ANALYTICAL SYNTHESIS OF FORCED PULSE ELECTRONIC DRIVE CONTROL OF A TRACKING SYSTEM

The problem of analytical synthesis of a control signal by a linear dynamical system is considered. As an optimization criterion, it is proposed to consider the transition time of the system from the initial state to a given final state. This type of control is called forced, providing the maximum system speed. The principle of solving this problem is considered on the basis of application of uncertain Lagrange multipliers and the Pontryagin maximum principle. Expressions are obtained for the matrix of transitions of the system and the control signal in a vector form.

As an example, the electric drive described by the widespread second-order mathematical model is considered to evaluate the efficiency of the proposed method. Qualitative illustrations of the operability of the proposed approach, obtained by modeling in the Mathcad environment, and quantitative characteristics of the change in the input and output signals of the hypothetical control system are presented. It is shown that the use of forced control does not lead to the output of variables characterizing the state of the system, beyond the limits of admissible values.

The use of forced control makes it possible to synthesize the control law in the form of a sequence of rectangular pulses of constant amplitude determined by the power source, variable duty cycle and polarity. This approach can be used for the control of DC-type DC motors used in various tracking systems used on unmanned aerial vehicles. Key words: forced control, target function, electric drive, pulse train. The use of forced control makes it possible to synthesize the control law in the form of a sequence of rectangular pulses of constant amplitude determined by the power source, variable duty cycle and polarity. This approach can be used for the control of DC-type DC motors used in various tracking systems used on unmanned aerial vehicles.

1. Unmanned aerial vehicles. Fundamentals of the device and functioning / ed. I. S. Golubeva, I. K. Turkina. – Moscow: MAI, 2010. – 654 p.

2. Terekhov, V. M. Control systems of electric drives / В. М. Terekhov. – M.: Publishing Center «Academy», 2006. – 304 p.

3. Lobaty, A. A. Mathematical modeling of hybrid electrotechnical systems / А. А. Lobaty, Yu. N. Petrenko Yu. N., A. Elzeyn, S. Abufanas // Science and Technology. – 2016. – No. 4. – P. 322–328.

4. Lobaty, A. A. Impulse control of a hybrid electrical system / А. А. Lobaty, Yu. N. Petrenko Yu. N., A. Elzeyn, A. S. Abufanas // System Analysis and Applied Informatics, 2016. No. 4 (12). Pp. 46–51.

5. Sage, E. P. Optimum system management / EP. Sage, C. S. White. – Moscow: Radio and Communication, 1982. – 392 p.

6. Synthesis of regulators of automatic control systems / ed. K. A. Pupkov and N. D. Egurovaa. – Moscow: Izd. MSTU them. N. E. Bauman, 2004. – 616 p.

7. The theory of automatic control systems / under. Ed. V. L. Besekersky, E. P. Popova. – Moscow: Izd. St. Petersburg, 2003. – 747 p.

8. Kazakov, I. E. Methods for optimizing stochastic systems. Kazakov, D. I. Gladkov. – Moscow: Nauka, 1987. – 304 p.

9. Bryson, A. Applied theory of optimal control / A. Bryson, Ho Yushu. – Moscow: Mir, 1972. – 544 p.

10. Gulkov, G. I. Automatic control systems for electric drives / G. I. Gulkov, Yu. N. Petrenko, Т. V. Bachilo; under the Society. Ed. Yu. N. Petrenko. – Minsk: IVC of the Ministry of Finance, 2014. – 366 p.