A Caltech Library Service

Body-induced vortical flows: a common mechanism for self-corrective trimming control in boxfishes

Bartol, Ian K. and Gharib, Morteza and Webb, Paul W. and Weihs, Daniel and Gordon, Malcolm S. (2005) Body-induced vortical flows: a common mechanism for self-corrective trimming control in boxfishes. Journal of Experimental Biology, 208 (2). pp. 327-344. ISSN 0022-0949. doi:10.1242/jeb.01356.

PDF - Published Version
See Usage Policy.


Use this Persistent URL to link to this item:


Boxfishes (Teleostei: Ostraciidae) are marine fishes having rigid carapaces that vary significantly among taxa in their shapes and structural ornamentation. We showed previously that the keels of the carapace of one species of tropical boxfish, the smooth trunkfish, produce leading edge vortices (LEVs) capable of generating self-correcting trimming forces during swimming. In this paper we show that other tropical boxfishes with different carapace shapes have similar capabilities. We conducted a quantitative study of flows around the carapaces of three morphologically distinct boxfishes (spotted boxfish, scrawled cowfish and buffalo trunkfish) using stereolithographic models and three separate but interrelated analytical approaches: digital particle image velocimetry (DPIV), pressure distribution measurements, and force balance measurements. The ventral keels of all three forms produced LEVs that grew in circulation along the bodies, resembling the LEVs produced around delta-winged aircraft. These spiral vortices formed above the keels and increased in circulation as pitch angle became more positive, and formed below the keels and increased in circulation as pitch angle became more negative. Vortices also formed along the eye ridges of all boxfishes. In the spotted boxfish, which is largely trapezoidal in cross section, consistent dorsal vortex growth posterior to the eye ridge was also present. When all three boxfishes were positioned at various yaw angles, regions of strongest concentrated vorticity formed in far-field locations of the carapace compared with near-field areas, and vortex circulation was greatest posterior to the center of mass. In general, regions of localized low pressure correlated well with regions of attached, concentrated vorticity, especially around the ventral keels. Although other features of the carapace also affect flow patterns and pressure distributions in different ways, the integrated effects of the flows were consistent for all forms: they produce trimming self-correcting forces, which we measured directly using the force balance. These data together with previous work on smooth trunkfish indicate that body-induced vortical flows are a common mechanism that is probably significant for trim control in all species of tropical boxfishes.

Item Type:Article
Related URLs:
URLURL TypeDescription
Additional Information:© 2005 The Company of Biologists Ltd. Accepted 22 October 2004. We thank R. M. Alexander and P. Krueger for valuable intellectual input, M. McNitt-Gray, J. Carnahan, B. Valiferdowsi, and P. Masson for aid during model construction, D. Lauritzen and S. Bartol for assistance during data collection, and D. Dabiri, L. Zuhal, and D. Jeon for technical assistance. We especially thank M. Grosenbaugh at Woods Hole Oceanographic Institution for providing office space during the writing phase of this paper and two anonymous reviewers for constructive comments. Buffalo trunkfish and scrawled cowfish were collected by W. Rosado, Department of Marine Science, University of Puerto Rico-Mayaquez. Financial support of the Office of Naval Research under grants N00014-96-1-0607 and N00014-02-1-0180 (to M.S.G. and M.G.) is gratefully acknowledged.
Funding AgencyGrant Number
Office of Naval ResearchN00014-96-1-0607
Office of Naval ResearchN00014-02-1-0180
Subject Keywords:vortex; boxfish; leading edge vortices (LEV); digital particle image velocimetry (DPIV); stability; pressure; pitch; yaw
Issue or Number:2
Record Number:CaltechAUTHORS:BARjeb04
Persistent URL:
Usage Policy:No commercial reproduction, distribution, display or performance rights in this work are provided.
ID Code:13679
Deposited By: Tony Diaz
Deposited On:07 Jul 2009 17:44
Last Modified:08 Nov 2021 22:39

Repository Staff Only: item control page