Morphological Measurement and Analysis of Gymnarchus Niloticus 被引量：10

Morphological Measurement and Analysis of Gymnarchus Niloticus

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摘要 Gyrnnarchus niloticus swims by undulations of a long-based dorsal fin, while its body axis is in many cases held straight during swimming. This paper provides a brief relevant introduction to Gyrnnarchus niloticus, which belongs to the African freshwater electric eels but can inspire our bionic interests in propulsion besides its abilities in electric sensing. A special larva of Gyrnnarchus niloticus was morphologically measured by photographing it with a piece of scale-calibrated paper as the background. Then we analyzed the data by a CFD-aided approach. Detailed flow patterns around the larva and a NACA0012 hydrofoil were respectively calculated and visualized at the Reynolds number of 7350 or so. The results show that the profile of Gyrnnarchus niloticus is well streamlined. Gyrnnarchus niloticus swims by undulations of a long-based dorsal fin, while its body axis is in many cases held straight during swimming. This paper provides a brief relevant introduction to Gyrnnarchus niloticus, which belongs to the African freshwater electric eels but can inspire our bionic interests in propulsion besides its abilities in electric sensing. A special larva of Gyrnnarchus niloticus was morphologically measured by photographing it with a piece of scale-calibrated paper as the background. Then we analyzed the data by a CFD-aided approach. Detailed flow patterns around the larva and a NACA0012 hydrofoil were respectively calculated and visualized at the Reynolds number of 7350 or so. The results show that the profile of Gyrnnarchus niloticus is well streamlined.

作者 Hu Tian-jiang Li Fei Wang Guang-ming Shen Lin-cheng

机构地区 College of Mechatronic Engineering and Automation

出处《Journal of Bionic Engineering》 SCIE EI CSCD 2005年第1期25-31,共7页 仿生工程学报（英文版）

关键词 BIONIC Gymnarchus niloticus morphological measurement CFD-based analysis streamlined profile bionic, Gymnarchus niloticus, morphological measurement, CFD-based analysis, streamlined profile

分类号 Q811 [生物学—生物工程]

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参考文献13

1HaoLiu,NaomiKato.Computation of Unsteady Flow Past a Biomimetic Fin[J].Journal of Bionic Engineering,2004,1(2):108-120. 被引量：1
2M. Kawasaki.The African wave-type electric fish, Gymnarchus niloticus, lacks corollary discharge mechanisms for electrosensory gating[J].Journal of Comparative Physiology A.1994(2)
3M. Kawasaki.Independently evolved jamming avoidance responses employ identical computational algorithms: a behavioral study of the African electric fish, Gymnarchus niloticus[J].Journal of Comparative Physiology A.1993(1)
4Lighthill M. J.Biofluiddynamics of balistiform and gymnotiform locomotion. Part 2. The pressure distribution arising in two-dimensional irrotational flow from a gen-eral symmetrical motion of a flexible flat plate normal to itself[].Journal of Fluid Mechanics.1990
5Sfakiotakis M,Lane D M,Davies J B C.Review of fish swimming modes for aquatic locomotion[].IEEE Journal of Oceanic Engineering.1999
6Kawasaki M.Independently Evolved Jamming Avoidance Responses Employ Identical Computational Algorithms: a Behavioral Study of the African Electric Fish, Gymnar-chus niloticus[].Journal of Comparative Physiology:A.1993
7Kawasaki M.Temporal Hyperacuity in the Gymnotiform Electric Fish, Eigenmannia[].American Zoologist.1993
8Lissmann,W,Chagas,C,Paesde Carvalho,A.Ecological studies on gymnotids[].Bioelectrogenesis.1961
9Lissmann H W.On the Function and Evolution of Electric Organ in Fish[].Journal of Experiment.1958
10Lighthill M J.Biofluiddynamics of Balistiform and Gymnotiform locomotion.Part 4. Short-Wavelength Limitations on Momentum Enhancement[].Journal of Fluid Mechanics.1990

二级参考文献10

1Kato N,Bugi Wiku W,Suzuki Y.Hydrodynamic characteristics of three-motor-driven mechanical pectoral fin and its application to an autonomous underwater vehicle[].Journal of the Society of Japan Naval Architects.2000
2Walker J A,Westneat M W.Mechanical performance of aquatic rowing and flying[].Proceedings of the Royal Society of London.2000
3Bandyopadhyay P R.Maneuvering hydrodynamics of fish and small underwater vehicles[].Integrative and Comparative Biology of American Zoologist.2002
4Anderson J M,Chhabra N K.Maneuvering and stability performance of a robotic tuna[].Integrative and Comparative Biology of American Zoologist.2002
5Wu T Y.Hydrodynamics of swimming propulsion.Part 3.Swimming and optimum movements of slender fish with side fins[].Journal of Fluid Mechanics.1971
6Cheng J Y,Zhuang L X,Tong B G.Analysis of swimming three-dimensional waving plates[].Journal of Fluid Mechanics.1991
7Triantafyllou M S,Triantafyllou G S.An efficient swimming machine[].Scientific American.1995
8Kato N.Hydrodynamic characteristics of a mechanical pectoral fin[].Journal of Fluids Engineering Transactions of the ASME.1999
9Walker J A,Westneat M W.Performance limits of labriform propulsion and correlates with fin shape and motion[].Journal of Experiment.2002
10Prewitt N C,Belk D M,Shyy W.Parallel computing of overset grids for aerodynamic problems with moving objects[].Progress in Aerospace Sciences.2000

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