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Editor-in-Chief
Nikiforov
Vladimir O.
D.Sc., Prof.
Partners
doi: 10.17586/2226-1494-2020-20-1-141-146
MOTION EQUATION AVERAGING IN POTENTIAL AUTONOMOUS SYSTEMS
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Article in Russian
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Abstract
For citation:
Rymkevich P.P., Golovina V.V., Altukhov A.I. Motion equation averaging in potential autonomous systems. Scientific and Technical Journal of Information Technologies, Mechanics and Optics, 2020, vol. 20, no. 1, pp. 141–146 (in Russian). doi: 10.17586/2226-1494-2020-20-1-141-146
Abstract
Subject of Research. The paper proposes the averaging method of motion equations. In various branches of physics (mechanics, electrodynamics) and while analyzing vibration processes, we may need to average the existing equations of motion over a certain time scale. Most often it is required to consider processes in real time and to exclude high-frequency oscillations. In this case, the averaging procedure leads to the fact that the equations of motion for “slow” time change significantly their form. The usually applied arithmetic mean, i.e. equally all-time values in the given interval, does not solve the problem of determining the explicit form of the new motion equations for a “slow” time scale. Method. For the averaging procedure we propose to use the integral transformation with a smooth normalized kernel. The Gauss function is chosen as this kernel, because it “cuts off” adequately high frequencies and has convenient algebraic properties. The algebra based on these properties gives the possibility to solve efficiently the averaging problem and create a system of equations averaged over a certain scale. Main Results. It is shown that additional terms depending on this scale appear as a result of averaging over a certain small time scale. In contrast to the absence of velocities in the original system of motion equations, additional terms appear in the new averaged system depending not only on the coordinates, but also on the velocities. This fact explains the nature of dissipative forces. Moreover, in the created averaging algebra, the equations remain in their original form. Practical Relevance. The proposed method can be applied to any system of differential equations when it is necessary to obtain smoothed solutions. In particular, deformable solid mechanics and vibration mechanics are the proposed method application areas.
Keywords: potential system, ring, linear operator, commutative multiplication, averaging
References
References
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3. Novatckii V. Theory of elasticity. Moscow, Mir Publ., 1975, 435 p. (in Russian)
4. Mindlin R.D. Microstructures in linear elasticity. Mechanics. Translation book, 1964, vol. 86, no 4, pp. 129–160. (in Russian)
5. Green A.E., Rivlin R.S. Multipolar continuum mechanics. Archive for Rational Mechanics and Analysis, 1964, vol. 17, no. 2, pp. 133–147. doi: 10.1007/BF00253051
6. Kunin I. A. Elastic Media with Microstructure. Berlin, Springer- Verlag, 1982, 296 p. doi: 10.1007/978-3-642-81748-9
7. Blekhman I.I. Theory of Vibration Processes and Devices. Vibration Mechanics and Vibration Technology. St. Petersburg, Publishing house “Ore&Metals”, 2013, 640 p. (in Russian)
8. Ivanov K.S., Vaisberg L.A. New modelling and calculation methods for vibrating screens and separators. Lecture Notes in Mechanical Engineering, 2015, vol. 22. pp. 55–61. doi: 10.1007/978-3-319-15684-2_8
9. Demidov I.V., Vaisberg L.A., Blekhman I.I. Vibrational dynamics of paramagnetic particles and processes of separation of granular materials. International Journal of Engineering Science, 2019, vol. 141, pp. 141–156. doi: 10.1016/j.ijengsci.2019.05.002
10. Mikusinskii Ya. Operator Calculus. Moscow, Foreign Languages Publishing House, 1956, 366 p. (in Russian)
11. Ditkin V.A., Prudnikov A.P. Operational Calculus. Moscow, Vysshaja shkola Publ., 1975, 407 p. (in Russian)
12. Golovina V.V. Modeling and Prediction of Deformation Properties of Polymer Textile Materials. Dissertation for the degree of candidate of technical sciences. St. Petersburg, 2013, 168 p. (in Russian)
13. Rymkevich P.P. Introduction to properties propagation theory. Proc. XXVII Summer International School “Analysis and synthesis of nonlinear mechanics of oscillatory systems”, St. Petersburg, 2000, pp. 455–497. (in Russian)
14. Gorshkov A.S., Makarov A.G., Rymkevitch O.V., Rymkevitch P.P. Mathematical modelling of non− stationary heat transmission process through multi layered textile and clothing industry fabrics. Design. Materials. Technology, 2010, no. 4, pp. 116–118. (in Russian)
15. Rymkevich P.P., Gorshkov A.S. Transport Theory. St. Petersburg, SPbPU Publ., 2015, 120 p. (in Russian)
16. Maslov V.P. Method of Operators. Moscow, Nauka Publ., 1973, 621 p. (in Russian)
17. Feinman R.P. On the operator calculus applied in quantum electrodynamics. Problemy sovremennoj fiziki, 1955, vol. 3, pp. 37–79 (in Russian)
18. Karasev M.V., Maslov V.P. Nonlinear Poisson Brackets. Geometry and Quantization. Moscow, Nauka Publ., 1991, 365 p. (in Russian)
19. Karasev M.V. Weyl and ordered calculus of noncommuting operators. Mathematical Notes of the Academy of Sciences of the USSR, 1979, vol. 26, no. 6, pp. 945–958. doi: 10.1007/BF01142081
20. Maslov V.P. Application of the method of ordered operators to obtain exact solutions. Theoretical and Mathematical Physics, 1977, vol. 33, no. 2, pp. 960–976. doi: 10.1007/BF01036594
21. Berezin F.A. Quantization. Mathematics of the USSR-Izvestiya, 1974, vol. 8,no. 5,pp. 1109–1165.doi:10.1070/IM1974v008n05ABEH002140
22. Arsenin V.Ya. Mathematical Physics Methods and Special Functions. Moscow, Nauka Publ., 1974, 430 p. (in Russian)
