Published November 4, 2021 | Version v1

Convergence of undulatory swimming kinematics across a diversity of fishes

  • 1. Harvard University
  • 2. Stockholm University
  • 3. Yale University
  • 4. USGS
  • 5. University of Florida
  • 6. Aberystwyth University

Description

Fishes exhibit an astounding diversity of locomotor behaviors, from classic swimming with their body and fins to jumping, flying, walking, and burrowing.  Fishes that use their body and caudal fin (BCF) during undulatory swimming have been traditionally divided into modes based on the length of the propulsive body wave and the ratio of head:tail oscillation amplitude: anguilliform, sub-carangiform, carangiform and thunniform. This classification was first proposed based on key morphological traits, such as body stiffness and elongation, to group fishes based on their expected swimming mechanics. Here, we present a comparative study of 44 diverse species quantifying kinematics and morphology of BCF-swimming fishes. Our results reveal that most species we studied share similar oscillation amplitude during steady locomotion that can be modeled using a second-degree order polynomial. The length of the propulsive body wave was shorter for species classified as anguilliform and longer for those classified as thunniform, although substantial variability existed both within and among species. Moreover, there was no decrease in head:tail amplitude from anguilliform to thunniform mode of locomotion as we expected from the traditional classification. While the expected swimming modes correlated with morphological traits, they did not accurately represent the kinematics of BCF locomotion. These results indicate that even fish species differing as substantially in morphology as tuna and eel exhibit statistically similar two-dimensional midline kinematics and point toward unifying locomotor hydrodynamic mechanisms that can serve as the basis for understanding aquatic locomotion and controlling biomimetic aquatic robots.

Notes

The data and code available here allow to reproduce the results presented in the article.

Funding provided by: National Science Foundation
Crossref Funder Registry ID: http://dx.doi.org/10.13039/100000001
Award Number: 093088-17158

Funding provided by: Office of Naval Research
Crossref Funder Registry ID: http://dx.doi.org/10.13039/100000006
Award Number: N000141410533

Funding provided by: Fonds de recherche du Québec – Nature et technologies
Crossref Funder Registry ID: http://dx.doi.org/10.13039/501100003151
Award Number:

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Related works

Is source of
10.5061/dryad.bg79cnp9x (DOI)