A proposed sixth order inverse polynomial method for the solution of non-linear physical models

IF 2 Q1 MATHEMATICS

Journal of Mathematics and Computer Science-JMCS Pub Date : 2023-08-01 DOI:10.22436/jmcs.032.02.01

S. E. Fadugba, I. Ibrahim, O. Adeyeye, A. Adeniji, M. Kekana, Joseph Temitayo Okunlola

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引用次数: 1

Abstract

There are several nonlinear physical models emanated from science and technology that have always remained a challenge for numerical analysts and applied mathematicians. Various one-step numerical methods were developed to deal with these models, however, it requires the developed method to have consistency, stability, zero stability and convergence characteristics to handle the non-linearity in the model. This paper proposes a new sixth order inverse polynomial method (SOIPM) with a relative measure of stability for the solution of non-linear physical models with different ﬂavors. Firstly, the properties of SOIPM are analyzed and investigated. Moreover, three illustrative non-linear physical models have been solved to measure the accuracy, computational performance, suitability and effectiveness of SOIPM. Furthermore, the results generated via SOIPM are compared with the existing method of the celebrated Runge-Kutta of order four (RK4) in the context of the exact value (EV). Finally, the absolute errors (ABEs) and ﬁnal absolute errors (FABEs) incurred by SOIPM are computed and compared with that of RK4.

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一种求解非线性物理模型的六阶逆多项式方法

科学技术产生的几种非线性物理模型一直是数值分析师和应用数学家面临的挑战。开发了各种一步数值方法来处理这些模型，然而，需要开发的方法具有一致性、稳定性、零稳定性和收敛性来处理模型中的非线性。本文提出了一种新的六阶逆多项式方法（SOPM），该方法具有相对稳定性的度量，用于求解具有不同频率的非线性物理模型。首先，对SOIPM的性能进行了分析和研究。此外，还求解了三个说明性的非线性物理模型来衡量SOIPM的准确性、计算性能、适用性和有效性。此外，在精确值（EV）的背景下，将通过SOPM生成的结果与著名的四阶龙格库塔（RK4）的现有方法进行比较。最后，计算了SOIMP产生的绝对误差（ABE）和最终绝对误差（FABEs），并与RK4进行了比较。

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

Journal of Mathematics and Computer Science-JMCS MATHEMATICS-

CiteScore

3.10

自引率

4.00%

发文量