Get 20M+ Full-Text Papers For Less Than $1.50/day. Start a 14-Day Trial for You or Your Team.

Learn More →

Reconstruction of a potential coefficient in the Rayleigh–Love equation with non-classical boundary condition

Reconstruction of a potential coefficient in the Rayleigh–Love equation with non-classical... The purpose of this paper is to reconstruct the potential numerically in the fourth-order Rayleigh–Love equation with boundary and nonclassical boundary conditions, from additional measurement.Design/methodology/approachAlthough, the aforesaid inverse identification problem is ill-posed but has a unique solution. The authors use the cubic B-spline (CBS) collocation and Tikhonov regularization techniques to discretize the direct problem and to obtain stable as well as accurate solutions, respectively. The stability, for the discretized system of the direct problem, is also carried out by means of the von Neumann method.FindingsThe acquired results demonstrate that accurate as well as stable solutions for the a(t) are accessed for λ∈ {10–8, 10–7, 10–6, 10–5}, when p ∈ {0.01%, 0.1%} for both linear and nonlinear potential coefficient a(t). The stability analysis shows that the discretized system of the direct problem is unconditionally stable.Research limitations/implicationsSince the noisy data are introduced, the investigation and analysis model real circumstances where the practical quantities are naturally infested with noise.Practical implicationsThe acquired results demonstrate that accurate as well as stable solutions for the a(t) are accessed for λ∈ {10–8, 10–7, 10–6, 10–5}, when p ∈ {0.01%, 0.1%} for both linear and nonlinear potential coefficient a(t). The stability analysis shows that the discretized system of the direct problem is unconditionally stable.Originality/valueThe potential term in the fourth-order Rayleigh–Love equation from additional measurement is reconstructed numerically, for the first time. The technique establishes that accurate, as well as stable solutions are obtained. http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Engineering Computations Emerald Publishing

Reconstruction of a potential coefficient in the Rayleigh–Love equation with non-classical boundary condition

Huntul, M.J.; Tamsir, Mohammad
Engineering Computations , Volume 39 (10): 17 – Dec 8, 2022
Download PDF
17 pages

Loading next page...
 
/lp/emerald-publishing/reconstruction-of-a-potential-coefficient-in-the-rayleigh-love-IS7f5tRTzC
Publisher
Emerald Publishing
Copyright
© Emerald Publishing Limited
ISSN
0264-4401
DOI
10.1108/ec-01-2022-0010
Publisher site
See Article on Publisher Site

Abstract

The purpose of this paper is to reconstruct the potential numerically in the fourth-order Rayleigh–Love equation with boundary and nonclassical boundary conditions, from additional measurement.Design/methodology/approachAlthough, the aforesaid inverse identification problem is ill-posed but has a unique solution. The authors use the cubic B-spline (CBS) collocation and Tikhonov regularization techniques to discretize the direct problem and to obtain stable as well as accurate solutions, respectively. The stability, for the discretized system of the direct problem, is also carried out by means of the von Neumann method.FindingsThe acquired results demonstrate that accurate as well as stable solutions for the a(t) are accessed for λ∈ {10–8, 10–7, 10–6, 10–5}, when p ∈ {0.01%, 0.1%} for both linear and nonlinear potential coefficient a(t). The stability analysis shows that the discretized system of the direct problem is unconditionally stable.Research limitations/implicationsSince the noisy data are introduced, the investigation and analysis model real circumstances where the practical quantities are naturally infested with noise.Practical implicationsThe acquired results demonstrate that accurate as well as stable solutions for the a(t) are accessed for λ∈ {10–8, 10–7, 10–6, 10–5}, when p ∈ {0.01%, 0.1%} for both linear and nonlinear potential coefficient a(t). The stability analysis shows that the discretized system of the direct problem is unconditionally stable.Originality/valueThe potential term in the fourth-order Rayleigh–Love equation from additional measurement is reconstructed numerically, for the first time. The technique establishes that accurate, as well as stable solutions are obtained.

Journal

Engineering ComputationsEmerald Publishing

Published: Dec 8, 2022

Keywords: Fourth-order Rayleigh–Love equation; Inverse problem; CBS functions; Collocation technique; Tikhonov regularization; Nonlinear optimization; Stability analysis

References

  • An inverse source problem for the wave equation. Nonlinear analysis: theory
    Bui, A.T.
  • An inverse problem for an unknown source term in a wave equation
    Cannon, J.R.; DuChateau, P.
  • An interior trust region approach for nonlinear minimization subject to bounds
    Coleman, T.F.; Li, Y.
  • A finite element formulation for the determination of unknown boundary conditions for three-dimensional steady thermoelastic problems
    Dennis, B.H.; Dulikravich, G.S.; Yoshimura, S.
  • A collocation technique based on modified form of trigonometric cubic B-spline basis functions for Fisher's reaction-diffusion equation
    Dhiman, N.; Tamsir, M.
  • Inverse problems for general second order hyperbolic equations with time-dependent coefficients
    Eskin, G.
  • Theory of free and forced vibrations of a rigid rod based on the Rayleigh model
    Fedotov, I.A.; Polyanin, A.D.; Shatalov, M.Y.
  • Solutions to Rayleigh–Love equation with constant coefficients and delay forcing term
    Gupta, N.; Maqbul, M.
  • Analysis of discrete ill-posed problems by means of the L-curve
    Hansen, P.C.
  • Determination of a time-dependent potential in the higher-order pseudo-hyperbolic problem
    Huntul, M.J.
  • Identifying an unknown heat source term in the third-order pseudo-parabolic equation from nonlocal integral observation
    Huntul, M.J.
  • Simultaneous reconstruction of time-dependent coefficients in the parabolic equation from over-specification conditions
    Huntul, M.J.
  • Recovery of timewise-dependent heat source for hyperbolic PDE from an integral condition
    Huntul, M.J.; Tamsir, M.
  • Identifying an unknown potential term in the fourth-order Boussinesq-Love equation from mass measurement
    Huntul, M.; Tamsir, M.
  • Reconstructing an unknown potential term in the third-order pseudo-parabolic problem
    Huntul, M.J.; Dhiman, N.; Tamsir, M.
  • An inverse problem of determining the time-dependent potential in a higher-order Boussinesq-Love equation from boundary data
    Huntul, M.J.; Tamisr, M.; Ahmadini, A.
  • On an inverse boundary value problem for the Boussinesq-Love equation with an integral Condition
    Isgendarov, N.S.; Mehraliyev, Y.T.; Huseyinova, A.F.
  • Inverse source problem for the hyperbolic equation with a time-dependent principal part
    Jiang, D.; Liu, Y.; Yamamoto, M.
  • Documentation optimization toolbox-least squares algorithms
  • Inverse boundary value problem for a Boussinesq type equation of fourth order with nonlocal time integral conditions of the second kind
    Megraliev, Y.T.; Alizade, F.K.
  • On solvability of an inverse boundary value problem for pseudo hyperbolic equation of the fourth order
    Mehraliyev, Y.T.; Huseynova, A.F.
  • On the solution of functional equations by the method of regularization
    Morozov, V.A.
  • Property C and an inverse problem for a hyperbolic equation
    Ramm, A.; Rakesh
  • Determination of time-dependent coefficients for a hyperbolic inverse problem
    Salazar, R.
  • Recovery of a source term or a speed with one measurement and applications
    Stefanov, P.; Uhlmann, G.
  • Determination of a time-dependent coefficient in a wave equation with unusual boundary condition
    Tekin, I.
  • Reconstruction of a time-dependent potential in a pseudo-hyperbolic equation
    Tekin, I.
  • Determination of a time-dependent potential in a Rayleigh-Love equation with non-classical boundary condition
    Tekin, I.
  • Stability charts in the numerical approximation of partial differential equations: a review
    Vichnevetsky, R.
  • Stability, reconstruction formula and regularization for an inverse source hyperbolic problem by a control method
    Yamamoto, M.
  • Inverse boundary-value problem for an integro-differential Boussinesq-type equation with degenerate kernel
    Yuldashev, T.K.
  • Inverse problem for the Boussinesq – Love mathematical model
    Zamyshlyaeva, A.A.; Lut, A.V.; Banasiak, J.; Bobrowski, A.; Lachowicz, M.; Tomilov, Y.