[ Log In | Register]
! Skip Navigation Links
Skip Navigation Links
Image of Journal of Applied Nonlinear Dynamics
ISSN:2164-6457 (print)
ISSN:2164-6473 (online)
Journal of Applied Nonlinear Dynamics
Miguel A. F. Sanjuan (editor), Albert C.J. Luo (editor)
Miguel A. F. Sanjuan (editor)

Department of Physics, Universidad Rey Juan Carlos, 28933 Mostoles, Madrid, Spain

Email: miguel.sanjuan@urjc.es

Albert C.J. Luo (editor)

Department of Mechanical and Industrial Engineering, Southern Illinois University Ed-wardsville, IL 62026-1805, USA

Fax: +1 618 650 2555 Email: aluo@siue.edu

Well-Posedness and Exponential Decay of the Thermoelastic Full Von K'arm'an Beam with Second Sound and Discrete Delay Term

Journal of Applied Nonlinear Dynamics 13(1) (2024) 1--12 | DOI:10.5890/JAND.2024.03.001

Lamine Bouzettouta$750000@yahoo.fr}

Laboratory of Applied Mathematics and History and Didactics of Mathematics (LAMAHIS) University of 20 August 1955, Skikda, Algeria

Download Full Text PDF

 

Abstract

The stabilization of one-dimensional thermoelastic system of full von Kármán beam with a delayed linear frictional damping is considered, where the heat fux is given by Cattaneo's law. Under suitable assumption on the weight of the delay and that of frictional damping, we prove that the system is exponentially stable. The idea here, is to generalize some previous existing results by considering a delayed problem.

Acknowledgments

The authors wish to thank deeply the anonymous supervisor for his/her useful remarks and his/her careful reading of the proofs presented in this paper.

References

  1. [1]  Haraux, A., Martinez, P., and Vancostenoble, J. (2005), Asymptotic stability for intermittently controlled second order evolution equations, SIAM Journal on Control and Optimization, 43, 2089-2108.
  2. [2]  Guesmia, A. (2013), Well-posedness and exponential stability of an abstract evolution equation with infinite memory and time delay, IMA Journal of Mathematical Control and Information, 30, 507-526.
  3. [3]  Ammari, K., Nicaise, S., and Pignotti, C. (2010), Feedback boundary stabilization of wave equations with interior delay, Systems and Control Letters, 59, 623-628.
  4. [4]  Nicaise, S. and Pignotti, C. (2006), Stability and instability results of the wave equation with a delay term in the boundary or internal feedbacks, SIAM Journal on Control and Optimization, 45(5), 1561-1585.
  5. [5]  Datko, R. (1991), Two questions concerning the boundary control of certain elastic systems, Journal of Differential Equations, 1 , 27-44.
  6. [6]  Foughali, F., Zitouni, S., Khochemane, H.E., and Djebabla, A. (2020), Well-posedness and exponential decay for a porous-thermoelastic system with second sound and a distributed delay term, Mathematics in Engineering, Science And Aerospace, 11(4), 1003-1020.
  7. [7]  Khochemane, H.E., Bouzettouta, L. and Guerouah, A. (2021), Exponential decay and well-posedness for a one-dimensional porous-elastic system with distributed delay, Applicable Analysis, 100(14), 2950-2964.
  8. [8]  Khochemane, H.E., Zitouni, S., and Bouzettouta, L. (2020), Stability result for a nonlinear damping porous-elastic system with delay term, Nonlinear Studies, 27(2), 487-503.
  9. [9]  Guesmia, A. (2015), Some well-posedness and stability results for abstract hyperbolic equations with infinite memory and distributed time delay, Communications on pure and Aapplied analysis, 14(2), 1-35.
  10. [10]  Apalara, T.A. (2014), Well-posedness and exponential stability for a linear damped Timoshenko system with second sound and internal distributed delay, Electronic Journal of Differential Equations, 254, 1-15.
  11. [11]  Benabdallah, A. and Teniou, D. (1998), Exponential stability of a Von K{a}rm{a}n model with thermal effects, electron, Journal of Differential Equations, 07, 1-13.
  12. [12]  Benabdallah, A. and Lasiecka, L. (2000), Exponential decay rates for a full von K{a}rm{a}n system of dynamic thermoelasticity, Journal of Differential Equations, 160, 51-93.
  13. [13]  Perla Menzala, G. and Zuazua, E. (2000), Timoshenko beam equation as limit of a nonlinear one-dimensional von K{a}rm% {a}n system, Proceedings of the Royal Society of Edinburgh Section A: Mathematics, A 130, 855-875.
  14. [14]  Djebabla, A. and Tatar, N.E. (2013), Exponential stabilization of the full von K{a}rm{a}n beam by a thermal effect and a frictional damping, Georgian Mathematical Journal, 20, 427-438.
  15. [15]  Liu, W., Chen, K., and Yu, J. (2015), Existence and general decay for the full von K{a}rm{a}n beam with a thermo-viscoelastic damping, frictional dampings and a delay term, IMA Journal of Mathematical Control and Information, 1-22.
  16. [16]  Bouzettouta, L. and Djebabla, A. (2019), Exponential stabilization of the full von K{a}rm{a}n beam by a thermal effect and a frictional damping and distributed delay, Journal of mathematical physics, 60, 041506, DOI:10.1063/1.5043615.
  17. [17]  Lasiecka, L. (1999), Uniform decay rates for a full von K{a}rm{a}n system of dynamics thermoelasticity with free boundary conditions and partial boundary dissipation, Communications in Partial Differential Equations, 24(9-10), 1801-1847.
  18. [18]  Perla Menzala, G., Pazoto, A.F., and Zuazua, E. (2002), Stabilization of Berger-Timoshenko's equation as limit of the uniform stabilization of the Von K{a}rm{a}n system of beams and plates, ESAIM, Mathematical Modelling and Numerical Analysis, 36(4), 657-691.

Copyright © 2011-2024 L & H Scientific Publishing. All rights reserved. Wildcard SSL Certificates