Numerical approximation of the stochastic heat equation with a distributional reaction term
Abstract
We study the numerical approximation of the stochastic heat equation with a distributional reaction term. Under a condition on the Besov regularity of the reaction term, it was proven recently that a strong solution exists and is unique in the pathwise sense, in a class of H\"older continuous processes. For a suitable choice of sequence (bk)k∈ N approximating b, we prove that the error between the solution u of the SPDE with reaction term b and its tamed Euler finite-difference scheme with mollified drift bk, converges to 0 in Lm() with a rate that depends on the Besov regularity of b. In particular, one can consider two interesting cases: first, even when b is only a (finite) measure, a rate of convergence is obtained. On the other hand, when b is a bounded measurable function, the (almost) optimal rate of convergence (12-)-in space and (14-)-in time is achieved. Stochastic sewing techniques are used in the proofs, in particular to deduce new regularising properties of the discrete Ornstein-Uhlenbeck process.
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