TY - JOUR T1 - Aerodynamic characteristics of a feathered dinosaur measured using physical models. Effects of form on static stability and control effectiveness JF - bioRxiv DO - 10.1101/001297 SP - 001297 AU - Dennis Evangelista AU - Griselda Cardona AU - Eric Guenther-Gleason AU - Tony Huynh AU - Austin Kwong AU - Dylan Marks AU - Neil Ray AU - Adrian Tisbe AU - Kyle Tse AU - Mimi Koehl Y1 - 2013/01/01 UR - http://biorxiv.org/content/early/2013/12/05/001297.abstract N2 - We report the effects of posture and morphology on the static aerodynamic stability and control effectiveness of physical models based on the feathered dinosaur, †Microraptor gui, from the Cretaceous of China. Postures had similar lift and drag coefficients and were broadly similar when simplified metrics of gliding were considered, but they exhibited different stability characteristics depending on the position of the legs and the presence of feathers on the legs and the tail. Both stability and the function of appendages in generating maneuvering forces and torques changed as the glide angle or angle of attack were changed. These are significant because they represent an aerial environment that may have shifted during the evolution of directed aerial descent and other aerial behaviors. Certain movements were particularly effective (symmetric movements of the wings and tail in pitch, asymmetric wing movements, some tail movements). Other appendages altered their function from creating yaws at high angle of attack to rolls at low angle of attack, or reversed their function entirely. While †M. gui lived after †Archaeopteryx and likely represents a side experiment with feathered morphology, the general patterns of stability and control effectiveness suggested from the manipulations of forelimb, hindlimb and tail morphology here may help understand the evolution of flight control aerodynamics in vertebrates. Though these results rest on a single specimen, as further fossils with different morphologies tested, the findings here could be applied in a phylogenetic context to reveal biomechanical constraints on extinct flyers arising from the need to maneuver. ER -