Development of a Finite-difference Regularized Solution of the One-Dimensional Inverse Problem of the Wave Process
American Journal of Applied Mathematics
Volume 8, Issue 2, April 2020, Pages: 64-73
Received: Mar. 3, 2020; Accepted: Mar. 23, 2020; Published: Apr. 13, 2020
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Authors
Abdugany Dzhunusovich Satybaev, Department of Information Technology and Management, Faculty of Cybernetics and Information Technology, Osh Technological University, Osh, Kyrgyzstan
Yuliya Vladimirovna Anishchenko, Department of Information Technology and Management, Faculty of Cybernetics and Information Technology, Osh Technological University, Osh, Kyrgyzstan
Ainagul Zhylkychyevna Kokozova, Department of Information Technology and Management, Faculty of Cybernetics and Information Technology, Osh Technological University, Osh, Kyrgyzstan
Aliyma Torozhanovna Mamatkasymova, Department of Informatics, Naturally-technical Faculty, Osh Technological University, Osh, Kyrgyzstan
Guljamal Abdazovna Kaldybaeva, Department of Physics, Mathematics and Information Technology, Osh State University, Osh, Kyrgyzstan
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Abstract
We consider a one-dimensional inverse problem for a partial differential equation of hyperbolic type with sources - the Dirac delta-function and the Heaviside theta-function. The generalized inverse problem is reduced to the inverse problem with data on the characteristics using the method of characteristics and the method of isolation of singularities. At the beginning, the inverse problem of the wave process with data on the characteristics with additional information for the inverse problem without small perturbations is solved by the finite-difference method. Then, for the inverse problem of the wave process with data on the characteristics with additional information with small perturbations, that is, with small changes is used by the finite-difference regularized method, which developed by one of the authors of this article. The convergence of the finite-difference regularized solution to the exact solution of the one-dimensional inverse problem of the wave process on the characteristics is shown, and the theorem on the convergence of the approximate solution to the exact solution is proved. An estimate is obtained for the convergence of the numerical regularized solution to the exact solution, which depends on the grid step, on the perturbations parameter, and on the norm of known functions. From the equivalence of the problems, the one-dimensional inverse problem of the wave process with sources - the Dirac delta-function and the Heaviside theta-function and the one-dimensional inverse problem of the wave process with data on the characteristics, it follows that the solution of the last problem will be the solution of the posed initial problem. An algorithm for solving a finite-difference regularized solution of a generalized one-dimensional inverse problem is constructed.
Keywords
One-dimensional Inverse Problem, Wave Process, Dirac Delta-Function, Heaviside Theta-Function, Method of Characteristic, Method of Isolation of Singularities, Finite-Difference Regularized Solution
To cite this article
Abdugany Dzhunusovich Satybaev, Yuliya Vladimirovna Anishchenko, Ainagul Zhylkychyevna Kokozova, Aliyma Torozhanovna Mamatkasymova, Guljamal Abdazovna Kaldybaeva, Development of a Finite-difference Regularized Solution of the One-Dimensional Inverse Problem of the Wave Process, American Journal of Applied Mathematics. Vol. 8, No. 2, 2020, pp. 64-73. doi: 10.11648/j.ajam.20200802.13
Copyright
Copyright © 2020 Authors retain the copyright of this article.
This article is an open access article distributed under the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0/) which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
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