In this paper we study the approximation of the distribution of $X_t$
Hilbert--valued stochastic process solution of a linear parabolic stochastic
partial differential equation written in an abstract form as $$ dX_t+AX_t dt =
Q^{1/2} d W_t, \quad X_0=x \in H, \quad t\in[0,T], $$ driven by a Gaussian
space time noise whose covariance operator $Q$ is given. We assume that
$A^{-\alpha}$ is a finite trace operator for some $\alpha>0$ and that $Q$ is
bounded from $H$ into $D(A^\beta)$ for some $\beta\geq 0$. It is not required
to be nuclear or to commute with $A$. The discretization is achieved thanks to
finite element methods in space (parameter $h>0$) and implicit Euler schemes in
time (parameter $\Delta t=T/N$). We define a discrete solution $X^n_h$ and for
suitable functions $\phi$ defined on $H$, we show that $$ |\E \phi(X^N_h) - \E
\phi(X_T) | = O(h^{2\gamma} + \Delta t^\gamma) $$ \noindent where $\gamma<1-
\alpha + \beta$. Let us note that as in the finite dimensional case the rate of
convergence is twice the one for pathwise approximations

Debussche, Arnaud

Printems, Jacques

English

arXiv

International audienceIn this paper we study the approximation of the distribution of $X_t$ Hilbert--valued stochastic process solution of a linear parabolic stochastic partial differential equation written in an abstract form as $$ dX_t+AX_t \, dt = Q^{1/2} d W_t, \quad X_0=x \in H, \quad t\in[0,T], $$ driven by a Gaussian space time noise whose covariance operator $Q$ is given. We assume that $A^{-\alpha}$ is a finite trace operator for some $\alpha>0$ and that $Q$ is bounded from $H$ into $D(A^\beta)$ for some $\beta\geq 0$. It is not required to be nuclear or to commute with $A$. The discretization is achieved thanks to finite element methods in space (parameter $h>0$) and implicit Euler schemes in time (parameter $\Delta t=T/N$). We define a discrete solution $X^n_h$ and for suitable functions $\varphi$ defined on $H$, we show that $$ |\E \, \varphi(X^N_h) - \E \, \varphi(X_T) | = O(h^{2\gamma} + \Delta t^\gamma) $$ \noindent where $\gamma<1- \alpha + \beta$. Let us note that as in the finite dimensional case the rate of convergence is twice the one for pathwise approximations

Weak order for the discretization of the stochastic heat equation

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