Optimized multilevel Monte Carlo methods in Banach spaces
摘要
We present a theoretical and numerical analysis of Monte Carlo methods for the estimation of statistical moments of random variables taking values in a Banach space . For practical computation, we consider finite-dimensional approximation subspaces of increasing dimension. We develop a refined error analysis that explicitly accounts for a dependence of the Rademacher type constants on the dimension of , leading to novel complexity results for single- and multilevel Monte Carlo methods to estimate the mean and injective moments of arbitrary order, which are, in certain cases, sharper than those derived in [Kirchner, Schwab, J. Funct. Anal, 2024]. Moreover, we show that, in favorable cases, the resulting error-vs.-work bounds are independent of the Rademacher type of . We then focus on -valued random variables for a -finite measure space satisfying certain approximation properties, and prove that for a random variable , with and , the -convergence rate of a Monte Carlo estimator is determined exclusively by the integrability parameter , with no dependence on the Rademacher type of . We further investigate the impact of measuring the (multilevel) Monte Carlo error in the -norm while possesses additional regularity, with . This analysis reveals an interplay between the sampling error and the strong approximation error, and leads to optimized error-vs.-work bounds for both single- and multilevel Monte Carlo methods. Numerical experiments confirm the sharpness of the analyses presented.
引用
@article{arxiv.2605.24620,
title = {Optimized multilevel Monte Carlo methods in Banach spaces},
author = {Kristin Kirchner and Fabio Nobile and Christoph Schwab and Tommaso Vanzan},
journal= {arXiv preprint arXiv:2605.24620},
year = {2026}
}
备注
46 pages, 6 figures