Research article Special Issues

Regularization of a final value problem for a linear and nonlinear biharmonic equation with observed data in $ L^{q} $ space

  • Received: 15 May 2022 Revised: 05 August 2022 Accepted: 21 August 2022 Published: 23 September 2022
  • MSC : 35A05, 35A08, 26A33, 35B05, 35B65, 35R11

  • In this work, we focus on the final value problem of an inverse problem for both linear and nonlinear biharmonic equations. The aim of this study is to provide a regularized method for the bi-harmonic equation, once the observed data are obtained at a terminal time in $ L^{q}(\Omega) $. We obtain an approximated solution using the Fourier series truncation method and the terminal input data in $ L^{q}(\Omega) $ for $ q \ne 2 $. In comparision with previous studies, the most highlight of this study is the error between the exact and regularized solutions to be estimated in $ L^{q}(\Omega) $; wherein an embedding between $ L^{q}(\Omega) $ and Hilbert scale spaces $ \mathcal{H}^{\rho}(\Omega) $ is applied.

    Citation: Anh Tuan Nguyen, Le Dinh Long, Devendra Kumar, Van Thinh Nguyen. Regularization of a final value problem for a linear and nonlinear biharmonic equation with observed data in $ L^{q} $ space[J]. AIMS Mathematics, 2022, 7(12): 20660-20683. doi: 10.3934/math.20221133

    Related Papers:

  • In this work, we focus on the final value problem of an inverse problem for both linear and nonlinear biharmonic equations. The aim of this study is to provide a regularized method for the bi-harmonic equation, once the observed data are obtained at a terminal time in $ L^{q}(\Omega) $. We obtain an approximated solution using the Fourier series truncation method and the terminal input data in $ L^{q}(\Omega) $ for $ q \ne 2 $. In comparision with previous studies, the most highlight of this study is the error between the exact and regularized solutions to be estimated in $ L^{q}(\Omega) $; wherein an embedding between $ L^{q}(\Omega) $ and Hilbert scale spaces $ \mathcal{H}^{\rho}(\Omega) $ is applied.



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