搭配(遥感)
离散化
正交配置
奇异边界法
数学优化
边值问题
搭配法
应用数学
基函数
边界(拓扑)
计算机科学
趋同(经济学)
功能(生物学)
热传导
数学
算法
有限元法
数学分析
边界元法
微分方程
常微分方程
物理
经济增长
生物
热力学
进化生物学
机器学习
经济
作者
Lin Qiu,Fajie Wang,Wenzhen Qu,Ji Lin,Yan Gu,Qing‐Hua Qin
摘要
ABSTRACT This study proposes a hybrid collocation approach for simulating heat conduction problems in anisotropic functionally graded materials over extended time intervals. In this approach, the Krylov deferred correction (KDC) scheme is employed for the temporal discretization of dynamic problems, featuring a novel numerical implementation designed to ensure the precise satisfaction of boundary conditions. The localized radial basis function (LRBF) collocation method is modified and utilized to solve the resulting boundary value problems. A new radial basis function is developed and combined with an optimization strategy for the distribution of source points to enhance the performance of the LRBF scheme. This method synergizes the KDC technique, which supports large time step sizes, with the LRBF collocation method, characterized by its truly meshless nature, to address dynamic problems over long durations. Additionally, the coefficient matrix produced by the LRBF method is sparse and depends solely on the spatial distances between collocation points and source points, which is advantageous for long‐term simulations. Numerical simulations spanning thousands of time steps demonstrate the accuracy, stability, and convergence of the hybrid approach. The developed numerical framework shows significant improvements over existing methods, particularly in handling dynamic problems with substantial temperature variations.
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