The Fourier Ratio and complexity of signals
Abstract
We study the Fourier ratio of a signal f: ZN C, \[ FR(f)\ :=\ N\,\| f\|L1(μ)\| f\|L2(μ) \ =\ \| f\|1\| f\|2, \] as a simple scalar parameter governing Fourier-side complexity, structure, and learnability. Using the Bourgain--Talagrand theory of random subsets of orthonormal systems, we show that signals concentrated on generic sparse sets necessarily have large Fourier ratio, while small FR(f) forces f to be well-approximated in both L2 and L∞ by low-degree trigonometric polynomials. Quantitatively, the class \f:FR(f) r\ admits degree O(r2) L2-approximants, which we use to prove that small Fourier ratio implies small algorithmic rate--distortion, a stable refinement of Kolmogorov complexity.
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