Bending rules for animal propulsion

Animal propulsors such as wings and fins bend during motion and these bending patterns are believed to contribute to the high efficiency of animal movements compared with those of man-made designs. However, efforts to implement flexible designs have been met with contradictory performance results. C...

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Bibliographic Details
Published in:Nature communications 2014-02, Vol.5 (1), p.3293-3293, Article 3293
Main Authors: Lucas, Kelsey N., Johnson, Nathan, Beaulieu, Wesley T., Cathcart, Eric, Tirrell, Gregory, Colin, Sean P., Gemmell, Brad J., Dabiri, John O., Costello, John H.
Format: Article
Language:English
Subjects:
631/601/1332
Animal Fins - physiology
Animals
Flight, Animal - physiology
Humanities and Social Sciences
Insecta - physiology
Mollusca - physiology
multidisciplinary
Phylogeny
Science
Science (multidisciplinary)
Swimming - physiology
Vertebrates - physiology
Wings, Animal - physiology
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Summary:Animal propulsors such as wings and fins bend during motion and these bending patterns are believed to contribute to the high efficiency of animal movements compared with those of man-made designs. However, efforts to implement flexible designs have been met with contradictory performance results. Consequently, there is no clear understanding of the role played by propulsor flexibility or, more fundamentally, how flexible propulsors should be designed for optimal performance. Here we demonstrate that during steady-state motion by a wide range of animals, from fruit flies to humpback whales, operating in either air or water, natural propulsors bend in similar ways within a highly predictable range of characteristic motions. By providing empirical design criteria derived from natural propulsors that have convergently arrived at a limited design space, these results provide a new framework from which to understand and design flexible propulsors. Animal propulsors—wings and fins—typically bend during motion. Here, the authors analysed video data on animal propulsor bending and find that, for propulsion within inertially dominated flows, the flexion angles and the positions of the point of flexion are similar across the animal kingdom.
ISSN:2041-1723
2041-1723
DOI:10.1038/ncomms4293