Time discretization of Quadratic Forward-Backward SDEs with singular drifts
Abstract
We investigate the convergence rate for the time discretization of a class of quadratic backward SDEs -- potentially involving path-dependent terminal values -- when coupled with non-standard Lipschitz-type forward SDEs. In our review of the explicit time-discretization schemes in the spirit of Pag\`es \& Sagna (see PaSa18), we achieve an error control close to 12, even under the modest assumptions considered in this work (see ChaRichou16, for comparison). A central element of our approach is a thorough re-examination of Zhang's L2-time regularity of the martingale integrand Z which follows from an extension of the first-order variational regularity for this class of singular forward-backward SDEs with non-uniform Cauchy-Lipschitz drivers. This is complemented by the recently introduced caracterisation of stochastic processes of bounded mean oscillation (abbreviated as ) by K. L\e (see Le22) which we used to derive an Lp-version of the strong approximation of SDEs with singular drifts from Dareiotis \& Gerencs\'er (see DaGe20). As such, this study addresses a crucial gap in the numerical analysis of forward-backward SDEs (FBSDEs). To our knowledge, for the first time, the impact of regularization by noise on Euler-Maruyama numerical schemes for singular forward SDEs has been successfully transferred to enhance the convergence rate of the discrete time approximations for solutions to backward SDEs.
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