# Adaptive Algebraic Multiscale Solver for Compressible Flow in   Heterogeneous Porous Media

**Authors:** Matei Tene, Yixuan Wang, Hadi Hajibeygi

arXiv: 1705.05783 · 2017-05-17

## TL;DR

This paper introduces an adaptive algebraic multiscale solver tailored for compressible flow in heterogeneous porous media, improving efficiency and convergence over traditional methods through adaptive updates and specialized basis functions.

## Contribution

The paper develops a novel adaptive algebraic multiscale solver for compressible flow, incorporating multiple basis function formulations and adaptive operator updates for enhanced efficiency.

## Key findings

- C-AMS outperforms industrial-grade AMG in efficiency.
- Adaptive updates reduce computational costs.
- Various basis functions influence convergence behavior.

## Abstract

This paper presents the development of an Adaptive Algebraic Multiscale Solver for Compressible flow (C-AMS) in heterogeneous porous media. Similar to the recently developed AMS for incompressible (linear) flows [Wang et al., JCP, 2014], C-AMS operates by defining primal and dual-coarse blocks on top of the fine-scale grid. These coarse grids facilitate the construction of a conservative (finite volume) coarse-scale system and the computation of local basis functions, respectively. However, unlike the incompressible (elliptic) case, the choice of equations to solve for basis functions in compressible problems is not trivial. Therefore, several basis function formulations (incompressible and compressible, with and without accumulation) are considered in order to construct an efficient multiscale prolongation operator. As for the restriction operator, C-AMS allows for both multiscale finite volume (MSFV) and finite element (MSFE) methods. Finally, in order to resolve high-frequency errors, fine-scale (pre- and post-) smoother stages are employed. In order to reduce computational expense, the C-AMS operators (prolongation, restriction, and smoothers) are updated adaptively. In addition to this, the linear system in the Newton-Raphson loop is infrequently updated. Systematic numerical experiments are performed to determine the effect of the various options, outlined above, on the C-AMS convergence behaviour. An efficient C-AMS strategy for heterogeneous 3D compressible problems is developed based on overall CPU times. Finally, C-AMS is compared against an industrial-grade Algebraic MultiGrid (AMG) solver. Results of this comparison illustrate that the C-AMS is quite efficient as a nonlinear solver, even when iterated to machine accuracy.

## Full text

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## Figures

68 figures with captions in the complete paper: https://tomesphere.com/paper/1705.05783/full.md

## References

32 references — full list in the complete paper: https://tomesphere.com/paper/1705.05783/full.md

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Source: https://tomesphere.com/paper/1705.05783