Actuation delay compensation of robots in semi-physical test

Xiao Zhang; Yun He; Zhigang Xu; Zainan Jiang; Yong Liu; Wenbo Feng; Junwu Wu

doi:10.3389/fnbot.2022.1099656

Actuation delay compensation of robots in semi-physical test

Xiao Zhang
, Yun He
, Zhigang Xu^*
, Zainan Jiang^*
, Yong Liu
, Wenbo Feng
, Junwu Wu

^*Corresponding author for this work

School of Mechatronics Engineering

CAS - Shenyang Institute of Automation
Chinese Academy of Sciences
Harbin Institute of Technology
University of Chinese Academy of Sciences
Institute of Aerospace System Engineering Shanghai

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

1 Scopus citations

Abstract

In general, the traditional spacecraft semi-physical docking tests include the evaluation of docking and separation performance. However, these tests often rely on “specific” equipment, such as specially designed actuators and fast-response hydraulic systems, to meet the stringent dynamic response requirements of semi-physical testing. In this paper, a novel docking test platform is designed based on a general-purpose industrial manipulator using 3-D force and 3-D torque sensors. Different from the traditional solution, this novel platform is well-assembled and cost-effective. Furthermore, an actuation delay compensation method is introduced to improve the performance. Finally, the proposed method is evaluated using simulations. The results show that the novel method is with promising performance in terms of actuation delay compensation.

Original language	English
Article number	1099656
Journal	Frontiers in Neurorobotics
Volume	16
DOIs	https://doi.org/10.3389/fnbot.2022.1099656
State	Published - 9 Jan 2023

Keywords

actuation delay compensation
docking test platform
robotic systems
semi-physical test
space docking dynamics modeling

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10.3389/fnbot.2022.1099656

Cite this

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title = "Actuation delay compensation of robots in semi-physical test",

abstract = "In general, the traditional spacecraft semi-physical docking tests include the evaluation of docking and separation performance. However, these tests often rely on “specific” equipment, such as specially designed actuators and fast-response hydraulic systems, to meet the stringent dynamic response requirements of semi-physical testing. In this paper, a novel docking test platform is designed based on a general-purpose industrial manipulator using 3-D force and 3-D torque sensors. Different from the traditional solution, this novel platform is well-assembled and cost-effective. Furthermore, an actuation delay compensation method is introduced to improve the performance. Finally, the proposed method is evaluated using simulations. The results show that the novel method is with promising performance in terms of actuation delay compensation.",

keywords = "actuation delay compensation, docking test platform, robotic systems, semi-physical test, space docking dynamics modeling",

author = "Xiao Zhang and Yun He and Zhigang Xu and Zainan Jiang and Yong Liu and Wenbo Feng and Junwu Wu",

note = "Publisher Copyright: Copyright {\textcopyright} 2023 Zhang, He, Xu, Jiang, Liu, Feng and Wu.",

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AU - Zhang, Xiao

AU - He, Yun

AU - Xu, Zhigang

AU - Jiang, Zainan

AU - Liu, Yong

AU - Feng, Wenbo

AU - Wu, Junwu

PY - 2023/1/9

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N2 - In general, the traditional spacecraft semi-physical docking tests include the evaluation of docking and separation performance. However, these tests often rely on “specific” equipment, such as specially designed actuators and fast-response hydraulic systems, to meet the stringent dynamic response requirements of semi-physical testing. In this paper, a novel docking test platform is designed based on a general-purpose industrial manipulator using 3-D force and 3-D torque sensors. Different from the traditional solution, this novel platform is well-assembled and cost-effective. Furthermore, an actuation delay compensation method is introduced to improve the performance. Finally, the proposed method is evaluated using simulations. The results show that the novel method is with promising performance in terms of actuation delay compensation.

AB - In general, the traditional spacecraft semi-physical docking tests include the evaluation of docking and separation performance. However, these tests often rely on “specific” equipment, such as specially designed actuators and fast-response hydraulic systems, to meet the stringent dynamic response requirements of semi-physical testing. In this paper, a novel docking test platform is designed based on a general-purpose industrial manipulator using 3-D force and 3-D torque sensors. Different from the traditional solution, this novel platform is well-assembled and cost-effective. Furthermore, an actuation delay compensation method is introduced to improve the performance. Finally, the proposed method is evaluated using simulations. The results show that the novel method is with promising performance in terms of actuation delay compensation.

KW - actuation delay compensation

KW - docking test platform

KW - robotic systems

KW - semi-physical test

KW - space docking dynamics modeling

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M3 - 文章

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Actuation delay compensation of robots in semi-physical test

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Keywords

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