EXPERIMENTAL STUDY OF ZEBRAFISH SWIMMING WITH LINEAR ACCELERATION

Guo Chunyu; Liang Zejun; Han Yang; Kuai Yunfei; Xu Peng; Sun Lucheng

doi:10.6052/0459-1879-22-157

Volume 54 Issue 9

Sep. 2022

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Chinese Journal of Theoretical and Applied Mechanics > 2022 > 54(9): 2446-2459. > DOI: 10.6052/0459-1879-22-157 CSTR: 32045.14.0459-1879-22-157

Guo Chunyu, Liang Zejun, Han Yang, Kuai Yunfei, Xu Peng, Sun Lucheng. Experimental study of zebrafish swimming with linear acceleration. Chinese Journal of Theoretical and Applied Mechanics, 2022, 54(9): 2446-2459. DOI: 10.6052/0459-1879-22-157

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EXPERIMENTAL STUDY OF ZEBRAFISH SWIMMING WITH LINEAR ACCELERATION

*.
Qingdao Innovation and Development Base, Harbin Engineering University, Qingdao 266000, Shandong, China
†.
College of Shipbuilding Engineering, Harbin Engineering University, Harbin 150001, China

Received Date: April 11, 2022
Accepted Date: May 30, 2022
Available Online: May 31, 2022

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Abstract

Abstract

The low-noise, high-speed and high-efficiency swimming ability of marine life is unmatched by any artificial underwater vehicle. With the help of time-resolved particle image velocimetry (TR-PIV), the fine flow field measurement of the zebrafish straight acceleration swimming process was carried out, and its kinematic behaviour characteristics and dynamic mechanism were analyzed. Meanwhile, bi-orthogonal decomposition (BOD) is applied to modal decomposition of the vorticity field, and the flow field's time evolution and spatial distribution characteristics are obtained. From the perspective of flow mechanism, the flow structure characteristics and the dynamic evolution characteristics of vortices during zebrafish swimming are explored. The results showed that: The flow visualization shows the structure distribution of the overall vortex wake, which is convenient to explore the coupling relationship between the motion characteristics and the vortex wake. From the beginning of the movement, all points on the body trunk of zebrafish maintain the wavy movement law. The first few large tail swings mainly provide kinetic energy during swimming, and the subsequent tail swings mainly adjust the direction and posture. Two tail swings in different directions will form a pair of vortices in opposite directions, and the vortices will gradually fall off under the timing sequence. Meanwhile, the change of the wake vorticity reflects the change of the swimming direction of the fish to a certain extent. Based on the time evolution results after BOD decomposition, it is verified that the vorticity field in this experiment has a reasonable constant amplitude in time. The spatial distribution indicates that the low-order spatial modes characterize the main vortex structure of zebrafish swimming, and the higher-order spatial modes characterize the detailed structure of the vortex flow. The research on the tail-swinging propulsion mechanism and the dynamic characteristics of fish during swimming can provide certain scientific value for designing high-efficiency fish-like propulsion devices.
- detailed flow measurements,
- bionic propulsion,
- particle image velocimetry,
- kinematic behaviour,
- kinetic mechanism

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[1]	Flammang BE, Lauder GV, Troolin DR, et al. Volumetric imaging of fish locomotion. Biology Letters, 2011, 7(5): 695-698 doi: 10.1098/rsbl.2011.0282
[2]	Flammang BE, Lauder GV, Troolin DR, et al. Volumetric imaging of shark tail hydrodynamics reveals a three-dimensional dual-ring vortex wake structure. Proceedings of the Royal Society B: Biological Sciences, 2011, 278(1725): 3670-3678 doi: 10.1098/rspb.2011.0489
[3]	Wolfgang MJ, Anderson JM, Grosenbaugh MA, et al. Near-body flow dynamics in swimming fish. Journal of Experimental Biology, 1999, 202(17): 2303-2327 doi: 10.1242/jeb.202.17.2303
[4]	Wolfgang MJ, Triantafyllou MS, Yue DKP. Visualization of complex near-body transport processes in flexible-body propulsion. Journal of Visualization, 1999, 2(2): 143-151 doi: 10.1007/BF03181517
[5]	Cheng B, Tu Z, Goerig E, et al. Swimming behaviour of silver carp (Hypophthalmichthys molitrix) in response to turbulent flow induced by a D‐cylinder. Journal of Fish Biology, 2022, 100(2): 486-497 doi: 10.1111/jfb.14958
[6]	Sánchez-Rodríguez J, Celestini F, Raufaste C, et al. Proprioceptive mechanism for bioinspired fish swimming. Physical Review Letters, 2021, 126(23): 234501
[7]	Sfakiotakis M, Lane DM, Davies JBC. Review of fish swimming modes for aquatic locomotion. IEEE Journal of Oceanic Engineering, 1999, 24(2): 237-252 doi: 10.1109/48.757275
[8]	Lighthill MJ. Large-amplitude elongated-body theory of fish locomotion. Proceedings of the Royal Society of London, 1971, 179(1055): 125-138
[9]	Weihs D. A hydrodynamical analysis of fish turning manoeuvres. Proceedings of the Royal Society B: Biological Sciences, 1972, 182(1066): 59-72
[10]	Gibb AC, Jayne BC, Lauder GV. Kinematics of pectoral fin locomotion in the bluegill sunfish lepomis macrochirus. Journal of Experimental Biology, 1994, 189(1): 133-161 doi: 10.1242/jeb.189.1.133
[11]	Standen EM. Pelvic fin locomotor function in fishes: three-dimensional kinematics in rainbow trout (oncorhynchus mykiss). Journal of Experimental Biology, 2008, 211(18): 2931-2942 doi: 10.1242/jeb.018572
[12]	Kazakidi A, Tsakiris DP, Ekaterinaris JA. Propulsive efficiency in drag-based locomotion of a reduced-size swimmer with various types of appendages. Computers & Fluids, 2018, 167: 241-248
[13]	Tytell ED. The hydrodynamics of eel swimming: I. Wake structure. Journal of Experimental Biology, 2004, 207(11): 1825-1841
[14]	Borazjani I, Sotiropoulos F. Numerical investigation of the hydrodynamics of anguilliform swimming in the transitional and inertial flow regimes. Journal of Experimental Biology, 2009, 212(4): 576-592 doi: 10.1242/jeb.025007
[15]	Cui Z, Jiang H. Numerical study of complex modal characteristics in anguilliform mode of fish swimming. Journal of Mechanical Science and Technology, 2021, 35(10): 4511-4521 doi: 10.1007/s12206-021-0921-5
[16]	郭春雨, 徐鹏, 韩阳等. 自由面对潜艇尾流场流动特性影响研究. 力学学报, 2021, 53(01): 156-167 Guo Chunyu, Xu Peng, Han Yang, et al. Research on the influence of free surface on the flow characteristics of submarine wake. Chinese Journal of Theoretical and Applied Mechanics, 2021, 53(01): 156-167(in Chinese))
[17]	Liu DM, Xu WL, Zhao YZ. Experimental study of the flow field of a high head model pump turbine based on PIV technique. Journal of Hydrodynamics, 2021, 33(5): 1045-1055 doi: 10.1007/s42241-021-0092-y
[18]	Jardin T, Choi J, Colonius T. An empirical correlation between lift and the properties of leading-edge vortices. Theoretical and Computational Fluid Dynamics, 2021, 35(4): 437-448 doi: 10.1007/s00162-021-00567-x
[19]	郭春雨, 徐鹏, 韩阳等. 船舶艉流场受预旋定子影响试验研究. 哈尔滨工程大学学报, 2021, 42(10): 1395-1402 Guo Chunyu, Xu Peng, Han Yang, et al. Experimental study on the influence of pre-swirl stator on the fluid field of ship sterns. Journal of Harbin Engineering University, 2021, 42(10): 1395-1402(in Chinese))
[20]	Kim M, Lee H, Hwang W. Experimental study on the flow interaction between two synthetic jets emanating from a dual round orifice. Experimental Thermal and Fluid Science, 2021, 126(4): 110400
[21]	Stamhuis EJ, Videler JJ. Quantitative flow analysis around aquatic animals using laser sheet particle image velocimetry. Journal of Experimental Biology, 1995, 198: 283-294
[22]	韩定强, 赵行, 武逸凡等. 基于PIV的仿生鲸尾型搅拌桨反应器流场研究. 西南师范大学学报(自然科学版), 2022, 47(02): 91-98 Han Dingqiang, Zhao Xing, Wu Yifan, et al. On Flow Field of a Bionic Whale Tail Turbine Agitator Based on PIV. Journal of Southwest China Normal University(Natural Science Edition), 2022, 47(02): 91-98(in Chinese))
[23]	Shih AM, Mendelson L, Techet AH. Archer fish jumping prey capture: kinematics and hydrodynamics. Journal of Experimental Biology, 2017, 220(8): 1411-1422 doi: 10.1242/jeb.145623
[24]	Mwaffo V, Peng Z, Cruz SR, et al. Zebrafish swimming in the flow: a particle image velocimetry study. Peerj, 2017, 5(1): e4041
[25]	McHenry MJ. The mechanical scaling of coasting in zebrafish (Daniorerio). Journal of Experimental Biology, 2005, 208(12): 2289-2301
[26]	Mignano AP, Kadapa S, Tangorra JL, et al. Passing the wake: Using multiple fins to shape forces for swimming. Biomimetics, 2019, 4(1): 23 doi: 10.3390/biomimetics4010023
[27]	杨国党, 胡晓, 张奔等. 基于粒子图像测速技术(PIV)的自由游泳草鱼动力学特征分析. 大连海洋大学学报, 2021, 36(05): 833-841 Yang Guodang, Hu Xiao, Zhang Ben, et al. Analysis of hydrodynamic characteristics of grass carp Ctenopharyngodon idellus juveniles under free-swimming status based on Particle Image Velocimetry (PIV). Journal of Dalian Fisheries University, 2021, 36(05): 833-841(in Chinese))
[28]	Drucker EG, Lauder GV. Experimental hydrodynamics of fish locomotion: Functional insights from wake visualization. Integrative and Comparative Biology, 2002
[29]	Sakakibara J, Nakagawa M, Yoshida M. Stereo-PIV study of flow around a maneuvering fish. Experiments in Fluids, 2004, 36(2): 282-293 doi: 10.1007/s00348-003-0720-z
[30]	Tytell ED, Lauder GV. Hydrodynamics of the escape response in bluegill sunfish, Lepomis macrochirus. Journal of Experimental Biology, 2008, 211(21): 3359-69 doi: 10.1242/jeb.020917
[31]	Ting SC, Yang JT. Extracting energetically dominant flow features in a complicated fish wake using singular-value decomposition. Physics of Fluids, 2009, 21(4): 33
[32]	Tu H, Wang FJ, Wang HP, et al. Experimental study on wake flows of a live fish with time-resolved tomographic PIV and pressure reconstruction. Experiments in Fluids, 2022, 63: 25 doi: 10.1007/s00348-021-03378-2
[33]	Lumley JL. The structure of inhomogeneous turbulent flows//Atmospheric Turbulence and Radio Wave Propagation, 1967: 166-178
[34]	Sirovich L. Turbulence and the dynamics of coherent structures. I-Coherent structures. II -Symmetries and transformations. III-Dynamics and scaling. Quarterly of Applied Mathematics, 1987, 45(3): 910463
[35]	Aubry N, Guyonnet R, Lima R. Spatiotemporal analysis of complex signals: Theory and applications. Journal of Statistical Physics, 1991, 64(3-4): 683-739 doi: 10.1007/BF01048312
[36]	Zhang Q, Liu Y, Wang S. The identification of coherent structures using proper orthogonal decomposition and dynamic mode decomposition. Journal of Fluids & Structures, 2014, 49: 53-72
[37]	Liu Y, Zhang Q. Dynamic mode decomposition of separated flow over a finite blunt plate: Time-resolved particle image velocimetry measurements. Experiments in Fluids, 2015, 56(7): 148 doi: 10.1007/s00348-015-2021-8
[38]	Zhang Q, Liu Y. Influence of incident vortex street on separated flow around a finite blunt plate: PIV measurement and POD analysis. Journal of Fluids and Structures, 2015, 55: 463-483 doi: 10.1016/j.jfluidstructs.2015.03.017
[39]	Paik BG, Kim KY, Lee JY, et al. Analysis of unstable vortical structure in a propeller wake affected by a simulated hull wake. Experiments in Fluids, 2009, 48(6): 1121-1133
[40]	胡建军, 朱晴, 王美达等. 近距离下射流冲击平板PIV实验研究. 力学学报, 2020, 52(05): 1350-1361 Hu Jianjun, Zhu Qing, Wang Meida, et al. PIV measurement of close impinging jet on flat plate. Chinese Journal of Theoretical and Applied Mechanics, 2020, 52(05): 1350-1361(in Chinese))
[41]	Meyer KE, Pedersen JM, Ozcan O. Turbulent jet in crossflow analyzed with proper orthogonal decomposition. Journal of Fluid Mechanics, 2007, 583: 199-228 doi: 10.1017/S0022112007006143
[42]	Song CZ, Yuille AL. FORMS: A flexible object recognition and modeling system. International Journal of Computer Vision, 1996, 20(3): 187-212
[43]	Jeong J, Hussain F. On the identification of a vortex. Journal of Fluid Mechanics, 1995, 332(1): 339-363
[44]	Hunt JCR, Wray AA, Moin P. Eddies, streams, and convergence zones in turbulent flows. Studying Turbulence Using Numerical Simulation Databases, 1988, 2(1): 193-208
[45]	Adrian RJ, Christensen KT, Liu ZC. Analysis and interpretation of instantaneous turbulent velocity fields. Experiments in Fluids, 2000, 29(3): 275-290 doi: 10.1007/s003489900087

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EXPERIMENTAL STUDY OF ZEBRAFISH SWIMMING WITH LINEAR ACCELERATION