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Full-Text Articles in Life Sciences
Hydrodynamic Properties Of Fin Whale Flippers Predict Maximum Rolling Performance, Paolo S. Segre, David E. Cade, Frank E. Fish, Jean Potvin, Ann N. Allen, John Calambokidis, Ari S. Friedlaender, Jeremy A. Goldbogen
Hydrodynamic Properties Of Fin Whale Flippers Predict Maximum Rolling Performance, Paolo S. Segre, David E. Cade, Frank E. Fish, Jean Potvin, Ann N. Allen, John Calambokidis, Ari S. Friedlaender, Jeremy A. Goldbogen
Biology Faculty Publications
Maneuverability is one of the most important and least understood aspects of animal locomotion. The hydrofoil-like flippers of cetaceans are thought to function as control surfaces that effect maneuvers, but quantitative tests of this hypothesis have been lacking. Here, we constructed a simple hydrodynamic model to predict the longitudinal-axis roll performance of fin whales, and we tested its predictions against kinematic data recorded by on-board movement sensors from 27 free-swimming fin whales. We found that for a given swimming speed and roll excursion, the roll velocity of fin whales calculated from our field data agrees well with that predicted by …
Hydrodynamic Performance Of Aquatic Flapping: Efficiency Of Underwater Flight In The Manta, Frank E. Fish, Christian M. Schreiber, Keith W. Moored, Geng Liu, Haibo Dong, Hilary Bart-Smith
Hydrodynamic Performance Of Aquatic Flapping: Efficiency Of Underwater Flight In The Manta, Frank E. Fish, Christian M. Schreiber, Keith W. Moored, Geng Liu, Haibo Dong, Hilary Bart-Smith
Biology Faculty Publications
The manta is the largest marine organism to swim by dorsoventral oscillation (flapping) of the pectoral fins. The manta has been considered to swim with a high efficiency stroke, but this assertion has not been previously examined. The oscillatory swimming strokes of the manta were examined by detailing the kinematics of the pectoral fin movements swimming over a range of speeds and by analyzing simulations based on computational fluid dynamic potential flow and viscous models. These analyses showed that the fin movements are asymmetrical up- and downstrokes with both spanwise and chordwise waves interposed into the flapping motions. These motions …