Abstract

We consider the estimation of parameter-dependent statistics of functional outputs of steady-state convection–diffusion–reaction equations with parametrized random and deterministic inputs in the framework of linear elliptic partial differential equations. For a given value of the deterministic parameter, a stochastic Galerkin finite element (SGFE) method can estimate the statistical moments of interest of a linear output at the cost of solving a single, large, block-structured linear system of equations. We propose a stochastic Galerkin reduced basis (SGRB) method as a means to lower the computational burden when statistical outputs are required for a large number of deterministic parameter queries. Our working assumption is that we have access to the computational resources necessary to set up such a reduced-order model for a spatial-stochastic weak formulation of the parameter-dependent model equations. In this scenario, the complexity of evaluating the SGRB model for a new value of the deterministic parameter only depends on the reduced dimension. To derive an SGRB model, we project the spatial-stochastic weak solution of a parameter-dependent SGFE model onto a reduced basis generated by a proper orthogonal decomposition (POD) of snapshots of SGFE solutions at representative values of the parameter. We propose residual-corrected estimates of the parameter-dependent expectation and variance of linear functional outputs and provide respective computable error bounds. We test the SGRB method numerically for a convection–diffusion–reaction problem, choosing the convective velocity as a deterministic parameter and the parametrized reactivity or diffusivity field as a random input. Compared to a standard reduced basis model embedded in a Monte Carlo sampling procedure, the SGRB model requires a similar number of reduced basis functions to meet a given tolerance requirement. However, only a single run of the SGRB model suffices to estimate a statistical output for a new deterministic parameter value, while the standard reduced basis model must be solved for each Monte Carlo sample.

Highlights

  • Convection–diffusion–reaction equations appear in many fields of science and engineering when modelling flow phenomena

  • Compared to a standard reduced basis model embedded in a Monte Carlo sampling procedure, the stochastic Galerkin reduced basis (SGRB) model requires a similar number of reduced basis functions to meet a given tolerance requirement

  • Only a single run of the SGRB model suffices to estimate a statistical output for a new deterministic parameter value, while the standard reduced basis model must be solved for each Monte Carlo sample

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Summary

Introduction

Convection–diffusion–reaction equations appear in many fields of science and engineering when modelling flow phenomena They describe the behavior of a physical quantity of interest in a considered domain under the influence of diffusive and convective effects when there is production. These types of equations are, for example, used to model combustion and chemotaxis, and appear in the context of the incompressible Navier–Stokes equations when solving the Oseen system or vorticity formulations. Our goal is to compute the parameter-dependent expected value and variance of a functional output of interest In this context, a reduced basis model provides a computationally inexpensive map between the deterministic input parameters and the corresponding output statistics.

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