基于WENO重构和原始变量时空预测的高效保守ADER方案

IF 16.281
Olindo Zanotti, Michael Dumbser
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引用次数: 34

摘要

本文提出了一种新版本的保守型ADER-WENO有限体积格式,其中重构多项式在局部时空预测阶段的高阶空间重构和时间演化都是在原始变量中进行的,而不是在保守变量中进行的。为了获得一种保守的方法,潜在的有限体积方案仍然用守恒量的单元平均值来表示。因此,我们的新方法进行了两次空间WENO重建:第一次WENO重建是在已知的保守变量的细胞平均值上进行的。然后在单元中心使用WENO多项式计算保守变量的点值,随后将其转换为原始变量的点值。这是新方案中唯一需要从保守变量转换为原始变量的地方。然后,对原始变量的点值进行二次WENO重构,得到原始变量的分段高阶重构多项式。随后,重构多项式随时间演化,并将一种新的时空有限元预测器直接应用于以原始形式编写的控制PDE。由此得到的原始变量的时空多项式可以直接用作基础保守有限体积格式中单元边界处的数值通量的输入。因此,从保守变量到原始变量的必要转换次数减少到每个单元格中心只有一次转换。我们已经在广泛的双曲系统中验证了新方法的有效性,包括气体动力学的经典欧拉方程,特殊相对论流体动力学(RHD)和理想磁流体动力学(RMHD)方程,以及可压缩两相流的Baer-Nunziato模型。在所有情况下,我们都注意到,与基于守恒变量重构的ADER有限体积格式相比,新的ADER格式提供了更少的振荡解,特别是对于RMHD和Baer-Nunziato方程。对于RHD和RMHD方程,总体精度得到了提高,CPU时间减少了约25%。由于其精度的提高和计算成本的降低,我们建议使用该版本的ADER作为相对论框架中的标准版本。最后,将该方法推广到时空自适应网格(AMR)上的ad - dg方案。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Efficient conservative ADER schemes based on WENO reconstruction and space-time predictor in primitive variables

Efficient conservative ADER schemes based on WENO reconstruction and space-time predictor in primitive variables

We present a new version of conservative ADER-WENO finite volume schemes, in which both the high order spatial reconstruction as well as the time evolution of the reconstruction polynomials in the local space-time predictor stage are performed in primitive variables, rather than in conserved ones. To obtain a conservative method, the underlying finite volume scheme is still written in terms of the cell averages of the conserved quantities. Therefore, our new approach performs the spatial WENO reconstruction twice: the first WENO reconstruction is carried out on the known cell averages of the conservative variables. The WENO polynomials are then used at the cell centers to compute point values of the conserved variables, which are subsequently converted into point values of the primitive variables. This is the only place where the conversion from conservative to primitive variables is needed in the new scheme. Then, a second WENO reconstruction is performed on the point values of the primitive variables to obtain piecewise high order reconstruction polynomials of the primitive variables. The reconstruction polynomials are subsequently evolved in time with a novel space-time finite element predictor that is directly applied to the governing PDE written in primitive form. The resulting space-time polynomials of the primitive variables can then be directly used as input for the numerical fluxes at the cell boundaries in the underlying conservative finite volume scheme. Hence, the number of necessary conversions from the conserved to the primitive variables is reduced to just one single conversion at each cell center. We have verified the validity of the new approach over a wide range of hyperbolic systems, including the classical Euler equations of gas dynamics, the special relativistic hydrodynamics (RHD) and ideal magnetohydrodynamics (RMHD) equations, as well as the Baer-Nunziato model for compressible two-phase flows. In all cases we have noticed that the new ADER schemes provide less oscillatory solutions when compared to ADER finite volume schemes based on the reconstruction in conserved variables, especially for the RMHD and the Baer-Nunziato equations. For the RHD and RMHD equations, the overall accuracy is improved and the CPU time is reduced by about 25?%. Because of its increased accuracy and due to the reduced computational cost, we recommend to use this version of ADER as the standard one in the relativistic framework. At the end of the paper, the new approach has also been extended to ADER-DG schemes on space-time adaptive grids (AMR).

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期刊介绍: Computational Astrophysics and Cosmology (CompAC) is now closed and no longer accepting submissions. However, we would like to assure you that Springer will maintain an archive of all articles published in CompAC, ensuring their accessibility through SpringerLink's comprehensive search functionality.
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