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Applicable Analysis
An International Journal
Volume 102, 2023 - Issue 18
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Research Article

The backward problem of a stochastic PDE with bi-harmonic operator driven by fractional Brownian motion

Xiaoli FengSchool of Mathematics and Statistics, Xidian University, Xi'an, People's Republic of ChinaCorrespondence[email protected]
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Chen ChenSchool of Mathematics and Statistics, Xidian University, Xi'an, People's Republic of ChinaView further author information
Pages 4972-4996 | Received 10 May 2022, Accepted 22 Nov 2022, Published online: 01 Dec 2022

References

  • Gong Y, Xu X. Inverse random source problem for biharmonic equation in two dimensions. Inverse Probl Imag. 2019;13:635–652.
  • Li PJ, Yao X, Zhao Y. Stability for an inverse source problem of the biharmonic operator. SIAM J Appl Math. 2021;81:2503–2525.
  • Pausader B. Scattering for the defocusing beam equation in low dimensions. Ind Univ Math J. 2010;59:791–822.
  • Gazzola F, Sweers G, Grunau HC. Polyharmonic boundary value problems, lecture notes in mathematics, positivity preserving and nonlinear higher order elliptic equations in bounded domains, lecture notes in mathematics. Berlin: Springer-Verlag; 2010.
  • Movchan NV, McPhedran RC, Movchan AB, et al. Wave scattering by platonic grating stacks. Proc R Soc A. 2009;465:3383–3400.
  • Assylbekov YM. Inverse problems for the perturbed polyharmonic operator with coefficients in Sobolev spaces with non-positive order. Inverse Probl. 2016;32:105009.
  • Choudhury A, Heck H. Stability of the inverse boundary value problem for the biharmonic operator: logarithmic estimates. J Inverse Ill-Posed Probl. 2017;25:251–263.
  • Isakov V. Completeness of products of solutions and some inverse problems for PDE. J Differ Equ. 1991;92:305–316.
  • Krupchyk K, Lassas M, Uhlmann G. Inverse boundary value problems for the perturbed polyharmonic operator. Trans Am Math Soc. 2014;366:95–112.
  • Lassas M, Krupchyk K, Uhlmann G. Determining a first order perturbation of the biharmonic operator by partial boundary measurements. J Funct Anal. 2012;262:1781–1801.
  • Aktosun T, Papanicolaou V. Time evolution of the scattering data for a fourth-order linear differential operator. Inverse Probl. 2008;24:055013.
  • Iwasaki K. Scattering theory for 4th order differential operators: I. Jpn J Math Vol. I. 1988;14:1–57.
  • Iwasaki K. Scattering theory for 4th order differential operators: II. Jpn J Math Vol. II. 1988;14:59–96.
  • Tyni T, Harju M, Serov V. Recovery of singularities in a fourth-order operator on the line from limited data. Inverse Probl. 2016;32:075001.
  • Tyni T, Serov V. Scattering problems for perturbations of the multidimensional biharmonic operator. Inverse Probl Imag. 2018;12:205–227.
  • Assylbekov YM, Iyer K. Determining rough first order perturbations of the polyharmonic operator. Inverse Probl Imag. 2019;13(5):1045–1066.
  • Assylbekov YM, Yang Y. Determining the first order perturbation of a polyharmonic operator on admissible manifolds. J Differ Equ. 2017;262(1):590–614.
  • Ghosh T. An inverse problem on determining upto first order perturbations of a fourth order operator with partial boundary data. Inverse Probl. 2015;31(10):105009.
  • Krupchyk K, Lassas M, Uhlmann G. Determining a first order perturbation of the biharmonic operator by partial boundary measurements. J Funct Anal. 2012;262(4):1781–1801.
  • Serov VS. Borg-Levinson theorem for perturbations of the bi-harmonic operator. Inverse Probl. 2016;32(4):045002.
  • Yang Y. Determining the first order perturbation of a bi-harmonic operator on bounded and unbounded domains from partial data. J. Differ Equ. 2014;257:3607–3639.
  • Tuan NH, Caraballo T, Thach TN. On terminal value problems for bi-parabolic equations driven by Wiener process and fractional Brownian motions. Asym Anal. 2021;123:335–366.
  • Li PJ, Wang X. An inverse random source problem for the Biharmonic Wave equation.  SIAM/ASA J. Uncertainty Quantification, 2022;10:949-974.
  • Li KX. Stochastic delay fractional evolution equations driven by fractional Brownian motion. Math Method Appl Sci. 2015;38:1582–1591.
  • Bai LH, Ma J. Stochastic differential equations driven by fractional Brownian motion and Poisson point process. Bernoulli. 2015;21:303–334.
  • Duc LH, Garrido-Atienzac MJ, Neuenkirch A, et al. Exponential stability of stochastic evolution equations driven by small fractional Brownian motion with Hurst parameter in (1/2, 1). J Differ Equ. 2018;264:1119–1145.
  • Feng XL, Li PJ, Wang X. An inverse random source problem for the time fractional diffusion equation driven by a fractional Brownian motion. Inverse Probl. 2020;36:045008 (30 p.).
  • Lv Q. Carleman estimate for stochastic parabolic equations and inverse stochastic parabolic problems. Inverse Probl. 2013;28:199–217.
  • Nie DX, Deng WH. An inverse random source problem for the time-space fractional diffusion equation driven by fractional Brownian motion. Available from: https://arxiv.org/abs/2106.00917
  • Nie DX, Deng WH. A unified convergence analysis for the fractional diffusion equation driven by fractional Gaussian noise with Hurst index Η∈(0,1). SIAM J. Numer. Anal.2022;60:1548-1573.
  • Au VV, Phuong ND, Tuan NH, et al. Some regularization methods for a class of nonlinear fractional evolution equations. Comput Math Appl. 2019;78:1752–1771.
  • Foias C, Temam R. Gevrey class regularity for the solutions of the Navier-Stokes equation. J Funct Anal. 1989;87:359–369.
  • Tuan NH, Kirane M, Quoc NDH, et al. Approximation of an inverse initial problem for a biparabolic equation. Mediterr J Math. 2018;15:18.
  • Feng XL, Zhao MX, Qian Z. A Tikhonov regularization method for solving a backward time-space fractional diffusion problem. J Comput Appl Math. 2022;411:114236.
  • Floridia G, Li Z, Yamamoto M. Well-posedness for the backward problems in time for general time-fractional diffusion equation. Rendiconti Lincei Matematica e Applicazioni. 2020;31(3):593–610.
  • Engl HW, Hanke M, Neubauer A. Regularization of inverse problem. Boston, MA: Kluwer Academic; 1996.
  • Kirsch A. An introduction to the mathematical theory of inverse problems. New York: Springer-Verlag; 1996.
  • Nualart D. The Mallivin calculus and related topics, probability and its applications. Commen Math Helvetici. 1996;71:168–168.
  • Buagini F, Hu Y, Øksendal B, et al. Stochastic calculus for fractional Brownian motion and applications. London: Springer; 2008.
  • Evans LC. An introduction to stochastic differential equations. Berkeley, Berkeley, CA: American Mathematical Society; 2014.

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