Drag of suction cup tags on swimming animals: Modeling and measurement

Bio‐logging tags are widely used to study the behavior and movements of marine mammals with the tacit assumption of little impact to the animal. However, tags on fast‐swimming animals generate substantial hydrodynamic forces potentially affecting behavior and energetics adversely, or promoting early...

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Published in:Marine Mammal Science
Main Authors: Alex Shorter, K., Murray, Mark M., Johnson, Mark, Moore, Michael, Howle, Laurens E.
Format: Article in Journal/Newspaper
Language:unknown
Published: SPAWAR Systems Center 2014
Subjects:
Hydrodynamic Tag Design
Suction Cups
CFD
Bio‐Logging
Natural Resources and Environment
Science
Polar Biology
Online Access:https://hdl.handle.net/2027.42/106906
https://doi.org/10.1111/mms.12083
id ftumdeepblue:oai:deepblue.lib.umich.edu:2027.42/106906
record_format openpolar
institution Open Polar
collection University of Michigan: Deep Blue
op_collection_id ftumdeepblue
language unknown
topic Hydrodynamic Tag Design
Suction Cups
CFD
Bio‐Logging
Natural Resources and Environment
Science
spellingShingle Hydrodynamic Tag Design
Suction Cups
CFD
Bio‐Logging
Natural Resources and Environment
Science
Alex Shorter, K.
Murray, Mark M.
Johnson, Mark
Moore, Michael
Howle, Laurens E.
Drag of suction cup tags on swimming animals: Modeling and measurement
topic_facet Hydrodynamic Tag Design
Suction Cups
CFD
Bio‐Logging
Natural Resources and Environment
Science
description Bio‐logging tags are widely used to study the behavior and movements of marine mammals with the tacit assumption of little impact to the animal. However, tags on fast‐swimming animals generate substantial hydrodynamic forces potentially affecting behavior and energetics adversely, or promoting early removal of the tag. In this work, hydrodynamic loading of three novel tag housing designs are compared over a range of swimming speeds using computational fluid dynamics ( CFD ). Results from CFD simulation were verified using tag models in a water flume with close agreement. Drag forces were reduced by minimizing geometric disruptions to the flow around the housing, while lift forces were reduced by minimizing the frontal cross‐sectional area of the housing and holding the tag close to the attachment surface. Hydrodynamic tag design resulted in an experimentally measured 60% drag force reduction in 5.6 m/s flow. For all housing designs, off‐axis flow increased the magnitude of the force on the tag. Experimental work with a common dolphin ( Delphinus delphis ) cadaver indicates that the suction cups used to attach the types of tags described here provide sufficient attachment force to resist failure to predicted forces at swimming speeds of up to 10 m/s. Peer Reviewed http://deepblue.lib.umich.edu/bitstream/2027.42/106906/1/mms12083.pdf
format Article in Journal/Newspaper
author Alex Shorter, K.
Murray, Mark M.
Johnson, Mark
Moore, Michael
Howle, Laurens E.
author_facet Alex Shorter, K.
Murray, Mark M.
Johnson, Mark
Moore, Michael
Howle, Laurens E.
author_sort Alex Shorter, K.
title Drag of suction cup tags on swimming animals: Modeling and measurement
title_short Drag of suction cup tags on swimming animals: Modeling and measurement
title_full Drag of suction cup tags on swimming animals: Modeling and measurement
title_fullStr Drag of suction cup tags on swimming animals: Modeling and measurement
title_full_unstemmed Drag of suction cup tags on swimming animals: Modeling and measurement
title_sort drag of suction cup tags on swimming animals: modeling and measurement
publisher SPAWAR Systems Center
publishDate 2014
url https://hdl.handle.net/2027.42/106906
https://doi.org/10.1111/mms.12083
genre Polar Biology
genre_facet Polar Biology
op_relation Alex Shorter, K.; Murray, Mark M.; Johnson, Mark; Moore, Michael; Howle, Laurens E. (2014). "Drag of suction cup tags on swimming animals: Modeling and measurement." Marine Mammal Science 30(2): 726-746.
0824-0469
1748-7692
https://hdl.handle.net/2027.42/106906
doi:10.1111/mms.12083
Marine Mammal Science
Schultz, M. P., and K. A. Flack. 2003. Turbulent boundary layers over surfaces smoothed by sanding. Journal of Fluid Engineering 125: 863 – 870.
Gupta, S., and B. Kumar. 2000. Suction blister induction time: 15 minutes or 150 minutes? Dermatologic Surgery 26: 754 – 757.
Hanson, M. B. 2001. An evaluation of the relationship between small cetacean tag design and attachment durations: A bioengineering approach. Ph.D. dissertation, University of Washington, Seattle, WA. 221 pp.
Hooker, S. K., and R. W. Baird. 2001. Diving and ranging behaviour of odontocetes: A methodological review and critique. Mammal Review 31: 81 – 105.
Johnson, M. P., and P. L. Tyack. 2003. A digital acoustic recording tag for measuring the response of wild marine mammals to sound. IEEE Oceanic Engineering Society 28: 3 – 12.
Madsen, P. T., R. Payne, N. U. Kristiansen, M. Wahlberg, I. Kerr and B. Møhl. 2002. Sperm whale sound production studied with ultrasound time/depth‐recording tags. The Journal of Experimental Biology 205: 1899 – 1906.
Mate, B., R. Mesecar and B. Lagerquist. 2007. The evolution of satellite‐monitored radio tags for large whales: One laboratory's experience. Deep Sea Research Part II: Topical Studies in Oceanography 54: 224 – 247.
Miller, P. J. O., M. P. Johnson and P. L. Tyack. 2004. Sperm whale behaviour indicates the use of echolocation click buzzes ‘creaks’ in prey capture. Proceedings of the Royal Society B‐Biological Sciences 271: 2239 – 2247.
Munson, B. R., D. F. Young and T. H. Okiishi. 2006. Fundamentals of fluid mechanics. 5th edition. John Wiley & Sons, Inc., Hoboken, NJ.
Pavlov, V. V., R. P. Wilson and K. Lucke. 2007. A new approach to tag design in dolphin telemetry: Computer simulations to minimize deleterious effects. Deep Sea Research Part II: Topical Studies in Oceanography 54: 404 – 414.
Pavlov, V. V., and A. M. Rashad. 2011. A non‐invasive dolphin telemetry tag: Computer design and numerical flow simulation. Marine Mammal Science 28: E16 – E27.
Read, A. J., and A. J. Westgate. 1997. Monitoring the movements of harbour porpoises ( Phocoena phocoena ) with satellite telemetry. Marine Biology 130: 315 – 322.
Ropert‐Coudert, Y., and R. P. Wilson. 2005. Trends and perspectives in animal‐attached remote sensing. Frontiers in Ecology and the Environment 3: 437 – 444.
Ropert‐Coudert, Y., R. P. Wilson, K. Yoda and A. Kato. 2007. Assessing performance constraints in penguins with externally‐attached devices. Marine Ecology Progress Series 333: 281 – 289.
Sato, K., Y. Watanuki, A. Takahashi, P. J. O. Miller, et al. 2007. Stroke frequency, but not swimming speed, is related to body size in free‐ranging seabirds, pinnipeds and cetaceans. Proceedings of the Royal Society B‐Biological Sciences 274: 471 – 477.
van Dam, R. P., P. J. Ponganis, K. V. Ponganis, D. H. Levenson and G. Marshall. 2002. Stroke frequencies of emperor penguins diving under sea ice. Journal of Experimental Biology 205: 3769 – 3774.
Viviant, M., A. W. Trites, D. A. S. Rosen, P. Monestiez and C. Guinet. 2010. Prey capture attempts can be detected in Steller sea lions and other marine predators using accelerometers. Polar Biology 33: 713 – 719.
Watanabe, Y. Y., K. Sato, Y. Watanuki, et al. 2011. Scaling of swim speed in breath‐hold divers. Journal of Animal Ecology 80: 57 – 68.
Weber, P. W., L. E. Howle, M. M. Murray and F. E. Fish. 2009. Lift and drag performance of odontocete cetacean flippers. Journal of Experimental Biology 212: 2149 – 2158.
Weber, P. W., L. E. Howle and M. M. Murray. 2011. Computational evaluation of the performance of lifting surfaces with leading‐edge protuberances. Journal of Aircraft 77: 591 – 600.
Wilson, R. P., and C. R. McMahon. 2006. Measuring devices on wild animals: What constitutes acceptable practice? Frontiers in Ecology and the Environment 4: 147 – 154.
Wilson, R. P., W. S. Grant and D. C. Duffy. 1986. Recording devices on free‐ranging marine animals: Does measurement affect foraging performance? Ecology 67: 1091 – 1093.
Wilson, R. P., J. M. Kreye, K. Lucke and H. Urquhart. 2004. Antennae on transmitters on penguins: Balancing energy budgets on the high wire. Journal of Experimental Biology 207: 2649 – 2662.
Aguilar Soto, N., M. P. Johnson, P. T. Madsen, F. Díaz, I. Domínguez, A. Brito and P. Tyack. 2008. Cheetahs of the deep sea: Deep foraging sprints in short‐finned pilot whales off Tenerife (Canary Islands). Journal of Animal Ecology 77: 936 – 947.
Andrews, R. D., R. L. Pitman and L. T. Ballance. 2008. Satellite tracking reveals distinct movement patterns for type B and type C killer whales in the southern Ross Sea, Antarctica. Polar Biology 31: 1461 – 1468.
Aoki, K., M. Amano, M. Yoshioka, K. Mori, D. Tokuda and N. Miyazaki. 2007. Diel diving behavior of sperm whales off Japan. Marine Ecological Press Series 349: 277 – 287.
Cooke, S. J., S. G. Hinch, M. Wikelski, R. D. Andrews, L. J. Kuchel, T. G. Wolcott and P. J. Butler. 2004. Biotelemetry: A mechanistic approach to ecology. Trends in Ecology & Evolution 6: 334 – 343.
Fish, F. E. 1998. Comparative kinematics and hydrodynamics of odontocete cetaceans: Morphological and ecological correlates with swimming performance. Journal of Experimental Biology 201: 2867 – 2877.
Fish, F. E., and J. J. Rohr. 1999. Review of dolphin hydrodynamics and swimming performance. Technical Report 1801, SPAWAR Systems Center, San Diego, CA. 196 pp.
Fox, R. W., and A. T. McDonald. 1999. Introduction to fluid mechanics. Wiley, New York, NY.
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spelling ftumdeepblue:oai:deepblue.lib.umich.edu:2027.42/106906 2023-08-20T04:09:22+02:00 Drag of suction cup tags on swimming animals: Modeling and measurement Alex Shorter, K. Murray, Mark M. Johnson, Mark Moore, Michael Howle, Laurens E. 2014-04 application/pdf https://hdl.handle.net/2027.42/106906 https://doi.org/10.1111/mms.12083 unknown SPAWAR Systems Center Wiley Periodicals, Inc. Alex Shorter, K.; Murray, Mark M.; Johnson, Mark; Moore, Michael; Howle, Laurens E. (2014). "Drag of suction cup tags on swimming animals: Modeling and measurement." Marine Mammal Science 30(2): 726-746. 0824-0469 1748-7692 https://hdl.handle.net/2027.42/106906 doi:10.1111/mms.12083 Marine Mammal Science Schultz, M. P., and K. A. Flack. 2003. Turbulent boundary layers over surfaces smoothed by sanding. Journal of Fluid Engineering 125: 863 – 870. Gupta, S., and B. Kumar. 2000. Suction blister induction time: 15 minutes or 150 minutes? Dermatologic Surgery 26: 754 – 757. Hanson, M. B. 2001. An evaluation of the relationship between small cetacean tag design and attachment durations: A bioengineering approach. Ph.D. dissertation, University of Washington, Seattle, WA. 221 pp. Hooker, S. K., and R. W. Baird. 2001. Diving and ranging behaviour of odontocetes: A methodological review and critique. Mammal Review 31: 81 – 105. Johnson, M. P., and P. L. Tyack. 2003. A digital acoustic recording tag for measuring the response of wild marine mammals to sound. IEEE Oceanic Engineering Society 28: 3 – 12. Madsen, P. T., R. Payne, N. U. Kristiansen, M. Wahlberg, I. Kerr and B. Møhl. 2002. Sperm whale sound production studied with ultrasound time/depth‐recording tags. The Journal of Experimental Biology 205: 1899 – 1906. Mate, B., R. Mesecar and B. Lagerquist. 2007. The evolution of satellite‐monitored radio tags for large whales: One laboratory's experience. Deep Sea Research Part II: Topical Studies in Oceanography 54: 224 – 247. Miller, P. J. O., M. P. Johnson and P. L. Tyack. 2004. Sperm whale behaviour indicates the use of echolocation click buzzes ‘creaks’ in prey capture. Proceedings of the Royal Society B‐Biological Sciences 271: 2239 – 2247. Munson, B. R., D. F. Young and T. H. Okiishi. 2006. Fundamentals of fluid mechanics. 5th edition. John Wiley & Sons, Inc., Hoboken, NJ. Pavlov, V. V., R. P. Wilson and K. Lucke. 2007. A new approach to tag design in dolphin telemetry: Computer simulations to minimize deleterious effects. Deep Sea Research Part II: Topical Studies in Oceanography 54: 404 – 414. Pavlov, V. V., and A. M. Rashad. 2011. A non‐invasive dolphin telemetry tag: Computer design and numerical flow simulation. Marine Mammal Science 28: E16 – E27. Read, A. J., and A. J. Westgate. 1997. Monitoring the movements of harbour porpoises ( Phocoena phocoena ) with satellite telemetry. Marine Biology 130: 315 – 322. Ropert‐Coudert, Y., and R. P. Wilson. 2005. Trends and perspectives in animal‐attached remote sensing. Frontiers in Ecology and the Environment 3: 437 – 444. Ropert‐Coudert, Y., R. P. Wilson, K. Yoda and A. Kato. 2007. Assessing performance constraints in penguins with externally‐attached devices. Marine Ecology Progress Series 333: 281 – 289. Sato, K., Y. Watanuki, A. Takahashi, P. J. O. Miller, et al. 2007. Stroke frequency, but not swimming speed, is related to body size in free‐ranging seabirds, pinnipeds and cetaceans. Proceedings of the Royal Society B‐Biological Sciences 274: 471 – 477. van Dam, R. P., P. J. Ponganis, K. V. Ponganis, D. H. Levenson and G. Marshall. 2002. Stroke frequencies of emperor penguins diving under sea ice. Journal of Experimental Biology 205: 3769 – 3774. Viviant, M., A. W. Trites, D. A. S. Rosen, P. Monestiez and C. Guinet. 2010. Prey capture attempts can be detected in Steller sea lions and other marine predators using accelerometers. Polar Biology 33: 713 – 719. Watanabe, Y. Y., K. Sato, Y. Watanuki, et al. 2011. Scaling of swim speed in breath‐hold divers. Journal of Animal Ecology 80: 57 – 68. Weber, P. W., L. E. Howle, M. M. Murray and F. E. Fish. 2009. Lift and drag performance of odontocete cetacean flippers. Journal of Experimental Biology 212: 2149 – 2158. Weber, P. W., L. E. Howle and M. M. Murray. 2011. Computational evaluation of the performance of lifting surfaces with leading‐edge protuberances. Journal of Aircraft 77: 591 – 600. Wilson, R. P., and C. R. McMahon. 2006. Measuring devices on wild animals: What constitutes acceptable practice? Frontiers in Ecology and the Environment 4: 147 – 154. Wilson, R. P., W. S. Grant and D. C. Duffy. 1986. Recording devices on free‐ranging marine animals: Does measurement affect foraging performance? Ecology 67: 1091 – 1093. Wilson, R. P., J. M. Kreye, K. Lucke and H. Urquhart. 2004. Antennae on transmitters on penguins: Balancing energy budgets on the high wire. Journal of Experimental Biology 207: 2649 – 2662. Aguilar Soto, N., M. P. Johnson, P. T. Madsen, F. Díaz, I. Domínguez, A. Brito and P. Tyack. 2008. Cheetahs of the deep sea: Deep foraging sprints in short‐finned pilot whales off Tenerife (Canary Islands). Journal of Animal Ecology 77: 936 – 947. Andrews, R. D., R. L. Pitman and L. T. Ballance. 2008. Satellite tracking reveals distinct movement patterns for type B and type C killer whales in the southern Ross Sea, Antarctica. Polar Biology 31: 1461 – 1468. Aoki, K., M. Amano, M. Yoshioka, K. Mori, D. Tokuda and N. Miyazaki. 2007. Diel diving behavior of sperm whales off Japan. Marine Ecological Press Series 349: 277 – 287. Cooke, S. J., S. G. Hinch, M. Wikelski, R. D. Andrews, L. J. Kuchel, T. G. Wolcott and P. J. Butler. 2004. Biotelemetry: A mechanistic approach to ecology. Trends in Ecology & Evolution 6: 334 – 343. Fish, F. E. 1998. Comparative kinematics and hydrodynamics of odontocete cetaceans: Morphological and ecological correlates with swimming performance. Journal of Experimental Biology 201: 2867 – 2877. Fish, F. E., and J. J. Rohr. 1999. Review of dolphin hydrodynamics and swimming performance. Technical Report 1801, SPAWAR Systems Center, San Diego, CA. 196 pp. Fox, R. W., and A. T. McDonald. 1999. Introduction to fluid mechanics. Wiley, New York, NY. IndexNoFollow Hydrodynamic Tag Design Suction Cups CFD Bio‐Logging Natural Resources and Environment Science Article 2014 ftumdeepblue https://doi.org/10.1111/mms.12083 2023-07-31T21:18:59Z Bio‐logging tags are widely used to study the behavior and movements of marine mammals with the tacit assumption of little impact to the animal. However, tags on fast‐swimming animals generate substantial hydrodynamic forces potentially affecting behavior and energetics adversely, or promoting early removal of the tag. In this work, hydrodynamic loading of three novel tag housing designs are compared over a range of swimming speeds using computational fluid dynamics ( CFD ). Results from CFD simulation were verified using tag models in a water flume with close agreement. Drag forces were reduced by minimizing geometric disruptions to the flow around the housing, while lift forces were reduced by minimizing the frontal cross‐sectional area of the housing and holding the tag close to the attachment surface. Hydrodynamic tag design resulted in an experimentally measured 60% drag force reduction in 5.6 m/s flow. For all housing designs, off‐axis flow increased the magnitude of the force on the tag. Experimental work with a common dolphin ( Delphinus delphis ) cadaver indicates that the suction cups used to attach the types of tags described here provide sufficient attachment force to resist failure to predicted forces at swimming speeds of up to 10 m/s. Peer Reviewed http://deepblue.lib.umich.edu/bitstream/2027.42/106906/1/mms12083.pdf Article in Journal/Newspaper Polar Biology University of Michigan: Deep Blue Marine Mammal Science 30 2 726 746

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