A Versatile Aerial Manipulator Design and Realization of UAV Take-Off from a Rocking Unstable Surface

Hannibal  Paul; Ryo Miyazaki; Kominami Takamasa; Robert Ladig; Kazuhiro Shimonomura

doi:10.3390/app11199157

A Versatile Aerial Manipulator Design and Realization of UAV Take-Off from a Rocking Unstable Surface

Hannibal Paul^*, Ryo Miyazaki, Kominami Takamasa, Robert Ladig, Kazuhiro Shimonomura^*

^*Kontaktforfatter

Ritsumeikan University

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

Abstract

UAVs are one of the fastest types of robots that can be deployed in a remote environment. Unfortunately, they have a limited flight time and therefore may need to stop occasionally in an unknown, uncontrolled area. However, conventional UAVs require flat and stationary surfaces for a safe landing and take-off. Some studies on adaptive landing approach for UAVs can be found in the past, but adaptive take-off from non-flat surfaces has not been discussed for the most part, yet. In this work, we discuss the problems associated with a conventional UAV take-off from non-flat surfaces and provide a novel approach for UAV take-off from a sloped or rocking surface. We also discuss the design of a novel multitasking three-arm aerial manipulator system with parallel link mechanism and achieve the above-mentioned task. With experiments, we show that the system can provide stability for a UAV landing on a rocking surface that allows for a safe take-off.

Originalsprog	Engelsk
Artikelnummer	9157
Tidsskrift	Applied Sciences
Vol/bind	11
Udgave nummer	19
Antal sider	16
ISSN	2076-3417
DOI	https://doi.org/10.3390/app11199157
Status	Udgivet - okt. 2021
Udgivet eksternt	Ja

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10.3390/app11199157Licens: CC BY

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Citationsformater

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abstract = "UAVs are one of the fastest types of robots that can be deployed in a remote environment. Unfortunately, they have a limited flight time and therefore may need to stop occasionally in an unknown, uncontrolled area. However, conventional UAVs require flat and stationary surfaces for a safe landing and take-off. Some studies on adaptive landing approach for UAVs can be found in the past, but adaptive take-off from non-flat surfaces has not been discussed for the most part, yet. In this work, we discuss the problems associated with a conventional UAV take-off from non-flat surfaces and provide a novel approach for UAV take-off from a sloped or rocking surface. We also discuss the design of a novel multitasking three-arm aerial manipulator system with parallel link mechanism and achieve the above-mentioned task. With experiments, we show that the system can provide stability for a UAV landing on a rocking surface that allows for a safe take-off.",

author = "Hannibal Paul and Ryo Miyazaki and Kominami Takamasa and Robert Ladig and Kazuhiro Shimonomura",

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AU - Paul, Hannibal

AU - Miyazaki, Ryo

AU - Takamasa, Kominami

AU - Ladig, Robert

AU - Shimonomura, Kazuhiro

PY - 2021/10

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N2 - UAVs are one of the fastest types of robots that can be deployed in a remote environment. Unfortunately, they have a limited flight time and therefore may need to stop occasionally in an unknown, uncontrolled area. However, conventional UAVs require flat and stationary surfaces for a safe landing and take-off. Some studies on adaptive landing approach for UAVs can be found in the past, but adaptive take-off from non-flat surfaces has not been discussed for the most part, yet. In this work, we discuss the problems associated with a conventional UAV take-off from non-flat surfaces and provide a novel approach for UAV take-off from a sloped or rocking surface. We also discuss the design of a novel multitasking three-arm aerial manipulator system with parallel link mechanism and achieve the above-mentioned task. With experiments, we show that the system can provide stability for a UAV landing on a rocking surface that allows for a safe take-off.

AB - UAVs are one of the fastest types of robots that can be deployed in a remote environment. Unfortunately, they have a limited flight time and therefore may need to stop occasionally in an unknown, uncontrolled area. However, conventional UAVs require flat and stationary surfaces for a safe landing and take-off. Some studies on adaptive landing approach for UAVs can be found in the past, but adaptive take-off from non-flat surfaces has not been discussed for the most part, yet. In this work, we discuss the problems associated with a conventional UAV take-off from non-flat surfaces and provide a novel approach for UAV take-off from a sloped or rocking surface. We also discuss the design of a novel multitasking three-arm aerial manipulator system with parallel link mechanism and achieve the above-mentioned task. With experiments, we show that the system can provide stability for a UAV landing on a rocking surface that allows for a safe take-off.

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DO - 10.3390/app11199157

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A Versatile Aerial Manipulator Design and Realization of UAV Take-Off from a Rocking Unstable Surface

Abstract

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