Propulsive force calculations in swimming frogs II. Application of a vortex ring model to DPIV data

E.J. Stamhuis; S. Nauwelaerts

doi:10.1242/jeb.01530

Propulsive force calculations in swimming frogs II. Application of a vortex ring model to DPIV data

E.J. Stamhuis, S. Nauwelaerts

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Abstract

Frogs propel themselves by kicking water backwards using a synchronised extension of their hind limbs and webbed feet. To understand this propulsion process, we quantified the water movements and displacements resulting from swimming in the green frog Rana esculenta, applying digital particle image velocimetry (DPIV) to the frog's wake.

The wake showed two vortex rings left behind by the two feet. The rings appeared to be elliptic in planform, urging for correction of the observed ring radii. The rings' long and short axes (average ratio 1.75:1) were about the same size as the length and width of the propelling frog foot and the ellipsoid mass of water accelerated with it. Average thrust forces were derived from the vortex rings, 1445 assuming all propulsive energy to be compiled in the rings. The calculated average forces (F-av=0.10 +/- 0.04 N) were in close agreement with our parallel study applying a momentum-impulse approach to water displacements during the leg extension phase.

We did not find any support for previously assumed propulsion enhancement mechanisms. The feet do not clap together at the end of the power stroke and no 'wedge-action' jetting is observed. Each foot accelerates its own water mantle, ending up in a separate vortex ring without interference by the other leg.

Original language	English
Pages (from-to)	1445-1451
Number of pages	7
Journal	Journal of Experimental Biology
Volume	208
Issue number	8
DOIs	https://doi.org/10.1242/jeb.01530
Publication status	Published - Apr-2005

Keywords

frog
Rana esculenta
swimming
thrust force
vortex ring
DPIV
PARTICLE IMAGE VELOCIMETRY
ANIMAL FLIGHT
HYMENOCHIRUS-BOETTGERI
SLOW FLIGHT
WAKE
MECHANICS
BIOMECHANICS
LOCOMOTION
ENERGETICS
ENERGY

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Propulsive force calculations in swimming frogs II. Application of a vortex ring model to DPIV dataFinal publisher's version, 328 KBLicence: Unspecified

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@article{7d559c8d531b4c1ca8ab79db3c6a2c23,

title = "Propulsive force calculations in swimming frogs II. Application of a vortex ring model to DPIV data",

abstract = "Frogs propel themselves by kicking water backwards using a synchronised extension of their hind limbs and webbed feet. To understand this propulsion process, we quantified the water movements and displacements resulting from swimming in the green frog Rana esculenta, applying digital particle image velocimetry (DPIV) to the frog's wake.The wake showed two vortex rings left behind by the two feet. The rings appeared to be elliptic in planform, urging for correction of the observed ring radii. The rings' long and short axes (average ratio 1.75:1) were about the same size as the length and width of the propelling frog foot and the ellipsoid mass of water accelerated with it. Average thrust forces were derived from the vortex rings, 1445 assuming all propulsive energy to be compiled in the rings. The calculated average forces (F-av=0.10 +/- 0.04 N) were in close agreement with our parallel study applying a momentum-impulse approach to water displacements during the leg extension phase.We did not find any support for previously assumed propulsion enhancement mechanisms. The feet do not clap together at the end of the power stroke and no 'wedge-action' jetting is observed. Each foot accelerates its own water mantle, ending up in a separate vortex ring without interference by the other leg.",

keywords = "frog, Rana esculenta, swimming, thrust force, vortex ring, DPIV, PARTICLE IMAGE VELOCIMETRY, ANIMAL FLIGHT, HYMENOCHIRUS-BOETTGERI, SLOW FLIGHT, WAKE, MECHANICS, BIOMECHANICS, LOCOMOTION, ENERGETICS, ENERGY",

author = "E.J. Stamhuis and S. Nauwelaerts",

year = "2005",

month = apr,

doi = "10.1242/jeb.01530",

language = "English",

volume = "208",

pages = "1445--1451",

journal = "Journal of Experimental Biology",

issn = "0022-0949",

publisher = "COMPANY OF BIOLOGISTS LTD",

number = "8",

}

TY - JOUR

T1 - Propulsive force calculations in swimming frogs II. Application of a vortex ring model to DPIV data

AU - Stamhuis, E.J.

AU - Nauwelaerts, S.

PY - 2005/4

Y1 - 2005/4

N2 - Frogs propel themselves by kicking water backwards using a synchronised extension of their hind limbs and webbed feet. To understand this propulsion process, we quantified the water movements and displacements resulting from swimming in the green frog Rana esculenta, applying digital particle image velocimetry (DPIV) to the frog's wake.The wake showed two vortex rings left behind by the two feet. The rings appeared to be elliptic in planform, urging for correction of the observed ring radii. The rings' long and short axes (average ratio 1.75:1) were about the same size as the length and width of the propelling frog foot and the ellipsoid mass of water accelerated with it. Average thrust forces were derived from the vortex rings, 1445 assuming all propulsive energy to be compiled in the rings. The calculated average forces (F-av=0.10 +/- 0.04 N) were in close agreement with our parallel study applying a momentum-impulse approach to water displacements during the leg extension phase.We did not find any support for previously assumed propulsion enhancement mechanisms. The feet do not clap together at the end of the power stroke and no 'wedge-action' jetting is observed. Each foot accelerates its own water mantle, ending up in a separate vortex ring without interference by the other leg.

AB - Frogs propel themselves by kicking water backwards using a synchronised extension of their hind limbs and webbed feet. To understand this propulsion process, we quantified the water movements and displacements resulting from swimming in the green frog Rana esculenta, applying digital particle image velocimetry (DPIV) to the frog's wake.The wake showed two vortex rings left behind by the two feet. The rings appeared to be elliptic in planform, urging for correction of the observed ring radii. The rings' long and short axes (average ratio 1.75:1) were about the same size as the length and width of the propelling frog foot and the ellipsoid mass of water accelerated with it. Average thrust forces were derived from the vortex rings, 1445 assuming all propulsive energy to be compiled in the rings. The calculated average forces (F-av=0.10 +/- 0.04 N) were in close agreement with our parallel study applying a momentum-impulse approach to water displacements during the leg extension phase.We did not find any support for previously assumed propulsion enhancement mechanisms. The feet do not clap together at the end of the power stroke and no 'wedge-action' jetting is observed. Each foot accelerates its own water mantle, ending up in a separate vortex ring without interference by the other leg.

KW - frog

KW - Rana esculenta

KW - swimming

KW - thrust force

KW - vortex ring

KW - DPIV

KW - PARTICLE IMAGE VELOCIMETRY

KW - ANIMAL FLIGHT

KW - HYMENOCHIRUS-BOETTGERI

KW - SLOW FLIGHT

KW - WAKE

KW - MECHANICS

KW - BIOMECHANICS

KW - LOCOMOTION

KW - ENERGETICS

KW - ENERGY

U2 - 10.1242/jeb.01530

DO - 10.1242/jeb.01530

M3 - Article

C2 - 15802668

SN - 0022-0949

VL - 208

SP - 1445

EP - 1451

JO - Journal of Experimental Biology

JF - Journal of Experimental Biology

IS - 8

ER -

Propulsive force calculations in swimming frogs II. Application of a vortex ring model to DPIV data

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