2012
DOI: 10.1098/rsbl.2012.0130
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Leading edge vortex in a slow-flying passerine

Abstract: Most hovering animals, such as insects and hummingbirds, enhance lift by producing leading edge vortices (LEVs) and by using both the downstroke and upstroke for lift production. By contrast, most hovering passerine birds primarily use the downstroke to generate lift. To compensate for the nearly inactive upstroke, weight support during the downstroke needs to be relatively higher in passerines when compared with, e.g. hummingbirds. Here we show, by capturing the airflow around the wing of a freely flying pied… Show more

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Cited by 43 publications
(48 citation statements)
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References 21 publications
(66 reference statements)
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“…The dominating unsteady mechanism used in nature is the dynamic stall and associated LEV, which have been shown for many insects (Ellington et al, 1996;Birch and Dickinson, 2001;Sane, 2003;Johansson et al, 2013), and a few bird species (Muijres et al, 2012a, Warrick et al, 2009, Wolf et al, 2013. In this context, wind tunnel experiments of on-wing flow measurements of slow flying bats have demonstrated the presence of LEVs in the relatively small Palla's long-tongued bats ( ) the LEV contributes up to 40% of the total aerodynamic force (Table 1).…”
Section: U=4 M Smentioning
confidence: 96%
“…The dominating unsteady mechanism used in nature is the dynamic stall and associated LEV, which have been shown for many insects (Ellington et al, 1996;Birch and Dickinson, 2001;Sane, 2003;Johansson et al, 2013), and a few bird species (Muijres et al, 2012a, Warrick et al, 2009, Wolf et al, 2013. In this context, wind tunnel experiments of on-wing flow measurements of slow flying bats have demonstrated the presence of LEVs in the relatively small Palla's long-tongued bats ( ) the LEV contributes up to 40% of the total aerodynamic force (Table 1).…”
Section: U=4 M Smentioning
confidence: 96%
“…2) that range in complexity from stiff-winged plant seeds ) to bird wings that can change shape (i.e. morphing wings) (Muijres et al, 2012;Videler et al, 2004). Based on studies of robotic insects, this aerodynamic mechanism may enhance lift by up to 45% in hovering fruit flies (Dickinson et al, 1999) and support up to two-thirds of the lift during the downstroke of hovering hawkmoths (van den Berg and .…”
Section: A Convergent Solution For Avoiding Stall: Leading Edge Vorticesmentioning
confidence: 99%
“…Based on studies of robotic insects, this aerodynamic mechanism may enhance lift by up to 45% in hovering fruit flies (Dickinson et al, 1999) and support up to two-thirds of the lift during the downstroke of hovering hawkmoths (van den Berg and . Among vertebrates, the LEV can increase lift by up to 40% in slow-flying bats (Muijres et al, 2008), and it represents up to 26% of the total lift in hovering hummingbirds (Warrick et al, 2009) and up to ∼50% of the lift in some forwardflying birds (Muijres et al, 2012). However, these estimates of vertebrate lift enhancement may only be rough approximations of the true values, because they are based on the quasi-steady method that uses inviscid vortex theory (Box 1).…”
Section: A Convergent Solution For Avoiding Stall: Leading Edge Vorticesmentioning
confidence: 99%
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