Flapping wing aerodynamics: from insects to vertebrates

Chin, Diana D.; Lentink, David

doi:10.1242/jeb.042317

Cited by 236 publications

(145 citation statements)

References 85 publications

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“…Sane, 2003;Chin and Lentink, 2016). These forces primarily result from aerodynamic mechanisms owing to leading edge vortices produced during wing translation (Ellington et al, 1996), rotational mechanisms during pronation and supination of the wing , and other mechanisms such as 'clap-and-fling' (see Glossary) which are observed more commonly in miniature insects (Weis-Fogh, 1973).…”

Section: Aerodynamic Constraints Of Miniaturizationmentioning

confidence: 99%

Mechanics of the thorax in flies

Deora

Gundiah

Sane

2017

Journal of Experimental Biology

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Insects represent more than 60% of all multicellular life forms, and are easily among the most diverse and abundant organisms on earth. They evolved functional wings and the ability to fly, which enabled them to occupy diverse niches. Insects of the hyper-diverse orders show extreme miniaturization of their body size. The reduced body size, however, imposes steep constraints on flight ability, as their wings must flap faster to generate sufficient forces to stay aloft. Here, we discuss the various physiological and biomechanical adaptations of the thorax in flies which enabled them to overcome the myriad constraints of small body size, while ensuring very precise control of their wing motion. One such adaptation is the evolution of specialized myogenic or asynchronous muscles that power the high-frequency wing motion, in combination with neurogenic or synchronous steering muscles that control higher-order wing kinematic patterns. Additionally, passive cuticular linkages within the thorax coordinate fast and yet precise bilateral wing movement, in combination with an actively controlled clutch and gear system that enables flexible flight patterns. Thus, the study of thoracic biomechanics, along with the underlying sensory-motor processing, is central in understanding how the insect body form is adapted for flight.

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Section: Aerodynamic Constraints Of Miniaturizationmentioning

confidence: 99%

Mechanics of the thorax in flies

Deora

Gundiah

Sane

2017

Journal of Experimental Biology

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“…The kinematics and mechanics of flapping flight for insects such as clap and fling, wake capture, and delayed stall have been thoroughly investigated and reported, as summarized by Shyy et al [3] and more recently by Chin and Lentink [4]. Of particular interest is the delayed stall phenomena, in which a leading edge vortex (LEV) on the upper edge of the wing enhances lift throughout the downstroke, which has been shown experimentally [5,6] and computationally [7,8].…”

Section: Introductionmentioning

confidence: 99%

Unsteady high-lift mechanisms from heaving flat plate simulations

Franck

Breuer

2017

International Journal of Heat and Fluid Flow

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Flapping animal flight is often modeled as a combined pitching and heaving motion in order to investigate the unsteady flow structures and resulting forces that could augment the animal's lift and propulsive capabilities. This work isolates the heaving motion of flapping flight in order to numerically investigate the flow physics at a Reynolds number of 40,000, a regime typical for large birds and bats and challenging to simulate due to the added complexity of laminar to turbulent transition in which boundary layer separation and reattachment are traditionally more difficult to predict. Periodic heaving of a thin flat plate at fixed angles of attacks of 1, 5, 9, 13, and 18 degrees are simulated using a large-eddy simulation (LES). The heaving motion significantly increases the average lift compared with the steady flow, and also surpasses the quasi-steady predictions due to the formation of a leading edge vortex (LEV) that persists well into the static stall region. The progression of the high-lift mechanisms throughout the heaving cycle is presented over the range of angles of attack. Lift enhancement compared with the equivalent steady state flow was found to be up to 17% greater, and up to 24% greater than that predicted by a quasi-steady analysis. For the range of kinematics explored it is found that maximum lift enhancement occurs at an angle of attack of 13 degrees, with a maximum lift coefficient of 2.1, a mean lift coefficient of 1.04.

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“…The kinematics of individual wingbeats also differ among birds and bats [124], primarily due to differences in how they flex their wings during upstrokes [59]. Whereas downstroke kinematics remain relatively consistent, upstroke kinematics vary among birds with flight speed and wing shape.…”

Section: Wing Kinematicsmentioning

confidence: 99%

“…While significant progress has been made in recent years, many gaps still exist in our understanding of vertebrate flight, especially with regard to manoeuvring flight and flight in different natural environments [124]. Additionally, many of the active control mechanisms identified for birds and bats have only been studied through the use of theoretical [153,154], computational [156] or robotic models [155].…”

Section: Performance Manoeuvring and Stabilitymentioning

confidence: 99%

“…With a robot, this constraint is removed. Robotic models, for example, have been used to study the effects of different aerodynamic mechanisms in flapping animal flight [124,174] and to isolate effects of individual kinematic variables in a flapping wing [25]. Robotic platforms will enable testing how different materials perform as aerofoils, how different wing shapes perform in different flight conditions and how integrated filoplume-like sensors might enhance flight.…”

Section: The Future Of Bio-inspired Flying Robotsmentioning

confidence: 99%

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Inspiration for wing design: how forelimb specialization enables active flight in modern vertebrates

Chin¹,

Matloff²,

Stowers³

et al. 2017

J. R. Soc. Interface.

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Harnessing flight strategies refined by millions of years of evolution can help expedite the design of more efficient, manoeuvrable and robust flying robots. This review synthesizes recent advances and highlights remaining gaps in our understanding of how bird and bat wing adaptations enable effective flight. Included in this discussion is an evaluation of how current robotic analogues measure up to their biological sources of inspiration. Studies of vertebrate wings have revealed skeletal systems well suited for enduring the loads required during flight, but the mechanisms that drive coordinated motions between bones and connected integuments remain ill-described. Similarly, vertebrate flight muscles have adapted to sustain increased wing loading, but a lack of in vivo studies limits our understanding of specific muscular functions. Forelimb adaptations diverge at the integument level, but both bird feathers and bat membranes yield aerodynamic surfaces with a level of robustness unparalleled by engineered wings. These morphological adaptations enable a diverse range of kinematics tuned for different flight speeds and manoeuvres. By integrating vertebrate flight specializationsparticularly those that enable greater robustness and adaptability-into the design and control of robotic wings, engineers can begin narrowing the wide margin that currently exists between flying robots and vertebrates. In turn, these robotic wings can help biologists create experiments that would be impossible in vivo.

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Flapping wing aerodynamics: from insects to vertebrates

Cited by 236 publications

References 85 publications

Mechanics of the thorax in flies

Mechanics of the thorax in flies

Unsteady high-lift mechanisms from heaving flat plate simulations

Inspiration for wing design: how forelimb specialization enables active flight in modern vertebrates

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