Grouped Transformations in High-Dimensional Explainable ANOVA Approximation
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Many applications are based on the use of efficient Fourier algorithms such as the fast Fourier transform and the nonequispaced fast Fourier transform. In a high-dimensional setting it is also already possible to deal with special sampling sets such as sparse grids or rank-1 lattices. In this paper we propose fast algorithms for high-dimensional scattered data points with corresponding frequency sets that consist of groups along the dimensions in the frequency domain. From there we propose a fast matrix-vector multiplication, the grouped Fourier transform, that finds theoretical foundation in the context of the analysis of variance (ANOVA) decomposition where there is a one-to-one correspondence from the ANOVA terms to our proposed groups. An application can be found in function approximation for high-dimensional functions where the number of the variable interactions is limited. We tested two different approximation approaches: Classical Tikhonov-regularization, namely, regularized least squares, and the technique of group lasso, which promotes sparsity in the groups. As for the latter, there are no explicit solution formulas which is why we applied the fast iterative shrinking-thresholding algorithm to obtain the minimizer. Numerical experiments in under-, overdetermined, and noisy settings indicate the applicability of our algorithms.
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