Body Accelerations During the Wingbeat in Six Bat Species: The Function of the Upstroke in Thrust Generation

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Journal of Experimental Biology 130,275-293 (1987)
Published by Company of Biologists 1987

Body Accelerations During the Wingbeat in Six Bat Species: The Function of the Upstroke in Thrust Generation

H. D. J. N. ALDRIDGE ¹

¹ Department of Zoology, University of Bristol, Woodland Road, Bristol, BS8 1UG, UK; Department of Pure and Applied Zoology, University of Leeds, Leeds, LS2 9JT

The kinematics and aerodynamics of Rhinolophus ferrumequinum,R. hipposideros, Myotis nattereri, M. mystacinus, Plecotus auritusand Eptesicus serotinus in horizontal flight at various flightspeeds are described. Three kinematic patterns can be recognized.At low speeds M. nattereri, M. mystacinus and P. auritus usea ‘tip-reversal’ upstroke in which thrust is generatedduring the backward ‘flick’ of the chiropatagium.R. hipposideros also uses this kinematic pattern, but does notappear to generate thrust during the upstroke. Both R. ferrumequinumflying at 3.12 m s^-1 and E. serotinus flying at 3.44 m s^-1 accelerateduring the ‘vertical’ upstroke (in which the wingsmove perpendicularly to the flight path), indicating that theirwings are active. When flying at 4.16 m s^-1, E. serotinus alsouses a ‘vertical’ upstroke, but in this case it decelerates,which suggests that thrust is not being generated. At minimumpower speed (4.8 m s^-1), R. ferrumequinum uses a ‘reduced-span’upstroke, thrust is not generated during the upstroke and theanimal decelerates.

Key words: bats, flight, kinematics, aerodynamics, upstroke function

Accepted on March 25, 1987

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