Quasi-Monte Carlo methods are used for numerically integrating multivariate functions. However, the error bounds for these methods typically rely on a priori knowledge of some semi-norm of the integrand, not on the sampled function values. In this article, we propose an error bound based on the discrete Fourier coefficients of the integrand. If these Fourier coefficients decay more quickly, the integrand has less fine scale structure, and the accuracy is higher. We focus on rank-1 lattices because they are a commonly used quasi-Monte Carlo design and because their algebraic structure facilitates an error analysis based on a Fourier decomposition of the integrand. This leads to a guaranteed adaptive cubature algorithm with computational cost O(mbm), where b is some fixed prime number and bm is the number of data points.
CITATION STYLE
Rugama, L. A. J., & Hickernell, F. J. (2016). Adaptive multidimensional integration based on rank-1 lattices. In Springer Proceedings in Mathematics and Statistics (Vol. 163, pp. 407–422). Springer New York LLC. https://doi.org/10.1007/978-3-319-33507-0_20
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