Optimal Strong Approximation of the One-dimensional Squared Bessel Process

Abstract

We consider the one-dimensional squared Bessel process given by the stochastic differential equation (SDE) align* dXt = 1\,dt + 2Xt\,dWt, X0=x0, t∈[0,1], align* and study strong (pathwise) approximation of the solution X at the final time point t=1. This SDE is a particular instance of a Cox-Ingersoll-Ross (CIR) process where the boundary point zero is accessible. We consider numerical methods that have access to values of the driving Brownian motion W at a finite number of time points. We show that the polynomial convergence rate of the n-th minimal errors for the class of adaptive algorithms as well as for the class of algorithms that rely on equidistant grids are equal to infinity and 1/2, respectively. This shows that adaption results in a tremendously improved convergence rate. As a by-product, we obtain that the parameters appearing in the CIR process affect the convergence rate of strong approximation.