Kinematics and aerodynamics of avian upstrokes during slow flight

ABSTRACT Slow flight is extremely energetically costly per unit time, yet highly important for takeoff and survival. However, at slow speeds it is presently thought that most birds do not produce beneficial aerodynamic forces during the entire wingbeat: instead they fold or flex their wings during upstroke, prompting the long-standing prediction that the upstroke produces trivial forces. There is increasing evidence that the upstroke contributes to force production, but the aerodynamic and kinematic mechanisms remain unknown. Here, we examined the wingbeat cycle of two species: the diamond dove (Geopelia cuneata) and zebra finch (Taeniopygia guttata), which exhibit different upstroke styles – a wingtip-reversal and flexed-wing upstroke, respectively. We used a combination of particle image velocimetry and near-wake streamline measures alongside detailed 3D kinematics. We show that during the middle of the wingtip-reversal upstroke, the hand-wing has a high angular velocity (15.3±0.8 deg ms−1) and translational speed (8.4±0.6 m s−1). The flexed-wing upstroke, in contrast, has low wingtip speed during mid-upstroke. Instead, later in the stroke cycle, during the transition from upstroke to downstroke, it exhibits higher angular velocities (45.5±13.8 deg ms−1) and translational speeds (11.0±1.9 m s−1). Aerodynamically, the wingtip-reversal upstroke imparts momentum to the wake, with entrained air shed backward (visible as circulation of 14.4±0.09 m2 s−1). In contrast, the flexed-wing upstroke imparts minimal momentum. Clap and peel in the dove enhances the time course for circulation production on the wings, and provides new evidence of convergent evolution on time-varying aerodynamic mechanisms during flapping in insects and birds. Summary: Some birds exhibit an upstroke style that enhances aerodynamic force production during energetically expensive slow flight. This aerodynamic signature is closely linked with their wing motion.

[1]  S. Vogel Life in Moving Fluids: The Physical Biology of Flow , 1981 .

[2]  Tobalske,et al.  Flight kinematics of black-billed magpies and pigeons over a wide range of speeds , 1996, The Journal of experimental biology.

[3]  A. Biewener,et al.  In vivo strains in pigeon flight feather shafts: implications for structural design , 1998, The Journal of experimental biology.

[4]  A. Hedenström,et al.  Leading-Edge Vortex Improves Lift in Slow-Flying Bats , 2008, Science.

[5]  S. Vogel Flight in Drosophila : III. Aerodynamic Characteristics of Fly Wing Sand Wing Models , 1967 .

[6]  Flight of Birds , 1874, Nature.

[7]  Tyson L Hedrick,et al.  Software techniques for two- and three-dimensional kinematic measurements of biological and biomimetic systems , 2008, Bioinspiration & biomimetics.

[8]  A. Biewener,et al.  Comparative power curves in bird flight , 2003, Nature.

[9]  K D Earls,et al.  Kinematics and mechanics of ground take-off in the starling Sturnis vulgaris and the quail Coturnix coturnix. , 2000, The Journal of experimental biology.

[10]  Bret W. Tobalske,et al.  Morphology, Velocity, and Intermittent Flight in Birds1 , 2001 .

[11]  Anders Hedenström,et al.  Quantitative studies of the wakes of freely flying birds in a low-turbulence wind tunnel , 2003 .

[12]  K. Lorenz,et al.  Beobachtetes über das Fliegen der Vögel und über die Beziehungen der Flügel- und Steuerform zur Art des Fluges , 2005, Journal für Ornithologie.

[13]  Tyson L. Hedrick,et al.  Wing inertia and whole-body acceleration: an analysis of instantaneous aerodynamic force production in cockatiels (Nymphicus hollandicus) flying across a range of speeds , 2004, Journal of Experimental Biology.

[14]  York Winter,et al.  Actuator disk model and span efficiency of flapping flight in bats based on time-resolved PIV measurements , 2011 .

[15]  M. Dickinson,et al.  The aerodynamic effects of wing–wing interaction in flapping insect wings , 2005, Journal of Experimental Biology.

[16]  K. D. Scholey,et al.  Developments in vertebrate flight : climbing and gliding of mammals and reptiles, and the flapping flight of birds , 1982 .

[17]  Melissa S. Bowlin,et al.  Vortex wake, downwash distribution, aerodynamic performance and wingbeat kinematics in slow-flying pied flycatchers , 2012, Journal of The Royal Society Interface.

[18]  A Hedenström,et al.  Time-resolved vortex wake of a common swift flying over a range of flight speeds , 2011, Journal of The Royal Society Interface.

[19]  Graham K. Taylor,et al.  Application of digital particle image velocimetry to insect aerodynamics: measurement of the leading-edge vortex and near wake of a Hawkmoth , 2006 .

[20]  S. Simpson The flight mechanism of the pigeon Columbia livia during take‐off , 2009 .

[21]  Charles P. Ellington,et al.  Non-Steady-State Aerodynamics of the Flight of Encarsia Formosa , 1975 .

[22]  A. M. Berg,et al.  Wing and body kinematics of takeoff and landing flight in the pigeon (Columba livia) , 2010, Journal of Experimental Biology.

[23]  K P Dial,et al.  Effects of body size on take-off flight performance in the Phasianidae (Aves). , 2000, The Journal of experimental biology.

[24]  C. Ellington The Aerodynamics of Hovering Insect Flight. IV. Aeorodynamic Mechanisms , 1984 .

[25]  Bret W. Tobalske,et al.  Aerodynamics of intermittent bounds in flying birds , 2009 .

[26]  L. Bennett Clap and Fling Aerodynamics-An Experimental Evaluation , 1977 .

[27]  D. B. Baier,et al.  X-ray reconstruction of moving morphology (XROMM): precision, accuracy and applications in comparative biomechanics research. , 2010, Journal of experimental zoology. Part A, Ecological genetics and physiology.

[28]  Anders Hedenström,et al.  High-speed stereo DPIV measurement of wakes of two bat species flying freely in a wind tunnel , 2009 .

[29]  Melissa S. Bowlin,et al.  Comparing Aerodynamic Efficiency in Birds and Bats Suggests Better Flight Performance in Birds , 2012, PloS one.

[30]  Dirk Michaelis,et al.  Tomographic particle image velocimetry of desert locust wakes: instantaneous volumes combine to reveal hidden vortex elements and rapid wake deformation , 2012, Journal of The Royal Society Interface.

[31]  Charles P. Ellington,et al.  THE AERODYNAMICS OF HOVERING INSECT FLIGHT. , 2016 .

[32]  R. Bomphrey,et al.  Span efficiency in hawkmoths , 2013, Journal of The Royal Society Interface.

[33]  David Lentink,et al.  In vivo recording of aerodynamic force with an aerodynamic force platform: from drones to birds , 2014, Journal of The Royal Society Interface.

[34]  Bret W Tobalske,et al.  Aerodynamics of tip-reversal upstroke in a revolving pigeon wing , 2011, Journal of Experimental Biology.

[35]  B. Tobalske,et al.  Transition from leg to wing forces during take-off in birds , 2012, Journal of Experimental Biology.

[36]  S. Vogel Flight in Drosophila , 1967 .

[37]  Sanjay P Sane,et al.  The aerodynamics of insect flight , 2003, Journal of Experimental Biology.

[38]  Richard J. Bomphrey,et al.  Time-varying span efficiency through the wingbeat of desert locusts , 2012, Journal of The Royal Society Interface.

[39]  A Hedenström,et al.  A family of vortex wakes generated by a thrush nightingale in free flight in a wind tunnel over its entire natural range of flight speeds , 2003, Journal of Experimental Biology.

[40]  R. H. Brown The Flight of Birds: II. Wing Function in Relation to Flight Speed , 1953 .

[41]  Efficiency of Lift Production in Flapping and Gliding Flight of Swifts , 2014, PloS one.

[42]  K. Dial Activity patterns of the wing muscles of the pigeon (Columba livia) during different modes of flight , 1992 .

[43]  Rick J Vazquez,et al.  Functional osteology of the avian wrist and the evolution of flapping flight , 1992, Journal of morphology.

[44]  Bret W Tobalske,et al.  Biomechanics of bird flight , 2007, Journal of Experimental Biology.

[45]  A Hedenström,et al.  Vortex wakes generated by robins Erithacus rubecula during free flight in a wind tunnel , 2006, Journal of The Royal Society Interface.

[46]  Tobalske,et al.  Kinematics of flap-bounding flight in the zebra finch over a wide range of speeds , 1999, The Journal of experimental biology.

[47]  William H. Rae,et al.  Low-Speed Wind Tunnel Testing , 1966 .

[48]  T. Experiments on the Weis-Fogh mechanism of lift generation by insects in hovering flight. Part 1. Dynamics of the fling , 2007 .

[49]  Anders Hedenström,et al.  Leading edge vortex in a slow-flying passerine , 2012, Biology Letters.

[50]  T. Weis-Fogh Quick estimates of flight fitness in hovering animals , 1973 .

[51]  Anders Hedenström,et al.  PIV-based investigations of animal flight , 2009 .

[52]  D. Altshuler,et al.  Hummingbirds generate bilateral vortex loops during hovering: evidence from flow visualization , 2012 .

[53]  B. Tobalske,et al.  Aerodynamics of the hovering hummingbird , 2005, Nature.

[54]  C. Tropea,et al.  The importance of leading edge vortices under simplified flapping flight conditions at the size scale of birds , 2010, Journal of Experimental Biology.

[55]  B. Tobalske,et al.  Lift production in the hovering hummingbird , 2009, Proceedings of the Royal Society B: Biological Sciences.

[56]  Adrian L. R. Thomas,et al.  Leading-edge vortices in insect flight , 1996, Nature.

[57]  B. Tobalske,et al.  Transition from wing to leg forces during landing in birds , 2014, Journal of Experimental Biology.

[58]  K. Breuer,et al.  Wake structure and wing kinematics: the flight of the lesser dog-faced fruit bat, Cynopterus brachyotis , 2010, Journal of Experimental Biology.

[59]  John O. Dabiri,et al.  On the estimation of swimming and flying forces from wake measurements , 2005, Journal of Experimental Biology.

[60]  Bret W Tobalske,et al.  Aerodynamics of wing-assisted incline running in birds , 2007, Journal of Experimental Biology.

[61]  HORACE B. Porter Flight of Birds , 1874, Nature.

[62]  G D E Povel,et al.  Leading-Edge Vortex Lifts Swifts , 2004, Science.

[63]  A. Hedenström,et al.  Bat Flight Generates Complex Aerodynamic Tracks , 2007, Science.

[64]  C. Peskin,et al.  Flexible clap and fling in tiny insect flight , 2009, Journal of Experimental Biology.

[65]  Andrew A Biewener,et al.  Pigeons steer like helicopters and generate down- and upstroke lift during low speed turns , 2011, Proceedings of the National Academy of Sciences.

[66]  R. H. Brown The flight of birds; the flapping cycle of the pigeon. , 1948, The Journal of experimental biology.

[67]  T. Maxworthy Experiments on the Weis-Fogh mechanism of lift generation by insects in hovering flight. Part 1. Dynamics of the ‘fling’ , 1979, Journal of Fluid Mechanics.