Features of application of sensitivity theory for analysis of influence of parametric disturbances on dynamic properties electromechanical converters

At the design and testing stage of electromechanical converters, the analysis of the influence of parametric perturbations on the dynamic properties of an object using sensitivity theory, which allows to evaluate the quality of operation of electrical machines depending on operating conditions, is relevant. Based on the system of differential equations of a DC motor, the sensitivity equations of the corresponding coordinates were obtained in three parameters. A vector structural scheme of the sensitivity model has been formed, as well as the Simulink-model, with the help of which sensitivity function plots were obtained, which determine the additional motion of the object of study when parameters change within specified limits. It is shown that the largest steady-state values of the sensitivity functions correspond to changes in the moment of inertia. It is revealed that the influence of the moment of inertia on the coordinates of the object of study is the most significant. Where in the coordinate most sensitive to variations in parameters is the rotation speed of the electromechanical converter. The problem of statistical analysis of errors of the output coordinates of a DC motor under the assumption of normal distribution of parametric disturbances was also solved. Simulations were carried out and dispersions and relative estimates of the influence of variable parameters were calculated, and graphs were obtained to estimate the degree of influence of parametric disturbances.

1. Kislitsyn AL. Questions of the theory and design of electrical machines. Parameters and characteristics of electric cars in static and dynamic modes. Collection of scientific papers. Ulyanovsk State Technical University. Ulyanovsk: UlGTU, 2017. 304 p.

2. Yusupov RM, Kosteltsev VI. Perturbations of the structure and sensitivity functions of mathematical models with their algorithmization. Theses of reports. V.1. 5 St. Petersburg Conference “Regional Informatics-96”).1996.

3. Yusupov RM, Gromyko PS, Panchenko AE. Investigation of the effectiveness of complex systems by the methods of sensitivity theory and correlation analysis. Questions of cybernetics. The theory of sensitivity and its application: Sat. scientific papers. Academy of Sciences of the USSR. 1981.

4. Zorzi M. Multivariate Spectral Estimation based on the concept of Optimal Prediction, IEEE Trans. Automat. Control. 2015;60:1647-1652.

5. Levy BC and Nikoukhah R. Robust state-space filtering under incremental model perturbations subject to a relative entropy tolerance, IEEE Trans. Automat. Control. 2013;58:682-695.

6. Ivanov AN, Kuznetsov PM. Identification of dynamic systems based on nonlinear matrix Li transformation. Bulletin of Ufa State Aviation Technical University. 2014;18:2 (63):237-242.

7. Garkina IA, Danilov AM, Tyukalov DE. Complex systems: identification of dynamic characteristics, disturbances and interferences. Modern problems of science and education. 2015;1(1):88.

8. Malev NA, Mukhametshin AI, Pogoditsky OV, et al. Experimental-analytical identification of a mathematical model of a dc motor using the least squares method. Power engineering: research, equipment, technology. 2019;21(4):113-122.

9. Malev NA, Pogoditsky OV. Statistical analysis of dynamic characteristics asynchronous electric motor with changing load parameters. Proceedings of the higher educational institutions. Energy sector problems. 2019;21 (1-2):120-130.

10. Malev NA, Pogoditsky OV. Research and synthesis of the modal regulator of the two-mass electromechanical system of the crane lifting mechanism. Proceedings of the higher educational institutions. Energy sector problems. 2018;20(7-8):99-106.

11. Furtat I. Dynamic compensation of disturbances in the condition of control signal saturation. Control of large systems. 2017;6:24-40.

12. Furtat I, Fradkov A, Tsykunov A. Robust synchronization of linear dynamical systems with compensation of disturbances. Int. J. Robust and Nonlinear Control. 2014;24(17):2774-2784.

13. Polyak BT, Tremba AA, Khlebnikov MV, et al. Large deviations in linear systems with non-zero initial conditions. Automation and Remote Control. 2015;6:18-41.

14. Kuznetsov BI, Nikitina TB, Kolomiets VV, et al. Investigation of the influence of nonlinearities and variations in the parameters of the control object on the dynamic characteristics of electromechanical servo systems. Visnik NTU "KhPI". 2015;12(1121):68-71.

15. Ivashin VV, Penchev VP. Features of the dynamics of work and energy diagrams of a pulsed electromagnetic drive with parallel and series connection of the excitation windings. Electrical Engineering. 2013;6:42-46.

16. Pabitra Kumar Behera, Manoj Kumar Behera, Amit Kumar Sahoo. Speed Control of Induction Motor using Scalar Control Technique. International Journal of Computer Applications. Proceedings on International Conference on Emergent Trends in Computing and Communication ETCC. 2014;1:37-39.

17. Rojas-Moreno A. Parameter extraction of an induction motor with gearbox for dynamic simulation. 2016 IEEE ANDESCON. 2016. pp. 1-4.

18. Pradeep Kumar, Mandeep Kumar, Surender Dahiya. Sensor Less Speed Control of PMSM using SVPWM Technique Based on MRAS Method for Various Speed and Load Variations. Proceedings of the World Congress on Engineering. 2015. pp. 198-204.