A Tail-Respecting Splitting Numerical Scheme for Lévy-Driven SDEs With Superlinear Drifts

Abstract

We present an explicit numerical approximation scheme, denoted by \Xn\, for the effective simulation of solutions X to a multivariate stochastic differential equation (SDE) with a superlinearly growing κ-dissipative drift, where κ>1, driven by a multiplicative heavy-tailed Lévy process that has a finite p-th moment, with p>0. We show that the strong LpX-convergence t∈[0,T] E \|Xnt-Xt\|pX= O (hnγ) holds for any pX∈ (0,p+κ-1), which is exactly the range where the pX-moment of the solution is known to be finite. Additionally, for any pX∈ (0,p) we establish strong uniform convergence: Et∈[0,T] \|Xnt-Xt\|pX=O ( hnδ ). In both cases we determine the convergence rates γ and δ. In the special case of SDEs driven solely by a Brownian motion, our numerical scheme preserves super-exponential moments of the solution. The scheme \Xn\ is realized as a combination of a well-known Euler method with a Lie-Trotter type splitting technique.