Interactions of localized wave and dynamics analysis in the new generalized stochastic fractional potential-KdV equation.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Yan Zhu, Chuyu Huang, Shengjie He, Yun Chen, Junjiang Zhong, Junjie Li, Runfa Zhang
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Abstract

In this paper, we investigate the new generalized stochastic fractional potential-Korteweg-de Vries equation, which describes nonlinear optical solitons and photon propagation in circuits and multicomponent plasmas. Inspired by Kolmogorov-Arnold network and our earlier work, we enhance the improved bilinear neural network method by using a large number of activation functions instead of neurons. This method incorporates the concept of simulating more complicated activation functions with fewer parameters, with more diverse activation functions to generate more complex and rare analytical solutions. On this basis, constraints are introduced into the method, reducing a significant amount of computational workload. We also construct neural network architectures, such as "2-3-1," "2-2-3-1," "2-3-3-1," and "2-3-2-1" using this method. Maple software is employed to obtain many exact analytical solutions by selecting appropriate parameters, such as the superposition of double-period lump solutions, lump-rogue wave solutions, and three interaction solutions. The results show that these solutions exhibit more complex waveforms than those obtained by conventional methods, which is of great significance for the electrical systems and multicomponent fluids to which the equation is applied. This novel method shows significant advantages when applied to fractional-order equations and is expected to be increasingly widely used in the study of nonlinear partial differential equations.

新广义随机分数势-KdV方程中局部波与动力学分析的相互作用
本文研究了新的广义随机分数势-Korteweg-de Vries方程,该方程描述了电路和多组分等离子体中的非线性光学孤子和光子传播。受 Kolmogorov-Arnold 网络和我们早期工作的启发,我们通过使用大量激活函数而不是神经元来增强改进的双线性神经网络方法。这种方法包含了用更少的参数模拟更复杂的激活函数的概念,激活函数更加多样化,从而产生更复杂、更罕见的分析解。在此基础上,该方法引入了约束条件,从而减少了大量的计算工作量。我们还利用这种方法构建了 "2-3-1"、"2-2-3-1"、"2-3-3-1 "和 "2-3-2-1 "等神经网络架构。利用 Maple 软件,通过选择适当的参数,得到了许多精确的解析解,如双周期块状解、块状蛙波解和三种相互作用解的叠加。结果表明,与传统方法相比,这些解呈现出更复杂的波形,这对于应用该方程的电气系统和多组分流体具有重要意义。这种新方法在应用于分数阶方程时显示出显著优势,有望在非线性偏微分方程研究中得到越来越广泛的应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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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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