Bioinspired Design Process for an Underwater Flying and Hovering Vehicle

Geder, Jason; Palmisano, John; Ramamurti, Ravi; Pruessner, Marius; Ratna, Banahalli R.; Sandberg, William C.

doi:10.4031/mtsj.45.4.5

Cited by 6 publications

(1 citation statement)

References 36 publications

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“…Mosquitoes beat their long slender wings at an enormous speed with a flapping frequency in the range of 600 to 800 Hz, compared to their natural counterparts [ 2 , 3 ]. Computational and experimental studies have helped us understand the sources of high-force development in insect flapping wings so far, such as the flapping and deforming of fish fins and the integration of that knowledge into bio-inspired vehicle designs along with trade-off studies carried out during the bio-inspired design between efficiency and productivity [ 15 , 16 ]. The energy of a flapping wing MAV is vital in order to build flapping-wing aerial vehicles.…”

Section: Wing Beat Frequency and Stroke Amplitudementioning

confidence: 99%

Study of Mosquito Aerodynamics for Imitation as a Small Robot and Flight in a Low-Density Environment

et al. 2021

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In terms of their flight and unusual aerodynamic characteristics, mosquitoes have become a new insect of interest. Despite transmitting the most significant infectious diseases globally, mosquitoes are still among the great flyers. Depending on their size, they typically beat at a high flapping frequency in the range of 600 to 800 Hz. Flapping also lets them conceal their presence, flirt, and help them remain aloft. Their long, slender wings navigate between the most anterior and posterior wing positions through a stroke amplitude about 40 to 45°, way different from their natural counterparts (>120°). Most insects use leading-edge vortex for lift, but mosquitoes have additional aerodynamic characteristics: rotational drag, wake capture reinforcement of the trailing-edge vortex, and added mass effect. A comprehensive look at the use of these three mechanisms needs to be undertaken—the pros and cons of high-frequency, low-stroke angles, operating far beyond the normal kinematic boundary compared to other insects, and the impact on the design improvements of miniature drones and for flight in low-density atmospheres such as Mars. This paper systematically reviews these unique unsteady aerodynamic characteristics of mosquito flight, responding to the potential questions from some of these discoveries as per the existing literature. This paper also reviews state-of-the-art insect-inspired robots that are close in design to mosquitoes. The findings suggest that mosquito-based small robots can be an excellent choice for flight in a low-density environment such as Mars.

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Section: Wing Beat Frequency and Stroke Amplitudementioning

confidence: 99%

Study of Mosquito Aerodynamics for Imitation as a Small Robot and Flight in a Low-Density Environment

et al. 2021

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Optical Signatures and Detection Strategy for a Finned Bioinspired Unmanned Undersea Vehicle

Judd

Novak

Geder

et al. 2018

IEEE J. Oceanic Eng.

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Effects of Cross Section and Flexibility of Pectoral Fins on the Swimming Performance of Biomimetic Underwater Vehicles

Sun¹,

Kato²,

Li³

2012

J.JASNAOE

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This paper is aiming at investigating the effects of flexibility and chord-wise cross section of pectoral fins on the swimming performance of the biomimetic underwater vehicle PLATYPUS by designing and making new types of pectoral fins. Experiments using a mechanical pectoral fin device BIRDFIN fixed in uniform flow verify the advantage of fin flexibility in underwater robot control. Fundamental experiments using PLATYPUS investigate the roles of both fin flexibility and chord-wise cross section in propelling underwater vehicles and iterative computation of spanwise deformation between Finite Element software and wing theory analyze the hydrodynamic characteristics of these new pectoral fins. Finally PTP control tests in still water and water currents check the different performances of each fin in carrying out specific task, and at the meantime the fuzzy control rules are revised to find the most suitable one for each fin respectively. It is found that asymmetric flexible fin (harder) behaves best in PTP control in still water but symmetric rigid fin does best in PTP control in water currents.

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Bioinspired Design Process for an Underwater Flying and Hovering Vehicle

Cited by 6 publications

References 36 publications

Study of Mosquito Aerodynamics for Imitation as a Small Robot and Flight in a Low-Density Environment

Study of Mosquito Aerodynamics for Imitation as a Small Robot and Flight in a Low-Density Environment

Optical Signatures and Detection Strategy for a Finned Bioinspired Unmanned Undersea Vehicle

Effects of Cross Section and Flexibility of Pectoral Fins on the Swimming Performance of Biomimetic Underwater Vehicles

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