Two-level discretization of the 3D stationary Navier–Stokes equations with damping based on a difference finite element method

IF 2.1 3区数学 Q2 MATHEMATICS, APPLIED

Advances in Computational Mathematics Pub Date : 2025-08-14 DOI:10.1007/s10444-025-10255-7

Qi Zhang, Pengzhan Huang

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引用次数: 0

Abstract

A difference finite element method based on the mixed finite element pair \(((P_1^b,P_1^b,P_1) \times (P_1,P_1,P_1))\)-\((P_1 \times P_0)\) is presented for the three-dimensional stationary Navier–Stokes equations with damping. Moreover, based on this proposed method, a two-level discretization is constructed, which involves solving a problem of the Navier–Stokes equations with damping on coarse mesh with mesh sizes H and \(\mathcal {T}\), and a general Stokes problem on fine mesh with mesh sizes \(h = O(H^2)\) and \(\tau = O(\mathcal {T}^2)\). This two-level difference finite element method provides an approximate solution with the same convergence rate as the difference finite element solution, which involves solving a problem of the Navier–Stokes equations with damping on fine mesh with mesh sizes h and \(\tau \). Hence, it can save a large amount of computational time. Finally, all computational results support the theoretical analysis and show the effectiveness of the two-level difference finite element method for solving the considered problem.

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基于差分有限元法的含阻尼三维平稳Navier-Stokes方程的两级离散化

提出了一种基于混合有限元对\(((P_1^b,P_1^b,P_1) \times (P_1,P_1,P_1))\) - \((P_1 \times P_0)\)的含阻尼三维平稳Navier-Stokes方程差分有限元方法。在此基础上，构造了一个两级离散化问题，解决了含阻尼的Navier-Stokes方程在网格尺寸为H和\(\mathcal {T}\)的粗网格上的问题，以及网格尺寸为\(h = O(H^2)\)和\(\tau = O(\mathcal {T}^2)\)的细网格上的一般Stokes问题。这种两级差分有限元方法提供了一种近似解，其收敛速度与差分有限元解相同，该近似解涉及在网格尺寸为h和\(\tau \)的细网格上求解具有阻尼的Navier-Stokes方程问题。因此，它可以节省大量的计算时间。最后，所有的计算结果都支持理论分析，表明了两级差分有限元法求解所考虑问题的有效性。

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

Advances in Computational Mathematics 数学-应用数学

CiteScore

3.00

自引率

5.90%

发文量

审稿时长

3 months

期刊介绍： Advances in Computational Mathematics publishes high quality, accessible and original articles at the forefront of computational and applied mathematics, with a clear potential for impact across the sciences. The journal emphasizes three core areas: approximation theory and computational geometry; numerical analysis, modelling and simulation; imaging, signal processing and data analysis. This journal welcomes papers that are accessible to a broad audience in the mathematical sciences and that show either an advance in computational methodology or a novel scientific application area, or both. Methods papers should rely on rigorous analysis and/or convincing numerical studies.