Approaching control for tethered space robot based on disturbance observer using super twisting law

Yongxin Hu; Panfeng Huang; Zhongjie Meng; Dongke Wang; Yingbo Lu

doi:10.1016/j.asr.2018.02.018

Approaching control for tethered space robot based on disturbance observer using super twisting law

Yongxin Hu, Panfeng Huang, Zhongjie Meng, Dongke Wang, Yingbo Lu

School of Astronautics

Northwestern Polytechnical University Xian

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

12 Scopus citations

Abstract

Approaching control is a key mission for the tethered space robot to perform the task of removing space debris. But the uncertainties of the TSR such as the change of model parameter have an important effect on the approaching mission. Considering the space tether and the attitude of the gripper, the dynamic model of the TSR is derived using Lagrange method. Then a disturbance observer is designed to estimate the uncertainty based on STW control method. Using the disturbance observer, a controller is designed, and the performance is compared with the dynamic inverse controller which turns out that the proposed controller performs better. Numerical simulation validates the feasibility of the proposed controller on the position and attitude tracking of the TSR.

Original language	English
Pages (from-to)	2344-2351
Number of pages	8
Journal	Advances in Space Research
Volume	61
Issue number	9
DOIs	https://doi.org/10.1016/j.asr.2018.02.018
State	Published - 1 May 2018

Keywords

Approaching
Space debris removal
Super twisting control
Tethered space robot

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10.1016/j.asr.2018.02.018

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title = "Approaching control for tethered space robot based on disturbance observer using super twisting law",

abstract = "Approaching control is a key mission for the tethered space robot to perform the task of removing space debris. But the uncertainties of the TSR such as the change of model parameter have an important effect on the approaching mission. Considering the space tether and the attitude of the gripper, the dynamic model of the TSR is derived using Lagrange method. Then a disturbance observer is designed to estimate the uncertainty based on STW control method. Using the disturbance observer, a controller is designed, and the performance is compared with the dynamic inverse controller which turns out that the proposed controller performs better. Numerical simulation validates the feasibility of the proposed controller on the position and attitude tracking of the TSR.",

keywords = "Approaching, Space debris removal, Super twisting control, Tethered space robot",

author = "Yongxin Hu and Panfeng Huang and Zhongjie Meng and Dongke Wang and Yingbo Lu",

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AU - Hu, Yongxin

AU - Huang, Panfeng

AU - Meng, Zhongjie

AU - Wang, Dongke

AU - Lu, Yingbo

PY - 2018/5/1

Y1 - 2018/5/1

N2 - Approaching control is a key mission for the tethered space robot to perform the task of removing space debris. But the uncertainties of the TSR such as the change of model parameter have an important effect on the approaching mission. Considering the space tether and the attitude of the gripper, the dynamic model of the TSR is derived using Lagrange method. Then a disturbance observer is designed to estimate the uncertainty based on STW control method. Using the disturbance observer, a controller is designed, and the performance is compared with the dynamic inverse controller which turns out that the proposed controller performs better. Numerical simulation validates the feasibility of the proposed controller on the position and attitude tracking of the TSR.

AB - Approaching control is a key mission for the tethered space robot to perform the task of removing space debris. But the uncertainties of the TSR such as the change of model parameter have an important effect on the approaching mission. Considering the space tether and the attitude of the gripper, the dynamic model of the TSR is derived using Lagrange method. Then a disturbance observer is designed to estimate the uncertainty based on STW control method. Using the disturbance observer, a controller is designed, and the performance is compared with the dynamic inverse controller which turns out that the proposed controller performs better. Numerical simulation validates the feasibility of the proposed controller on the position and attitude tracking of the TSR.

KW - Approaching

KW - Space debris removal

KW - Super twisting control

KW - Tethered space robot

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M3 - 文章

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SN - 0273-1177

VL - 61

SP - 2344

EP - 2351

JO - Advances in Space Research

JF - Advances in Space Research

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ER -

Approaching control for tethered space robot based on disturbance observer using super twisting law

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Keywords

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