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Keywords: Maneuvering
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Journal Articles
J Exp Biol (2023) 226 (6): jeb244739.
Published: 15 March 2023
.... 31 7 2022 30 1 2023 © 2023. Published by The Company of Biologists Ltd 2023 Highlighted Article: Deep-bodied, pectoral fin swimming fish show lower net energetic costs of maneuvering in a bidirectional wave-surge type flow. Wave surge Cost of swimming Respirometry...
Journal Articles
J Exp Biol (2020) 223 (16): jeb223230.
Published: 24 August 2020
... to quantify hydrodynamic mechanisms of fish locomotion and facilitates the understanding of how body kinematics generate locomotor forces in freely swimming fishes. Li et al. (2012 , 2014 ) studied flow patterns produced by maneuvering zebrafish larvae, and although the anatomy and muscular development...
Includes: Supplementary data
Journal Articles
J Exp Biol (2018) 221 (6): jeb166041.
Published: 22 March 2018
...Frank E. Fish; Allison Kolpas; Andrew Crossett; Michael A. Dudas; Keith W. Moored; Hilary Bart-Smith ABSTRACT For aquatic animals, turning maneuvers represent a locomotor activity that may not be confined to a single coordinate plane, making analysis difficult, particularly in the field. To measure...
Includes: Supplementary data
Journal Articles
J Exp Biol (2016) 219 (21): 3315–3320.
Published: 1 November 2016
... to function as control surfaces that effect maneuvers, but quantitative tests of this hypothesis have been lacking. Here, we constructed a simple hydrodynamic model to predict the longitudinal-axis roll performance of fin whales, and we tested its predictions against kinematic data recorded by on-board...
Includes: Supplementary data
Journal Articles
J Exp Biol (2012) 215 (23): 4070–4084.
Published: 1 December 2012
... also share asymmetry in inner and outer stroke amplitudes with the Drosophila ‘sashay maneuvers’ ( Ristroph et al., 2009 ), which have a strong yaw component, but again differ with respect to deviation and stroke plane angle between the inner and outer wings. Fig. 7. Matrix of significance...
Includes: Supplementary data
Journal Articles
Journal Articles
J Exp Biol (2008) 211 (21): 3359–3369.
Published: 1 November 2008
.... * Author for correspondence (e-mail: tytell@umd.edu ) 1 9 2008 © The Company of Biologists Limited 2008 2008 fluid dynamics escape response C-start turning maneuvering bluegill sunfish Lepomis macrochirus particle image velocimetry The escape response (also called a C...
Includes: Multimedia, Supplementary data
Journal Articles
Journal Articles
Journal Articles
J Exp Biol (2007) 210 (1): 107–117.
Published: 1 January 2007
... to achieve higher braking forces at higher swimming speeds without altering body or fin kinematics. This result can likely be extended to other maneuvers such as turning. Protraction of the pectoral fins during prey capture is a mechanism of deceleration employed by largemouth bass and bluegill( Fig. 5A...
Journal Articles
J Exp Biol (2005) 208 (23): 4479–4494.
Published: 1 December 2005
...Eliot G. Drucker; George V. Lauder SUMMARY In this study, we examine the kinematics and hydrodynamics of the soft dorsal fin in a representative basal teleost, the rainbow trout( Oncorhynchus mykiss ), during steady rectilinear locomotion at 0.5–2.0 body lengths ( L ) s –1 and during maneuvering...
Journal Articles
Journal Articles
J Exp Biol (2003) 206 (5): 813–826.
Published: 1 March 2003
... the behavioral and hydromechanical repertoire of the paired pectoral fins of rainbow trout Oncorhynchus mykiss , performing both steady rectilinear swimming and unsteady maneuvering locomotion. A combination of kinematic analysis and quantitative flow visualization (using digital particle image velocimetry...
Journal Articles
J Exp Biol (2001) 204 (17): 2943–2958.
Published: 1 September 2001
... hydrodynamic study of dorsal fin function in teleost fishes, we analyzed the wake created by the soft dorsal fin of bluegill sunfish ( Lepomis macrochirus ) during both steady swimming and unsteady turning maneuvers. Digital particle image velocimetry was used to visualize wake structures and to calculate...
Journal Articles
J Exp Biol (1998) 201 (5): 655–672.
Published: 1 March 1998
...) and flight path by producing a series of rapidly oscillating movements. Although the primary locomotor event (downstroke) is saltatory, maneuvering during slow flight should be considered as a product of nearly continuous, juxtaposed force generation throughout the wingbeat cycle. Further, viewing upstroke...