Avian FlightBird flight has always intrigued mankind. This book provides an up to date account of our existing knowledge on the subject, as well as offering new insights and challenging some established views. A brief history of the science of flight introduces the basic physical principles governing aerial locomotion. A treatment of flight-related functional morphology concentrates on the difference in shape of the arm and hand part of the wings, on the structure and function of tails, and on the shape of the body. The anatomy and mechanical properties of feathers receive special attention. Aerodynamic principles used by birds are explained in theory by simply applying Newton's laws, and in practice by showing the direction and velocity of the attached flow around an arm wing cross section and of the leading edge vortex flow above a hand wing. The Archaeopteryx fossils remain crucial in our understanding of the evolution of bird flight despite the recent discovery of a range of well-preserved ancient birds. A novel insight into the interactions between wings and air challenges established theories relating to the origin of bird flight. Take-off, flapping flight, gliding and landing are the basic ingredients of bird flight, and birds use a variety of flight styles from hovering to soaring. Flight muscles consisting of mosaics of specialised fibres are the engines that generate the force required to keep the wings and tail in the gliding configuration and perform work during flapping motion. The energy required to fly can be estimated or measured directly, and a comparison of the empirical results provides insights into the trend in metabolic costs of flight of birds varying in shape and mass from hummingbirds to albatrosses. |
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acceleration aerodynamic aircraft albatrosses alula angle of attack animal Archaeopteryx arm wing average barbs barbules Basilisk lizards behaviour bird flight bird wings body mass carpometacarpus Chapter common kestrels common swift decrease direction distance dorsal downstroke energy expenditure estimate European starling Experimental film flapping flight flight costs flight speed flow fluid flying birds foraging fossils function furcula gliding hand wing horizontal hovering humerus hummingbird increase indicated kestrels kinematics kinetic energy leading edge length lift force maximum measured metabolic rates movements muscles pectoralis pigeon position pressure primary feathers remiges rotation run over water shape shoulder joint skeleton species sternum stretched structures studies surface swift tail take-off technique thrush nightingale thrust ulna upstroke values vanes vary velocity ventral vertical Videler vortex wandering albatross weight wind tunnel windhovering wing beat cycle wing beat frequencies wing tip wrist