English

Optimal Extrapolation Bounds for Sparse Fourier Sums

Data Structures and Algorithms 2026-07-11 v1 Classical Analysis and ODEs Numerical Analysis

Abstract

We prove an optimal extrapolation theorem for kk-sparse Fourier sums over arbitrary real frequencies, without any separation assumption, bounding how large such a sum can be just outside an interval on which its energy is observed. For every g(t)=j=1kvjeiλjtg(t)=\sum_{j=1}^k v_j e^{i\lambda_jt} with λjR\lambda_j\in\mathbb R and every x1x\ge1, g(x)kO(1)exp(O(karcoshx))gL2[1,1]. |g(x)|\le k^{O(1)}\exp(O(k\mathop{\mathrm{arcosh}} x))\|g\|_{L^2[-1,1]} . In the endpoint regime, this refines to the explicit bound g(1+δ)O(k)exp(O(kδ))gL2[1,1],0δ1. |g(1+\delta)|\le O(k)\exp(O(k\sqrt\delta))\|g\|_{L^2[-1,1]}, \qquad 0\le\delta\le1 . This improves on the exp(O(k2logkδ))\exp(O(k^2\log k\cdot\delta)) growth estimate of Chen and Price (ICALP 2019), and the exponential scaling is optimal up to constants and polynomial factors in kk. As an algorithmic consequence, we improve the cluster-center resolution of Chen--Price's clustered-frequency recovery algorithm by a factor of kk, while preserving its sample complexity up to logarithmic factors. We also obtain exterior leverage-score and transfer bounds for sparse Fourier feature spaces, converting in-domain active-regression guarantees into essentially sharp prediction guarantees just outside the sampling interval.

Cite

@article{arxiv.2607.10501,
  title  = {Optimal Extrapolation Bounds for Sparse Fourier Sums},
  author = {Ruizhe Zhang},
  journal= {arXiv preprint arXiv:2607.10501},
  year   = {2026}
}