Fishes Regulate Tail-beat Kinematics to Minimize Speed-specific Cost of Transport

Overview

Journal Proc Biol Sci

Specialty Biology

Date 2021 Dec 1

PMID 34847768

Citations 3

Authors

Gen Li

Hao Liu

Ulrike K Muller

Cees J Voesenek

Johan L van Leeuwen

Affiliations

Soon will be listed here.

Abstract

Energetic expenditure is an important factor in animal locomotion. Here we test the hypothesis that fishes control tail-beat kinematics to optimize energetic expenditure during undulatory swimming. We focus on two energetic indices used in swimming hydrodynamics, cost of transport and Froude efficiency. To rule out one index in favour of another, we use computational-fluid dynamics models to compare experimentally observed fish kinematics with predicted performance landscapes and identify energy-optimized kinematics for a carangiform swimmer, an anguilliform swimmer and larval fishes. By locating the areas in the predicted performance landscapes that are occupied by actual fishes, we found that fishes use combinations of tail-beat frequency and amplitude that minimize cost of transport. This energy-optimizing strategy also explains why fishes increase frequency rather than amplitude to swim faster, and why fishes swim within a narrow range of Strouhal numbers. By quantifying how undulatory-wave kinematics affect thrust, drag, and power, we explain why amplitude and frequency are not equivalent in speed control, and why Froude efficiency is not a reliable energetic indicator. These insights may inspire future research in aquatic organisms and bioinspired robotics using undulatory propulsion.

Citing Articles

Identification of the trade-off between speed and efficiency in undulatory swimming using a bio-inspired robot.

Anastasiadis A, Paez L, Melo K, Tytell E, Ijspeert A, Mulleners K Sci Rep. 2023; 13(1):15032.

PMID: 37699939 PMC: 10497532. DOI: 10.1038/s41598-023-41074-9.

Cost of Transport of Undulating Fin Propulsion.

Vercruyssen T, Henrion S, Muller U, van Leeuwen J, van der Helm F Biomimetics (Basel). 2023; 8(2).

PMID: 37366809 PMC: 10296648. DOI: 10.3390/biomimetics8020214.

Hydrodynamical Fingerprint of a Neighbour in a Fish Lateral Line.

Li G, Kolomenskiy D, Liu H, Thiria B, Godoy-Diana R Front Robot AI. 2022; 9:825889.

PMID: 35224003 PMC: 8878980. DOI: 10.3389/frobt.2022.825889.

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