Massing, Till2021-11-282021-11-282021http://hdl.handle.net/2003/40577http://dx.doi.org/10.17877/DE290R-22446We consider the simulation of a system of decoupled forward-backward stochastic differential equations (FBSDEs) driven by a pure jump Lévy process L and an independent Brownian motion B. We allow the Lévy process L to have an infinite jump activity. Therefore, it is necessary for the simulation to employ a finite approximation of its Lévy measure. We use the generalized shot noise series representation method by Rosinski (2001) to approximate the driving Lévy process L. We compute the Lp error, p > 2, between the true and the approximated FBSDEs which arises from the finite truncation of the shot noise series (given sufficient conditions for existence and uniqueness of the FBSDE). We also derive the Lp error between the true solution and the discretization of the approximated FBSDE using an appropriate backward Euler scheme.endecoupled forward-backward SDEs with jumpsEuler SchemeDiscrete-time approximationshot noise series representationLévy processes310330620Text