Second order interlaced polynomial lattice rules for integration over Rs

Abstract

We study numerical integration of functions f: Rs R with respect to a probability measure. By applying the corresponding inverse cumulative distribution function, the problem is transformed into integrating an induced function over the unit cube (0,1)s. We introduce a new orthonormal system: order~2 localized Walsh functions. These basis functions retain the approximation power of classical Walsh functions for twice-differentiable integrands while inheriting the spatial localization of Haar wavelets. Localization is crucial because the transformed integrand is typically unbounded at the boundary. We show that the worst-case quasi-Monte Carlo integration error decays like O(N-1/λ) for every λ ∈ (1/2,1]. As an application, we consider elliptic partial differential equations with a finite number of log-normal random coefficients and show that our error estimates remain valid for their stochastic Galerkin discretizations by applying a suitable importance sampling density.