English

Optimal Reconstruction from Linear Queries

Machine Learning 2026-05-20 v1

Abstract

We study the problem of reconstructing an unknown point in Rd\mathbb{R}^d from approximate linear queries. This setting arises naturally in applications ranging from low-dimensional remote sensing and signal recovery to high-dimensional data analysis and privacy-sensitive inference. Our main goal is to characterize the optimal reconstruction error as a function of the number of queries TT, the ambient dimension dd, and the noise parameter δ\delta. We first analyze the limit TT \to \infty and show that the optimal reconstruction error converges to the explicit value 2d/(d+1)δ\sqrt{2d/(d+1)} \delta, which plays a role analogous to the Bayes optimal error in supervised learning. When the dimension is fixed, we show that the excess error above this limit decays doubly exponentially fast as TT \to \infty, a rate that is significantly faster than those typically encountered in learning curves. When the dimension grows, we show that a number of queries on the order of exp(d)\exp(d) is necessary and sufficient to achieve vanishing excess error. Finally, we introduce and analyze an improper variant of the reconstruction problem. From a technical perspective, our main contribution is a generalization of Jung's theorem (1901). The classical theorem bounds the maximum possible radius of a set of diameter 1 and characterizes extremal bodies. Our generalization provides a robust variant that characterizes near-extremal bodies and is proved via geometric and dynamical arguments exploiting symmetry and Lie group actions.

Keywords

Cite

@article{arxiv.2605.19625,
  title  = {Optimal Reconstruction from Linear Queries},
  author = {Yuval Filmus and Shay Moran and Elizaveta Nesterova},
  journal= {arXiv preprint arXiv:2605.19625},
  year   = {2026}
}

Comments

Accepted to COLT 2026. 46 pages, 4 figures