Safety Control for UR-Type Robotic Manipulators via High-Order Control Barrier Functions and Analytical Inverse Kinematics

Juncheng Lin; Di Hua Zhai; Yuhan Xiong; Yuanqing Xia

doi:10.1109/TIE.2023.3296810

Safety Control for UR-Type Robotic Manipulators via High-Order Control Barrier Functions and Analytical Inverse Kinematics

Juncheng Lin, Di Hua Zhai^*, Yuhan Xiong, Yuanqing Xia

^*Corresponding author for this work

School of Automation

Beijing Institute of Technology

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

2 Citations (Scopus)

Abstract

In robotics field, safety is an extensively researched subject. This article proposes an approach, which is based on high-order control barrier functions (HOCBFs) and computed torque control (CTC), for UR-type manipulators to guarantee safety while minimizing input changes. Since modeling accuracy influences the final performance, a novel analytic solution of inverse kinematics is proposed in this article with complete singularity analysis. Using CTC to construct a nominal controller, a quadratic program (QP) is formed by combining it with designed HOCBF constraints. Solving the QP, trajectory tracking can be achieved under particular safety constraints. The proposed approach has been validated on the UR3 robot in simulation and experiment, taking an obstacle avoidance task as safety constraints.

Original language	English
Pages (from-to)	6150-6160
Number of pages	11
Journal	IEEE Transactions on Industrial Electronics
Volume	71
Issue number	6
DOIs	https://doi.org/10.1109/TIE.2023.3296810
Publication status	Published - 1 Jun 2024

Keywords

Computed torque control (CTC)
control barrier functions (CBFs)
safety control

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10.1109/TIE.2023.3296810

Cite this

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abstract = "In robotics field, safety is an extensively researched subject. This article proposes an approach, which is based on high-order control barrier functions (HOCBFs) and computed torque control (CTC), for UR-type manipulators to guarantee safety while minimizing input changes. Since modeling accuracy influences the final performance, a novel analytic solution of inverse kinematics is proposed in this article with complete singularity analysis. Using CTC to construct a nominal controller, a quadratic program (QP) is formed by combining it with designed HOCBF constraints. Solving the QP, trajectory tracking can be achieved under particular safety constraints. The proposed approach has been validated on the UR3 robot in simulation and experiment, taking an obstacle avoidance task as safety constraints.",

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AU - Xia, Yuanqing

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AB - In robotics field, safety is an extensively researched subject. This article proposes an approach, which is based on high-order control barrier functions (HOCBFs) and computed torque control (CTC), for UR-type manipulators to guarantee safety while minimizing input changes. Since modeling accuracy influences the final performance, a novel analytic solution of inverse kinematics is proposed in this article with complete singularity analysis. Using CTC to construct a nominal controller, a quadratic program (QP) is formed by combining it with designed HOCBF constraints. Solving the QP, trajectory tracking can be achieved under particular safety constraints. The proposed approach has been validated on the UR3 robot in simulation and experiment, taking an obstacle avoidance task as safety constraints.

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Safety Control for UR-Type Robotic Manipulators via High-Order Control Barrier Functions and Analytical Inverse Kinematics

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Keywords

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