通过实时预测牛顿-拉斐森迭代的初始猜测,加快水库模拟速度

IF 2.1 3区 地球科学 Q3 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
Musheg Petrosyants, Vladislav Trifonov, Egor Illarionov, Dmitry Koroteev
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引用次数: 0

摘要

我们研究了预测非线性牛顿-拉斐森求解器初始猜测的线性模型。这些模型使用一个或多个先前的模拟步骤进行预测,其参数用普通最小二乘法估算。这种方法的一个主要特点是,参数估计是利用在模拟过程中直接获得的数据进行的,而且模型是实时更新的。因此,我们避免了昂贵的数据集生成过程,也不需要预先训练模型。我们在多孔介质中两相流的标准基准 Egg 数据集上验证了该工作流程,并将其与估计初始猜测的标准方法进行了比较。我们证明,所提出的方法减少了牛顿-拉夫逊算法的迭代次数,加快了模拟时间。特别是在 Egg 数据集上,我们减少了 30% 的非线性迭代次数,并缩短了 20% 的模拟时间。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Speeding up the reservoir simulation by real time prediction of the initial guess for the Newton-Raphson’s iterations

We study linear models for the prediction of the initial guess for the nonlinear Newton-Raphson solver. These models use one or more of the previous simulation steps for prediction, and their parameters are estimated by the ordinary least-squares method. A key feature of the approach is that the parameter estimation is performed using data obtained directly during the simulation and the models are updated in real time. Thus we avoid the expensive process of dataset generation and the need for pre-trained models. We validate the workflow on a standard benchmark Egg dataset of two-phase flow in porous media and compare it to standard approaches for the estimation of initial guess. We demonstrate that the proposed approach leads to reduction in the number of iterations in the Newton-Raphson algorithm and speeds up simulation time. In particular, for the Egg dataset, we obtained a 30% reduction in the number of nonlinear iterations and a 20% reduction in the simulation time.

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来源期刊
Computational Geosciences
Computational Geosciences 地学-地球科学综合
CiteScore
6.10
自引率
4.00%
发文量
63
审稿时长
6-12 weeks
期刊介绍: Computational Geosciences publishes high quality papers on mathematical modeling, simulation, numerical analysis, and other computational aspects of the geosciences. In particular the journal is focused on advanced numerical methods for the simulation of subsurface flow and transport, and associated aspects such as discretization, gridding, upscaling, optimization, data assimilation, uncertainty assessment, and high performance parallel and grid computing. Papers treating similar topics but with applications to other fields in the geosciences, such as geomechanics, geophysics, oceanography, or meteorology, will also be considered. The journal provides a platform for interaction and multidisciplinary collaboration among diverse scientific groups, from both academia and industry, which share an interest in developing mathematical models and efficient algorithms for solving them, such as mathematicians, engineers, chemists, physicists, and geoscientists.
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