Litcius/Paper detail

Raptor wing morphing with flight speed

Jorn A. Cheney, Jonathan P. J. Stevenson, Nicholas E. Durston, Masateru Maeda, Jialei Song, D. Smith, Shane P. Windsor, James R. Usherwood, Richard J. Bomphrey

2021Journal of The Royal Society Interface51 citationsDOIOpen Access PDF

Abstract

In gliding flight, birds morph their wings and tails to control their flight trajectory and speed. Using high-resolution videogrammetry, we reconstructed accurate and detailed three-dimensional geometries of gliding flights for three raptors (barn owl, Tyto alba ; tawny owl, Strix aluco , and goshawk, Accipiter gentilis ). Wing shapes were highly repeatable and shoulder actuation was a key component of reconfiguring the overall planform and controlling angle of attack. The three birds shared common spanwise patterns of wing twist, an inverse relationship between twist and peak camber, and held their wings depressed below their shoulder in an anhedral configuration. With increased speed, all three birds tended to reduce camber throughout the wing, and their wings bent in a saddle-shape pattern. A number of morphing features suggest that the coordinated movements of the wing and tail support efficient flight, and that the tail may act to modulate wing camber through indirect aeroelastic control.

Topics & Concepts

WingBird flightWingspanBarn-owlAccipiterMorphingCamber (aerodynamics)Flight featherAngle of attackFuselageCurvatureAerospace engineeringAerodynamicsBiologyComputer scienceGeometryEngineeringMathematicsEcologyArtificial intelligencePredationLarvaMoultingBiomimetic flight and propulsion mechanismsAeroelasticity and Vibration ControlAerospace Engineering and Energy Systems