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First published online July 20, 2007
Journal of Experimental Biology 210, 2593-2606 (2007)
Published by The Company of Biologists 2007
doi: 10.1242/jeb.002071

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Aerodynamic force generation, performance and control of body orientation during gliding in sugar gliders (Petaurus breviceps)

Kristin L. Bishop

Department of Ecology and Evolutionary Biology, Brown University, Providence, RI 02912, USA

Present address: Section of Ecology and Evolution, University of California, Davis, Davis, CA 95616, USA (e-mail: kvwbishop{at}ucdavis.edu)

Accepted 24 March 2007

Gliding has often been discussed in the literature as a possible precursor to powered flight in vertebrates, but few studies exist on the mechanics of gliding in living animals. In this study I analyzed the 3D kinematics of sugar gliders (Petaurus breviceps) during short glides in an enclosed space. Short segments of the glide were captured on video, and the positions of marked anatomical landmarks were used to compute linear distances and angles, as well as whole body velocities and accelerations. From the whole body accelerations I estimated the aerodynamic forces generated by the animals. I computed the correlations between movements of the limbs and body rotations to examine the control of orientation during flight. Finally, I compared these results to those of my earlier study on the similarly sized and distantly related southern flying squirrel (Glaucomys volans). The sugar gliders in this study accelerated downward slightly (1.0±0.5 m s^–2), and also accelerated forward (2.1±0.6 m s^–2) in all but one trial, indicating that the body weight was not fully supported by aerodynamic forces and that some of the lift produced forward acceleration rather than just balancing body weight. The gliders used high angles of attack (44.15±3.12°), far higher than the angles at which airplane wings would stall, yet generated higher lift coefficients (1.48±0.18) than would be expected for a stalled wing. Movements of the limbs were strongly correlated with body rotations, suggesting that sugar gliders make extensive use of limb movements to control their orientation during gliding flight. In addition, among individuals, different limb movements were associated with a given body rotation, suggesting that individual variation exists in the control of body rotations. Under similar conditions, flying squirrels generated higher lift coefficients and lower drag coefficients than sugar gliders, yet had only marginally shallower glides. Flying squirrels have a number of morphological specializations not shared by sugar gliders that may help to explain their greater lift generating performance.

Key words: aerodynamics, biomechanics, gliding, mammal, stability

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