New approaches for assessing squid fin motions: coupling proper orthogonal decomposition with volumetric particle tracking velocimetry

Squid, which swim using a coupled fin/jet system powered by muscular hydrostats, pose unique challenges for the study of locomotion. The high flexibility of the fins and complex flow fields generated by distinct propulsion systems require innovative techniques for locomotive assessment. For this stu...

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Published in:Journal of Experimental Biology
Main Authors: Bartol, Ian K., Krueger, Paul S., York, Carly A., Thompson, Joseph T.
Format: Text
Language:English
Published: The Company of Biologists Ltd 2018
Subjects:
RESEARCH ARTICLE
DML
Online Access:http://jeb.biologists.org/cgi/content/short/221/14/jeb176750
https://doi.org/10.1242/jeb.176750
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spelling fthighwire:oai:open-archive.highwire.org:jexbio:221/14/jeb176750 2023-05-15T16:01:48+02:00 New approaches for assessing squid fin motions: coupling proper orthogonal decomposition with volumetric particle tracking velocimetry Bartol, Ian K. Krueger, Paul S. York, Carly A. Thompson, Joseph T. 2018-07-20 01:08:24.0 text/html http://jeb.biologists.org/cgi/content/short/221/14/jeb176750 https://doi.org/10.1242/jeb.176750 en eng The Company of Biologists Ltd http://jeb.biologists.org/cgi/content/short/221/14/jeb176750 http://dx.doi.org/10.1242/jeb.176750 Copyright (C) 2018, Company of Biologists RESEARCH ARTICLE TEXT 2018 fthighwire https://doi.org/10.1242/jeb.176750 2018-12-30T19:27:19Z Squid, which swim using a coupled fin/jet system powered by muscular hydrostats, pose unique challenges for the study of locomotion. The high flexibility of the fins and complex flow fields generated by distinct propulsion systems require innovative techniques for locomotive assessment. For this study, we used proper orthogonal decomposition (POD) to decouple components of the fin motions and defocusing digital particle tracking velocimetry (DDPTV) to quantify the resultant 3D flow fields. Kinematic footage and DDPTV data were collected from brief squid, Lolliguncula brevis [3.1–6.5 cm dorsal mantle length (DML)], swimming freely in a water tunnel at speeds of 0.39–7.20 DML s−1. Both flap and wave components were present in all fin motions, but the relative importance of the wave components was higher for arms-first swimming than for tail-first swimming and for slower versus higher speed swimming. When prominent wave components were present, more complex interconnected vortex ring wakes were observed, while fin movements dominated by flapping resulted in more spatially separated vortex ring patterns. Although the jet often produced the majority of the thrust for steady rectilinear swimming, our results demonstrated that the fins can contribute more thrust than the jet at times, consistently produce comparable levels of lift to the jet during arms-first swimming, and can boost overall propulsive efficiency. By producing significant drag signatures, the fins can also aid in stabilization and maneuvering. Clearly, fins play multiple roles in squid locomotion, and when coupled with the jet, allow squid to perform a range of swimming behaviors integral to their ecological success. Text DML HighWire Press (Stanford University) Journal of Experimental Biology
institution Open Polar
collection HighWire Press (Stanford University)
op_collection_id fthighwire
language English
topic RESEARCH ARTICLE
spellingShingle RESEARCH ARTICLE
Bartol, Ian K.
Krueger, Paul S.
York, Carly A.
Thompson, Joseph T.
New approaches for assessing squid fin motions: coupling proper orthogonal decomposition with volumetric particle tracking velocimetry
topic_facet RESEARCH ARTICLE
description Squid, which swim using a coupled fin/jet system powered by muscular hydrostats, pose unique challenges for the study of locomotion. The high flexibility of the fins and complex flow fields generated by distinct propulsion systems require innovative techniques for locomotive assessment. For this study, we used proper orthogonal decomposition (POD) to decouple components of the fin motions and defocusing digital particle tracking velocimetry (DDPTV) to quantify the resultant 3D flow fields. Kinematic footage and DDPTV data were collected from brief squid, Lolliguncula brevis [3.1–6.5 cm dorsal mantle length (DML)], swimming freely in a water tunnel at speeds of 0.39–7.20 DML s−1. Both flap and wave components were present in all fin motions, but the relative importance of the wave components was higher for arms-first swimming than for tail-first swimming and for slower versus higher speed swimming. When prominent wave components were present, more complex interconnected vortex ring wakes were observed, while fin movements dominated by flapping resulted in more spatially separated vortex ring patterns. Although the jet often produced the majority of the thrust for steady rectilinear swimming, our results demonstrated that the fins can contribute more thrust than the jet at times, consistently produce comparable levels of lift to the jet during arms-first swimming, and can boost overall propulsive efficiency. By producing significant drag signatures, the fins can also aid in stabilization and maneuvering. Clearly, fins play multiple roles in squid locomotion, and when coupled with the jet, allow squid to perform a range of swimming behaviors integral to their ecological success.
format Text
author Bartol, Ian K.
Krueger, Paul S.
York, Carly A.
Thompson, Joseph T.
author_facet Bartol, Ian K.
Krueger, Paul S.
York, Carly A.
Thompson, Joseph T.
author_sort Bartol, Ian K.
title New approaches for assessing squid fin motions: coupling proper orthogonal decomposition with volumetric particle tracking velocimetry
title_short New approaches for assessing squid fin motions: coupling proper orthogonal decomposition with volumetric particle tracking velocimetry
title_full New approaches for assessing squid fin motions: coupling proper orthogonal decomposition with volumetric particle tracking velocimetry
title_fullStr New approaches for assessing squid fin motions: coupling proper orthogonal decomposition with volumetric particle tracking velocimetry
title_full_unstemmed New approaches for assessing squid fin motions: coupling proper orthogonal decomposition with volumetric particle tracking velocimetry
title_sort new approaches for assessing squid fin motions: coupling proper orthogonal decomposition with volumetric particle tracking velocimetry
publisher The Company of Biologists Ltd
publishDate 2018
url http://jeb.biologists.org/cgi/content/short/221/14/jeb176750
https://doi.org/10.1242/jeb.176750
genre DML
genre_facet DML
op_relation http://jeb.biologists.org/cgi/content/short/221/14/jeb176750
http://dx.doi.org/10.1242/jeb.176750
op_rights Copyright (C) 2018, Company of Biologists
op_doi https://doi.org/10.1242/jeb.176750
container_title Journal of Experimental Biology
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