Kinematic, aerodynamic and anatomical mechanisms in the slow, maneuvering flight of pigeons

A high-speed (200 Hz) infrared video system was used in a three-dimensional analysis of pigeon wing and body kinematics to determine the aerodynamic and anatomical mechanisms they use to produce force asymmetries to effect a turn during slow (3 m s-1) flight. Contrary to our expectations, pigeons used downstroke velocity asymmetries, rather than angle of attack or surface area asymmetries, to produce the disparities in force needed for directional changes. To produce a bank, a velocity asymmetry is created early in the downstroke and, in the majority of cases, then reversed at the end of the same downstroke, thus arresting the rolling angular momentum. When the velocity asymmetry was not reversed at the end of downstroke, the arresting force asymmetry was produced during upstroke, with velocity asymmetries creating disparate drag forces on the wings. Rather than using subtle aerodynamic variables to produce subtle downstroke force asymmetries, pigeons constantly adjust their position using a series of large alternating and opposing forces during downstroke and upstroke. Thus, a pigeon creates a precise 'average' body position (e.g. bank angle) and flight path by producing a series of rapidly oscillating movements. Although the primary locomotor event (downstroke) is saltatory, maneuvering during slow flight should be considered as a product of nearly continuous, juxtaposed force generation throughout the wingbeat cycle. Further, viewing upstroke as more than stereotypical, symmetrical wing recovery alters the evolutionary and functional context of investigations into the musculoskeletal mechanisms and the associated neural control involved in this unique kinematic event.

[1]  D. Clark MUSCLE COUNTS OF MOTOR UNITS: A STUDY IN INNERVATION RATIOS , 1931 .

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

[3]  H. I. Fisher,et al.  Bony Mechanism of Automatic Flexion and Extension in the Pigeon's Wing , 1957 .

[4]  G. Somjen,et al.  Excitability and inhibitability of motoneurons of different sizes. , 1965, Journal of neurophysiology.

[5]  U. M. Norberg,et al.  Aerodynamics, kinematics, and energetics of horizontal flapping flight in the long-eared bat Plecotus auritus. , 1976, The Journal of experimental biology.

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

[7]  H. Aldridge,et al.  Kinematics and aerodynamics of the greater horseshoe bat, Rhinolophus ferrumequinum, in horizontal flight at various flight speeds. , 1986, The Journal of experimental biology.

[8]  G. E. Goslow,et al.  Structure and neural control of the pectoralis in pigeons: Implications for flight mechanics , 1987, The Anatomical record.

[9]  J. Rayner,et al.  Ecological Morphology and Flight in Bats (Mammalia; Chiroptera): Wing Adaptations, Flight Performance, Foraging Strategy and Echolocation , 1987 .

[10]  G. E. Goslow,et al.  A functional analysis of the primary upstroke and downstroke muscles in the domestic pigeon (Columba livia) during flight. , 1988, The Journal of experimental biology.

[11]  Jeremy M. V. Rayner,et al.  Form and Function in Avian Flight , 1988 .

[12]  G. E. Goslow,et al.  Neuromuscular organization of the pectoralis (pars thoracicus) of the pigeon (Columba livia): Implications for motor control , 1989, The Anatomical record.

[13]  U. Norberg Vertebrate Flight: Mechanics, Physiology, Morphology, Ecology and Evolution , 1990 .

[14]  J. Weiner,et al.  Norberg U. M. Vertebrate flight. Mechanics, Physiology, Morphology, Ecology and Evolution. Springer Verlag (xiv) + 291 pp. DM 238. ISBN 3-540-51370-1. , 1992 .

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

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

[17]  K. Dial,et al.  AVIAN FORELIMB MUSCLES AND NONSTEADY FLIGHT: CAN BIRDS FLY WITHOUT USING THE MUSCLES IN THEIR WINGS? , 1992 .

[18]  R. B. Srygley,et al.  CORRELATIONS OF THE POSITION OF CENTER OF BODY MASS WITH BUTTERFLY ESCAPE TACTICS , 1993 .

[19]  K. Dial,et al.  Neuromuscular organization and regional EMG activity of the pectoralis in the pigeon , 1993, Journal of morphology.

[20]  Frederick H. Lutze,et al.  Kinematics and aerodynamics of the velocity vector roll , 1994 .

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

[22]  A. Biewener,et al.  Mechanical power output of bird flight , 1997, Nature.

[23]  G. E. Goslow,et al.  Wing upstroke and the evolution of flapping flight , 1997, Nature.

[24]  A. Biewener,et al.  Mechanical poweroutput of bird flight , 1997 .