Izvestiya of Saratov University.

Mathematics. Mechanics. Informatics

ISSN 1816-9791 (Print)
ISSN 2541-9005 (Online)

For citation:

Smirnov A. S., Bulov S. A., Degilevich E. A. Construction and analysis of nonlinear oscillation modes of a three-link pendulum by asymptotic methods. Izvestiya of Saratov University. Mathematics. Mechanics. Informatics, 2024, vol. 24, iss. 4, pp. 598-610. DOI: 10.18500/1816-9791-2024-24-4-598-610, EDN: ZBOGPA

This is an open access article distributed under the terms of Creative Commons Attribution 4.0 International License (CC-BY 4.0).
Published online: 
25.11.2024
Full text:
download
(downloads: 140)
Language: 
Russian
Heading: 
Mechanics
Article type: 
Article
UDC: 
534.014
DOI: 
10.18500/1816-9791-2024-24-4-598-610
EDN: 
ZBOGPA

Construction and analysis of nonlinear oscillation modes of a three-link pendulum by asymptotic methods

Autors: 
Smirnov Alexey S., Peter the Great St. Petersburg Polytechnic University
Bulov Serafim A., Сenter of Engineering Physics, Simulation and Analysis (JSC “CEPSA”)
Degilevich Egor A., Institute for Problems in Mechanical Engineering of the Russian Academy of Sciences
Abstract: 

This article is devoted to the study of nonlinear oscillations of one of the most common systems with three degrees of freedom – a three-link mathematical pendulum, the parameters of all weightless links and all end loads of which are assumed to be identical. The wide use of the three-link pendulum model in applied problems of robotics and biomechanics, as well as its important scientific significance in the problems of equilibrium stability, stabilization and motion control are discussed. The question of finding nonlinear oscillation modes of a three-link pendulum is considered, the knowledge of which makes it possible to implement single-frequency modes of its motion with sufficiently large deviations. For this purpose, asymptotic methods of nonlinear mechanics are used, which make it possible to determine the oscillation modes of the system in the first approximation within a weakly nonlinear model. The main features of the constructed nonlinear oscillation modes are discussed and their qualitative and quantitative differences from the traditional linear modes of small oscillations are revealed. In addition, it is noted that nonlinear oscillation modes can also be found on the basis of numerical simulation by accelerating the system under the action of collinear control from small deviations specified on a linear mode to finite amplitudes with access to single-frequency motion on a nonlinear mode. The obtained analytical expressions for the frequencies of nonlinear oscillations and the ratios of the oscillation amplitudes of the pendulum links for each of the nonlinear modes are compared with similar numerical dependencies by constructing graphic illustrations corresponding to them at the same level of total mechanical energy. It is established that the analytical and numerical results are in agreement with each other, which determines the value of the approximate solution constructed in the work. The formulas obtained and the conclusions drawn are of undoubted theoretical interest, and they may also be helpful for their use in specific practical purposes.

Key words: 
three-link mathematical pendulum
nonlinear oscillation mode
asymptotic methods
References: 
  1. Gribkov V. A., Khokhlov A. O. Experimental study of inverted regulable pendulum stability. Herald of the Bauman Moscow State Technical University. Series Natural Sciences, 2017, iss. 2 (71), pp. 22–39 (in Russian). https://doi.org/10.18698/1812-3368-2017-2-22-39, EDN: YJGTOR
  2. Arkhipova I. M. On stabilization of a triple inverted pendulum via vibration of a support point with an arbitrary frequency. Vestnik of the St. Petersburg University: Mathematics, 2019, vol. 52, iss. 2, pp. 194–198. https://doi.org/10.1134/S1063454119020031, EDN: DCCHMC
  3. Jibril M., Tadese M., Tadese E. A. Comparison of a triple inverted pendulum stabilization using optimal control technique. Report and Opinion, 2020, vol. 12, iss. 10, pp. 62–70. https://doi.org/10.7537/marsroj121020.10
  4. Anan’evskii I. M. The control of a three-link inverted pendulum near the equilibrium point. Mechanics of Solids, 2018, vol. 53, suppl. 1, pp. S16–S21. https://doi.org/10.3103/S0025654418030020, EDN: NIEIYE
  5. Gluck T., Eder A., Kugi A. Swing-up control of a triple pendulum on a cart with experimental validation. Automatica, 2013, vol. 49, iss. 3, pp. 801–808. https://doi.org/10.1016/j.automatica.2012.12.006
  6. Chen W., Theodomile N. Simulation of a triple inverted pendulum based on fuzzy control. World Journal of Engineering and Technology, 2016, vol. 4, iss. 2, pp. 267–272. https://doi.org/10.4236/wjet.2016.42026
  7. Hussein M. T. CAD design and control of triple inverted-pendulums system. The Iraqi Journal for Mechanical and Materials Engineering, 2018, vol. 18, iss. 3, pp. 481–497. https://doi.org/10.32852/iqjfmme.v18i3.183
  8. Huang X., Wen F., Wei Z. Optimization of triple inverted pendulum control process based on motion vision. EURASIP Journal on Image and Video Processing, 2018, vol. 2018, iss. 73, pp. 1–8. https://doi.org/10.1186/s13640-018-0294-6
  9. Ivanova A. I. On the stability of the equilibrium position of a three-link pendulum under the action of a follower force. Herald of the Bauman Moscow State Technical University. Series Natural Sciences, 2004, iss. 3 (14), pp. 19–26 (in Russian).
  10. Kovalchuk V. Triple inverted pendulum with a follower force: Decomposition on the equations of perturbed motion. Danish Scientific Journal, 2020, iss. 36-2, pp. 46–48. EDN: MWQFZL
  11. Evdokimenko A. P. Stability and branching of the relative equilibria of a three-link pendulum in a rapidly rotating frame of reference. Journal of Applied Mathematics and Mechanics, 2009, vol. 73, iss. 6, pp. 648–663. https://doi.org/10.1016/j.jappmathmech.2010.01.005, EDN: NAKFXN
  12. Awrejcewicz J., Kudra G., Lamarque C.-H. Investigation of triple pendulum with impacts using fundamental solution matrices. International Journal of Bifurcation and Chaos, 2004, vol. 14, iss. 2, pp. 4191–4213. https://doi.org/10.1142/S0218127404011818
  13. Smirnov A. S., Degilevich E. A. Oscillations of chain systems. St. Petersburg, Polytech-Press, 2021. 246 p. (in Russian). EDN: XIOEBN
  14. Agarana M. C., Akinlabi E. T. Mathematical modelling and analysis of human arm as a triple pendulum system using Euler–Lagragian model. IOP Conference Series: Materials Science and Engineering, vol. 413. The 2nd International Conference on Engineering for Sustainable World (ICESW 2018), July 9–13, 2018. Mechanical Engineering Department, Covenant University, Ota, Nigeria, 2018, art. 012010. https://doi.org/10.1088/1757-899X/413/1/012010
  15. Novozhilov I. V., Terekhov A. V., Zabelin A. V., Levik Yu. S., Shlykov V. Yu., Kazennikov O. V. Three-link mathematical model for the problem of stabilization of the vertical posture of a person. In: Novozhilov I. V., Kruchinin P. A. (eds.) Matematicheskoe modelirovanie dvizheniy cheloveka v norme i pri nekotorykh vidakh patologi [Mathematical modeling of human movements in normal conditions and in some types of pathology]. Moscow, Moscow University Press, 2005, pp. 7–20 (in Russian).
  16. Tyazhelov A. A., Kizilova N. N., Fischenko V. A., Yaremin S. Yu., Karpinsky M. Yu., Karpinskaya Ye. D. Analysis of posturography based on mathematical model of human body as multilink system. Travma [Injury], 2012, vol. 13, iss. 4, pp. 17–25 (in Russian). EDN: RBKNXF
  17. Loskutov Yu. V., Kudryavcev I. A. Determination of the maximum torque in the knee drive of exoskeleton during “sit-to-stand” and “stand-to-sit” movement. Vestnik of Volga State University of Technology. Series: Materials. Constructions. Technologies, 2018, iss. 3 (7), pp. 55–62 (in Russian). EDN: YZUYPZ
  18. Smirnov A. S., Smolnikov B. A. Resonance oscillations control of the non-linear mechanical systems based on the principles of biodynamics. Mashinostroenie i inzhenernoe obrazovanie [Mechanical Engineering and Engineering Education], 2017, iss. 4 (53), pp. 11–19 (in Russian). EDN: YNTDQY
  19. Bulov S. A., Smirnov A. S. Control of the oscillation modes of a three-link pendulum. In: Nedelya nauki FizMekh [Week of Science PhysMech]. Collection of articles of the All-Russian Scientific Conference (St. Petersburg, April 04–09, 2022). St. Petersburg, Polytech-Press, 2022, pp. 184–186 (in Russian). EDN: UGWRVB
  20. Smirnov A. S., Bulov S. A., Smolnikov B. A. Numerical simulation of nonlinear oscillation modes of a three-link manipulator. In: Evgrafov A. N., Popovich A. A. (eds.) Sovremennoe mashinostroenie: Nauka i obrazovanie [Modern Mechanical Engineering: Science and Education]. Proceedings of the 12th International Scientific Conference (St. Petersburg, June 22, 2023). St. Petersburg, Polytech-Press, 2023, pp. 117–133 (in Russian). EDN: IEOHKZ
  21. Bogolyubov N. N., Mitropol’skiy Yu. A. Asimptoticheskie metody v teorii nelineynykh kolebaniy [Asymptotic methods in the theory of nonlinear oscillations]. Moscow, GIFML, 1958. 408 p. (in Russian).
Received: 
09.09.2023
Accepted: 
15.10.2023
Published: 
29.11.2024
  • 414 reads