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Bibliographic Details
Main Author: Liu, Yanghui
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2401.16338
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author Liu, Yanghui
author_facet Liu, Yanghui
contents In this paper, we consider a "compensated" random sum that arises from numerical approximation of stochastic integrations and differential equations. We show that the compensated sum exhibits some surprising cancellations among its components, a property which allows to transform it into a Skorohod-type Riemann sum. We then establish limit theorem for the compensated sum based on study of the Skorohod-type Riemann sum. Our proof employs techniques from Malliavin calculus and rough path. We apply our limit theorem result to the Euler approximation method for stochastic integrals and additive stochastic differential equations, filling a notable gap in this area of research. We show that the Euler method converges to the solution at the rate $(1/n)^{H+1/2}$, and that this rate is exact in the sense that the asymptotic error distribution solves a linear differential equation.
format Preprint
id arxiv_https___arxiv_org_abs_2401_16338
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Limit theorems for compensated weighted sums and application to numerical approximations
Liu, Yanghui
Probability
60F17, 60H07
In this paper, we consider a "compensated" random sum that arises from numerical approximation of stochastic integrations and differential equations. We show that the compensated sum exhibits some surprising cancellations among its components, a property which allows to transform it into a Skorohod-type Riemann sum. We then establish limit theorem for the compensated sum based on study of the Skorohod-type Riemann sum. Our proof employs techniques from Malliavin calculus and rough path. We apply our limit theorem result to the Euler approximation method for stochastic integrals and additive stochastic differential equations, filling a notable gap in this area of research. We show that the Euler method converges to the solution at the rate $(1/n)^{H+1/2}$, and that this rate is exact in the sense that the asymptotic error distribution solves a linear differential equation.
title Limit theorems for compensated weighted sums and application to numerical approximations
topic Probability
60F17, 60H07
url https://arxiv.org/abs/2401.16338