Multicriteria Parametric Optimization of Nonlinear Robust Control with Two Degrees of Freedom by a Discrete-Continuous Plant
-
Published:2023-09-30
Issue:3
Volume:26
Page:42-53
-
ISSN:2709-2984
-
Container-title:Journal of Mechanical Engineering
-
language:
-
Short-container-title:J. of Mech. Eng.
Author:
Kuznetsov Borys I.ORCID, , Bovdui Ihor V.ORCID, Voloshko Olena V.ORCID, Nikitina Tetyana B.ORCID, Kobylianskyi Borys B.ORCID, , , ,
Abstract
A multicriteria parametric optimization of nonlinear robust control with two degrees of freedom by a discrete-continuous plant has been developed to increase accuracy and reduce sensitivity to uncertain plant parameters. Such plants are mounted on a moving base, on which sensors for angles, angular velocities and angular accelerations are installed. To increase the accuracy of control, systems with two degrees of freedom, which include control with feedback and a closed-loop, and with direct connections and open-loop control of the setting and disturbing effects, are used. The multicriteria optimization of nonlinear robust control with two degrees of freedom by a discrete-continuous plant is reduced to the solution of the Hamilton-Jacobi-Isaacs equations. The robust control target vector is calculated as a solution of a zero-sum antagonistic vector game. The vector payoffs of this game are direct indexes performance vector presented in the system in different modes of its operation. The calculation of the vector payoffs of this game is related to the simulation of the synthesized nonlinear system for different operating modes of the system, input signals and values of the plant parameters. The solutions of this vector game are calculated on the basis of the system of Pareto-optimal solutions, taking into account the binary relations of preferences, on the basis of the stochastic metaheuristic of Archimedes optimization algorithm by several swarms. Thanks to the synthesis of nonlinear robust control with two degrees of freedom by a discrete-continuous object, it is shown that the use of synthesized controllers made it possible to increase the accuracy of control of an electromechanical system with distributed parameters of the mechanical part to reduce the time of transient processes by 1.5–2 times, reduce dispersion of errors by 1.3 times and reduce the sensitivity of the system to changes in the plant parameters in comparison with typical controllers used in existing systems. Further improvement of control accuracy is restrained by energy limitations of executive mechanisms and information limitations of measuring devices.
Publisher
National Academy of Sciences of Ukraine (Co. LTD Ukrinformnauka) (Publications)
Reference15 articles.
1. 1. Sushchenko, O., Averyanova, Yu., Ostroumov, I., Kuzmenko, N., Zaliskyi, M., Solomentsev, O., Kuznetsov, B., Nikitina, T., Havrylenko, O., Popov, A., Volosyuk, V., Shmatko, O., Ruzhentsev, N., Zhyla, S., Pavlikov, V., Dergachov, K., & Tserne, E. (2022). Algorithms for design of robust stabilization systems. In: Gervasi, O., Murgante, B., Hendrix, E. M. T., Taniar, D., Apduhan, B. O. (eds.) Computational Science and Its Applications - ICCSA 2022. Lecture Notes in Computer Science, vol. 13375. Cham: Springer, pp. 198-213. https://doi.org/10.1007/978-3-031-10522-7_15. 2. 2. Shmatko, O., Volosyuk, V., Zhyla, S., Pavlikov, V., Ruzhentsev, N., Tserne, E., Popov, A., Ostroumov, I., Kuzmenko, N., Dergachov, K., Sushchenko, O., Averyanova, Yu., Zaliskyi, M., Solomentsev, O., Havrylenko, O., Kuznetsov, B., & Nikitina, T. (2021). Synthesis of the optimal algorithm and structure of contactless optical device for estimating the parameters of statistically uneven surfaces. Radioelectronic and Computer Systems, no. 4, pp. 199-213. https://doi.org/10.32620/reks.2021.4.16. 3. 3. Volosyuk, V., Zhyla, S., Pavlikov, V., Ruzhentsev, N., Tserne, E., Popov, A., Shmatko, O., Dergachov, K., Havrylenko, O., Ostroumov, I., Kuzmenko, N., Sushchenko, O., Averyanova, Yu., Zaliskyi, M., Solomentsev, O., Kuznetsov, B., & Nikitina, T. (2022). Optimal method for polarization selection of stationary objects against the background of the Earth's surface. International Journal of Electronics and Telecommunications, vol. 68, no. 1, pp. 83-89. https://doi.org/10.24425/ijet.2022.139852. 4. 4. Martynenko, G. (2020). Analytical method of the analysis of electromagnetic circuits of active magnetic bearings for searching energy and forces taking into account control law. Conference proceedings of the 2020 IEEE KhPI Week on Advanced Technology (IEEE KhPIWeek 2020), Ukraine, Kharkiv, October 5-10, 2020, pp. 86-91, https://doi.org/10.1109/KhPIWeek51551.2020.9250138. 5. 5. Martynenko, G. & Martynenko, V. (2020). Rotor dynamics modeling for compressor and generator of the energy gas turbine unit with active magnetic bearings in operating modes. Proceedings of the 25th IEEE International Conference on Problems of Automated Electric Drive. Theory and Practice (IEEE PAEP 2020), Ukraine, Kremenchuk, September 21-25, 2020, pp. 1-4. https://doi.org/10.1109/PAEP49887.2020.9240781.
|
|