Numerical analysis of time filter method for the stabilized incompressible diffusive Peterlin viscoelastic fluid model

IF 2.9 2区数学 Q1 MATHEMATICS, APPLIED

Computers & Mathematics with Applications Pub Date : 2024-07-18 DOI:10.1016/j.camwa.2024.07.002

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引用次数: 0

Abstract

The Diffusion Peterlin Viscoelastic Fluid (DPVF) model describes the movement of specific incompressible polymeric fluids. In this paper, we introduce and evaluate a new low-complexity linear-time filter finite element (FE) method for the DPVF model. In order to avoid the value at time $t = - Δ t$ , the proposed time filter method consists of three steps, including a post-processing step. Firstly, a first-order Euler backward nonlinear fully discrete mixed FE scheme is employed to compute the numerical solutions at time $t_{1} = Δ t$ . For $n \geq 1$ , we obtain the intermediate values $({\tilde{u}}_{h}^{n + 1}, {\tilde{p}}_{h}^{n + 1}, {\tilde{d}}_{h}^{n + 1})$ in Step II using a fully implicit backward Euler scheme. At the same time level, we proceed with these intermediate values $({\tilde{u}}_{h}^{n + 1}, {\tilde{p}}_{h}^{n + 1}, {\tilde{d}}_{h}^{n + 1})$ using the linear time filters. The linear time filters step does not significantly increase computational complexity. However, it can enhance temporal convergence accuracy from first order to second order for backward Euler time filter (BE time filter), and from second order to three order for BDF2 time filter. We demonstrate the almost unconditional stability of the scheme. Error estimates for the time filter method are derived and presented. Several numerical experiments are conducted to validate the theoretical findings and showcase the efficiency of the proposed method.

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稳定的不可压缩扩散性彼得林粘弹性流体模型的时间滤波法数值分析

扩散彼得林粘弹性流体（DPVF）模型描述了特定不可压缩聚合物流体的运动。本文针对 DPVF 模型介绍并评估了一种新的低复杂度线性时间滤波有限元（FE）方法。为了避免时间 t=-Δt 时的数值，所提出的时间滤波法由三个步骤组成，包括一个后处理步骤。首先，采用一阶欧拉后向非线性全离散混合 FE 方案计算时间 t1=Δt 时的数值解。对于 n≥1，我们在步骤 II 中采用全隐式后向欧拉方案获得中间值（u˜hn+1,p˜hn+1,d˜hn+1）。同时，我们使用线性时间滤波器对这些中间值（u˜hn+1,p˜hn+1,d˜hn+1）进行处理。线性时间滤波器步骤不会显著增加计算复杂度。但是，它可以提高时间收敛精度，对于后向欧拉时间滤波器（BE 时间滤波器），收敛精度从一阶提高到二阶；对于 BDF2 时间滤波器，收敛精度从二阶提高到三阶。我们证明了该方案几乎无条件的稳定性。推导并给出了时间滤波方法的误差估计值。我们还进行了一些数值实验来验证理论结论，并展示了所提方法的效率。

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

Computers & Mathematics with Applications 工程技术-计算机：跨学科应用

CiteScore

5.10

自引率

10.30%

发文量

396

审稿时长

9.9 weeks

期刊介绍： Computers & Mathematics with Applications provides a medium of exchange for those engaged in fields contributing to building successful simulations for science and engineering using Partial Differential Equations (PDEs).