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JACIII Vol.29 No.5 pp. 1203-1211
doi: 10.20965/jaciii.2025.p1203
(2025)

Research Paper:

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Proposal and Design of a Mobile Robot-Restrained UAV Trainer

Daichi Arai ORCID Icon and Edwardo F. Fukushima ORCID Icon

Graduate School of Engineering, Tokyo University of Technology
1404-1 Katakuramachi, Hachioji, Tokyo 192-0982, Japan

Corresponding author

Received:
March 31, 2025
Accepted:
June 4, 2025
Published:
September 20, 2025
Creative Commons License
Keywords:
trainer system control, flying object, drone, unmanned aerial vehicles, tracking control
Abstract

Unmanned aerial vehicles (UAVs), such as multicopter drones, are expected to play pivotal roles in varied domains. However, their operation poses challenges owing to the need for stringent safety measures and comprehensive training. This paper introduces a novel mobile robot-restrained UAV trainer to facilitate safe outdoor flight experiments and training sessions, which mitigates the risk of UAV crashes. The proposed system comprises three fundamental components: the UAV (flying object), a coupling-restraint mechanism, and a base platform. The base platform, which operates on the ground, is connected to the UAV via the coupling-restraint mechanism. This configuration allows the base platform to follow the movement of the UAV, thereby enabling training and experimental activities without concerns about potential UAV crashes. This paper outlines the system design, evaluates its impact on UAV motion through simulations, and presents a full-scale prototype for validation.

Conceptual diagram and sample configurations

Conceptual diagram and sample configurations

Cite this article as:
D. Arai and E. Fukushima, “Proposal and Design of a Mobile Robot-Restrained UAV Trainer,” J. Adv. Comput. Intell. Intell. Inform., Vol.29 No.5, pp. 1203-1211, 2025.
Data files:
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Last updated on Sep. 19, 2025