物理
非线性系统
薛定谔方程
人工神经网络
反向
数学物理
反问题
应用数学
统计物理学
经典力学
量子力学
数学分析
计算机科学
数学
人工智能
几何学
作者
Lingyun Hou,Li Cheng,Yang Yi,Junchao Chen,Weiyi Shi
标识
DOI:10.1088/1572-9494/adfc37
摘要
Abstract In this paper, we investigate data-driven bright soliton solutions of the nonlocal reverse-time nonlinear Schrödinger (NLS) equation and the parameter identification using the physically informed neural networks (PINNs) algorithm. Accurate simulations and comparative analyses of relative and absolute errors are performed for two-soliton and four-soliton solutions including linear solitary waves and periodic waves. In the training process, the standard PINNs scheme is employed for linear solitary wave solutions, while the prior information is added at local sharp regions for periodic wave solutions due to the complicated collision behaviors. For the parameter identification, we accurately recognize the nonlinear coefficients of the nonlocal NLS equation from known solutions with different noises. These results reinforce the application of deep learning with the PINNs framework to successfully study nonlocal integrable systems.
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