We present a multilevel Monte Carlo (MLMC) method for the uncertainty quantification of variably saturated porous media flow that are modeled using the Richards’ equation. We propose a stochastic extension for the empirical models that are typically employed to close the Richards’ equations. This is achieved by treating the soil parameters in these models as spatially correlated random fields with appropriately defined marginal distributions. As some of these parameters can only take values in a specific range, non-Gaussian models are utilized. The randomness in these parameters may result in path-wise highly nonlinear systems, so that a robust solver with respect to the random input is required. For this purpose, a solution method based on...
Abstract We consider the numerical solution of elliptic par-tial differential equations with random ...
Spatial heterogeneity of geologic media leads to uncertainty in predicting both flow and transport i...
In this study, we apply four Monte Carlo simulation methods, namely, Monte Carlo, quasi-Monte Carlo,...
We present a multilevel Monte Carlo (MLMC) method for the uncertainty quantification of variably sat...
This is the author accepted manuscript. The final version is available from Society for Industrial a...
In this paper we address the problem of the prohibitively large computational cost of existing Marko...
In this paper we address the problem of the prohibitively large computational cost of ex-isting Mark...
In many models used in engineering and science, material properties are uncertain or spatially varyi...
In many models used in engineering and science, material properties are uncertain or spatially varyi...
Uncertainty is ubiquitous in many areas of science and engineering. It may result from the inadequac...
We consider the numerical solution of elliptic partial differential equations with random coefficien...
textabstractA multilevel Monte Carlo (MLMC) method for Uncertainty Quantification (UQ) of advection-...
This work presents the application of a Monte Carlo simulation method to perform an statistical anal...
We devise and implement quasi-Monte Carlo methods for computing the expectations of nonlinear functi...
In this paper, we study multiscale finite element methods for stochastic porous media flow equations...
Abstract We consider the numerical solution of elliptic par-tial differential equations with random ...
Spatial heterogeneity of geologic media leads to uncertainty in predicting both flow and transport i...
In this study, we apply four Monte Carlo simulation methods, namely, Monte Carlo, quasi-Monte Carlo,...
We present a multilevel Monte Carlo (MLMC) method for the uncertainty quantification of variably sat...
This is the author accepted manuscript. The final version is available from Society for Industrial a...
In this paper we address the problem of the prohibitively large computational cost of existing Marko...
In this paper we address the problem of the prohibitively large computational cost of ex-isting Mark...
In many models used in engineering and science, material properties are uncertain or spatially varyi...
In many models used in engineering and science, material properties are uncertain or spatially varyi...
Uncertainty is ubiquitous in many areas of science and engineering. It may result from the inadequac...
We consider the numerical solution of elliptic partial differential equations with random coefficien...
textabstractA multilevel Monte Carlo (MLMC) method for Uncertainty Quantification (UQ) of advection-...
This work presents the application of a Monte Carlo simulation method to perform an statistical anal...
We devise and implement quasi-Monte Carlo methods for computing the expectations of nonlinear functi...
In this paper, we study multiscale finite element methods for stochastic porous media flow equations...
Abstract We consider the numerical solution of elliptic par-tial differential equations with random ...
Spatial heterogeneity of geologic media leads to uncertainty in predicting both flow and transport i...
In this study, we apply four Monte Carlo simulation methods, namely, Monte Carlo, quasi-Monte Carlo,...