Existence and convergence results for infinite dimensional nonlinear stochastic equations with multiplicative noise

Abstract

The solution Xn to a nonlinear stochastic differential equation of the form dXn(t)+An(t)Xn(t)\,dt-12Σj=1N(Bjn(t))2Xn(t)\,dt=Σj=1N Bjn(t)Xn(t)dβjn(t)+fn(t)\,dt, Xn(0)=x, where βjn is a regular approximation of a Brownian motion βj, Bjn(t) is a family of linear continuous operators from V to H strongly convergent to Bj(t), An(t) A(t), \An(t)\ is a family of maximal monotone nonlinear operators of subgradient type from V to V', is convergent to the solution to the stochastic differential equation dX(t)+A(t)X(t)\,dt-12Σj=1NBj2(t)X(t)\,dt=Σj=1NBj(t)X(t)\,dβj(t)+f(t) \,dt, X(0)=x. Here V⊂ H H'⊂ V' where V is a reflexive Banach space with dual V' and H is a Hilbert space. These results can be reformulated in terms of Stratonovich stochastic equation dY(t)+A(t)Y(t)\,dt=Σj=1NBj(t)Y(t) dβj(t)+f(t)\,dt.