Mechanisms underlying rhythmic locomotion: body–fluid interaction in undulatory swimming

SUMMARY Swimming of fish and other animals results from interactions of rhythmic body movements with the surrounding fluid. This paper develops a model for the body–fluid interaction in undulatory swimming of leeches, where the body is represented by a chain of rigid links and the hydrodynamic force model is based on resistive and reactive force theories. The drag and added-mass coefficients for the fluid force model were determined from experimental data of kinematic variables during intact swimming, measured through video recording and image processing. Parameter optimizations to minimize errors in simulated model behaviors revealed that the resistive force is dominant, and a simple static function of relative velocity captures the essence of hydrodynamic forces acting on the body. The model thus developed, together with the experimental kinematic data, allows us to investigate temporal and spatial (along the body) distributions of muscle actuation, body curvature, hydrodynamic thrust and drag, muscle power supply and energy dissipation into the fluid. We have found that: (1) thrust is generated continuously along the body with increasing magnitude toward the tail, (2) drag is nearly constant along the body, (3) muscle actuation waves travel two or three times faster than the body curvature waves and (4) energy for swimming is supplied primarily by the mid-body muscles, transmitted through the body in the form of elastic energy, and dissipated into the water near the tail.

[1]  J. Gray,et al.  STUDIES IN ANIMAL LOCOMOTION II. THE RELATIONSHIP BETWEEN WAVES OF MUSCULAR CONTRACTION AND THE PROPULSIVE MECHANISM OF THE EEL , 1933 .

[2]  J. Gray,et al.  Studies in Animal Locomotion: I. The Movement of Fish with Special Reference to the Eel , 1933 .

[3]  J. Gray Studies in Animal Locomotion , 1936 .

[4]  G. Taylor Analysis of the swimming of long and narrow animals , 1952, Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences.

[5]  M. Lighthill Note on the swimming of slender fish , 1960, Journal of Fluid Mechanics.

[6]  M. Lighthill Hydromechanics of Aquatic Animal Propulsion , 1969 .

[7]  A. E. Stuart Physiological and morphological properties of motoneurones in the central nervous system of the leech , 1970, The Journal of physiology.

[8]  M. Lighthill Aquatic animal propulsion of high hydromechanical efficiency , 1970, Journal of Fluid Mechanics.

[9]  M. Lighthill Large-amplitude elongated-body theory of fish locomotion , 1971, Proceedings of the Royal Society of London. Series B. Biological Sciences.

[10]  C. Crowe,et al.  Engineering fluid mechanics , 1975 .

[11]  John J. Videler,et al.  Fast Continuous Swimming of Two Pelagic Predators, Saithe (Pollachius Virens) and Mackerel (Scomber Scombrus): a Kinematic Analysis , 1984 .

[12]  J. Videler,et al.  FAST CONTINUOUS SWIMMING OF SAITHE (POLLACHIUS VIRENS): A DYNAMIC ANALYSIS OF BENDING MOMENTS AND MUSCLE POWER , 1984 .

[13]  Richard J. Wassersug,et al.  THE KINEMATICS OF SWIMMING IN ANURAN LARVAE , 1985 .

[14]  S. Rossignol,et al.  LOCOMOTION IN LAMPREY AND TROUT: THE RELATIVE TIMING OF ACTIVATION AND MOVEMENT , 1989 .

[15]  T. Williams,et al.  Anguilliform Body Dynamics: Modelling the Interaction between Muscle Activation and Body Curvature , 1991 .

[16]  Bing-Gang Tong,et al.  Analysis of swimming three-dimensional waving plates , 1991, Journal of Fluid Mechanics.

[17]  C. I. Smith,et al.  MYOTOMAL MUSCLE FUNCTION AT DIFFERENT LOCATIONS IN THE BODY OF A SWIMMING FISH , 1993 .

[18]  J. Videler Fish Swimming , 1993, Springer Netherlands.

[19]  L C Rome,et al.  How fish power swimming. , 1993, Science.

[20]  T. Williams,et al.  Anguilliform body dynamics: a continuum model for the interaction between muscle activation and body curvature , 1994, Journal of mathematical biology.

[21]  C. S. Wardle,et al.  Tuning in to fish swimming waves: body form, swimming mode and muscle function , 1995, The Journal of experimental biology.

[22]  C. E. Jordan Coupling Internal and External Mechanics to Predict Swimming Behavior: A General Approach , 1996 .

[23]  G. Gillis,et al.  Undulatory Locomotion in Elongate Aquatic Vertebrates: Anguilliform Swimming since Sir James Gray , 1996 .

[24]  Aerts,et al.  Kinematics and efficiency of steady swimming in adult axolotls (Ambystoma mexicanum) , 1997, The Journal of experimental biology.

[25]  J. Videler,et al.  Fish foot prints: morphology and energetics of the wake behind a continuously swimming mullet (Chelon labrosus Risso). , 1997, The Journal of experimental biology.

[26]  Williams,et al.  Self-propelled anguilliform swimming: simultaneous solution of the two-dimensional navier-stokes equations and Newton's laws of motion , 1998, The Journal of experimental biology.

[27]  J. Altringham,et al.  A continuous dynamic beam model for swimming fish , 1998 .

[28]  S Grillner,et al.  Simulations of neuromuscular control in lamprey swimming. , 1999, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[29]  M. Triantafyllou,et al.  Hydrodynamics of Fishlike Swimming , 2000 .

[30]  J. Videler,et al.  How the body contributes to the wake in undulatory fish swimming: flow fields of a swimming eel (Anguilla anguilla). , 2001, The Journal of experimental biology.

[31]  J. Brackenbury Kinematics and hydrodynamics of an invertebrate undulatory swimmer: the damsel-fly larva. , 2002, The Journal of experimental biology.

[32]  Tetsuya Iwasaki,et al.  Serpentine locomotion with robotic snakes , 2002 .

[33]  George V Lauder,et al.  Hydrodynamics of caudal fin locomotion by chub mackerel, Scomber japonicus (Scombridae). , 2002, The Journal of experimental biology.

[34]  E. Azizi,et al.  The hydrodynamics of locomotion at intermediate Reynolds numbers: undulatory swimming in ascidian larvae (Botrylloides sp.) , 2003, Journal of Experimental Biology.

[35]  J. Brackenbury Kinematics and hydrodynamics of swimming in the mayfly larva , 2004, Journal of Experimental Biology.

[36]  Eric D Tytell,et al.  Kinematics and hydrodynamics of linear acceleration in eels, Anguilla rostrata , 2004, Proceedings of the Royal Society of London. Series B: Biological Sciences.

[37]  R. Verovnik,et al.  Genetic differentiation between two species of the medicinal leech, Hirudo medicinalis and the neglected H. verbana, based on random-amplified polymorphic DNA , 2004, Parasitology Research.

[38]  Robert Dillon,et al.  Simulation of swimming organisms: coupling internal mechanics with external fluid dynamics , 2004, Computing in Science & Engineering.

[39]  G. Lauder,et al.  The hydrodynamics of eel swimming , 2004, Journal of Experimental Biology.

[40]  Örjan Ekeberg,et al.  A combined neuronal and mechanical model of fish swimming , 2005, Biological Cybernetics.

[41]  R. Blickhan,et al.  Generation of a vortex chain in the wake of a Suhundulatory swimmer , 1992, Naturwissenschaften.

[42]  W. O. Friesen,et al.  Neuronal control of leech behavior , 2005, Progress in Neurobiology.

[43]  P Holmes,et al.  An elastic rod model for anguilliform swimming , 2006, Journal of mathematical biology.

[44]  P. Koumoutsakos,et al.  Simulations of optimized anguilliform swimming , 2006, Journal of Experimental Biology.

[45]  J. L. Leeuwen,et al.  Undulatory fish swimming: from muscles to flow , 2006 .

[46]  G. Lauder,et al.  Passive and Active Flow Control by Swimming Fishes and Mammals , 2006 .

[47]  Tetsuya Iwasaki,et al.  Systems-level modeling of neuronal circuits for leech swimming , 2007, Journal of Computational Neuroscience.

[48]  W. O. Friesen,et al.  Muscle function in animal movement: passive mechanical properties of leech muscle , 2007, Journal of Comparative Physiology A.

[49]  M. Siddall,et al.  Diverse molecular data demonstrate that commercially available medicinal leeches are not Hirudo medicinalis , 2007, Proceedings of the Royal Society B: Biological Sciences.

[50]  T. Williams,et al.  Nonlinear Muscles, Passive Viscoelasticity and Body Taper Conspire To Create Neuromechanical Phase Lags in Anguilliform Swimmers , 2008, PLoS Comput. Biol..

[51]  I. Borazjani,et al.  Numerical investigation of the hydrodynamics of carangiform swimming in the transitional and inertial flow regimes , 2008, Journal of Experimental Biology.

[52]  Tetsuya Iwasaki,et al.  Multivariable harmonic balance analysis of the neuronal oscillator for leech swimming , 2008, Journal of Computational Neuroscience.

[53]  I. Borazjani,et al.  Numerical investigation of the hydrodynamics of anguilliform swimming in the transitional and inertial flow regimes , 2009, Journal of Experimental Biology.

[54]  Tetsuya Iwasaki,et al.  Analysis of impulse adaptation in motoneurons , 2010, Journal of Comparative Physiology A.

[55]  Tetsuya Iwasaki,et al.  Optimal Gaits for Mechanical Rectifier Systems , 2011, IEEE Transactions on Automatic Control.