Sparsity for Infinite-Parametric Holomorphic Functions on Gaussian Spaces

Abstract

We investigate the sparsity of Wiener polynomial chaos expansions of holomorphic maps G on Gaussian Hilbert spaces, as arise in the coefficient-to-solution maps of linear, second order, divergence-form elliptic PDEs with log-Gaussian diffusion coefficient. Representing the Gaussian random field input as an affine-parametric expansion, the nonlinear map becomes a countably-parametric, deterministic holomorphic map of the coordinate sequence y = (yj)j∈N ∈ R∞. We establish weighted summability results for the Wiener-Hermite coefficient sequences of images of affine-parametric expansions of the log-Gaussian input under G. These results give rise to N-term approximation rate bounds for the full range of input summability exponents p∈ (0,2). We show that these approximation rate bounds apply to parameter-to-solution maps for elliptic diffusion PDEs with lognormal coefficients.

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