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Discontinuity, Nonlinearity, and Complexity

Dimitry Volchenkov (editor), Dumitru Baleanu (editor)

Dimitry Volchenkov(editor)

Mathematics & Statistics, Texas Tech University, 1108 Memorial Circle, Lubbock, TX 79409, USA

Email: dr.volchenkov@gmail.com

Dumitru Baleanu (editor)

Cankaya University, Ankara, Turkey; Institute of Space Sciences, Magurele-Bucharest, Romania

Email: dumitru.baleanu@gmail.com


Reachability of Fractional Dynamical Systems with Distributed Delays in Control using $psi$-Hilfer Pseudo-Fractional Derivative

Discontinuity, Nonlinearity, and Complexity 13(4) (2024) 609--620 | DOI:10.5890/DNC.2024.12.003

A. Panneer Selvam, V. Govindaraj

Department of Mathematics, National Institute of Technology Puducherry, Karaikal - 609 609, India

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Abstract

This research investigates the reachability of linear and non-linear fractional dynamical systems with distributed delays in control using the $\psi$-Hilfer pseudo-fractional derivative in g-calculus. Grammian matrices, which are characterized by Mittag-Leffler functions, are used to provide necessary and sufficient criteria for reachability in the linear case, while Schauder's fixed point theorem is used to create sufficient conditions for reachability in the nonlinear case. A couple of numerical results is offered to explain the theoretical results.

References

  1. [1]  Liu, Y. and Wu, C. (2018), Global dynamics for an HIV infection model with Crowley-Martin functional response and two distributed delays, Mathematical Medicine and Biology, 31, 385-395.
  2. [2]  Avila, J.L., Bonnet, C., Clairambault, J., Özbay, H., Niculescu, S.I., Merhi, F., Tang, R., and Marie, J.P. (2012), A new model of cell dynamics in Acute Myeloid Leukemia involving distributed delays, IFAC Proceedings Volumes, 45(14), 55-60.
  3. [3]  Ozbay, H., Bonnet, C., and Clairambault, J. (2008), December. Stability analysis of systems with distributed delays and application to hematopoietic cell maturation dynamics, In 2008 47th IEEE Conference on Decision and Control, IEEE, 2050-2055.
  4. [4]  Huang, Z., Luo, X., and Yang, Q. (2007), Global asymptotic stability analysis of bidirectional associative memory neural networks with distributed delays and impulse, Chaos, Solitons and Fractals, 34, 878–885.
  5. [5]  Song, Q. and Cao, J. (2006), Stability analysis of Cohen–Grossberg neural network with both time-varying and continuously distributed delays Journal of Computational and Applied Mathematics, 197, 188-203.
  6. [6]  Zhang, L., Fan, R., Liu, A., and Xiao, L. (2013), Existence and stability of periodic solution for impulsive hopfield cellular neural networks with distributed delays, Applied Mechanics and Materials, 275, 2601-2605.
  7. [7]  Klamka, J. (1978), Relative controllability of non-linear systems with distributed delays in control, International Journal of Control, 28, 307-312.
  8. [8]  Balachandran, K., Kokila, J., and Trujillo, J.J. (2012), Relative controllability of fractional dynamical systems with distributed delays in control, Computers and Mathematics with Applications, 64, 3037-3045.
  9. [9]  Debbouche, A., Vadivoo, B.S., Fedorov, V.E., and Antonov, V. (2023), Controllability criteria for nonlinear impulsive fractional differential systems with distributed delays in controls. Mathematical and Computational Applications, 28, 13.
  10. [10] Selvam, A.P., Govindaraj, V., and Ahmad, H. (2024), Examining reachability criteria for fractional dynamical systems with mixed delays in control utilizing {$\psi$}-Hilfer pseudo-fractional derivative, Chaos, Solitons and Fractals, 181, 114702.
  11. [11]  Klamka, J. (1976), Relative controllability and minimum energy control of linear systems with distributed delays in control, IEEE Transactions on Automatic Control, 21(4), 594-595.
  12. [12]  Balachandran, K. (1983), Controllability of a class of nonlinear systems with distributed delays in control, International Journal of Institute of Information Theory and Automation, 19, 475-482.
  13. [13]  Balachandran, K., Karthikeyan, S., and Park, J.Y. (2009), Controllability of stochastic systems with distributed delays in control, International Journal of Control, 82, 1288-1296.
  14. [14]  Sousa, J.V.C., Vellappandi, M., Govindaraj, V., and Frederico, G.S. (2021), Reachability of fractional dynamical systems using $\psi$-Hilfer pseudo-fractional derivative, Journal of Mathematical Physics, 62(8), 082703.
  15. [15]  Babakhani, A., Yadollahzadeh, M., and Neamaty, A. (2018), Some properties of pseudo-fractional operators, Journal of Pseudo-Differential Operators and Applications, 9(3), 677-700.
  16. [16]  Panneer Selvam, A. and Govindaraj, V. (2022), Reachability of fractional dynamical systems with multiple delays in control using $\psi$-Hilfer pseudo-fractional derivative, Journal of Mathematical Physics, 63(10), 102706.
  17. [17]  Trzasko, W. (2008), Reachability and controllability of positive fractional discrete-time systems with delay, Journal of Automation, Mobile Robotics, and Intelligent Systems, 2(3), 43-47.
  18. [18]  Sajewski, L. (2016), Reachability, observability and minimum energy control of fractional positive continuous-time linear systems with two different fractional orders, Multidimensional Systems and Signal Processing, 27(1), 27-41.
  19. [19]  Rogowski, K. (2016), Reachability of standard and fractional continuous-time systems with constant inputs, Archives of Control Sciences, 26(2), 147-159.
  20. [20]  Kaczorek, T. (2008), Fractional positive continuous-time linear systems and their reachability, International Journal of Applied Mathematics and Computer Science, 18(2), 223-228.
  21. [21]  Kaczorek, T. (2009), Reachability of positive 2D fractional linear systems, Physica Scripta, 2009(T136), 1621-1631.
  22. [22]  Selvam, A.P., Vellappandi, M., and Govindaraj, V. (2023), Controllability of fractional dynamical systems with $\psi$-Caputo fractional derivative, Physica Scripta, 98(2), 025206.
  23. [23]  Panneer Selvam, A., and Govindaraj, V. (2024), Examining reachability of fractional dynamical systems with delays in control utilizing $ \psi-$Hilfer pseudo-fractional derivative, Physica Scripta, 99, 035225.
  24. [24]  Zhang, H., Cao, J., and Jiang, W. (2013), Reachability and controllability of fractional singular dynamical systems with control delay, Journal of Applied Mathematics, 2013(1), 1-10.
  25. [25]  Xu, D., Li, Y. and Zhou, W. (2014), Controllability and observability of fractional linear systems with two different orders, The Scientific World Journal, 2014, 1-8.
  26. [26]  Pap, E. (2002), Pseudo-additive measures and their applications, Handbook of Measure Theory, North-Holland, 1403-1468.
  27. [27]  Sousa, J.C. and Oliveira, E.C. (2018), On the $\psi$-Hilfer fractional derivative, Communications in Nonlinear Science and Numerical Simulation, 60, 72-91.
  28. [28]  Sousa, J.V.D.C., Frederico, G.S., and De Oliveira, E.C. (2020), $\psi$-Hilfer pseudo-fractional operator: new results about fractional calculus, Computational and Applied Mathematics, 39(4), 1-33.
  29. [29]  Cameron, R.H. and Martin, W.T. (1941), An unsymmetric Fubini theorem.
  30. [30]  Dauer, J.P. (1976), Nonlinear perturbations of quasi-linear control problems, Journal of Mathematical Analysis and Applications, 54, 717-725.