Survey on the novel hybrid aquatic–aerial amphibious aircraft: Aquatic unmanned aerial vehicle (AquaUAV)

The aquatic unmanned aerial vehicle (AquaUAV), a kind of vehicle that can operate both in the air and the water, has been regarded as a new breakthrough to broaden the application scenario of UAV. Wide application prospects in military and civil field are more than bright, therefore many institution...

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Bibliographic Details
Published in:Progress in aerospace sciences 2015-04, Vol.74, p.131-151
Main Authors: Yang, Xingbang, Wang, Tianmiao, Liang, Jianhong, Yao, Guocai, Liu, Miao
Format: Article
Language:English
Subjects:
Aerial surveys
Air–water transition
Amphibious aircraft
Aquatic unmanned aerial vehicle (AquaUAV)
Aquatic–aerial operation
Bionics
Categories
Morphing structure
Unmanned aerial vehicles
Vehicles
Water based airplanes
Water–air transition
Wings (aircraft)
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Summary:The aquatic unmanned aerial vehicle (AquaUAV), a kind of vehicle that can operate both in the air and the water, has been regarded as a new breakthrough to broaden the application scenario of UAV. Wide application prospects in military and civil field are more than bright, therefore many institutions have focused on the development of such a vehicle. However, due to the significant difference of the physical properties between the air and the water, it is rather difficult to design a fully-featured AquaUAV. Until now, majority of partially-featured AquaUAVs have been developed and used to verify the feasibility of an aquatic–aerial vehicle. In the present work, we classify the current partially-featured AquaUAV into three categories from the scope of the whole UAV field, i.e., the seaplane UAV, the submarine-launched UAV, and the submersible UAV. Then the recent advancements and common characteristics of the three kinds of AquaUAVs are reviewed in detail respectively. Then the applications of bionics in the design of AquaUAV, the transition mode between the air and the water, the morphing wing structure for air–water adaptation, and the power source and the propulsion type are summarized and discussed. The tradeoff analyses for different transition methods between the air and the water are presented. Furthermore, it indicates that applying the bionics into the design and development of the AquaUAV will be essential and significant. Finally, the significant technical challenges for the AquaUAV to change from a conception to a practical prototype are indicated.
ISSN:0376-0421
1873-1724
DOI:10.1016/j.paerosci.2014.12.005