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On some features of the numerical solving of coefficient inverse problems for an equation of the reaction-diffusion-advection-type with data on the position of a reaction front. / Argun, Raul; Gorbachev, Alexandr; Lukyanenko, Dmitry et al.

In: Mathematics, Vol. 9, No. 22, 2894, 01.11.2021.

Research output: Contribution to journalArticlepeer-review

Harvard

Argun, R, Gorbachev, A, Lukyanenko, D & Shishlenin, M 2021, 'On some features of the numerical solving of coefficient inverse problems for an equation of the reaction-diffusion-advection-type with data on the position of a reaction front', Mathematics, vol. 9, no. 22, 2894. https://doi.org/10.3390/math9222894

APA

Argun, R., Gorbachev, A., Lukyanenko, D., & Shishlenin, M. (2021). On some features of the numerical solving of coefficient inverse problems for an equation of the reaction-diffusion-advection-type with data on the position of a reaction front. Mathematics, 9(22), [2894]. https://doi.org/10.3390/math9222894

Vancouver

Argun R, Gorbachev A, Lukyanenko D, Shishlenin M. On some features of the numerical solving of coefficient inverse problems for an equation of the reaction-diffusion-advection-type with data on the position of a reaction front. Mathematics. 2021 Nov 1;9(22):2894. doi: 10.3390/math9222894

Author

Argun, Raul ; Gorbachev, Alexandr ; Lukyanenko, Dmitry et al. / On some features of the numerical solving of coefficient inverse problems for an equation of the reaction-diffusion-advection-type with data on the position of a reaction front. In: Mathematics. 2021 ; Vol. 9, No. 22.

BibTeX

@article{c5914d4b71a7450390c7b7e3668548cc,
title = "On some features of the numerical solving of coefficient inverse problems for an equation of the reaction-diffusion-advection-type with data on the position of a reaction front",
abstract = "The work continues a series of articles devoted to the peculiarities of solving coefficient inverse problems for nonlinear singularly perturbed equations of the reaction-diffusion-advection-type with data on the position of the reaction front. In this paper, we place the emphasis on some problems of the numerical solving process. One of the approaches to solving inverse problems of the class under consideration is the use of methods of asymptotic analysis. These methods, under certain conditions, make it possible to construct the so-called reduced formulation of the inverse problem. Usually, a differential equation in this formulation has a lower dimension/order with respect to the differential equation, which is included in the full statement of the inverse problem. In this paper, we consider an example that leads to a reduced formulation of the problem, the solving of which is no less a time-consuming procedure in comparison with the numerical solving of the problem in the full statement. In particular, to obtain an approximate numerical solution, one has to use the methods of the numerical diagnostics of the solution{\textquoteright}s blow-up. Thus, it is demonstrated that the possibility of constructing a reduced formulation of the inverse problem does not guarantee its more efficient solving. Moreover, the possibility of constructing a reduced formulation of the problem does not guarantee the existence of an approximate solution that is qualitatively comparable to the true one. In previous works of the authors, it was shown that an acceptable approximate solution can be obtained only for sufficiently small values of the singular parameter included in the full statement of the problem. However, the question of how to proceed if the singular parameter is not small enough remains open. The work also gives an answer to this question.",
keywords = "Blow-up, Coefficient inverse problem, Inverse problem with data on the position of a reaction front, Reaction–diffusion equation, Reaction–diffusion–advection equation, Singularly perturbed problem",
author = "Raul Argun and Alexandr Gorbachev and Dmitry Lukyanenko and Maxim Shishlenin",
note = "Funding Information: Acknowledgments: The paper was published with the support of the Ministry of Education and Science of the Russian Federation as part of the program of the Moscow Center for Fundamental and Applied Mathematics under Agreement N075-15-2019-1621. Funding Information: Funding: The reported study was funded by RFBR, Project Number 20-31-70016. Publisher Copyright: {\textcopyright} 2021 by the authors. Licensee MDPI, Basel, Switzerland.",
year = "2021",
month = nov,
day = "1",
doi = "10.3390/math9222894",
language = "English",
volume = "9",
journal = "Mathematics",
issn = "2227-7390",
publisher = "MDPI AG",
number = "22",

}

RIS

TY - JOUR

T1 - On some features of the numerical solving of coefficient inverse problems for an equation of the reaction-diffusion-advection-type with data on the position of a reaction front

AU - Argun, Raul

AU - Gorbachev, Alexandr

AU - Lukyanenko, Dmitry

AU - Shishlenin, Maxim

N1 - Funding Information: Acknowledgments: The paper was published with the support of the Ministry of Education and Science of the Russian Federation as part of the program of the Moscow Center for Fundamental and Applied Mathematics under Agreement N075-15-2019-1621. Funding Information: Funding: The reported study was funded by RFBR, Project Number 20-31-70016. Publisher Copyright: © 2021 by the authors. Licensee MDPI, Basel, Switzerland.

PY - 2021/11/1

Y1 - 2021/11/1

N2 - The work continues a series of articles devoted to the peculiarities of solving coefficient inverse problems for nonlinear singularly perturbed equations of the reaction-diffusion-advection-type with data on the position of the reaction front. In this paper, we place the emphasis on some problems of the numerical solving process. One of the approaches to solving inverse problems of the class under consideration is the use of methods of asymptotic analysis. These methods, under certain conditions, make it possible to construct the so-called reduced formulation of the inverse problem. Usually, a differential equation in this formulation has a lower dimension/order with respect to the differential equation, which is included in the full statement of the inverse problem. In this paper, we consider an example that leads to a reduced formulation of the problem, the solving of which is no less a time-consuming procedure in comparison with the numerical solving of the problem in the full statement. In particular, to obtain an approximate numerical solution, one has to use the methods of the numerical diagnostics of the solution’s blow-up. Thus, it is demonstrated that the possibility of constructing a reduced formulation of the inverse problem does not guarantee its more efficient solving. Moreover, the possibility of constructing a reduced formulation of the problem does not guarantee the existence of an approximate solution that is qualitatively comparable to the true one. In previous works of the authors, it was shown that an acceptable approximate solution can be obtained only for sufficiently small values of the singular parameter included in the full statement of the problem. However, the question of how to proceed if the singular parameter is not small enough remains open. The work also gives an answer to this question.

AB - The work continues a series of articles devoted to the peculiarities of solving coefficient inverse problems for nonlinear singularly perturbed equations of the reaction-diffusion-advection-type with data on the position of the reaction front. In this paper, we place the emphasis on some problems of the numerical solving process. One of the approaches to solving inverse problems of the class under consideration is the use of methods of asymptotic analysis. These methods, under certain conditions, make it possible to construct the so-called reduced formulation of the inverse problem. Usually, a differential equation in this formulation has a lower dimension/order with respect to the differential equation, which is included in the full statement of the inverse problem. In this paper, we consider an example that leads to a reduced formulation of the problem, the solving of which is no less a time-consuming procedure in comparison with the numerical solving of the problem in the full statement. In particular, to obtain an approximate numerical solution, one has to use the methods of the numerical diagnostics of the solution’s blow-up. Thus, it is demonstrated that the possibility of constructing a reduced formulation of the inverse problem does not guarantee its more efficient solving. Moreover, the possibility of constructing a reduced formulation of the problem does not guarantee the existence of an approximate solution that is qualitatively comparable to the true one. In previous works of the authors, it was shown that an acceptable approximate solution can be obtained only for sufficiently small values of the singular parameter included in the full statement of the problem. However, the question of how to proceed if the singular parameter is not small enough remains open. The work also gives an answer to this question.

KW - Blow-up

KW - Coefficient inverse problem

KW - Inverse problem with data on the position of a reaction front

KW - Reaction–diffusion equation

KW - Reaction–diffusion–advection equation

KW - Singularly perturbed problem

UR - http://www.scopus.com/inward/record.url?scp=85119612845&partnerID=8YFLogxK

U2 - 10.3390/math9222894

DO - 10.3390/math9222894

M3 - Article

AN - SCOPUS:85119612845

VL - 9

JO - Mathematics

JF - Mathematics

SN - 2227-7390

IS - 22

M1 - 2894

ER -

ID: 34856005