High-dimensional sparse trigonometric approximation in the uniform norm and consequences for sampling recovery
Abstract
Recent findings by Jahn, T. Ullrich, Voigtlaender [10] relate non-linear sampling numbers for the square norm to quantities involving trigonometric best m-term approximation errors in the uniform norm. Here we establish new results for sparse trigonometric approximation with respect to the high-dimensional setting, where the influence of the dimension d has to be controlled. In particular, we focus on best m-term trigonometric approximation for (unweighted) Wiener classes in Lq and give precise constants. Our main results are approximation guarantees where the number of terms m scales at most quadratic in the inverse accuracy 1/. Providing a refined version of the classical Nikol'skij inequality we are able to extrapolate the Lq-result to L∞ while limiting the influence of the dimension to a d-factor and an additonal -term in the size of the (rectangular) spectrum. This has consequences for the tractable sampling recovery via 1-minimization of functions belonging to certain Besov classes with bounded mixed smoothness. This complements polynomial tractability results recently given by Krieg [12].
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