Discretizing Malliavin calculus
Abstract
Suppose is a Brownian motion and is an approximating sequence of rescaled random walks on the same probability space converging to pointwise in probability. We provide necessary and sufficient conditions for weak and strong -convergence of a discretized Malliavin derivative, a discrete Skorokhod integral, and discrete analogues of the Clark-Ocone derivative to their continuous counterparts. Moreover, given a sequence of random variables which admit a chaos decomposition in terms of discrete multiple Wiener integrals with respect to , we derive necessary and sufficient conditions for strong -convergence to a -measurable random variable via convergence of the discrete chaos coefficients of to the continuous chaos coefficients of . In the special case of binary noise, our results support the known formal analogies between Malliavin calculus on the Wiener space and Malliavin calculus on the Bernoulli space by rigorous -convergence results.
Keywords
Cite
@article{arxiv.1602.08858,
title = {Discretizing Malliavin calculus},
author = {Christian Bender and Peter Parczewski},
journal= {arXiv preprint arXiv:1602.08858},
year = {2016}
}
Comments
36 pages, 1 figure