Stabilization Mechanism in Swimming Odontocete Cetaceans by Phased Movements

Propulsive movements of the caudal oscillating flukes produce large forces that could induce equally large recoil forces at the cranial end of the animal, and, thus, affect stability. To examine these vertical oscillations, video analysis was used to measure the motions of the rostrum, pectoral flip...

Full description

Bibliographic Details
Main Authors: Rohr, Jim J., Fish, F. E., Peacock, J. E.
Other Authors: SPACE AND NAVAL WARFARE SYSTEMS CENTER SAN DIEGO CA
Format: Text
Language:English
Published: 2002
Subjects:
Biology
Escape
Rescue and Survival
*SWIMMING
*DOLPHINS(MAMMALS)
KINEMATICS
VELOCITY
REPRINTS
STABILITY
POSTURE(PHYSIOLOGY)
CETACEA
MOTION
RECOIL
VIDEO SIGNALS
SENSES(PHYSIOLOGY)
Delphinapterus leucas
Orca
Online Access:http://www.dtic.mil/docs/citations/ADA445907
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA445907
id ftdtic:ADA445907
record_format openpolar
spelling ftdtic:ADA445907 2023-05-15T16:00:30+02:00 Stabilization Mechanism in Swimming Odontocete Cetaceans by Phased Movements Rohr, Jim J. Fish, F. E. Peacock, J. E. SPACE AND NAVAL WARFARE SYSTEMS CENTER SAN DIEGO CA 2002-11-25 text/html http://www.dtic.mil/docs/citations/ADA445907 http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA445907 en eng http://www.dtic.mil/docs/citations/ADA445907 Approved for public release; distribution is unlimited. DTIC Biology Escape Rescue and Survival *SWIMMING *DOLPHINS(MAMMALS) KINEMATICS VELOCITY REPRINTS STABILITY POSTURE(PHYSIOLOGY) CETACEA MOTION RECOIL VIDEO SIGNALS SENSES(PHYSIOLOGY) Text 2002 ftdtic 2016-02-22T02:38:11Z Propulsive movements of the caudal oscillating flukes produce large forces that could induce equally large recoil forces at the cranial end of the animal, and, thus, affect stability. To examine these vertical oscillations, video analysis was used to measure the motions of the rostrum, pectoral flipper, caudal peduncle, and fluke tip for seven odontocete cetaceans: Delphinapterus leucas, Globicephala melaena, Lagenorhynchus obliquidens, Orcinnus orca, Pseudorca crassidens, Stenella plagiodon, and Tursiops truncatus. Animals swam over a range of speeds of 1.4-7.3 m/sec. For each species, oscillatory frequency of the fluke tip increased linearly with swimming speed. Peak-to-peak amplitude at each body position remained constant with respect to swimming speed for all species Mean peak-to-peak amplitude tanged from 0.02 to 0.06 body length at the rostrum and from 0.17 to 0.25 body length at the fluke tip. The phase relationships between the various body components remain constant with respect to swimming speed. Oscillations of the rostrum were neatly in phase with the fluke tip with phase differences out of 9.40.00 of a cycle period of 3600. Pectoral flipper oscillations trailed fluke oscillations by 60.903.40. The lower range in amplitude at the rostrum compared to the fluke tip reflects increased resistance to vertical oscillation at the cranial end, which enhances the animal's stability. This resistance is likely due to both active and passive increased body stiffness, resistance on the flippers, phased movements of body components, and use of a lift-based propulsion. Collectively, these mechanisms stabilize the body of cetaceans during active swimming, which can reduce locomotor energy expenditure and reduce excessive motions of the head affecting sensory capabilities. Pub. in Jnl. of Marine Mammal Science, v19 n3 p515-528, July 2003. Text Delphinapterus leucas Orca Defense Technical Information Center: DTIC Technical Reports database
institution Open Polar
collection Defense Technical Information Center: DTIC Technical Reports database
op_collection_id ftdtic
language English
topic Biology
Escape
Rescue and Survival
*SWIMMING
*DOLPHINS(MAMMALS)
KINEMATICS
VELOCITY
REPRINTS
STABILITY
POSTURE(PHYSIOLOGY)
CETACEA
MOTION
RECOIL
VIDEO SIGNALS
SENSES(PHYSIOLOGY)
spellingShingle Biology
Escape
Rescue and Survival
*SWIMMING
*DOLPHINS(MAMMALS)
KINEMATICS
VELOCITY
REPRINTS
STABILITY
POSTURE(PHYSIOLOGY)
CETACEA
MOTION
RECOIL
VIDEO SIGNALS
SENSES(PHYSIOLOGY)
Rohr, Jim J.
Fish, F. E.
Peacock, J. E.
Stabilization Mechanism in Swimming Odontocete Cetaceans by Phased Movements
topic_facet Biology
Escape
Rescue and Survival
*SWIMMING
*DOLPHINS(MAMMALS)
KINEMATICS
VELOCITY
REPRINTS
STABILITY
POSTURE(PHYSIOLOGY)
CETACEA
MOTION
RECOIL
VIDEO SIGNALS
SENSES(PHYSIOLOGY)
description Propulsive movements of the caudal oscillating flukes produce large forces that could induce equally large recoil forces at the cranial end of the animal, and, thus, affect stability. To examine these vertical oscillations, video analysis was used to measure the motions of the rostrum, pectoral flipper, caudal peduncle, and fluke tip for seven odontocete cetaceans: Delphinapterus leucas, Globicephala melaena, Lagenorhynchus obliquidens, Orcinnus orca, Pseudorca crassidens, Stenella plagiodon, and Tursiops truncatus. Animals swam over a range of speeds of 1.4-7.3 m/sec. For each species, oscillatory frequency of the fluke tip increased linearly with swimming speed. Peak-to-peak amplitude at each body position remained constant with respect to swimming speed for all species Mean peak-to-peak amplitude tanged from 0.02 to 0.06 body length at the rostrum and from 0.17 to 0.25 body length at the fluke tip. The phase relationships between the various body components remain constant with respect to swimming speed. Oscillations of the rostrum were neatly in phase with the fluke tip with phase differences out of 9.40.00 of a cycle period of 3600. Pectoral flipper oscillations trailed fluke oscillations by 60.903.40. The lower range in amplitude at the rostrum compared to the fluke tip reflects increased resistance to vertical oscillation at the cranial end, which enhances the animal's stability. This resistance is likely due to both active and passive increased body stiffness, resistance on the flippers, phased movements of body components, and use of a lift-based propulsion. Collectively, these mechanisms stabilize the body of cetaceans during active swimming, which can reduce locomotor energy expenditure and reduce excessive motions of the head affecting sensory capabilities. Pub. in Jnl. of Marine Mammal Science, v19 n3 p515-528, July 2003.
author2 SPACE AND NAVAL WARFARE SYSTEMS CENTER SAN DIEGO CA
format Text
author Rohr, Jim J.
Fish, F. E.
Peacock, J. E.
author_facet Rohr, Jim J.
Fish, F. E.
Peacock, J. E.
author_sort Rohr, Jim J.
title Stabilization Mechanism in Swimming Odontocete Cetaceans by Phased Movements
title_short Stabilization Mechanism in Swimming Odontocete Cetaceans by Phased Movements
title_full Stabilization Mechanism in Swimming Odontocete Cetaceans by Phased Movements
title_fullStr Stabilization Mechanism in Swimming Odontocete Cetaceans by Phased Movements
title_full_unstemmed Stabilization Mechanism in Swimming Odontocete Cetaceans by Phased Movements
title_sort stabilization mechanism in swimming odontocete cetaceans by phased movements
publishDate 2002
url http://www.dtic.mil/docs/citations/ADA445907
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA445907
genre Delphinapterus leucas
Orca
genre_facet Delphinapterus leucas
Orca
op_source DTIC
op_relation http://www.dtic.mil/docs/citations/ADA445907
op_rights Approved for public release; distribution is unlimited.
_version_ 1766396492520620032

Similar Items