Pseudo grid-based physics-informed convolutional-recurrent network solving the integrable nonlinear lattice equations

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-07-30 DOI:10.1016/j.physd.2024.134304
Zhe Lin , Yong Chen
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Abstract

Traditional discrete learning methods involve discretizing continuous equations using difference schemes, necessitating considerations of stability and convergence. Integrable nonlinear lattice equations possess a profound mathematical structure that enables them to revert to continuous integrable equations in the continuous limit, particularly retaining integrable properties such as conservation laws, Hamiltonian structure, and multiple soliton solutions. The pseudo grid-based physics-informed convolutional-recurrent network (PG-PhyCRNet) is proposed to investigate the localized wave solutions of integrable lattice equations, which significantly enhances the model’s extrapolation capability to lattice points beyond the temporal domain. We conduct a comparative analysis of PG-PhyCRNet with and without pseudo grid by investigating the multi-soliton solutions and rational solitons of the Toda lattice and self-dual network equation. The results indicate that the PG-PhyCRNet excels in capturing long-term evolution and enhances the model’s extrapolation capability for solitons, particularly those with steep waveforms and high wave speeds. Finally, the robustness of the PG-PhyCRNet method and its effect on the prediction of solutions in different scenarios are confirmed through repeated experiments involving pseudo grid partitioning.

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基于伪网格的物理信息卷积递归网络求解可积分非线性网格方程
传统的离散学习方法涉及使用差分方案对连续方程进行离散化,因此必须考虑稳定性和收敛性。可积分非线性晶格方程具有深刻的数学结构,使其能够在连续极限中恢复为连续可积分方程,特别是保留了守恒定律、哈密顿结构和多重孤子解等可积分特性。我们提出了基于伪网格的物理信息卷积-并流网络(PG-PhyCRNet)来研究可积分晶格方程的局部波解,这大大增强了模型对时域以外晶格点的外推能力。我们通过研究户田晶格和自偶网络方程的多孤子解和有理孤子,对 PG-PhyCRNet 进行了有伪网格和无伪网格的对比分析。结果表明,PG-PhyCRNet 在捕捉长期演化方面表现出色,并增强了模型对孤子的外推能力,尤其是那些波形陡峭、波速较高的孤子。最后,PG-PhyCRNet 方法的稳健性及其对不同情况下预测解的影响通过涉及伪网格划分的反复实验得到了证实。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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