Aerodynamic forces of revolving hummingbird wings and wing models

Douglas L. Altshuler; Robert Dudley; Charles P. Ellington

doi:10.1017/S0952836904005813

Abstract

A central challenge to the study of animal aerodynamics has been the measurement of forces generated by flapping wings. Relative to wings of other birds, hummingbird wings are of particular interest in that the smaller species operate in more viscous regimes (5000<Re<10 000) for which substantial drag and reduced lift:drag coefficients might be expected. Lift and drag forces were measured on mounted hummingbird wings and wing models spinning in continuous tipwise revolution about the wing base. Lift coefficients tended to increase as wing models became more realistic (i.e. with sharpened leading edges and with substantial camber). Lift:drag ratios of real wings were substantially higher than those of wing models, suggesting morphological contributions of feathers to lift enhancement and drag reduction. At Re=5000, high values of the lift:drag ratio (8–16) at low angles of attack suggest that wings of hummingbirds are exceptionally good at producing lift.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Altshuler, Douglas L. Dudley, Robert and McGuire, Jimmy A. 2004. Resolution of a paradox: Hummingbird flight at high elevation does not come without a cost. Proceedings of the National Academy of Sciences, Vol. 101, Issue. 51, p. 17731.

Stiles, F. Gary Altshuler, Douglas L. Dudley, Robert and Johnson, K. P. 2005. Wing Morphology and Flight Behavior of Some North American Hummingbird Species. The Auk, Vol. 122, Issue. 3, p. 872.

Stiles, F. Gary Altshuler, Douglas L. and Dudley, Robert 2005. WING MORPHOLOGY AND FLIGHT BEHAVIOR OF SOME NORTH AMERICAN HUMMINGBIRD SPECIES. The Auk, Vol. 122, Issue. 3, p. 872.

Warrick, Douglas R. Tobalske, Bret W. and Powers, Donald R. 2005. Aerodynamics of the hovering hummingbird. Nature, Vol. 435, Issue. 7045, p. 1094.

Altshuler, Douglas L. 2006. Flight Performance and Competitive Displacement of Hummingbirds across Elevational Gradients. The American Naturalist, Vol. 167, Issue. 2, p. 216.

Ellington, Charles 2006. Insects Versus Birds: The Great Divide (Invited).

Hunter, Philip 2007. The nature of flight. EMBO reports, Vol. 8, Issue. 9, p. 811.

LIVEZEY, BRADLEY C. and ZUSI, RICHARD L. 2007. Higher-order phylogeny of modern birds (Theropoda, Aves: Neornithes) based on comparative anatomy. II. Analysis and discussion. Zoological Journal of the Linnean Society, Vol. 149, Issue. 1, p. 1.

Welch, Kenneth C. Altshuler, Douglas L. and Suarez, Raul K. 2007. Oxygen consumption rates in hovering hummingbirds reflect substrate-dependent differences in P/O ratios: carbohydrate as a `premium fuel'. Journal of Experimental Biology, Vol. 210, Issue. 12, p. 2146.

Secord, Thomas W. Jun Ueda and Asada, H. Harry 2008. Dynamic analysis of a high-bandwidth, large-strain, PZT cellular muscle actuator with layered strain amplification. p. 761.

Sallstrom, Erik and Ukeiley, Lawrence 2008. Three-Dimensional Averaged Flow Around Rigid Flapping Wings.

Love, Robert and Lind, Rick 2009. Identification of Aeroservoelastic Models from Experimental Flapping-Wing Deflections.

Sällström, Erik Ukeiley, Lawrence Wu, Pin and Ifju, Peter 2009. Three-Dimensional Averaged Flow Around Flexible Flapping Wings.

Agrawal, Arun and Agrawal, Sunil K. 2009. Design of Bio-inspired Flexible Wings for Flapping-Wing Micro-sized Air Vehicle Applications. Advanced Robotics, Vol. 23, Issue. 7-8, p. 979.

Usherwood, James R. 2009. The aerodynamic forces and pressure distribution of a revolving pigeon wing. Experiments in Fluids, Vol. 46, Issue. 5, p. 991.

Love, Robert Lind, Rick Wu, Pin and Ifju, Peter 2009. Time-Frequency Analysis of Aeroelastic Deformations of Flapping Wings.

Jones, Anya and Babinsky, Holger 2009. Three-Dimensional Waving Wings at Low Reynolds Numbers.

Lentink, David and Dickinson, Michael H. 2009. Rotational accelerations stabilize leading edge vortices on revolving fly wings. Journal of Experimental Biology, Vol. 212, Issue. 16, p. 2705.

Wu, Pin Ifju, Peter and Stanford, Bret 2010. Flapping Wing Structural Deformation and Thrust Correlation Study with Flexible Membrane Wings. AIAA Journal, Vol. 48, Issue. 9, p. 2111.

Hubel, Tatjana Y. and Tropea, Cameron 2010. The importance of leading edge vortices under simplified flapping flight conditions at the size scale of birds. Journal of Experimental Biology, Vol. 213, Issue. 11, p. 1930.

Download full list

Article contents

Aerodynamic forces of revolving hummingbird wings and wing models

Abstract

Keywords

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Aerodynamic forces of revolving hummingbird wings and wing models

Abstract

Keywords

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests