Design of Optimal Control Systems in the Frequency Domain by the Functional of the Generalized Work

   The paper considers the problem of analytical design of optimal controllers (ADOC) for one-dimensional linear stationary objects according to the functional of generalized work (FGW) A. A. Krasovsky. The use of FGW in comparison with the quadratic performance functional greatly simplifies the calculation of the optimal controller — the calculation of its matrix of coefficients mainly consists in solving the linear matrix Lyapunov equation, which, in contrast to the nonlinear matrix Riccati equation, fundamentally reduces the amount of calculations. In addition, the use of FGW provides the best stability margins of the designed system in terms of amplitude and phase. This work is devoted to the development of a method for solving the ADOC problem A. A. Krasovsky in the frequency (complex) domain, which reduces the determination of the transfer function coefficients of the optimal controller for an object of order n to the solution of the corresponding system of n linear algebraic equations. In this regard, the proposed method for solving the ADOC problem by A. A. Krasovsky differs by a much smaller amount of calculations in comparison with the standard method, in which the Lyapunov equation is solved with the desired matrix of dimensions n * n. The proposed method for the synthesis of optimal control systems, which has an analytical nature, became the basis for solving the inverse problem ADOC A. A. Krasovsky, which consists in determining the values of the weight coefficients of the FGW, which provide the given primary quality indicators of the synthesized control system. Using its relations, a relatively simple method for calculating the FGW coefficients based on the given values of the error coefficients for the designed dynamic system has been developed.

1. Krasovskii A. A. et al. Handbook on the theory of automatic control, Moscow, Nauka, 1987, 712 p (in Russian).

2. Krasovskii A. A. Automatic flight control systems and their analytical design, Moscow, Nauka, 1973, 558 p. (in Russian).

3. Filimonov N. B. The problem of the quality of management processes: a change in the optimization paradigm, Mekhatronika, Avtomatizatsiia, Upravlenie, 2010, no. 12, pp. 2—10 (in Russian).

4. Filimonov A. B., Filimonov N. B. Control of zeros and poles in the problems of synthesis of regulation systems. Part I. Compensation approach, Mekhatronika, Avtomatizatsiia, Upravlenie, 2020, no. 8, pp. 443—452 (in Russian).

5. Letov A. M. Analytical design of regulators. I, II, III, Avtomatika i telemekhanika, 1960, no. 4, pp. 406—411; no. 5, pp. 561—568; no. 6, pp. 661—665 (in Russian).

6. Letov A. M. Mathematical theory of control processes, Moscow, Nauka, 1981, 256 p. (in Russian).

7. Kalman R. E. Contributions to the Theory of Optimal Control, Boletin de la Sociedad Matematica Mexicana, 1960, vol. 5, no. 1, pp. 102—119.

8. Kalman R. E. When is a linear control system optimal? Journal of Basic Engineering (American Society of Mechanical Engineers), 1964, vol. 86, ser. D, iss.1, pp. 51—60.

9. Pupkov K. A., Egupov N. D., Filimonov N. B. et al. Methods of Classic and Modem Control Theory. Vol. 4. Theory of Optimization of Automatic Control Systems, Moscow, Publishing House of BMSTU, 2004, 744 p. (in Russian).

10. Solodovnikov V. V., Filimonov N. B. Dynamic Quality of Automatic Control Systems, Moscow, BMSTU, 1987, 84 p.

11. Aleksandrov A. G. Properties of Analytically Designed Linear Systems, Avtomatika i telemehanika, 1975, no. 10, pp. 5—11 (in Russian).

12. Aleksandrov A. G. Synthesis of regulators of multidimensional systems, Moscow, Mashinostroenie, 1986, 272 p. (in Russian).

13. Abdulaev N. D. Theory and methods of designing optimal controllers, Leningrad, Energoatomizdat, 1985, 240 p. (in Russian).

14. Petrov Ju. P. Synthesis of optimal control systems with incompletely known perturbing forces, Leningrad, Publishing house of Leningrad University, 1987, 290 p. (in Russian).

15. Gajduk A. R. Theory and methods of analytical synthesis of automatic control systems (polynomial approach), Moscow, Fizmatlit, 2012, 360 p. (in Russian).

16. Kim D. P. Algebraic methods for the synthesis of automatic control systems, Moscow, Fizmatlit, 2014, 164 p. (in Russian).

17. Janushevskij R. T. Theory of linear optimal multiply connected control systems, Moscow, Nauka, 1973, 464 p. (in Russian).

18. Lovchakov V. I., Shibjakin O. A. Modified Butterworth filters in solving the inverse problem of analytical design of optimal controllers, Mehatronika, Avtomatizacija, Upravlenie, 2021, no. 2, pp. 71—82 (in Russian).

19. Volgin L. N. Optimal discrete control of dynamical systems, Moscow, Nauka, 1986, 240 p. (in Russian).

20. Strejc V. State Space Theory of Discrete Linear Control. Translated by R. Major ACADEMIA/Prague 1981, 295 p.