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Theoretical and Applied Mechanics, 2018, Volume 45, Issue 1, Pages 17–33
DOI: https://doi.org/10.2298/TAM171017001C (Mi tam36) 		 
This article is cited in 8 scientific papers (total in 8 papers)

Locomotion of multibody robotic systems: dynamics and optimization

Felix L. Chernouskoab

a Institute for Problems in Mechanics of Russian Academy of Sciences, Moscow, Russia
b Moscow Institute of Physics and Technology, Dolgoprudnyi, Russia
Full-text PDF (2057 kB) Citations (8)
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DOI: https://doi.org/10.2298/TAM171017001C
Abstract: Locomotion of multibody systems in resistive media can be based on periodic change of the system configuration. The following types of mobile robotic systems are examined in the paper: multilink snake-like systems; multibody systems in quasi-static motion; systems consisting of several interacting bodies; fish-like, frog-like, and boat-like systems swimming in fluids; systems containing moving internal masses. Dynamics of these systems subjected to various resistance forces, both isotropic and anisotropic, are investigated, including dry friction forces obeying Coulomb's law and forces directed against the velocity of the moving body and proportional to the velocity value or its square. Possible modes of locomotion and control algorithms are discussed. Optimization for various types of mobile robots is considered. Optimal values of geometrical and mechanical parameters as well as optimal controls are obtained that provide the maximum locomotion speed or minimum energy consumption. Results of experiments and computer simulation are discussed.
Keywords: multibody systems, robotics, locomotion, optimization.
Funding agency Grant number
Russian Foundation for Basic Research 17-01-00652_а
17-51-12025_ННИО_а
Russian Academy of Sciences - Federal Agency for Scientific Organizations 29
The research described in the paper was supported by the Russian Foundation for Basic Research, projects No. 17-01-00652 and No. 17-51-12025, and by the Program No. 29 “Advanced Topics of Robotic Systems” of the Presidium of the Russian Academy of Sciences.
Received: 17.10.2017
Revised: 10.01.2018
Bibliographic databases:
Document Type: Article
MSC: 70E55
Language: English
Citation: Felix L. Chernousko, “Locomotion of multibody robotic systems: dynamics and optimization”, Theor. Appl. Mech., 45:1 (2018), 17–33
Citation in format AMSBIB
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  • https://www.mathnet.ru/eng/tam/v45/i1/p17
    • This publication is cited in the following 8 articles:
    1. E. A. Tkachenko, D. I. Merkulov, D. A. Pelevina, V. A. Turkov, A. S. Vinogradova, V. A. Naletova, “Mathematical model of a mobile robot with a magnetizable material in a uniform alternating magnetic field”, Meccanica, 58:2-3 (2023), 357  crossref
    2. Evgeniya Mikishanina, “The problem of acceleration in the dynamics of a double-link wheeled vehicle with arbitrarily directed periodic excitation”, Theor appl mech (Belgr), 50:2 (2023), 205  crossref
    3. Norihiro Kamamichi, Katsuhisa Furuta, “Locomotion analysis of self-propelled board by inclined internal mass motion with slider-crank mechanism”, Meccanica, 58:2-3 (2023), 473  crossref
    4. Vitaliy Korendiy, Oleksandr Kachur, Lecture Notes in Mechanical Engineering, Advanced Manufacturing Processes IV, 2023, 434  crossref
    5. M. Z. Dosaev, L. A. Klimina, V. A. Samsonov, Yu. D. Selyutsky, “Plane-Parallel Motion of a Snake Robot in the Presence of Anisotropic Dry Friction and a Single Control Input”, J. Comput. Syst. Sci. Int., 61:5 (2022), 858  crossref
    6. Marat Dosaev, Vitaly Samsonov, Shyh-Shin Hwang, “Construction of control algorithm in the problem of the planar motion of a friction-powered robot with a flywheel and an eccentric weight”, Applied Mathematical Modelling, 89 (2021), 1517  crossref
    7. F. L. Chernousko, “Two- and three-dimensional motions of a body controlled by an internal movable mass”, Nonlinear Dyn, 99:1 (2020), 793  crossref
    8. F. L. Chernous'ko, “Controlling the orientation of a solid using the internal mass”, J. Appl. Mech. Tech. Phys., 60:2 (2019), 278–283  mathnet  mathnet  crossref  crossref
    Citing articles in Google Scholar: Russian citations, English citations
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