Denoising data using convex relaxations
Abstract
We study the problem of denoising observations , where the latent variables are sampled from a low-dimensional manifold in and the noise variables are isotropic Gaussian. We propose a convex-relaxation estimator that first reduces dimension by principal component analysis and then projects the observations onto the convex hull of the projected latent manifold. We construct a statistical oracle that estimates its supporting hyperplanes from empirical Gaussian tail probabilities of the noisy sample. Under a lower-mass condition on the latent distribution, we prove finite-sample guarantees for the oracle and derive error bounds for the resulting denoiser. The analysis combines risk bounds for least-squares projection under convex constraints with entropy bounds for convex hulls. We also verify the assumptions of the framework for a Cryo-Electron Microscopy observation model by establishing suitable covering number and Lipschitz estimates for the associated group action and imaging operators.
Keywords
Cite
@article{arxiv.2605.02327,
title = {Denoising data using convex relaxations},
author = {Charles Fefferman and Aalok Gangopadhyay and Matti Lassas and Jonathan Marty and Hariharan Narayanan},
journal= {arXiv preprint arXiv:2605.02327},
year = {2026}
}
Comments
38 pages, 6 figures