2014
DOI: 10.1007/s10208-014-9226-8
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Construction of Interlaced Scrambled Polynomial Lattice Rules of Arbitrary High Order

Abstract: Higher order scrambled digital nets are randomized quasi-Monte Carlo rules which have recently been introduced in [J. Dick, Ann. Statist., 39 (2011), 1372-1398 and shown to achieve the optimal rate of convergence of the root mean square error for numerical integration of smooth functions defined on the s-dimensional unit cube. The key ingredient there is a digit interlacing function applied to the components of a randomly scrambled digital net whose number of components is ds, where the integer d is the so-ca… Show more

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Cited by 44 publications
(62 citation statements)
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“…A key component for obtaining higher-order convergence rates is the interlacing of lattice point sets, as introduced in [6]. To this end, we define the digit interlacing function, which maps α points in [0, 1) to one point in [0, 1).…”
Section: Definitionsmentioning
confidence: 99%
See 1 more Smart Citation
“…A key component for obtaining higher-order convergence rates is the interlacing of lattice point sets, as introduced in [6]. To this end, we define the digit interlacing function, which maps α points in [0, 1) to one point in [0, 1).…”
Section: Definitionsmentioning
confidence: 99%
“…In the present paper, we consider the realization of novel higher-order interlaced polynomial lattice rules introduced in [4,6], which allow an integrand-adapted construction of a quasi-Monte Carlo quadrature rule that exploits sparsity of the parameter-to-solution map. We consider in what follows the problem of integrating a function f : [0, 1) s → R of s variables y 1 , .…”
Section: Introductionmentioning
confidence: 99%
“…, q αj should be searched for simultaneously. The papers [35,33] originally gave a justification for employing the former approach, i.e., component-by-component construction.…”
Section: Digit Interlacing Constructionmentioning
confidence: 99%
“…We denote the ν-th partial derivative of f by ∂ ν f = (∂ |ν| f )/(∂ ν 1 y 1 ∂ ν 2 y 2 · · · ∂ νs ys ). This function space setting can be paired with interlaced polynomial lattice rules [30,31] to achieve higher order convergence rates in the unit cube. A polynomial lattice rule [64] is similar to a lattice rule (see (3) without the random shift ∆), but instead of a generating vector of integers we have a generating vector of polynomials, and thus the regular multiplication and division are replaced by their polynomial equivalents.…”
Section: Setting 3: Smooth Integrands In the Unit Cubementioning
confidence: 99%