Hendrik Fischer, Julian Roth, Ludovic Chamoin, Amélie Fau, Mary Wheeler, Thomas Wick
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引用次数: 0
摘要
在这项工作中,针对多孔介质中的单相流问题,扩展并进一步发展了时空 MORe DWR(双加权残差误差估计的模型阶次缩减)框架。具体来说,我们的问题陈述是由矢量位移(地质力学)与达西流动压力方程耦合而成的 Biot 系统。MORe DWR 方法引入了一种以目标为导向、基于正交分解(POD)的自适应增量减阶模型(ROM)。在模拟过程中,对还原目标函数中的误差进行估算,如果估算值超过给定阈值,则对 POD 基础进行即时增强。这就减少了多孔介质模拟的全阶模型求解总数,对相关量进行了稳健的估计,并为当前问题提供了合适的简化基础。我们在空间采用了带有泰勒胡德元素的时空 Galerkin 离散化方法,在时间采用了带有片断常数函数的非连续 Galerkin 方法。众所周知,后者类似于后向欧拉方案。我们在著名的二维 Mandel 基准和三维地基问题上演示了我们方法的效率。
Adaptive space-time model order reduction with dual-weighted residual (MORe DWR) error control for poroelasticity
In this work, the space-time MORe DWR (Model Order Reduction with Dual-Weighted Residual error estimates) framework is extended and further developed for single-phase flow problems in porous media. Specifically, our problem statement is the Biot system which consists of vector-valued displacements (geomechanics) coupled to a Darcy flow pressure equation. The MORe DWR method introduces a goal-oriented adaptive incremental proper orthogonal decomposition (POD) based-reduced-order model (ROM). The error in the reduced goal functional is estimated during the simulation, and the POD basis is enriched on-the-fly if the estimate exceeds a given threshold. This results in a reduction of the total number of full-order-model solves for the simulation of the porous medium, a robust estimation of the quantity of interest and well-suited reduced bases for the problem at hand. We apply a space-time Galerkin discretization with Taylor-Hood elements in space and a discontinuous Galerkin method with piecewise constant functions in time. The latter is well-known to be similar to the backward Euler scheme. We demonstrate the efficiency of our method on the well-known two-dimensional Mandel benchmark and a three-dimensional footing problem.
期刊介绍:
The research topics addressed by Advanced Modeling and Simulation in Engineering Sciences (AMSES) cover the vast domain of the advanced modeling and simulation of materials, processes and structures governed by the laws of mechanics. The emphasis is on advanced and innovative modeling approaches and numerical strategies. The main objective is to describe the actual physics of large mechanical systems with complicated geometries as accurately as possible using complex, highly nonlinear and coupled multiphysics and multiscale models, and then to carry out simulations with these complex models as rapidly as possible. In other words, this research revolves around efficient numerical modeling along with model verification and validation. Therefore, the corresponding papers deal with advanced modeling and simulation, efficient optimization, inverse analysis, data-driven computation and simulation-based control. These challenging issues require multidisciplinary efforts – particularly in modeling, numerical analysis and computer science – which are treated in this journal.