6D pose task trajectory tracking for a class of 3D aerial manipulator from differential flatness

Yushu Yu; Vincenzo Lippiello

doi:10.1109/ACCESS.2019.2910379

6D pose task trajectory tracking for a class of 3D aerial manipulator from differential flatness

Yushu Yu, Vincenzo Lippiello^*

^*Corresponding author for this work

School of Mechatronical Engineering

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

13 Citations (Scopus)

Abstract

In this paper, the dynamics and control of a novel class of aerial manipulator for the purpose of end effector full pose trajectory tracking are investigated. The 6D pose of the end effector is set as a part of the flat output, from which the conditions that the system has the proposed flat output is obtained. The control law for the end effector tracking purpose is designed. The core part of the controller is an almost global controller in the configuration space of the system. From the transformation between the state space and the output space, the tracking control of the end effector in SE(3) is also achieved. The stability of the controlled system is analyzed. A numerical example is presented to demonstrate the theoretical analysis.

Original language	English
Article number	8686333
Pages (from-to)	52257-52265
Number of pages	9
Journal	IEEE Access
Volume	7
DOIs	https://doi.org/10.1109/ACCESS.2019.2910379
Publication status	Published - 2019

Keywords

Aerial manipulator
differential flatness
task space
tracking control

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10.1109/ACCESS.2019.2910379

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title = "6D pose task trajectory tracking for a class of 3D aerial manipulator from differential flatness",

abstract = "In this paper, the dynamics and control of a novel class of aerial manipulator for the purpose of end effector full pose trajectory tracking are investigated. The 6D pose of the end effector is set as a part of the flat output, from which the conditions that the system has the proposed flat output is obtained. The control law for the end effector tracking purpose is designed. The core part of the controller is an almost global controller in the configuration space of the system. From the transformation between the state space and the output space, the tracking control of the end effector in SE(3) is also achieved. The stability of the controlled system is analyzed. A numerical example is presented to demonstrate the theoretical analysis.",

keywords = "Aerial manipulator, differential flatness, task space, tracking control",

author = "Yushu Yu and Vincenzo Lippiello",

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AB - In this paper, the dynamics and control of a novel class of aerial manipulator for the purpose of end effector full pose trajectory tracking are investigated. The 6D pose of the end effector is set as a part of the flat output, from which the conditions that the system has the proposed flat output is obtained. The control law for the end effector tracking purpose is designed. The core part of the controller is an almost global controller in the configuration space of the system. From the transformation between the state space and the output space, the tracking control of the end effector in SE(3) is also achieved. The stability of the controlled system is analyzed. A numerical example is presented to demonstrate the theoretical analysis.

KW - Aerial manipulator

KW - differential flatness

KW - task space

KW - tracking control

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ER -

6D pose task trajectory tracking for a class of 3D aerial manipulator from differential flatness

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Keywords

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