2000
DOI: 10.1090/s0025-5718-00-01203-5
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Testing multivariate uniformity and its applications

Abstract: Abstract. Some new statistics are proposed to test the uniformity of random samples in the multidimensional unit cube [0, 1] d (d ≥ 2). These statistics are derived from number-theoretic or quasi-Monte Carlo methods for measuring the discrepancy of points in [0, 1] d . Under the null hypothesis that the samples are independent and identically distributed with a uniform distribution in [0, 1] d , we obtain some asymptotic properties of the new statistics. By Monte Carlo simulation, it is found that the finite-s… Show more

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Cited by 48 publications
(67 citation statements)
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“…This phenomenon is clearly observed in the simulations of Section 3 below as well as in those given by Liang et al (2001). At first sight, this could seem a bit surprising as it contradicts the well-known "curse of dimensionality" phenomenon which affects many statistical procedures.…”
Section: Theorem 2 Every Convex Polyhedron (With Deepest Point At 0)mentioning
confidence: 69%
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“…This phenomenon is clearly observed in the simulations of Section 3 below as well as in those given by Liang et al (2001). At first sight, this could seem a bit surprising as it contradicts the well-known "curse of dimensionality" phenomenon which affects many statistical procedures.…”
Section: Theorem 2 Every Convex Polyhedron (With Deepest Point At 0)mentioning
confidence: 69%
“…A different approach is followed in the paper by Liang, Fang, Hickernell and Li (2001) where several tests are proposed for testing uniformity on [0, 1] d . These tests are based on non-trivial number-theoretic considerations and can be used even in high-dimensional cases.…”
Section: Introductionmentioning
confidence: 99%
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“…Using an argument based on the probability integral transform (see e.g. [1], for the result and [27], for applications to Stochastic Programming) and on its multivariate generalization ( [29]; see [20], p. 354, for an application to Numerical Analysis), it is possible to create random vectors with arbitrary distributions: however, this method often requires the evaluation of complex functions (quantile functions of conditional distributions) and can be quite time-demanding in practice. Moreover, quasi-Monte Carlo methods require more stringent hypotheses on the behavior of the function g: indeed, while any Lebesgue integrable function can be integrated using Monte Carlo algorithms, low discrepancy point sets require the function to be Riemann integrable (however, in order to derive a convergence rate it also has to be of bounded variation in the sense of HardyKrause).…”
Section: Example 3 (Quasi-monte Carlo)mentioning
confidence: 99%
“…Set N 1 x∈X k≥1 N 1 (x, k), where we recall that X is a dense countable subset of X. Inequality (12) is valid for ω ∈ Ω\N 1 , k ≥ 1 and x ∈ X ; moreover, it remains valid for any x ∈ X because each side of (12) defines a Lipschitz function of x, with Lipschitz constant k. Then, taking the supremum, with respect to k, in both sides of (12) and using formula (20) together with the monotone convergence theorem, we obtain (9).…”
Section: Proofsmentioning
confidence: 99%