TY - GEN
T1 - A multi-stage drag de-orbit strategy and optimal commands design for a tethered system during large space debris removal
AU - Wei, Tao
AU - Di, Jingnan
AU - Chu, Zhongyi
AU - Cui, Jing
N1 - Publisher Copyright:
© 2018 KASHYAP.
PY - 2018
Y1 - 2018
N2 - There is a serious challenge to the safe operation of orbiting satellites as the number of space debris on the geosynchronous orbit increases. Consequently, the active removal of space debris has drawn wide attention in recent years. And a tethered system is considered to be a promising method to remove debris in high orbit with its low power consumption and costs. However, the flexible tether of the system can bring the coupling of the orbit motion, the sway motion and the variation of large debris attitude, which means great danger in deorbiting phase and bring a huge challenge in later control. Hence, in this paper, aiming to de-orbit large space debris safely with a tethered system, a multi-stage horizontal drag de-orbit strategy is designed to deal with the coupling caused by a flexible tether. Based on that, optimal commands are planed using Gaussian pseudospectral method to achieve decoupling of the orbit motion, the sway motion and the variation of target attitude. Finally, numerical simulation is established to follow the planned commands by tension and tug thrusts in large space debris removal to verify the effectiveness of the proposed de-orbit strategy.
AB - There is a serious challenge to the safe operation of orbiting satellites as the number of space debris on the geosynchronous orbit increases. Consequently, the active removal of space debris has drawn wide attention in recent years. And a tethered system is considered to be a promising method to remove debris in high orbit with its low power consumption and costs. However, the flexible tether of the system can bring the coupling of the orbit motion, the sway motion and the variation of large debris attitude, which means great danger in deorbiting phase and bring a huge challenge in later control. Hence, in this paper, aiming to de-orbit large space debris safely with a tethered system, a multi-stage horizontal drag de-orbit strategy is designed to deal with the coupling caused by a flexible tether. Based on that, optimal commands are planed using Gaussian pseudospectral method to achieve decoupling of the orbit motion, the sway motion and the variation of target attitude. Finally, numerical simulation is established to follow the planned commands by tension and tug thrusts in large space debris removal to verify the effectiveness of the proposed de-orbit strategy.
UR - https://www.scopus.com/pages/publications/85058974817
M3 - 会议稿件
AN - SCOPUS:85058974817
SN - 9780877036531
T3 - Advances in the Astronautical Sciences
SP - 2023
EP - 2035
BT - Dynamics and Control of Space Systems
A2 - Chern, Jeng-Shing
A2 - Luo, Ya-Zhong
A2 - Chen, Xiao-Qian
A2 - Chen, Lei
PB - Univelt Inc.
T2 - 4th IAA Conference on Dynamics and Control of Space Systems, DYCOSS 2018
Y2 - 21 May 2018 through 23 May 2018
ER -