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Main Authors: Yuan, Shanhao, Liu, Yanqin, Zhang, Runfa, Yan, Limei, Wu, Shunjun, Feng, Libo
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.16702
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author Yuan, Shanhao
Liu, Yanqin
Zhang, Runfa
Yan, Limei
Wu, Shunjun
Feng, Libo
author_facet Yuan, Shanhao
Liu, Yanqin
Zhang, Runfa
Yan, Limei
Wu, Shunjun
Feng, Libo
contents In this study, we firstly propose an auxiliary equation neural networks method (AENNM), an innovative analytical method that integrates neural networks (NNs) models with the auxiliary equation method to obtain exact solutions of nonlinear partial differential equations (NLPDEs). A key novelty of this method is the introduction of a novel activation function derived from the solutions of the Riccati equation, establishing a new mathematical link between differential equations theory and deep learning. By combining the strong approximation capability of NNs with the high precision of symbolic computation, AENNM significantly enhances computational efficiency and accuracy. To demonstrate the effectiveness of the AENNM in solving NLPDEs, three numerical examples are investigated, including the nonlinear evolution equation, the Korteweg-de Vries-Burgers equation, and the (2+1)-dimensional Boussinesq equation. Furthermore, some new trial functions are constructed by setting specific activation functions within the "2-2-2-1" and "3-2-2-1" NNs models. By embedding the auxiliary equation method into the NNs framework, we derive previously unreported solutions. The exact analytical solutions are expressed in terms of hyperbolic functions, trigonometric functions, and rational functions. Finally, three-dimensional plots, contour plots, and density plots are presented to illustrate the dynamic characteristics of the obtained solutions. This research provides a novel methodological framework for addressing NLPDEs, with broad applicability across scientific and engineering fields.
format Preprint
id arxiv_https___arxiv_org_abs_2508_16702
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle A novel auxiliary equation neural networks method for exactly explicit solutions of nonlinear partial differential equations
Yuan, Shanhao
Liu, Yanqin
Zhang, Runfa
Yan, Limei
Wu, Shunjun
Feng, Libo
Machine Learning
In this study, we firstly propose an auxiliary equation neural networks method (AENNM), an innovative analytical method that integrates neural networks (NNs) models with the auxiliary equation method to obtain exact solutions of nonlinear partial differential equations (NLPDEs). A key novelty of this method is the introduction of a novel activation function derived from the solutions of the Riccati equation, establishing a new mathematical link between differential equations theory and deep learning. By combining the strong approximation capability of NNs with the high precision of symbolic computation, AENNM significantly enhances computational efficiency and accuracy. To demonstrate the effectiveness of the AENNM in solving NLPDEs, three numerical examples are investigated, including the nonlinear evolution equation, the Korteweg-de Vries-Burgers equation, and the (2+1)-dimensional Boussinesq equation. Furthermore, some new trial functions are constructed by setting specific activation functions within the "2-2-2-1" and "3-2-2-1" NNs models. By embedding the auxiliary equation method into the NNs framework, we derive previously unreported solutions. The exact analytical solutions are expressed in terms of hyperbolic functions, trigonometric functions, and rational functions. Finally, three-dimensional plots, contour plots, and density plots are presented to illustrate the dynamic characteristics of the obtained solutions. This research provides a novel methodological framework for addressing NLPDEs, with broad applicability across scientific and engineering fields.
title A novel auxiliary equation neural networks method for exactly explicit solutions of nonlinear partial differential equations
topic Machine Learning
url https://arxiv.org/abs/2508.16702