A computationally efficient approach to swimming monofin optimization

A computationally efficient approach to swimming monofin optimization

0.00 Avg rating0 Votes
Article ID: iaor20105403
Volume: 31
Issue: 6
Start Page Number: 488
End Page Number: 496
Publication Date: Jun 2006
Journal: Structural and Multidisciplinary Optimization
Authors: , , ,
Keywords: design, sports
Abstract:

Monofins provide swimmers with an efficient alternative to the standard pair of fins. For example, all short and long distance human swimming records have been established using monofins. Current monofin design is mostly empirical, so the objectives of this work are to analyze monofin propulsion through coupled fluid– structure simulation and to optimize its flexural stiffness distribution. The optimization process maximizes the propulsive power provided by the monofin with a constraint on the total expended power. To be able to carry out the optimization of the coupled fluid– structure system, which is numerically costly to evaluate, the following simplifications are proposed: (1) a 2-D unsteady, inviscid, and incompressible fluid flow is considered; (2) the swimmer is composed of linear articulated segments, whose kinematics is imposed and identified from experimental data; and (3) the monofin is represented by rigid bars linked by torsional springs. For various allowable swimmer powers, optimal 2-D stiffness distributions are obtained using the Globalized and Bounded Nelder– Mead algorithm. Finally, an identification procedure is described to translate the optimal 2-D stiffness distributions into 3-D thickness profiles for a given monofin planform shape.

Reviews

Required fields are marked *. Your email address will not be published.