Khadijeh Sadri , David Amilo , Muhammad Farman , Evren Hinçal
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引用次数: 0
Abstract
The utilization of time-fractional Burgers’ equations is widespread, employed in modeling various phenomena such as heat conduction, acoustic wave propagation, gas turbulence, and the propagation of chaos in non-linear Markov processes. This study introduces a novel pseudo-operational collocation method, leveraging two-variable Jacobi polynomials. These polynomials are obtained through the Kronecker product of their one-variable counterparts, concerning both spatial () and temporal () domains. The study explores the impact of four parameters () on the accuracy of resulting approximate solutions, marking the first examination of such influence. Collocation nodes in a tensor approach are constructed employing the roots of one-variable Jacobi polynomials of varying degrees in and . The study delves into analyzing how the distribution of these roots affects the outcomes. Consequently, pseudo-operational matrices are devised to integrate both integer and fractional orders, presenting a novel methodological advancement. By employing these matrices and appropriate approximations, the governing equations transform into an algebraic system, facilitating computational analysis. Furthermore, the existence and uniqueness of the equations under study are investigated and the study estimates error bounds within a Jacobi-weighted space for the obtained approximate solutions. Numerical simulations underscore the simplicity, applicability, and efficiency of the proposed matrix spectral scheme.
时间分布尔格斯方程的应用非常广泛,可用于模拟各种现象,如热传导、声波传播、气体湍流以及非线性马尔可夫过程中的混沌传播。本研究利用双变量雅可比多项式引入了一种新颖的伪运算配位方法。这些多项式是通过其单变对应项的 Kronecker 乘积获得的,涉及空间(x)和时间(t)域。研究探讨了四个参数(θ,ϑ,σ,ς>-1)对所得近似解精度的影响,这是首次对此类影响进行研究。张量法中的拼合节点是利用 x 和 t 中不同度数的一变量雅可比多项式的根构建的。因此,设计了伪运算矩阵来整合整数阶和分数阶,在方法上取得了新的进展。通过使用这些矩阵和适当的近似值,治理方程转化为代数系统,从而方便了计算分析。此外,研究还探讨了所研究方程的存在性和唯一性,并估算了所获近似解在雅各比加权空间内的误差范围。数值模拟强调了所提矩阵谱方案的简便性、适用性和高效性。
期刊介绍:
Computational Science is a rapidly growing multi- and interdisciplinary field that uses advanced computing and data analysis to understand and solve complex problems. It has reached a level of predictive capability that now firmly complements the traditional pillars of experimentation and theory.
The recent advances in experimental techniques such as detectors, on-line sensor networks and high-resolution imaging techniques, have opened up new windows into physical and biological processes at many levels of detail. The resulting data explosion allows for detailed data driven modeling and simulation.
This new discipline in science combines computational thinking, modern computational methods, devices and collateral technologies to address problems far beyond the scope of traditional numerical methods.
Computational science typically unifies three distinct elements:
• Modeling, Algorithms and Simulations (e.g. numerical and non-numerical, discrete and continuous);
• Software developed to solve science (e.g., biological, physical, and social), engineering, medicine, and humanities problems;
• Computer and information science that develops and optimizes the advanced system hardware, software, networking, and data management components (e.g. problem solving environments).
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