LADM procedure to find the analytical solutions of the nonlinear fractional dynamics of partial integro-differential equations

IF 2 3区数学 Q1 MATHEMATICS

Demonstratio Mathematica Pub Date : 2024-01-01 DOI:10.1515/dema-2023-0101

Qasim Khan, Hassan Khan, P. Kumam, Fairouz Tchier, Gurpreet Singh

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Abstract

Generally, fractional partial integro-differential equations (FPIDEs) play a vital role in modeling various complex phenomena. Because of the several applications of FPIDEs in applied sciences, mathematicians have taken a keen interest in developing and utilizing the various techniques for its solutions. In this context, the exact and analytical solutions are not very easy to investigate the solution of FPIDEs. In this article, a novel analytical approach that is known as the Laplace adomian decomposition method is implemented to calculate the solutions of FPIDEs. We obtain the approximate solution of the nonlinear FPIDEs. The results are discussed using graphs and tables. The graphs and tables have shown the greater accuracy of the suggested method compared to the extended cubic-B splice method. The accuracy of the suggested method is higher at all fractional orders of the derivatives. A sufficient degree of accuracy is achieved with fewer calculations with a simple procedure. The presented method requires no parametrization or discretization and, therefore, can be extended for the solutions of other nonlinear FPIDEs and their systems.

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用 LADM 程序求解非线性分式偏积分微分方程的解析解

一般来说，分数偏积分微分方程（FPIDE）在模拟各种复杂现象中发挥着重要作用。由于 FPIDEs 在应用科学中的多种应用，数学家们对开发和利用各种技术求解 FPIDEs 产生了浓厚的兴趣。在这种情况下，要研究 FPIDE 的解法，精确和分析解法并不十分容易。本文采用了一种被称为拉普拉斯阿多米分解法的新型分析方法来计算 FPIDE 的解。我们得到了非线性 FPIDE 的近似解。我们使用图形和表格对结果进行了讨论。图和表显示，与扩展立方 B 拼接法相比，建议方法的精度更高。在导数的所有分数阶上，建议方法的精度都更高。计算量少，程序简单，就能达到足够的精确度。提出的方法无需参数化或离散化，因此可扩展用于其他非线性 FPIDE 及其系统的求解。

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

Demonstratio Mathematica MATHEMATICS-

CiteScore

2.40

自引率

5.00%

发文量

审稿时长

35 weeks

期刊介绍： Demonstratio Mathematica publishes original and significant research on topics related to functional analysis and approximation theory. Please note that submissions related to other areas of mathematical research will no longer be accepted by the journal. The potential topics include (but are not limited to): -Approximation theory and iteration methods- Fixed point theory and methods of computing fixed points- Functional, ordinary and partial differential equations- Nonsmooth analysis, variational analysis and convex analysis- Optimization theory, variational inequalities and complementarity problems- For more detailed list of the potential topics please refer to Instruction for Authors. The journal considers submissions of different types of articles. "Research Articles" are focused on fundamental theoretical aspects, as well as on significant applications in science, engineering etc. “Rapid Communications” are intended to present information of exceptional novelty and exciting results of significant interest to the readers. “Review articles” and “Commentaries”, which present the existing literature on the specific topic from new perspectives, are welcome as well.