Elliptic equations of higher stochastic order

Lototsky, Sergey V.; Rozovskiĭ, B. L.; Wan, Xiaoliang

doi:10.1051/m2an/2010055

Cited by 16 publications

(5 citation statements)

References 23 publications

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“…In this work, we consider a general case, where we assume that a(x,ω) is lognormal and the underlying Gaussian random process is homogeneous stationary and ergodicity is not required. For such a set-up, we refer to [1,2,[6][7][8]14] and references therein for theoretical and numerical studies for model I and [9][10][11][17][18][19] and references therein for model II. The difference between models I and II is twofold: a scaling factor induced by the way of applying the Wick product and the regularization induced by the Wick product itself.…”

Section: Introductionmentioning

confidence: 99%

A Discussion on Two Stochastic Elliptic Modeling Strategies

Wan

2012

Commun. comput. phys.

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Based on the study of two commonly used stochastic elliptic models: I: − ∇· (a(x,w)·∇u(x,w)) = f (x) and II: − ∇·(a(x,w)◊∇u(x,w)) = f (x), we constructed a new stochastic elliptic model III: −∇ ◊ ((a−1)·(−1)◊∇u(x,w)) = f (x), in. The difference between models I and II is twofold: a scaling factor induced by the way of applying the Wick product and the regularization induced by the Wick product itself. In, we showed that model III has the same scaling factor as model I. In this paper we present a detailed discussion about the difference between models I and III with respect to the two characteristic parameters of the random coefficient, i.e., the standard deviation σ and the correlation length lc. Numerical results are presented for both one- and two-dimensional cases.

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Section: Introductionmentioning

confidence: 99%

A Discussion on Two Stochastic Elliptic Modeling Strategies

Wan

2012

Commun. comput. phys.

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“…This model has been studied in the past, for example, by Wan et al [8], Theting [16] and Lototsky et al [17]. The main motivation was that the Wick product is consistent with the Skorokhod stochastic integral, and it is expected that the solution can be smoothed to some extent by the convolution in the probability space.…”

Section: B Ipmentioning

confidence: 99%

Wick–Malliavin approximation to nonlinear stochastic partial differential equations: analysis and simulations

et al. 2013

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Approximating nonlinearities in stochastic partial differential equations (SPDEs) via the Wick product has often been used in quantum field theory and stochastic analysis. The main benefit is simplification of the equations but at the expense of introducing modelling errors. In this paper, we study the accuracy and computational efficiency of Wick-type approximations to SPDEs and demonstrate that the Wick propagator, i.e. the system of equations for the coefficients of the polynomial chaos expansion of the solution, has a sparse lower triangular structure that is seemingly universal, i.e. independent of the type of noise. We also introduce new higher-order stochastic approximations via Wick-Malliavin series expansions for Gaussian and uniformly distributed noises, and demonstrate convergence as the number of expansion terms increases. Our results are for diffusion, Burgers and Navier-Stokes equations, but the same approach can be readily adopted for other nonlinear SPDEs and more general noises.

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“…Theoretical difficulties of problem (1) are mainly related to the lack of uniform ellipticity, where the Lax-Milgram lemma is not applicable. The existence and uniqueness of the solution of problem (1) are usually established with respect to a weighted norm [11,20,29] or a weighted measure [24], or by using the Fernique theorem [7,33]. Considering the Wiener chaos approach and Galerkin projection [10,20], the difficulties of numerical approximation of problem (1) are twofold: First, if we start from the theoretical study [24,29], a different test space rather than L 2 (F; H 1 0 (D)) is required,,which may be not easy to construct.…”

Section: Introductionmentioning

confidence: 99%

“…The existence and uniqueness of the solution of problem (1) are usually established with respect to a weighted norm [11,20,29] or a weighted measure [24], or by using the Fernique theorem [7,33]. Considering the Wiener chaos approach and Galerkin projection [10,20], the difficulties of numerical approximation of problem (1) are twofold: First, if we start from the theoretical study [24,29], a different test space rather than L 2 (F; H 1 0 (D)) is required,,which may be not easy to construct. Here F := (Ω, F, P ) is the probability space for ω, detailed presentation of F is given in Section 2.…”

Section: Introductionmentioning

confidence: 99%

Numerical Approximation of Elliptic Problems With Log-Normal Random Coefficients

Wan

2019

Int. J. UncertaintyQuantification

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In this work, we consider a non-standard preconditioning strategy for the numerical approximation of the classical elliptic equations with log-normal random coefficients. In [45], a Wick-type elliptic model was proposed by modeling the random flux through the Wick product. Due to the lower-triangular structure of the uncertainty propagator, this model can be approximated efficiently using the Wiener chaos expansion in the probability space. Such a Wick-type model provides, in general, a second-order approximation of the classical one in terms of the standard deviation of the underlying Gaussian process. Furthermore, when the correlation length of the underlying Gaussian process goes to infinity, the Wick-type model yields the same solution as the classical one. These observations imply that the Wick-type elliptic equation can provide an effective preconditioner for the classical random elliptic equation under appropriate conditions. We use the Wick-type elliptic model to accelerate the Monte Carlo method and the stochastic Galerkin finite element method. Numerical results are presented and discussed.

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Elliptic equations of higher stochastic order

Cited by 16 publications

References 23 publications

A Discussion on Two Stochastic Elliptic Modeling Strategies

A Discussion on Two Stochastic Elliptic Modeling Strategies

Wick–Malliavin approximation to nonlinear stochastic partial differential equations: analysis and simulations

Numerical Approximation of Elliptic Problems With Log-Normal Random Coefficients

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