CFD study of hydrodynamic signal perception by fish using the lateral line system

Rapo, Mark Andrew

doi:10.1575/1912/2735

2009

DOI: 10.1575/1912/2735

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CFD study of hydrodynamic signal perception by fish using the lateral line system

Mark Andrew Rapo¹

Abstract: The lateral line system on fish has been found to aid in schooling behavior, courtship communication, active and passive hydrodynamic imaging, and prey detection. The most widely used artificial prey stimulus has been the vibrating sphere, which some fish are able to detect even when the signal velocities to its lateral line are orders of magnitude smaller than background current velocities. It is not clear how the fish are able to extract this signal. This thesis uses a series of computational fluid dynamic (… Show more

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Using computational fluid dynamics to calculate the stimulus to the lateral line of a fish in still water

Rapo

Jiang

Grosenbaugh

et al. 2009

Journal of Experimental Biology

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SUMMARY This paper presents the first computational fluid dynamics (CFD)simulations of viscous flow due to a small sphere vibrating near a fish, a configuration that is frequently used for experiments on dipole source localization by the lateral line. Both two-dimensional (2-D) and three-dimensional (3-D) meshes were constructed, reproducing a previously published account of a mottled sculpin approaching an artificial prey. Both the fish-body geometry and the sphere vibration were explicitly included in the simulations. For comparison purposes, calculations using potential flow theory (PFT) of a 3-D dipole without a fish body being present were also performed. Comparisons between the 2-D and 3-D CFD simulations showed that the 2-D calculations did not accurately represent the 3-D flow and therefore did not produce realistic results. The 3-D CFD simulations showed that the presence of the fish body perturbed the dipole source pressure field near the fish body, an effect that was obviously absent in the PFT calculations of the dipole alone. In spite of this discrepancy, the pressure-gradient patterns to the lateral line system calculated from 3-D CFD simulations and PFT were similar. Conversely, the velocity field, which acted on the superficial neuromasts (SNs), was altered by the oscillatory boundary layer that formed at the fish's skin due to the flow produced by the vibrating sphere (accounted for in CFD but not PFT). An analytical solution of an oscillatory boundary layer above a flat plate, which was validated with CFD, was used to represent the flow near the fish's skin and to calculate the detection thresholds of the SNs in terms of flow velocity and strain rate. These calculations show that the boundary layer effects can be important, especially when the height of the cupula is less than the oscillatory boundary layer's Stokes viscous length scale.

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Using computational fluid dynamics to calculate the stimulus to the lateral line of a fish in still water

Rapo

Jiang

Grosenbaugh

et al. 2009

Journal of Experimental Biology

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CFD study of hydrodynamic signal perception by fish using the lateral line system

Cited by 1 publication

References 50 publications

Using computational fluid dynamics to calculate the stimulus to the lateral line of a fish in still water

Using computational fluid dynamics to calculate the stimulus to the lateral line of a fish in still water

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