Approximating the coefficients in semilinear stochastic partial differential equations

Abstract

We investigate, in the setting of UMD Banach spaces E, the continuous dependence on the data A, F, G and X0 of mild solutions of semilinear stochastic evolution equations with multiplicative noise of the form dX(t) = [AX(t) + F(t,X(t))]dt + G(t,X(t))dWH(t), X(0)=X0, where WH is a cylindrical Brownian motion on a Hilbert space H. We prove continuous dependence of the compensated solutions X(t)-etAX0 in the norms Lp(;Cλ([0,T];E)) assuming that the approximating operators An are uniformly sectorial and converge to A in the strong resolvent sense, and that the approximating nonlinearities Fn and Gn are uniformly Lipschitz continuous in suitable norms and converge to F and G pointwise. Our results are applied to a class of semilinear parabolic SPDEs with finite-dimensional multiplicative noise.