Numerical approximation of the one-dimensional inverse Cauchy–Stefan problem using heat polynomials methods

Samat A. Kassabek; Durvudkhan Suragan

doi:10.1007/s40314-022-01896-1

Numerical approximation of the one-dimensional inverse Cauchy–Stefan problem using heat polynomials methods

Samat A. Kassabek, Durvudkhan Suragan

Research output: Contribution to journal › Article › peer-review

6 Citations (Scopus)

Abstract

The paper presents a new approximate method of solving one-dimensional inverse Cauchy–Stefan problems. We apply the heat polynomials method (HPM) for solving the one-dimensional inverse Cauchy–Stefan problem, where the initial and boundary data are reconstructed on a fixed boundary. The solution of the problem is presented in the form of linear combination of heat polynomials. We have studied the effects of accuracy and measurement error for different degree of heat polynomials. Due to ill-conditioning of the matrix generated by HPM, optimization techniques are used to obtain regularized solution. Therefore, the sensitivity of the method to the data disturbance has been checked. Theoretical properties of the proposed method, as well as numerical experiments, demonstrate that to reach accurate results, it is quite sufficient to consider only a few of polynomials.

Original language	English
Article number	189
Journal	Computational and Applied Mathematics
Volume	41
Issue number	4
DOIs	https://doi.org/10.1007/s40314-022-01896-1
Publication status	Published - Jun 2022

Keywords

Approximate solution
Inverse Cauchy–Stefan problem
Method of heat polynomials
Tikhonov regularization

ASJC Scopus subject areas

Computational Mathematics
Applied Mathematics

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10.1007/s40314-022-01896-1

Cite this

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title = "Numerical approximation of the one-dimensional inverse Cauchy–Stefan problem using heat polynomials methods",

abstract = "The paper presents a new approximate method of solving one-dimensional inverse Cauchy–Stefan problems. We apply the heat polynomials method (HPM) for solving the one-dimensional inverse Cauchy–Stefan problem, where the initial and boundary data are reconstructed on a fixed boundary. The solution of the problem is presented in the form of linear combination of heat polynomials. We have studied the effects of accuracy and measurement error for different degree of heat polynomials. Due to ill-conditioning of the matrix generated by HPM, optimization techniques are used to obtain regularized solution. Therefore, the sensitivity of the method to the data disturbance has been checked. Theoretical properties of the proposed method, as well as numerical experiments, demonstrate that to reach accurate results, it is quite sufficient to consider only a few of polynomials.",

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AU - Kassabek, Samat A.

AU - Suragan, Durvudkhan

PY - 2022/6

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N2 - The paper presents a new approximate method of solving one-dimensional inverse Cauchy–Stefan problems. We apply the heat polynomials method (HPM) for solving the one-dimensional inverse Cauchy–Stefan problem, where the initial and boundary data are reconstructed on a fixed boundary. The solution of the problem is presented in the form of linear combination of heat polynomials. We have studied the effects of accuracy and measurement error for different degree of heat polynomials. Due to ill-conditioning of the matrix generated by HPM, optimization techniques are used to obtain regularized solution. Therefore, the sensitivity of the method to the data disturbance has been checked. Theoretical properties of the proposed method, as well as numerical experiments, demonstrate that to reach accurate results, it is quite sufficient to consider only a few of polynomials.

AB - The paper presents a new approximate method of solving one-dimensional inverse Cauchy–Stefan problems. We apply the heat polynomials method (HPM) for solving the one-dimensional inverse Cauchy–Stefan problem, where the initial and boundary data are reconstructed on a fixed boundary. The solution of the problem is presented in the form of linear combination of heat polynomials. We have studied the effects of accuracy and measurement error for different degree of heat polynomials. Due to ill-conditioning of the matrix generated by HPM, optimization techniques are used to obtain regularized solution. Therefore, the sensitivity of the method to the data disturbance has been checked. Theoretical properties of the proposed method, as well as numerical experiments, demonstrate that to reach accurate results, it is quite sufficient to consider only a few of polynomials.

KW - Approximate solution

KW - Inverse Cauchy–Stefan problem

KW - Method of heat polynomials

KW - Tikhonov regularization

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Numerical approximation of the one-dimensional inverse Cauchy–Stefan problem using heat polynomials methods

Abstract

Keywords

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