Open AccessStochastic Finite Differences and Multilevel Monte Carlo for a Class of SPDEs in Finance
Author(s) -
Michael B. Giles,
Christoph Reisinger
Publication year - 2012
Publication title -
siam journal on financial mathematics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.251
H-Index - 33
ISSN - 1945-497X
DOI - 10.1137/110841916
Subject(s) - discretization , mathematics , partial differential equation , monte carlo method , stochastic differential equation , convergence (economics) , stochastic partial differential equation , boundary value problem , finite difference , boundary (topology) , mathematical analysis , statistics , economics , economic growth
In this article, we propose a Milstein finite difference scheme for a stochastic partial differential equation (SPDE) describing a large particle system. We show, by means of Fourier analysis, that the discretization on an unbounded domain is convergent of first order in the timestep and second order in the spatial grid size, and that the discretization is stable with respect to boundary data. Numerical experiments clearly indicate that the same convergence order also holds for boundary value problems. Multilevel path simulation, previously used for SDEs, is shown to give substantial complexity gains compared to a standard discretization of the SPDE or direct simulation of the particle system. We derive complexity bounds and illustrate the results by an application to basket credit derivatives. Copyright © 2012 by SIAM
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