Geodesic
Controlled motion of a~rigid body with internal mechanisms in an ideal incompressible fluid
Trudy Matematicheskogo Instituta imeni V.A. Steklova, Modern problems of mechanics, Tome 295 (2016), pp. 321-351.

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We consider the controlled motion in an ideal incompressible fluid of a rigid body with moving internal masses and an internal rotor in the presence of circulation of the fluid velocity around the body. The controllability of motion (according to the Rashevskii–Chow theorem) is proved for various combinations of control elements. In the case of zero circulation, we construct explicit controls (gaits) that ensure rotation and rectilinear (on average) motion. In the case of nonzero circulation, we examine the problem of stabilizing the body (compensating the drift) at the end point of the trajectory. We show that the drift can be compensated for if the body is inside a circular domain whose size is defined by the geometry of the body and the value of circulation. 
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E. V. Vetchanin; A. A. Kilin. Controlled motion of a~rigid body with internal mechanisms in an ideal incompressible fluid. Trudy Matematicheskogo Instituta imeni V.A. Steklova, Modern problems of mechanics, Tome 295 (2016), pp. 321-351. http://geodesic.mathdoc.fr/item/TM_2016_295_a17/

[1] Ageev M. D., Kiselev L. V., Matvienko Yu. V. i dr., Avtonomnye podvodnye roboty: Sistemy i tekhnologii, ed. M. D. Ageev, Nauka, M., 2005

[2] Agrachev A. A., Sachkov Yu. L., Control theory from the geometric viewpoint, Springer, Berlin, 2004 | MR | Zbl

[3] Alexander R. McN., “The history of fish mechanics”, Fish biomechanics, eds. P. W. Webb, D. Weihs, Praeger, New York, 1983, 1–35

[4] Antonelli G., Underwater robots, Springer, Cham, 2014

[5] Berg H. C., Random walks in biology, Princeton Univ. Press, Princeton, NJ, 1993 | MR

[6] Bhatta P., Leonard N. E., “Stabilization and coordination of underwater gliders”, Proc. 41st IEEE Conf. on Decision and Control, v. 2, IEEE, Piscataway, NJ, 2002, 2081–2086

[7] Blake R. W., Fish locomotion, Cambridge Univ. Press, Cambridge, 1983

[8] Bolotnik N. N., Figurina T. Yu., Chernousko F. L., “Optimalnoe upravlenie pryamolineinym dvizheniem sistemy dvukh tel v soprotivlyayuscheisya srede”, PMM, 76:1 (2012), 3–22 | MR | Zbl

[9] Bonnard B., “Contrôlabilité des systèmes non linéaires”, C. r. Acad. sci. Paris. Sér. 1, 292 (1981), 535–537 | MR | Zbl

[10] Bonnard B., Chyba M., Singular trajectories and their role in control theory, Math. Appl., 40, Springer, Paris, 2003 | MR | Zbl

[11] Borisov A. V., Jalnine A. Yu., Kuznetsov S. P., Sataev I. R., Sedova Ju. V., “Dynamical phenomena occurring due to phase volume compression in nonholonomic model of the rattleback”, Regul. Chaotic Dyn., 17:6 (2012), 512–532 | DOI | MR | Zbl

[12] Borisov A. V., Kilin A. A., Mamaev I. S., “Novye effekty v dinamike keltskikh kamnei”, DAN, 408:2 (2006), 192–195 | MR | Zbl

[13] Borisov A. V., Kilin A. A., Mamaev I. S., “How to control Chaplygin's sphere using rotors”, Regul. Chaotic Dyn., 17:3–4 (2012), 258–272 | DOI | MR | Zbl

[14] Borisov A. V., Kilin A. A., Mamaev I. S., “How to control the Chaplygin ball using rotors. II”, Regul. Chaotic Dyn., 18:1–2 (2013), 144–158 | DOI | MR | Zbl

[15] Borisov A. V., Kilin A. A., Mamaev I. S., “The problem of drift and recurrence for the rolling Chaplygin ball”, Regul. Chaotic Dyn., 18:6 (2013), 832–859 | DOI | MR | Zbl

[16] Borisov A. V., Kozlov V. V., Mamaev I. S., “Asymptotic stability and associated problems of dynamics of falling rigid body”, Regul. Chaotic Dyn., 12:5 (2007), 531–565 | DOI | MR | Zbl

[17] Borisov A. V., Mamaev I. S., Dinamika tverdogo tela: Gamiltonovy metody, integriruemost, khaos, In-t kompyut. issled., M.–Izhevsk, 2005 | MR

[18] Borisov A. V., Mamaev I. S., “On the motion of a heavy rigid body in an ideal fluid with circulation”, Chaos, 16:1 (2006), 013118 | DOI | MR | Zbl

[19] Borisov A. V., Mamaev I. S., Ramodanov S. M., “Motion of a circular cylinder and $n$ point vortices in a perfect fluid”, Regul. Chaotic Dyn., 8:4 (2003), 449–462 | DOI | MR | Zbl

[20] Borisov A. V., Mamaev I. S., Ramodanov S. M., “Dynamic interaction of point vortices and a two-dimensional cylinder”, J. Math. Phys., 48:6 (2007), 065403 | DOI | MR | Zbl

[21] Canudas de Wit C., Olsson H., Åström K. J., Lischinsky P., “A new model for control of systems with friction”, IEEE Trans. Autom. Control, 40:3 (1995), 419–425 | DOI | MR | Zbl

[22] Chaplygin S. A., “O vliyanii ploskoparallelnogo potoka vozdukha na dvizhuscheesya v nem tsilindricheskoe krylo”, Tr. TsAGI, 19, M., 1926; Собр. соч., т. 2, Гостехиздат, М.–Л., 1948, 300–382

[23] Chaplygin S. A., “O dvizhenii tyazhelykh tel v neszhimaemoi zhidkosti”, Sobr. soch., v. 1, Gostekhizdat, M.–L., 1948, 312–336

[24] Chernousko F. L., “Optimalnye periodicheskie dvizheniya dvukhmassovoi sistemy v soprotivlyayuscheisya srede”, PMM, 72:2 (2008), 202–215 | MR | Zbl

[25] Childress S., Spagnolie S. E., Tokieda T., “A bug on a raft: Recoil locomotion in a viscous fluid”, J. Fluid Mech., 669 (2011), 527–556 | DOI | MR | Zbl

[26] Chu W.-S., et al., “Review of biomimetic underwater robots using smart actuators”, Int. J. Precis. Eng. Manuf., 13:7 (2012), 1281–1292 | DOI

[27] Chyba M., Leonard N. E., Sontag E. D., “Optimality for underwater vehicles”, Proc. 40th IEEE Conf. on Decision and Control, v. 5, IEEE, Piscataway, NJ, 2001, 4204–4209 | DOI

[28] Cochran J., Kanso E., Kelly S. D., Xiong H., Krstic M., “Source seeking for two nonholonomic models of fish locomotion”, IEEE Trans. Rob., 25:5 (2009), 1166–1176 | DOI

[29] Colgate J. E., Lynch K. M., “Mechanics and control of swimming: A review”, IEEE J. Oceanic Eng., 29:3 (2004), 660–673 | DOI

[30] Crouch P. E., “Spacecraft attitude control and stabilization: Applications of geometric control theory to rigid body models”, IEEE Trans. Autom. Control, 29:4 (1984), 321–331 | DOI | Zbl

[31] Do K. D., Jiang Z. P., Pan J., Nijmeijer H., “A global output-feedback controller for stabilization and tracking of underactuated ODIN: A spherical underwater vehicle”, Automatica, 40:1 (2004), 117–124 | DOI | MR | Zbl

[32] Ehlers K. M., Koiller J., “Micro-swimming without flagella: Propulsion by internal structures”, Regul. Chaotic Dyn., 16:6 (2011), 623–652 | DOI | MR | Zbl

[33] Föppl L., “Wirbelbewegung hinter einem Kreiszylinder”, Münch. Ber., 1913 (1913), 1–17 | Zbl

[34] Gray J., “Studies in animal locomotion. VI: The propulsive powers of the dolphin”, J. Exp. Biol., 13:2 (1936), 192–199

[35] Havelock T. H., “The stability of motion of rectilinear vortices in ring formation”, Philos. Mag. Ser. 7, 11:70, Suppl. (1931), 617–633 | DOI | Zbl

[36] Jagadeesh P., Murali K., Idichandy V. G., “Experimental investigation of hydrodynamic force coefficients over AUV hull form”, Ocean Eng., 36:1 (2009), 113–118 | DOI

[37] Jones M. A., Shelley M. J., “Falling cards”, J. Fluid Mech., 540 (2005), 393–425 | DOI | MR | Zbl

[38] Jurdjevic V., Geometric control theory, Cambridge Univ. Press, Cambridge, 1997 | MR | Zbl

[39] Kanso E., Marsden J. E., Rowley C. W., Melli-Huber J. B., “Locomotion of articulated bodies in a perfect fluid”, J. Nonlinear Sci., 15:4 (2005), 255–289 | DOI | MR | Zbl

[40] Karavaev Yu. L., Kilin A. A., “The dynamics and control of a spherical robot with an internal omniwheel platform”, Regul. Chaotic Dyn., 20:2 (2015), 134–152 | DOI | MR | Zbl | Zbl

[41] Kazakov A. O., “Strange attractors and mixed dynamics in the problem of an unbalanced rubber ball rolling on a plane”, Regul. Chaotic Dyn., 18:5 (2013), 508–520 | DOI | MR | Zbl

[42] Kilin A. A., Pivovarova E. N., Ivanova T. B., “Spherical robot of combined type: Dynamics and control”, Regul. Chaotic Dyn., 20:6 (2015), 716–728 | DOI | MR | Zbl

[43] Kilin A. A., Vetchanin E. V., “Upravlenie dvizheniem tverdogo tela v zhidkosti s pomoschyu dvukh podvizhnykh mass”, Nelineinaya dinamika, 11:4 (2015), 633–645

[44] Kiselev L. V., Medvedev A. V., “Sravnitelnyi analiz i optimizatsiya dinamicheskikh svoistv avtonomnykh podvodnykh robotov razlichnykh proektov i konfiguratsii”, Podvodnye issledovaniya i robototekhnika, 2012, no. 1, 24–35

[45] Kirchhoff G., Vorlesungen über mathematische Physik: Mechanik, B. G. Teubner, Leipzig, 1877 | Zbl

[46] Koiller J., Ehlers K., Montgomery R., “Problems and progress in microswimming”, J. Nonlinear Sci., 6:6 (1996), 507–541 | DOI | MR | Zbl

[47] Kozlov V. V., Onischenko D. A., “O dvizhenii tela s zhestkoi obolochkoi i peremennoi geometriei mass v beskonechnom ob'eme idealnoi zhidkosti”, Problemy mekhaniki, Sb. st. k 90-letiyu A. Yu. Ishlinskogo, Fizmatlit, M., 2003, 465–476

[48] Kozlov V. V., Ramodanov S. M., “O dvizhenii izmenyaemogo tela v idealnoi zhidkosti”, PMM, 65:4 (2001), 592–601 | MR | Zbl

[49] Kozlov V. V., Ramodanov S. M., “O dvizhenii v idealnoi zhidkosti tela s zhestkoi obolochkoi i menyayuscheisya geometriei mass”, DAN, 382:4 (2002), 478–481 | MR

[50] Kumar R. P., Dasgupta A., Kumar C. S., “Real-time optimal motion planning for autonomous underwater vehicles”, Ocean Eng., 32:11–12 (2005), 1431–1447 | DOI

[51] Lamb H., Hydrodynamics, 6th ed., Dover Publ., New York, 1945; Lamb G., Gidrodinamika, Gostekhizdat, M.–L., 1947

[52] Leonard N. E., “Stability of a bottom-heavy underwater vehicle”, Automatica, 33:3 (1997), 331–346 | DOI | MR | Zbl

[53] Leonard N. E., Marsden J. E., “Stability and drift of underwater vehicle dynamics: Mechanical systems with rigid motion symmetry”, Physica D, 105:1–3 (1997), 130–162 | DOI | MR | Zbl

[54] Lyapunov A. M., “O postoyannykh' vintovykh' dvizheniyakh' tverdago tѣla v' zhidkosti”, Soobsch. Kharkov. mat. o-va. Ser. 2, 1:1 (1888), 7–60

[55] Michelin S., Llewelly Smith S. G., “An unsteady point vortex method for coupled fluid–solid problems”, Theor. Comput. Fluid Dyn., 23:2 (2009), 127–153 | DOI | Zbl

[56] Murray R. M., Burdick J. W., Kelly S. D., Radford J., “Trajectory generation for mechanical systems with application to robotic locomotion”, Robotics: The algorithmic perspective, Proc. 3rd Workshop on the Algorithmic Foundations of Robotics, A. K. Peters, Natick, MA, 1998, 81–90 | MR | Zbl

[57] Paull L., Saeedi S., Seto M., Li H., “AUV navigation and localization: A review”, IEEE J. Oceanic Eng., 39:1 (2014), 131–149 | DOI

[58] Purcell E. M., “Life at low Reynolds number”, Amer. J. Phys., 45:1 (1977), 3–11 | DOI | MR

[59] Ramodanov S. M., Tenenev V. A., “Dvizhenie v idealnoi zhidkosti dvumernogo tela, upravlyaemogo posredstvom dvukh podvizhnykh vnutrennikh mass”, PMM, 79:4 (2015), 463–475 | MR

[60] Ramodanov S. M., Tenenev V. A., Treschev D. V., “Self-propulsion of a body with rigid surface and variable coefficient of lift in a perfect fluid”, Regul. Chaotic Dyn., 17:6 (2012), 547–558 | DOI | MR | Zbl

[61] Rashevskii P. K., “O soedinimosti lyubykh dvukh tochek vpolne negolonomnogo prostranstva dopustimoi liniei”, Uchen. zap. Mosk. gos. ped. in-ta im. K. Libknekhta. Ser. fiz.-mat., 3:2 (1938), 83–94

[62] Saffman P. G., “The self-propulsion of a deformable body in a perfect fluid”, J. Fluid Mech., 28:2 (1967), 385–389 | DOI | MR | Zbl

[63] Saffman P. G., Vortex dynamics, Cambridge Univ. Press, Cambridge, 1992 | MR | Zbl

[64] Sakharov A. V., “Rotation of the body with movable internal masses around the center of mass on a rough plane”, Regul. Chaotic Dyn., 20:4 (2015), 428–440 | DOI | MR | Zbl

[65] Sfakiotakis M., Lane D. M., Davies J. B. C., “Review of fish swimming modes for aquatic locomotion”, IEEE J. Oceanic Eng., 24:2 (1999), 237–252 | DOI

[66] Shashikanth B. N., “Poisson brackets for the dynamically interacting system of a 2D rigid cylinder and $N$ point vortices: The case of arbitrary smooth cylinder shapes”, Regul. Chaotic Dyn., 10:1 (2005), 1–14 | DOI | MR | Zbl

[67] Shashikanth B. N., Sheshmani A., Kelly S. D., Marsden J. E., “Hamiltonian structure for a neutrally buoyant rigid body interacting with $N$ vortex rings of arbitrary shape: The case of arbitrary smooth body shape”, Theor. Comput. Fluid Dyn., 22:1 (2008), 37–64 | DOI | Zbl

[68] Sparenberg J. A., “Survey of the mathematical theory of fish locomotion”, J. Eng. Math., 44:4 (2002), 395–448 | DOI | MR | Zbl

[69] Steklov V. A., “O dvizhenii tyazhelago tverdago tѣla v' zhidkosti”, Soobsch. Kharkov. mat. o-va. Ser. 2, 2:1–2 (1889), 209–235

[70] Steklov V. A., “O nѣkotorykh' vozmozhnykh' dvizheniyakh' tverdago tѣla v' zhidkosti”, Tr. otd. fiz. nauk O-va lyubitelei estestvoznaniya, 7:2 (1895), 10–21

[71] T. Y.-T. Wu, C. J. Brokaw, C. Brennen (Eds), Swimming and flying in nature, v. 1, Plenum, New York, 1975

[72] Tallapragada P., Kelly S. D., “Dynamics and self-propulsion of a spherical body shedding coaxial vortex rings in an ideal fluid”, Regul. Chaotic Dyn., 18:1–2 (2013), 21–32 | DOI | MR | Zbl

[73] Tallapragada P., Kelly S. D., “Self-propulsion of free solid bodies with internal rotors via localized singular vortex shedding in planar ideal fluids”, Eur. Phys. J. Spec. Top., 224:17 (2015), 3185–3197 | DOI

[74] Tenenev V. A., Vetchanin E. V., Ilaletdinov L. F., “Khaoticheskaya dinamika v zadache o padenii tela vintovoi formy v zhidkosti”, Nelineinaya dinamika, 12:1 (2016), 99–120 | Zbl

[75] Triantafyllou M. S., Techet A. H., Hover F. S., “Review of experimental work in biomimetic foils”, IEEE J. Oceanic Eng., 29:3 (2004), 585–594 | DOI

[76] Triantafyllou M. S., Triantafyllou G. S., Yue D. K. P., “Hydrodynamics of fishlike swimming”, Annu. Rev. Fluid Mech., 32 (2000), 33–53 | DOI | MR | Zbl

[77] Vankerschaver J., Kanso E., Marsden J., “The geometry and dynamics of interacting rigid bodies and point vortices”, J. Geom. Mech., 1:2 (2009), 223–266 | DOI | MR | Zbl

[78] Vankerschaver J., Kanso E., Marsden J. E., “The dynamics of a rigid body in potential flow with circulation”, Regul. Chaotic Dyn., 15:4–5 (2010), 606–629 | DOI | MR | Zbl

[79] Vetchanin E. V., Kilin A. A., “Svobodnoe i upravlyaemoe dvizhenie v zhidkosti tela s podvizhnoi vnutrennei massoi pri nalichii tsirkulyatsii vokrug tela”, DAN, 466:3 (2016), 293–297 | MR

[80] Vetchanin E. V., Kilin A. A., “Control of body motion in an ideal fluid using the internal mass and the rotor in the presence of circulation around the body”, J. Dyn. Control Syst., 2016 | DOI

[81] Vetchanin E. V., Mamaev I. S., Tenenev V. A., “The self-propulsion of a body with moving internal masses in a viscous fluid”, Regul. Chaotic Dyn., 18:1–2 (2013), 100–117 | DOI | MR | Zbl

[82] Woolsey C. A., Leonard N. E., “Stabilizing underwater vehicle motion using internal rotors”, Automatica, 38:12 (2002), 2053–2062 | DOI | MR | Zbl

[83] Wu T. Y., “Fish swimming and bird/insect flight”, Annu. Rev. Fluid Mech., 43 (2011), 25–58 | DOI | MR | Zbl

[84] Yu J., Tan M., Wang S., Chen E., “Development of a biomimetic robotic fish and its control algorithm”, IEEE Trans. Syst. Man Cybern. B, 34:4 (2004), 1798–1810 | DOI

[85] Zhou C., Low K. H., “Design and locomotion control of a biomimetic underwater vehicle with fin propulsion”, IEEE/ASME Trans. Mechatron, 17:1 (2012), 25–35 | DOI