Sage Journals: Discover world-class research

Abstract

As an important structure for generating thrust, the shapes of fish tails have adaptively evolved to achieve great swimming performance through natural selection over hundreds of millions of years. The particular optimal tail shape of fish is not universal for all situations but significantly varies with other factors, such as undulatory kinematics. In this study, using a sharp-interface immersed boundary method with a self-propelled model, we investigated the hydrodynamic performance of swimmers that equipped with three different caudal fins in a common undulatory mode, carangiform locomotion, to determine the optimal shape. The three caudal fins tested are as follows: a round fin emulating that of snakehead fish (channidae), an indented fin emulating that of saithe (Pollachius virens), and a lunate fin emulating that of tuna (Thunnus thynnus). At the regular undulating amplitude A = 0.1 L at the tail tip (L is the body length), the swimmer with the indented tail achieves the highest speed U = 1.45 L/s with a relatively high quasi-propulsive efficiency of η_q = 0.324; at a higher undulating amplitude A = 0.15 L, the indented tail swimmer achieves slightly lower speed than the lunate fin swimmer, who has the highest speed (2.06 L/s vs. 2.07 L/s), but the efficiency of the former is higher than that of the latter. Therefore, the indented fin is believed to perform the best among the three fins tested regarding carangiform undulatory swimming. This finding is consistent with observations made on fish in nature, for example, carangiform swimming fish that have been evolving for hundreds of millions of years have a caudal fin similar to the indented caudal fin in the current study.

Keywords

Undulatory swimming fish locomotion caudal fin shape

Get full access to this article

View all access options for this article.

References

Videler

. Fish Swimming, volume 10. London: Chapman & Hall, 1993.

Sfakiotakis

Lane

Davies

JBC

. Review of fish swimming modes for aquatic locomotion. IEEE J Oceanic Eng 1999; 24(2): 237–252.

Deng

H-B

Y-Q

Chen

D-D

, et al. On numerical modeling of animal swimming and flight. Comput Mech 2013; 52(6): 1221–1242.

Lindsey

. Form, function, and locomotory habits in fish. Fish Physiol 1979; 7: 1–100.

Lighthill

. Large-amplitude elongated-body theory of fish locomotion. Proc R Soc Lond B: Biol Sci 1971; 179(1055): 125–138.

Lighthill

. Hydromechanics of aquatic animal propulsion. Annu Rev Fluid Mech 1969; 1(1): 413–446.

Lighthill

. Aquatic animal propulsion of high hydromechanical efficiency. J Fluid Mech 1970; 44(02): 265–301.

Webb

. ‘Steady’ swimming kinematics of Tiger Musky, an esociform accelerator, and rainbow trout, a generalist cruiser. J Exp Biol 1988; 138(1): 51–69.

Wolfgang

Anderson

Grosenbaugh

, et al. Near-body flow dynamics in swimming fish. J Exp Biol 1999; 202(17): 2303–2327.

10.

Blake

Chan

KHS

. Swimming in four goldfishCarassius auratusmorphotypes: understanding functional design and performance employing artificially selected forms. J Fish Biol 2009; 75(3): 591–617.

11.

Webb

. Body form, locomotion and foraging in aquatic vertebrates. Am Zoologist 1984; 24(1): 107–120.

12.

Akanyeti

Thornycroft

PJM

Lauder

, et al. Fish optimize sensing and respiration during undulatory swimming. Nat Commun 2016; 7(1): 11044.

13.

Lucas

Lauder

Tytell

. The Fish Body Functions as an Airfoil: Surface Pressures Generate Thrust during Carangiform Locomotion. bioRxiv, 2020, In press.

14.

Feilich

Lauder

. Passive mechanical models of fish caudal fins: effects of shape and stiffness on self-propulsion. Bioinspiration & Biomimetics 2015; 10(3): 036002.

15.

Krishnadas

Ravichandran

Rajagopal

. Analysis of biomimetic caudal fin shapes for optimal propulsive efficiency. Ocean Eng 2018; 153: 132–142.

16.

Videler

Hess

. Fast continuous swimming of two pelagic predators, saithe (pollachius virens) and mackerel (scomber scombrus): a kinematic analysis. J Exp Biol 1984; 109(1): 209–228.

17.

G-j

Zhu

X-y

. Numerical studies on Locomotion perfromance of fishlike tail fins. J Hydrodynamics 2012; 24(4): 488–495.

18.

Van Buren

Floryan

Brunner

, et al. Impact of trailing edge shape on the wake and propulsive performance of pitching panels. Phys Rev Fluids 2017; 2(1): 014702.

19.

Borazjani

Sotiropoulos

. On the role of form and kinematics on the hydrodynamics of self-propelled body/caudal fin swimming. J Exp Biol 2010; 213(1): 89–107.

20.

Chang

Zhang

. Numerical study of the thunniform mode of fish swimming with different reynolds number and caudal fin shape. Comput Fluids 2012; 68: 54–70.

21.

Zhong

. Parametric study of the swimming performance of a novel robot fish with active compliant propulsion mechanism. In: ASME 2016 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference, Charlotte, North Carolina, USA, 21–24 August 2016, V05AT07A077. American Society of Mechanical Engineers (ASME); 2016.

22.

Liu

Dukes

. Novel mechatronics design for a robotic fish. In: Intelligent Robots and Systems, 2005. (IROS 2005). 2005 IEEE/RSJ International Conference on. IEEE, Edmonton, AB, Canada, 2–6 Aug 2005, pp. 807–812.

23.

Valdivia y Alvarado

Youcef-Toumi

. Design of machines with compliant bodies for biomimetic locomotion in liquid environments. J Dynamic Systems, Measurement, Control 2006; 128(1): 3–13.

24.

Epps

Valdivia y Alvarado

Youcef-Toumi

, et al. Swimming performance of a biomimetic compliant fish-like robot. Experiments in Fluids 2009; 47(6): 927–939.

25.

Liu

J-D

. Biologically inspired behaviour design for autonomous robotic fish. Int J Automation Comput 2006; 3(4): 336–347.

26.

Bainbridge

. Caudal fin and body movement in the propulsion of some fish. J Exp Biol 1963; 40(1): 23–56.

27.

Bainbridge

. The speed of swimming of fish as related to size and to the frequency and amplitude of the tail beat. J Exp Biol 1958; 35(1): 109–133.

28.

Luo

Dai

Ferreira de Sousa

PJSA

, et al. On the numerical oscillation of the direct-forcing immersed-boundary method for moving boundaries. Comput Fluids 2012; 56: 61–76.

29.

Blake

. Fish functional design and swimming performance. J Fish Biol 2004; 65(5): 1193–1222.

30.

Dai

Luo

Doyle

. Dynamic pitching of an elastic rectangular wing in hovering motion. J Fluid Mech 2012; 693: 473–499.

31.

Song

Luo

Hedrick

. Three-dimensional flow and lift characteristics of a hovering ruby-throated hummingbird. J R Soc Interf 2014; 11(98): 20140541.

32.

Song

Tobalske

Powers

, et al. Three-dimensional simulation for fast forward flight of a calliope hummingbird. R Soc Open Sci 2016; 3(6): 160230.

33.

Song

Zhong

Luo

, et al. Hydrodynamics of larval fish quick turning: a computational study. Proc Inst Mech Eng C: J Mech Eng Sci 2018; 232(14): 2515–2523.

34.

Song

Zhong

, et al. Tail shapes lead to different propulsive mechanisms in the body/caudal fin undulation of fish. Proc Inst Mech Eng Part C: J Mech Eng Sci 2021; 235(2): 351–364.

35.

Ming

Jin

Song

, et al. 3d computational models explain muscle activation patterns and energetic functions of internal structures in fish swimming. PLOS Comput Biol 2019; 15(9): e1006883.

36.

Standen

Lauder

. Dorsal and anal fin function in bluegill sunfishLepomis macrochirus: three-dimensional kinematics during propulsion and maneuvering. J Exp Biol 2005; 208(14): 2753–2763.

37.

Maertens

Triantafyllou

Yue

. Efficiency of fish propulsion. Bioinspiration & Biomimetics 2015; 10(4): 046013–046023.

38.

Zhang

Y-m

Wang

Z-l

. Numerical and experimental studies of influence of the caudal fin shape on the propulsion performance of a flapping caudal fin. J Hydrodynamics 2011; 23(3): 325–332.

39.

Shadwick

Lauder

. . Fish Physiology: Fish Biomechanics 2006; 23.

40.

Akanyeti

Putney

Yanagitsuru

, et al. Accelerating fishes increase propulsive efficiency by modulating vortex ring geometry. Proc Natl Acad Sci 2017; 114(52): 13828–13833.

41.

Dong

Mittal

Najjar

. Wake topology and hydrodynamic performance of low-aspect-ratio flapping foils. J Fluid Mech 2006; 566: 309–343.

42.

Jeong

Hussain

. On the identification of a vortex. J Fluid Mech 1995; 285: 69–94.

43.

Dickinson

Lehmann

Sane

. Wing rotation and the aerodynamic basis of insect flight. Science (New York, N.Y.) 1999; 284(5422): 1954–1960.

44.

Liao

. The role of the lateral line and vision on body kinematics and hydrodynamic preference of rainbow trout in turbulent flow. J Exp Biol 2006; 209(20): 4077–4090.

45.

Gazzola

Argentina

Mahadevan

. Scaling macroscopic aquatic locomotion. Nat Phys 2014; 10(10): 758–761.

46.

Katz

. Design of heterothermic muscle in fish. J Exp Biol 2002; 205(15): 2251–2266.

47.

Biewener

Patek

. Animal Locomotion. Oxford, UK: Oxford University Press, 2018.

48.

Webb

. Kinematics of plaice,Pleuronectes platessa, and cod,Gadus morhua, swimming near the bottom. J Exp Biol 2002; 205(14): 2125–2134.

49.

Donley

Dickson

. Swimming kinematics of juvenile kawakawa tuna (euthynnus affinis) and chub mackerel (scomber japonicus). J Exp Biol 2000; 203(20): 3103–3116.

50.

Dickson

Donley

Sepulveda

, et al. Effects of temperature on sustained swimming performance and swimming kinematics of the chub mackerelScomber japonicus. J Exp Biol 2002; 205(7): 969–980.

51.

Jayne

Lauder

. Speed effects on midline kinematics during steady undulatory swimming of largemouth bass, micropterus salmoides. J Exp Biol 1995; 198(2): 585–602.

52.

Long

Hale

Mchenry

, et al. Functions of fish skin: flexural stiffness and steady swimming of longnose gar, lepisosteus osseus. J Exp Biol 1996; 199(10): 2139–2151.

53.

Tytell

Lauder

. The hydrodynamics of eel swimming. J Exp Biol 2004; 207(11): 1825–1841.

54.

Langerhans

. Trade-off between steady and unsteady swimming underlies predator-driven divergence inGambusia affinis. J Evol Biol 2009; 22: 1057–1075.

55.

Muller

Stamhuis

Videler

. Riding the waves: the role of the body wave in undulatory fish swimming. Integr Comp Biol 2002; 42(5): 981–987.

56.

Wolfgang

Anderson

Grosenbaugh

, et al. Near-body flow dynamics in swimming fish. J Exp Biol 1999; 202(17): 2303–2327.

57.

Ellerby

Altringham

Williams

, et al. Slow muscle function of pacific bonito (sarda chiliensis) during steady swimming. J Exp Biol 2000; 203(13): 2001–2013.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.54 MB

Hydrodynamic effects of the caudal fin shape of fish in carangiform undulatory swimming

Abstract

Keywords

Get full access to this article

References

Supplementary Material