Quasi-steady aerodynamic modeling and dynamic stability of mosquito-inspired flapping wing pico aerial vehicle

Recent exploration in insect-inspired robotics has generated considerable interest. Among insects navigating at low Reynolds numbers, mosquitoes exhibit distinct flight characteristics, including higher wingbeat frequencies, reduced stroke amplitudes, and slender wings. This leads to unique aerodyna...

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Published inFrontiers in robotics and AI Vol. 11; p. 1362206
Main Authors Singh, Balbir, Ahmad, Kamarul Arifin, Murugaiah, Manikandan, Yidris, Noorfaizal, Basri, Adi Azriff, Pai, Raghuvir
Format Journal Article
LanguageEnglish
Published Switzerland Frontiers Media S.A 07.05.2024
Subjects
flapping wing
flight control
mosquitoes
pico aerial vehicle
quasi-steady modeling
Robotics and AI
trailing edge vortices
mosquitoes
pico aerial vehicle
flapping wing
dynamic stability
quasi-steady modeling
flight control
kinematics
trailing edge vortices
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Summary:Recent exploration in insect-inspired robotics has generated considerable interest. Among insects navigating at low Reynolds numbers, mosquitoes exhibit distinct flight characteristics, including higher wingbeat frequencies, reduced stroke amplitudes, and slender wings. This leads to unique aerodynamic traits such as trailing edge vortices wake capture, diminished reliance on leading vortices, and rotational drag. This paper shows the energetic analysis of a mosquito-inspired flapping-wing Pico aerial vehicle during hovering, contributing insights to its future design and fabrication. The investigation relies on kinematic and quasi-steady aerodynamic modeling of a symmetric flapping-wing model with a wingspan of approximately 26 mm, considering translational, rotational, and wake capture force components. The control strategy adapts existing bird flapping wing approaches to accommodate insect wing kinematics and aerodynamic features. Flight controller design is grounded in understanding the impact of kinematics on wing forces. Additionally, a thorough analysis of the dynamic stability of the mosquito-inspired PAV model is conducted, revealing favorable controller response and maneuverability at a small scale. The modified model, incorporating rigid body dynamics and non-averaged aerodynamics, exhibits weak stability without a controller or sufficient power density. However, the controller effectively stabilizes the PAV model, addressing attitude and maneuverability. These preliminary findings offer valuable insights for the mechanical design, aerodynamics, and fabrication of RoboMos, an insect-inspired flapping wing pico aerial vehicle developed at UPM Malaysia.
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Thomas Roelandt, KU Leuven, Belgium
Reviewed by: Kyunam Kim, Sungkyunkwan University, Republic of Korea
Edited by: Hugo Rodrigue, Sungkyunkwan University, Republic of Korea
ISSN:2296-9144
2296-9144
DOI:10.3389/frobt.2024.1362206