Time-Frequency Analysis for Neural Networks
Abstract
We develop a quantitative approximation theory for shallow neural networks using tools from time-frequency analysis. Working in weighted modulation spaces Mp,qm(Rd), we prove dimension-independent approximation rates in Sobolev norms Wn,r() for networks whose units combine standard activations with localized time-frequency windows. Our main result shows that for f ∈ Mp,qm(Rd) one can achieve \[ \|f - fN\|Wn,r() N-1/2\,\|f\|Mp,qm(Rd), \] on bounded domains, with explicit control of all constants. We further obtain global approximation theorems on Rd using weighted modulation dictionaries, and derive consequences for Feichtinger's algebra, Fourier-Lebesgue spaces, and Barron spaces. Numerical experiments in one and two dimensions confirm that modulation-based networks achieve substantially better Sobolev approximation than standard ReLU networks, consistent with the theoretical estimates.
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