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Main Authors: Marquette, Wade, Schultz, Kyle, Jonnalagadda, Vamsi, Wong, Benjamin, Garbini, Joseph, Devasia, Santosh
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2412.10973
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_version_ 1866915063849287680
author Marquette, Wade
Schultz, Kyle
Jonnalagadda, Vamsi
Wong, Benjamin
Garbini, Joseph
Devasia, Santosh
author_facet Marquette, Wade
Schultz, Kyle
Jonnalagadda, Vamsi
Wong, Benjamin
Garbini, Joseph
Devasia, Santosh
contents Visual inspection of confined spaces such as aircraft wings is ergonomically challenging for human mechanics. This work presents a novel crane robot that can travel the entire span of the aircraft wing, enabling mechanics to perform inspection from outside of the confined space. However, teleoperation of the crane robot can still be a challenge due to the need to avoid obstacles in the workspace and potential oscillations of the camera payload. The main contribution of this work is to exploit the differential flatness of the crane-robot dynamics for designing reduced-oscillation, collision-free time trajectories of the camera payload for use in teleoperation. Autonomous experiments verify the efficacy of removing undesired oscillations by 89%. Furthermore, teleoperation experiments demonstrate that the controller eliminated collisions (from 33% to 0%) when 12 participants performed an inspection task with the use of proposed trajectory selection when compared to the case without it. Moreover, even discounting the failures due to collisions, the proposed approach improved task efficiency by 18.7% when compared to the case without it.
format Preprint
id arxiv_https___arxiv_org_abs_2412_10973
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Semi-autonomous Teleoperation using Differential Flatness of a Crane Robot for Aircraft In-Wing Inspection
Marquette, Wade
Schultz, Kyle
Jonnalagadda, Vamsi
Wong, Benjamin
Garbini, Joseph
Devasia, Santosh
Robotics
Visual inspection of confined spaces such as aircraft wings is ergonomically challenging for human mechanics. This work presents a novel crane robot that can travel the entire span of the aircraft wing, enabling mechanics to perform inspection from outside of the confined space. However, teleoperation of the crane robot can still be a challenge due to the need to avoid obstacles in the workspace and potential oscillations of the camera payload. The main contribution of this work is to exploit the differential flatness of the crane-robot dynamics for designing reduced-oscillation, collision-free time trajectories of the camera payload for use in teleoperation. Autonomous experiments verify the efficacy of removing undesired oscillations by 89%. Furthermore, teleoperation experiments demonstrate that the controller eliminated collisions (from 33% to 0%) when 12 participants performed an inspection task with the use of proposed trajectory selection when compared to the case without it. Moreover, even discounting the failures due to collisions, the proposed approach improved task efficiency by 18.7% when compared to the case without it.
title Semi-autonomous Teleoperation using Differential Flatness of a Crane Robot for Aircraft In-Wing Inspection
topic Robotics
url https://arxiv.org/abs/2412.10973