Proves temporal convergence rate of almost 1 for stochastic-convolution-based approximations of nonlinear 1+1D SPDEs with additive space-time white noise, improving on the optimal 1/4 rate for Wiener-increment schemes.
Strong and weak divergence of exponential and linear-implicit Euler approximations for stochastic partial differential equations with superlinearly growing nonlinearities
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abstract
The explicit Euler scheme and similar explicit approximation schemes (such as the Milstein scheme) are known to diverge strongly and numerically weakly in the case of one-dimensional stochastic ordinary differential equations with superlinearly growing nonlinearities. It remained an open question whether such a divergence phenomenon also holds in the case of stochastic partial differential equations with superlinearly growing nonlinearities such as stochastic Allen-Cahn equations. In this work we solve this problem by proving that full-discrete exponential Euler and full-discrete linear-implicit Euler approximations diverge strongly and numerically weakly in the case of stochastic Allen-Cahn equations. This article also contains a short literature overview on existing numerical approximation results for stochastic differential equations with superlinearly growing nonlinearities.
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Tamed-FEM yields time-uniform strong convergence rates and Wasserstein-2 convergence of invariant measures for superlinear SPDEs driven by multiplicative noise.
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