in which the dynamic residuals are used as the metric to determine the distribution of collocation points. A finite-time feedback control is further employed in tracking the optimized trajectory. In particular, the stability and convergence of the controller are proved. Numerical results are given to demonstrate the effectiveness of the proposed methods.

AB - This paper presents a trajectory-optimization method for a chaser spacecraft operating in ultra-close proximity to a failed satellite. Based on the combination of active and passive trajectory protection, the constraints in the optimization framework are formulated for collision avoidance and successful docking in the presence of any thruster failure. The constraints are then handled by an adaptive Gauss pseudospectral method, in which the dynamic residuals are used as the metric to determine the distribution of collocation points. A finite-time feedback control is further employed in tracking the optimized trajectory. In particular, the stability and convergence of the controller are proved. Numerical results are given to demonstrate the effectiveness of the proposed methods.

KW - Active and passive trajectory protection

KW - Adaptive Gauss pseudospectral method

KW - Collision avoidance

KW - Finite-time control

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Safe-trajectory optimization and tracking control in ultra-close proximity to a failed satellite

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Keywords

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