Inertial swimming as a singular perturbation

Stephen Childress

Inertial swimming as a singular perturbation

Stephen Childress

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

7 Scopus citations

Abstract

The swimming of a sheet, originally treated by G.I. Taylor (1951) for the case of Stokes flow, is considered at moderate and high Reynolds numbers using matched asymptotic expansions. It is shown that for propagating waves with frequency CO, wavenum-ber k, and amplitude b, the swimming speed must be deduced from a dual expansion in powers of the small parameters bkR^1/2 and R^-1/2, where R = ω/vk² is the Reynolds number. The result of Tuck (1968) for the leading term of the swimming velocity is recovered, and higher-order results are given. For the case of a planar, stretching sheet, the expansion is in powers of bk and R^-1/2 and a limit for large R is obtained as a boundary layer. We contrast these results with the inviscid case, where no swimming is possible. We also consider briefly the application of these ideas to "recoil swimming", wherein the movements of the center of mass and center of volume of a body allow swimming at both finite and infinite Reynolds numbers.

Original language	English
Title of host publication	2008 Proceedings of the ASME Dynamic Systems and Control Conference, DSCC 2008
Pages	1083-1090
Number of pages	8
Edition	PART B
State	Published - 2009
Externally published	Yes
Event	2008 ASME Dynamic Systems and Control Conference, DSCC 2008 - Ann Arbor, MI, United States Duration: 20 Oct 2008 → 22 Oct 2008

Publication series

Name	2008 Proceedings of the ASME Dynamic Systems and Control Conference, DSCC 2008
Number	PART B

Conference

Conference	2008 ASME Dynamic Systems and Control Conference, DSCC 2008
Country/Territory	United States
City	Ann Arbor, MI
Period	20/10/08 → 22/10/08

Cite this

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title = "Inertial swimming as a singular perturbation",

abstract = "The swimming of a sheet, originally treated by G.I. Taylor (1951) for the case of Stokes flow, is considered at moderate and high Reynolds numbers using matched asymptotic expansions. It is shown that for propagating waves with frequency CO, wavenum-ber k, and amplitude b, the swimming speed must be deduced from a dual expansion in powers of the small parameters bkR1/2 and R-1/2, where R = ω/vk2 is the Reynolds number. The result of Tuck (1968) for the leading term of the swimming velocity is recovered, and higher-order results are given. For the case of a planar, stretching sheet, the expansion is in powers of bk and R-1/2 and a limit for large R is obtained as a boundary layer. We contrast these results with the inviscid case, where no swimming is possible. We also consider briefly the application of these ideas to {"}recoil swimming{"}, wherein the movements of the center of mass and center of volume of a body allow swimming at both finite and infinite Reynolds numbers.",

author = "Stephen Childress",

year = "2009",

language = "English",

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series = "2008 Proceedings of the ASME Dynamic Systems and Control Conference, DSCC 2008",

number = "PART B",

pages = "1083--1090",

booktitle = "2008 Proceedings of the ASME Dynamic Systems and Control Conference, DSCC 2008",

edition = "PART B",

note = "2008 ASME Dynamic Systems and Control Conference, DSCC 2008 ; Conference date: 20-10-2008 Through 22-10-2008",

}

Inertial swimming as a singular perturbation. / Childress, Stephen.
2008 Proceedings of the ASME Dynamic Systems and Control Conference, DSCC 2008. PART B. ed. 2009. p. 1083-1090 (2008 Proceedings of the ASME Dynamic Systems and Control Conference, DSCC 2008; No. PART B).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Inertial swimming as a singular perturbation

AU - Childress, Stephen

PY - 2009

Y1 - 2009

N2 - The swimming of a sheet, originally treated by G.I. Taylor (1951) for the case of Stokes flow, is considered at moderate and high Reynolds numbers using matched asymptotic expansions. It is shown that for propagating waves with frequency CO, wavenum-ber k, and amplitude b, the swimming speed must be deduced from a dual expansion in powers of the small parameters bkR1/2 and R-1/2, where R = ω/vk2 is the Reynolds number. The result of Tuck (1968) for the leading term of the swimming velocity is recovered, and higher-order results are given. For the case of a planar, stretching sheet, the expansion is in powers of bk and R-1/2 and a limit for large R is obtained as a boundary layer. We contrast these results with the inviscid case, where no swimming is possible. We also consider briefly the application of these ideas to "recoil swimming", wherein the movements of the center of mass and center of volume of a body allow swimming at both finite and infinite Reynolds numbers.

AB - The swimming of a sheet, originally treated by G.I. Taylor (1951) for the case of Stokes flow, is considered at moderate and high Reynolds numbers using matched asymptotic expansions. It is shown that for propagating waves with frequency CO, wavenum-ber k, and amplitude b, the swimming speed must be deduced from a dual expansion in powers of the small parameters bkR1/2 and R-1/2, where R = ω/vk2 is the Reynolds number. The result of Tuck (1968) for the leading term of the swimming velocity is recovered, and higher-order results are given. For the case of a planar, stretching sheet, the expansion is in powers of bk and R-1/2 and a limit for large R is obtained as a boundary layer. We contrast these results with the inviscid case, where no swimming is possible. We also consider briefly the application of these ideas to "recoil swimming", wherein the movements of the center of mass and center of volume of a body allow swimming at both finite and infinite Reynolds numbers.

UR - https://www.scopus.com/pages/publications/70349906785

M3 - Conference contribution

AN - SCOPUS:70349906785

SN - 9780791843352

T3 - 2008 Proceedings of the ASME Dynamic Systems and Control Conference, DSCC 2008

SP - 1083

EP - 1090

BT - 2008 Proceedings of the ASME Dynamic Systems and Control Conference, DSCC 2008

T2 - 2008 ASME Dynamic Systems and Control Conference, DSCC 2008

Y2 - 20 October 2008 through 22 October 2008

ER -

Inertial swimming as a singular perturbation

Abstract

Publication series

Conference

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