分数阶柯西-黎曼方程组的向量约简微分变换方法

IF 0.9 Q3 MATHEMATICS, APPLIED
Tahir Naseem, Noreen Niazi, Muhammad Ayub, Muhammad Sohail
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引用次数: 3

摘要

柯西-黎曼方程在具有可微性和连续性的条件下是非常重要的;这些是函数为解析函数的充分必要条件。物理上,柯西-黎曼方程表示向量场的旋度和散度。像经典微分方程一样,大量的物理问题都是用偏微分方程(PDEs)来解决的。偏微分方程需要推广为分数偏微分方程。本文研究了柯西-黎曼方程组的空间和时间变量的分数化。采用向量分数阶降阶微分变换方法,用解析柯西数据求解时空变量非齐次分数阶柯西-黎曼方程。由此得到的解是收敛无穷级数的形式。用图形表示了模型问题的精确解和近似解,并观察到这些解与α = β = 1的精确解符合得很好。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Vectorial reduced differential transform method for fractional Cauchy–Riemann system of equations

Cauchy–Riemann equations are very important as with condition of differentiability and continuity; these are the necessary and sufficient conditions for function to be analytic. Physically, Cauchy–Riemann equations represent the curl and divergence of vector fields. Like classical differential equations, a large class of physical problems are plugging with partial differential equations (PDEs). So PDEs need to be generalizing as fractional PDEs. This study proceeded to involves fractionalization of space and time variables of Cauchy–Riemann system of equations. Vectorial fractional reduced differential transformed method is used to solve inhomogeneous fractional Cauchy–Riemann equation in both space and time variable with analytic Cauchy data. Solutions so obtained are in the form of convergent infinite series. The exact and approximate solutions of model problems are shown graphically and observed that the solutions are in good agreement with exact solution for α = β = 1.

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