Numerical solution of (2+1)-dimensional nonlinear sine-Gordon equation with variable coefficients by using an efficient deep learning approach

In this article, we present an efficient neural-network-based deep learning approach, physics-informed neural networks (PINNs) with regularization technique, to resolve (2+1)-dimensional nonlinear damped and undamped sine-Gordon problem with variable coefficients. We suggest a multi-objective cost f...

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Vydáno v:	Zeitschrift für angewandte Mathematik und Physik Ročník 76; číslo 4; s. 134
Hlavní autoři:	Deresse, Alemayehu Tamirie, Dufera, Tamirat Temesgen
Médium:	Journal Article
Jazyk:	angličtina
Vydáno:	Heidelberg Springer Nature B.V 01.08.2025
Témata:	Approximation Artificial neural networks Boundary conditions Boundary value problems Cost function Deep learning Finite volume method Inverse problems Iterative methods Machine learning Neural networks Numerical analysis Parameter estimation Partial differential equations Physics Regularization
ISSN:	0044-2275, 1420-9039
On-line přístup:	Získat plný text
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Popis
Shrnutí:	In this article, we present an efficient neural-network-based deep learning approach, physics-informed neural networks (PINNs) with regularization technique, to resolve (2+1)-dimensional nonlinear damped and undamped sine-Gordon problem with variable coefficients. We suggest a multi-objective cost function that incorporates the beginning circumstances, the governing problem’s residual, and various boundary circumstances to directly incorporate physical information of the proposed initial boundary value problem into the learning process. We employed a multiple densely connected network called feed-forward deep neural networks. To further enhance the network’s robustness and adaptability capabilities, we apply two regularization approaches to the PINNs. We point out three illustrative examples to demonstrate our suggested method’s effectiveness, validity, and practical consequences. The results showed that regularized PINNs produce better outcomes than the usual PINNs. We assess the accuracy of the model based on the relative, absolute, and training errors through tables and graphs. The findings suggested that the proposed machine learning approach PINNs is efficient and accurate and can be applied to any variable coefficient problem without requiring any linearization, perturbation, or interpolation techniques and the inclusion of appropriate regularization strategies in the PINNs can improve its performance. Therefore, to solve the variable coefficient nonlinear sine-Gordon equation and other difficult nonlinear physical issues in a range of fields, the PINNs is an appropriate programming machine learning method that is both accurate and efficient.
Bibliografie:	ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 14
ISSN:	0044-2275 1420-9039
DOI:	10.1007/s00033-025-02515-9