Extensible grids: uniform sampling on a space-filling curve

Abstract

We study the properties of points in [0,1]d generated by applying Hilbert's space-filling curve to uniformly distributed points in [0,1]. For deterministic sampling we obtain a discrepancy of O(n-1/d) for d2. For random stratified sampling, and scrambled van der Corput points, we get a mean squared error of O(n-1-2/d) for integration of Lipshitz continuous integrands, when d3. These rates are the same as one gets by sampling on d dimensional grids and they show a deterioration with increasing d. The rate for Lipshitz functions is however best possible at that level of smoothness and is better than plain IID sampling. Unlike grids, space-filling curve sampling provides points at any desired sample size, and the van der Corput version is extensible in n. Additionally we show that certain discontinuous functions with infinite variation in the sense of Hardy and Krause can be integrated with a mean squared error of O(n-1-1/d). It was previously known only that the rate was o(n-1). Other space-filling curves, such as those due to Sierpinski and Peano, also attain these rates, while upper bounds for the Lebesgue curve are somewhat worse, as if the dimension were 2(3) times as high.