Remote radio control of insect flight reveals why beetles lift their legs in flight while other insects tightly fold
In the research and development of micro air vehicles, understanding and imitating the flight mechanism of insects presents a viable way of progressing forward. While research is being conducted on the flight mechanism of insects such as flies and dragonflies, research on beetles that can carry larg...
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sg-ntu-dr.10356-1602072022-07-15T06:07:31Z Remote radio control of insect flight reveals why beetles lift their legs in flight while other insects tightly fold Kosaka, Takumi Gan, Jia Hui Long, Le Duc Umezu, Shinjiro Sato, Hirotaka School of Mechanical and Aerospace Engineering Engineering::Mechanical engineering Insect Flight Free Flight In the research and development of micro air vehicles, understanding and imitating the flight mechanism of insects presents a viable way of progressing forward. While research is being conducted on the flight mechanism of insects such as flies and dragonflies, research on beetles that can carry larger loads is limited. Here, we clarified the beetle midlegs' role in the attenuation and cessation of the wingbeat. We anatomically confirmed the connection between the midlegs and the elytra. We also further clarified which pair of legs are involved in the wingbeat attenuation mechanism, and lastly demonstrated free-flight control via remote leg muscle stimulation. Observation of multiple landings using a high-speed camera revealed that the wingbeat stopped immediately after their midlegs were lowered. Moreover, the action of lowering the midleg attenuated and often stopped the wingbeat. A miniature remote stimulation device (backpack) mountable on beetles was designed and utilized for the free-flight demonstration. Beetles in free flight were remotely induced into lowering (swing down) each leg pair via electrical stimulation, and they were found to lose significant altitude only when the midlegs were stimulated. Thus, the results of this study revealed that swinging down of the midlegs played a significant role in beetle wingbeat cessation. In the future, our findings on the wingbeat attenuation and cessation mechanism are expected to be helpful in designing bioinspired micro air vehicles. Ministry of Education (MOE) This work was partly supported by the Singapore Ministry of Education (Grant No. MOE2017-T2-2-067), MEXT/JSPS KAKENHI (Grant No. 18K18838), and MEXT Super Global University Project: Frontier of Embodiment Informatics: ICT and Robotics, Waseda University. 2022-07-15T06:07:31Z 2022-07-15T06:07:31Z 2021 Journal Article Kosaka, T., Gan, J. H., Long, L. D., Umezu, S. & Sato, H. (2021). Remote radio control of insect flight reveals why beetles lift their legs in flight while other insects tightly fold. Bioinspiration and Biomimetics, 16(3), 036001-. https://dx.doi.org/10.1088/1748-3190/abe138 1748-3182 https://hdl.handle.net/10356/160207 10.1088/1748-3190/abe138 33513597 2-s2.0-85104566327 3 16 036001 en MOE2017-T2-2-067 Bioinspiration and Biomimetics © 2021 IOP Publishing Ltd. All rights reserved. |
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Engineering::Mechanical engineering Insect Flight Free Flight |
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Engineering::Mechanical engineering Insect Flight Free Flight Kosaka, Takumi Gan, Jia Hui Long, Le Duc Umezu, Shinjiro Sato, Hirotaka Remote radio control of insect flight reveals why beetles lift their legs in flight while other insects tightly fold |
| description |
In the research and development of micro air vehicles, understanding and imitating the flight mechanism of insects presents a viable way of progressing forward. While research is being conducted on the flight mechanism of insects such as flies and dragonflies, research on beetles that can carry larger loads is limited. Here, we clarified the beetle midlegs' role in the attenuation and cessation of the wingbeat. We anatomically confirmed the connection between the midlegs and the elytra. We also further clarified which pair of legs are involved in the wingbeat attenuation mechanism, and lastly demonstrated free-flight control via remote leg muscle stimulation. Observation of multiple landings using a high-speed camera revealed that the wingbeat stopped immediately after their midlegs were lowered. Moreover, the action of lowering the midleg attenuated and often stopped the wingbeat. A miniature remote stimulation device (backpack) mountable on beetles was designed and utilized for the free-flight demonstration. Beetles in free flight were remotely induced into lowering (swing down) each leg pair via electrical stimulation, and they were found to lose significant altitude only when the midlegs were stimulated. Thus, the results of this study revealed that swinging down of the midlegs played a significant role in beetle wingbeat cessation. In the future, our findings on the wingbeat attenuation and cessation mechanism are expected to be helpful in designing bioinspired micro air vehicles. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Kosaka, Takumi Gan, Jia Hui Long, Le Duc Umezu, Shinjiro Sato, Hirotaka |
| format |
Article |
| author |
Kosaka, Takumi Gan, Jia Hui Long, Le Duc Umezu, Shinjiro Sato, Hirotaka |
| author_sort |
Kosaka, Takumi |
| title |
Remote radio control of insect flight reveals why beetles lift their legs in flight while other insects tightly fold |
| title_short |
Remote radio control of insect flight reveals why beetles lift their legs in flight while other insects tightly fold |
| title_full |
Remote radio control of insect flight reveals why beetles lift their legs in flight while other insects tightly fold |
| title_fullStr |
Remote radio control of insect flight reveals why beetles lift their legs in flight while other insects tightly fold |
| title_full_unstemmed |
Remote radio control of insect flight reveals why beetles lift their legs in flight while other insects tightly fold |
| title_sort |
remote radio control of insect flight reveals why beetles lift their legs in flight while other insects tightly fold |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/160207 |
| _version_ |
1738844868503928832 |