Optimization of the Mean-Square Approximation Procedures for Iterated Ito Stochastic Integrals of Multiplicities 1 to 5 from the Unified Taylor-Ito Expansion Based on Multiple Fourier-Legendre Series

TL;DR

This paper improves the efficiency of mean-square approximation procedures for iterated Ito stochastic integrals of multiplicities 1 to 5, crucial for high-order numerical solutions of stochastic differential equations, by reducing the required sequence lengths.

Contribution

It introduces optimized methods using multiple Fourier-Legendre series that significantly decrease the sequence lengths needed without sacrificing accuracy.

Findings

Sequence lengths can be significantly reduced.

Maintains mean-square accuracy of approximations.

Applicable to stochastic differential equations with non-commutative noise.

Abstract

The article is devoted to optimization of the mean-square approximation procedures for iterated Ito stochastic integrals of multiplicities 1 to 5. The mentioned stochastic integrals are part of strong numerical methods with convergence orders 1.0, 1.5, 2.0, and 2.5 for Ito stochastic differential equations with multidimensional non-commutative noise based on the unified Taylor-Ito expansion and multiple Fourier-Legendre series converging in the sense of norm in Hilbert space $L_2([t, T]^k)$ $(k=1,\ldots,5).$ In this article we use multiple Fourier-Legendre series within the framework of the method of expansion and mean-square approximation of iterated Ito stochastic integrals based on generalized multiple Fourier series. We show that the lengths of sequences of independent standard Gaussian random variables required for the mean-square approximation of iterated Ito stochastic integrals of multiplicities 1 to 5 can be significantly reduced without the loss of the mean-square accuracy of approximation for these stochastic integrals.