Optimal error estimates of a non-uniform IMEX-L1 finite element method for time fractional PDEs and PIDEs

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-07-18 DOI:10.1016/j.apnum.2024.07.003

Aditi Tomar , Lok Pati Tripathi , Amiya K. Pani

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Abstract

Stability and optimal convergence analysis of a non-uniform implicit-explicit L1 finite element method (IMEX-L1-FEM) is studied for a class of time-fractional linear partial differential/integro-differential equations with non-self-adjoint elliptic part having (space-time) variable coefficients. The proposed scheme is based on a combination of an IMEX-L1 method on graded mesh in the temporal direction and a finite element method in the spatial direction. With the help of a discrete fractional Grönwall inequality, global almost optimal error estimates in $L^{2}$ - and $H^{1}$ -norms are derived for the problem with initial data $u_{0} \in H_{0}^{1} (Ω) \cap H^{2} (Ω)$ . The novelty of our approach is based on managing the interaction of the L1 approximation of the fractional derivative and the time discrete elliptic operator to derive the optimal estimate in $H^{1}$ -norm directly. Furthermore, a super convergence result is established when the elliptic operator is self-adjoint with time and space varying coefficients, and as a consequence, an $L^{\infty}$ error estimate is obtained for 2D problems that too with the initial condition is in $H_{0}^{1} (Ω) \cap H^{2} (Ω)$ . All results proved in this paper are valid uniformly as $α \to 1^{-}$ , where α is the order of the Caputo fractional derivative. Numerical experiments are presented to validate our theoretical findings.

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时间分数 PDE 和 PIDE 非均匀 IMEX-L1 有限元方法的最佳误差估计

针对一类具有（时空）可变系数的非自交椭圆部分的时分线性偏微分/微分方程，研究了非均匀隐式-显式 L1 有限元方法（IMEX-L1-FEM）的稳定性和最佳收敛性分析。所提出的方案基于时间方向上分级网格上的 IMEX-L1 方法和空间方向上的有限元方法的组合。在离散分数格伦沃不等式的帮助下，对于初始数据为 u0∈H01(Ω)∩H2(Ω) 的问题，得出了 L2 和 H1 准则下的全局几乎最优误差估计值。我们方法的新颖之处在于管理分数导数的 L1 近似值与时间离散椭圆算子的相互作用，从而直接得出 H1 规范下的最优估计值。此外，当椭圆算子是具有时间和空间变化系数的自联合算子时，建立了一个超收敛结果，因此，对于初始条件也在 H01(Ω)∩H2(Ω)中的二维问题，可以获得 L∞ 误差估计。本文证明的所有结果在 α→1- 时均匀有效，其中 α 是卡普托分数导数的阶数。本文给出了数值实验来验证我们的理论发现。

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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