Total variation distance between SDEs with stable noise and Brownian motion

Abstract

We consider a d-dimensional stochastic differential equation (SDE) of the form d Ut = b(Ut) dt + σ\,d Zt, let Xt be the solution if the driving noise Zt is a d-dimensional rotationally symmetric α-stable process (1<α<2), and let Yt be the solution if the driving noise is a d-dimensional Brownian motion. Continuing the work of [Deng,Schilling, Xu, Bernoulli, 23], we derive an estimate of the total variation distance \| L (Xt)- law(Yt)\| TV for all t>0, and we show that the ergodic measures μα and μ2 of Xt and Yt, respectively, satisfy \|μα-μ2\| TV ≤ Cd(1+d)α-1(2-α). We shall show that this bound is optimal with respect to α by an Ornstein--Uhlenbeck SDE. Combining this bound with a recent interpolation result from HRW23, we can derive a bound in Wasserstein-p distance (0< p <1): gather* \|μα-μ2\|Wp ≤Cd(p+3)/2(1+d)α-1 (2-α). gather* Key Words: Total variation distance, Wasserstein-p distance, stochastic differential equation, Poisson equation, stable process.

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