We consider a system of stochastic differential equations driven by a standard n-dimensional Brownian motion where the drift coefficient satisfies a Novikov-type condition while the diffusion coefficient is the identity matrix. We define a vector Z of square integrable stochastic processes with the following property: if the filtration of the translated Brownian motion obtained from the Girsanov transform coincides with the one of the driving noise then Z coincides with the unique strong solution of the equation; otherwise the process Z solves in the strong sense a related stochastic differential inequality. This fact together with an additional assumption will provide a comparison result similar to well known theorems obtained in the presence of strong solutions.
A strong and weak approximation scheme for stochastic differential equations driven by a time-changed Brownian motion
The rate of convergence of Euler approximations for solutions of stochastic differential equations driven by fractional Brownian motion
First exit times of solutions of stochastic differential equations driven by multiplicative Levy noise with heavy tails
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