Aerodynamics and Energetics of Intermittent Flight in Birds

Hypotheses explaining the use of intermittent bounding and undulatingflight modes in birds are considered. Existing theoretical modelsof intermittent flight have assumed that the animal flies ata constant speed throughout. They predict that mean mechanicalpower in undulating (flap-gliding) flight is reduced comparedto steady flight over a broad range of speeds, but is reducedin bounding flight only at very high flight speeds. Lift generatedby the bird's body or tail has a small effect on power, butis insufficient to explain observations of bounding at intermediateflight speeds. Measurements on starlings Sturnus vulgaris inundulating flight in a wind tunnel show that flight speed variesby around ±1 m/sec during a flap-glide cycle. Dynamicenergy is used to quantify flight performance, and reveals thatthe geometry of the flight path depends upon wingbeat kinematics,and that neither flapping nor gliding phases are at constantspeed and angle to the horizontal. The bird gains both kineticand potential energy during the flapping phases. A new theoreticalmodel indicates that such speed variation can give significantsavings in mechanical power in both bounding and undulatingflight. Alternative hypotheses for intermittent flight includea gearing mechanism, based on duty factor, mediating musclepower or force output against aerodynamic requirements. Thiscould explain the use of bounding flight in hovering and climbingin small passerines. Both bounding and undulating confer otheradaptive benefits; undulating may be primitive in birds, butbounding may have evolved in response to flight performanceoptimization, or to factors such as unpredictability in responseto predation.