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Complex Discrete Systems Graph Simulation

  • Received : 2015.08.11
  • Accepted : 2015.11.02
  • Published : 2015.09.30
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Abstract

The subject of this work is the complex discrete systems simulation special features with the aid of dynamic graph models. The proposed simulation technique allows to determine the ways for tasks solutions in terms of discrete systems analysis and synthesis of various complication: one-dimensional and multidimensional, steady and unstable, with the pulse elements abnormal operating mode and others. Often complex control systems analysis and synthesis task solutions, via classical approach comes out to be insolvent, because of the computational problems. The application of graph models allows to perform clear and strict characterization and computer procedures automation. The optimal controls synthesis algorithm presented in this paper, transferring the discrete system from target initial state to target final state within the minimum time, allows to consider the zero initial conditions systems, with the initial potential energy, with the control actions limitations and complex pulse elements operating mode.

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References

  1. Tu Yu, Current Control Theory. Transl. from eng. Under the editorship V.V.Solodovnikov. Moscow: Engineering, 1971.
  2. L. T. Kuzin, Calculation and Design of Discrete Control Systems. Moscow: Mashgiz, 1962.
  3. S. Mezon and Zimmerman, Electronic Circuits, Signals and Systems. Transl. from eng. Moscow: Foreign literature, 1963.
  4. A. A. Kadirov, Dynamic Graph Models in Control Systems. Tashkent: Fun, 1984.
  5. V. N. Fomin, Methods of Control by Linear Discrete Objects. Leningrad: LSU, 1985.
  6. L. N. Volgin, The optimal discrete control by dynamic systems. -M.: Science, 1986.
  7. V.M. Matrosov, S.N. Vasiliev and A.I. Moskalenko, Nonlinear control theory: dynamics, control, optimization. Under the editorship. Moscow: Physmatlit, 2003.
  8. Ling Hou and Anthony N. Michel, "Unifying theory for stability of continuous, discontinuous, and discretetime dynamical systems," Nonlinear Analysis: Hybrid Systems , vol. 1, no. 2, pp. 154-172, 2007. https://doi.org/10.1016/j.nahs.2006.10.002
  9. Rafal Goebel, G. Ricardo. Sanfelice and Andrew R. Teel, Hybrid Dynamical Systems. PrincetonUniversity Press, 2012. 227 p.
  10. D. Mignone, "Control and Estimation of Hybrid Systems with Mathematical Optimization," A dissertation submitted to the Swiss Federal Institute of Technology (ETH), Zurich for the degree of Dr. sc. techn., 2002.
  11. A.A. Kadirova, The Modeling Methods and Research of Nonlinear and Logical-Dynamic Control Systems. Tashkent: Yangi Asr Avlodi, 2010.