Three-dimensional simulation for fast forward flight of a calliope hummingbird | Zendy

Jialei Song | Zendy; Bret W. Tobalske | Zendy; Donald R. Powers | Zendy; Tyson L. Hedrick | Zendy; Haoxiang Luo | Zendy

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Three-dimensional simulation for fast forward flight of a calliope hummingbird

Author(s) -

Jialei Song,

Bret W. Tobalske,

Donald R. Powers,

Tyson L. Hedrick,

Haoxiang Luo

Publication year - 2016

Publication title -

royal society open science

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 0.84

H-Index - 51

ISSN - 2054-5703

DOI - 10.1098/rsos.160230

Subject(s) - hummingbird , flapping , bird flight , wing , thrust , aerodynamics , aerospace engineering , kinematics , lift (data mining) , drag , physics , geology , mechanics , computer science , engineering , classical mechanics , biology , ecology , data mining

We present a computational study of flapping-wing aerodynamics of a calliope hummingbird ( Selasphorus calliope ) during fast forward flight. Three-dimensional wing kinematics were incorporated into the model by extracting time-dependent wing position from high-speed videos of the bird flying in a wind tunnel at 8.3 m s −1 . The advance ratio, i.e. the ratio between flight speed and average wingtip speed, is around one. An immersed-boundary method was used to simulate flow around the wings and bird body. The result shows that both downstroke and upstroke in a wingbeat cycle produce significant thrust for the bird to overcome drag on the body, and such thrust production comes at price of negative lift induced during upstroke. This feature might be shared with bats, while being distinct from insects and other birds, including closely related swifts.

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