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Logical-dynamical controllers for multiply connected technical objects (on examples of gas-turbine engines)

  • Adaptive Control
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Abstract

We propose a design structure and conception for a logical-dynamical controller for separate subsystems of a multiply connected automatic control system for a complex technical object. Basing on the discrete analysis of the movement of the multiply connected control object towards its equilibrium state, we synthesize a double logical algorithm forming a logically corrected signal taking into account the influence of natural cross interfaces inside the object. Using the simulation modeling of the proposed logical-dynamical multiply connected automatic control system for an aviation gas-turbine engine, we confirm the efficiency of the double logical control algorithm authority for a complex technical object functioning under conditions of parametric and functional indefiniteness.

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References

  1. G. V. Dobryanskii and T. S. Mart’yanova, Dynamics of Aviation Gas Turbine Engines (Mashinostroenie, Moscow, 1989) [in Russian].

    Google Scholar 

  2. V. Yu. Rutkovskii, B. G. Il’yasov, and Yu. S. Kabal’nov, Adaptive Control Systems of Gas Turbine Engines of Aircrafts, Ed. by M. N. Krasil’shchikov (Mosk. Aviats. Inst., Moscow, 1994) [in Russian].

  3. S. N. Vasil’ev, B. G. Il’yasov, and R. A. Munasypov, Intelligent Systems of Management and Control of Gas Turbine Engines, Ed. by S. N. Vasil’ev (Mashinostroenie, Moscow, 2008) [in Russian].

  4. S. N. Vasil’ev, B. G. Il’yasov, and M. N. Krasil’shchikov, Problems of Control of Complex Dynamical Objects of Aviation and Space Technology, Ed. by S. N. Vasil’ev (Mashinostroenie, Moscow, 2015) [in Russian].

  5. B. MacIsaac and R. Langton, Gas Turbine Propulsion Systems (Wiley, Chichester, 2011).

    Book  Google Scholar 

  6. A. A. Uskov and A. V. Kuz’min, Intelligent Control Technology. Artificial Neural Networks and Fuzzy Logic (Goryachaya Liniya-Telekom, Moscow, 2004) [in Russian].

    Google Scholar 

  7. D. A. Beloglazov and E. Yu. Kosenko, “Study of stability of fuzzy management systems,” Izv. Yuzh. Fed. Univ., Tekh. Nauki, No. 2 (2013).

  8. B. G. Il’yasov, R. A. Munasypov, and G. A. Saitova, “Analysis of periodic motions in multivariable systems with fuzzy controllers in separate subsystems,” Mekhatron., Avtomatiz., Upravl., No. 8, 24–29 (2004).

    Google Scholar 

  9. S. V. Emel’yanov, “The way of obtaining complicated laws of control using only an error signal and its first derivative,” Avtom. Telemekh. 18, 873–885 (1957).

    Google Scholar 

  10. V. I. Petunin, “Methods of synthesis of logical-dynamic systems with the selector of control channels,” Aviakosm. Priborostroen., No. 11, 79–91 (2013).

    Google Scholar 

  11. R. C. Gaylord and W. N. Keller, “Attitude control system using logically controlled pulses,” Guidance Control 8, 629–648 (1962).

    Article  Google Scholar 

  12. S. N. Vasil’ev and A. I. Malikov, “On some results on stability of switched and hybride systems,” in Actual Problems of Continuous Media Mechanics, Collection of Articles, Dedicated to 20 Years of Inst. Math. Mech. Kazan. Scientific Center of RAS (Kazan, 2011), Vol. 1, pp. 23–81 [in Russian].

    Google Scholar 

  13. B. N. Petrov, B. A. Cherkasov, B. G. Il’yasov, and G. G. Kulikov, “Frequency method of analysis and synthesis of multidimensional systems of automatic control,” Dokl. Akad. Nauk SSSR 247, 304–307 (1979).

    MathSciNet  MATH  Google Scholar 

  14. B. G. Il’yasov and Yu. S. Kabal’nov, “An investigation into the stability of single-type multiply connected automatic control systems with holonomic ties between subsystems,” Autom. Remote Control 56, 1120–1125 (1995).

    MATH  Google Scholar 

  15. B. G. Il’yasov, G. A. Saitova, and A. Sh. Nazarov, “About one approach to design of adaptive multivariable automatic control systems of composite dynamic object,” Mekhatron., Avtomatiz., Upravl., No. 8, 13–20 (2010).

    Google Scholar 

  16. B. G. Il’yasov, G. A. Saitova, and I. I. Sabitov, “Logical control law of separate subsystem under the conditions of structural-parametric changes of multivariable object,” Nauka Obrazov., No. 11, 585–595 (2014). http://technomag.bmstu.ru/file/749785.html?__s=1. Accessed May 27, 2016.

    Google Scholar 

  17. B. G. Il’yasov and I. I. Sabitov, “Synthesis of multivariable automatic control systems with logical bonds between subsystems,” Sovrem. Probl. Nauki Obrazov., No. 1 (2015). http://www.science-education. ru/pdf/2015/1/251.pdf. Accessed May 27, 2016.

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Authors and Affiliations

  1. Ufa State Aviation Technical University, Ufa, Russia

    B. G. Ilyasov & I. I. Sabitov

Authors
  1. B. G. Ilyasov
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  2. I. I. Sabitov
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Correspondence to B. G. Ilyasov.

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Original Russian Text © B.G. Ilyasov, I.I. Sabitov, 2017, published in Izvestiya Akademii Nauk, Teoriya i Sistemy Upravleniya, 2017, No. 4, pp. 121–132.

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Ilyasov, B.G., Sabitov, I.I. Logical-dynamical controllers for multiply connected technical objects (on examples of gas-turbine engines). J. Comput. Syst. Sci. Int. 56, 668–680 (2017). https://doi.org/10.1134/S1064230717040104

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  • DOI: https://doi.org/10.1134/S1064230717040104

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