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Engineers Study Bird Flight

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Stock image of gulls in flight against a light blue sky
Christina Harvey, assistant professor in the Department of Mechanical and Aerospace Engineering, uses a combination of wind tunnel studies and modeling of inertial forces to understand how birds maintain stable flight. (Getty Images)

People have been fascinated by bird flight for centuries, but exactly how birds can be so agile in the air remains mysterious. A new study, published the week of Sept. 5 in , uses modeling and aerodynamics to describe how gulls can change the shape of their wings to control their response to gusts or other disturbances. The lessons could one day apply to uncrewed aerial vehicles or other flying machines.

鈥淏irds easily perform challenging maneuvers and they鈥檙e adaptable, so what exactly about their flight is most useful to implement in future aircraft?鈥 said Christina Harvey, assistant professor in the Department of Mechanical and Aerospace Engineering at the University of California, Davis, and lead author on the paper.

Harvey began studying gulls as a master鈥檚 student in zoology at the University of British Columbia, after earning her bachelor鈥檚 degree in mechanical engineering.

鈥淕ulls are very common and easy to find, and they鈥檙e really impressive gliders,鈥 she said.

Harvey continued her work on gulls as a doctoral student at the University of Michigan. She recently joined the faculty at 澳门六合彩资料库 Davis after completing her Ph.D. in aerospace engineering. 

A woman in a dark sweatshirt, wearing facemask, examines a model of a bird's wing. Other models stand on a bench to the left.
Harvey with wind tunnel models of wings in the lab at the University of Michigan.

In March this year, Harvey and colleagues at the University of Michigan published a analyzing the flight dynamics of 22 bird species. While previous studies have tended to focus on aerodynamics 鈥 how air moves around a bird 鈥 Harvey developed equations to describe birds鈥 inertial properties, such as the center of gravity and the neutral point, where aerodynamic forces can be consistently modeled as point forces.

Aircraft are typically designed to be stable or unstable. A stable aircraft will tend to return back to steady flight when perturbed (for example, getting pushed up by a wind gust). This is desirable, for example, in an airliner, but not for a jet fighter. Highly maneuverable aircraft are designed to be unstable.

In their Nature paper, Harvey and colleagues showed that almost all the bird species studied are capable of both stable and unstable flight and use wing movements to shift between these modes.

Controllable flight 

The new study builds on this work, bringing together using 3D printed models of gulls and gull wings in a wind tunnel, with computer modeling of inertial forces to understand how gulls achieve stability along their long axis (falling or rising).

Gulls can adjust how they respond to perturbations in that axis by adjusting their wrist and elbow joints, and morphing the shape of the wings, they found. The team was able to predict the gulls鈥 flying qualities and how rapidly they can recover from a perturbation like a gust. That reaction time also gives insights into the 鈥渃ontrollable range鈥 for the bird and into applying bird flight dynamics to aircraft.

鈥淭he flight qualities analysis asks: if you built an aircraft exactly like a gull, would a human be able to fly it?鈥 Harvey said.

As uncrewed aerial vehicles, or drones, become more widely used, they need to be able to navigate complex urban environments, something birds do very well. A deeper understanding of bird flight could help improve drone designs for various uses.

Harvey will be opening her lab at 澳门六合彩资料库 Davis this fall. She hopes to collaborate with other campus researchers, including the California Raptor Center and researchers working on insect flight at the College of Biological Sciences.

鈥淭here are so many open questions about bird flight,鈥 she said, 鈥淚鈥檓 looking forward to seeing what else is out there to discover.鈥

Co-author on the paper is Daniel Inman, University of Michigan. Harvey鈥檚 work is partly supported by grants from the U.S. Air Force Office of Scientific Research and the National Science Foundation.  

Media Resources

(PNAS)

Media Contacts:

  • Christina Harvey, Mechanical and Aerospace Engineering, harvey@ucdavis.edu
  • Andy Fell, News and Media Relations, 530-304-8888, ahfell@ucdavis.edu

 

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