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General decay for a system of viscoelastic wave equation with past history, distributed delay and Balakrishnan-Taylor damping terms

  • Received: 25 June 2022 Revised: 12 August 2022 Accepted: 22 August 2022 Published: 29 August 2022
  • The subject of this research is a coupled system of nonlinear viscoelastic wave equations with distributed delay components, infinite memory and Balakrishnan-Taylor damping. Assume the kernels $ g_{i} :{\bf R}_{+}\rightarrow {\bf R}_{+} $ holds true the below

    $ g_{i}'(t)\leq-\zeta_{i}(t)G_{i}(g_{i}(t)), \quad \forall t\in {\bf R}_{+}, \quad {\rm{for}} \quad i = 1, 2, $

    in which $ \zeta_{i} $ and $ G_{i} $ are functions. We demonstrate the stability of the system under this highly generic assumptions on the behaviour of $ g_i $ at infinity and by dropping the boundedness assumptions in the historical data.

    Citation: Abdelbaki Choucha, Salah Boulaaras, Djamel Ouchenane, Salem Alkhalaf, Rashid Jan. General decay for a system of viscoelastic wave equation with past history, distributed delay and Balakrishnan-Taylor damping terms[J]. Electronic Research Archive, 2022, 30(10): 3902-3929. doi: 10.3934/era.2022199

    Related Papers:

  • The subject of this research is a coupled system of nonlinear viscoelastic wave equations with distributed delay components, infinite memory and Balakrishnan-Taylor damping. Assume the kernels $ g_{i} :{\bf R}_{+}\rightarrow {\bf R}_{+} $ holds true the below

    $ g_{i}'(t)\leq-\zeta_{i}(t)G_{i}(g_{i}(t)), \quad \forall t\in {\bf R}_{+}, \quad {\rm{for}} \quad i = 1, 2, $

    in which $ \zeta_{i} $ and $ G_{i} $ are functions. We demonstrate the stability of the system under this highly generic assumptions on the behaviour of $ g_i $ at infinity and by dropping the boundedness assumptions in the historical data.



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