Deconvolution with Unknown Error Distribution Interpreted as Blind Isotonic Regression
Abstract
Deconvolution is a statistical inverse problem to estimate the distribution of a random variable based on its noisy observations. Despite the extensive studies on the topic, deconvolution with unknown noise distribution remains as a notoriously hard problem. We propose a matrix-based viewpoint for collective deconvolution that subsumes the setup with repeated measurements as a special case. As the main result, we describe a simple algorithm that partially utilizes matrix structure to solve deconvolution problem and provide non-asymptotic error analysis for the algorithm. We show that the proposed algorithm achieves the minimax optimal rate for deconvolution in a restricted sense. We also remark the connection between the collective deconvolution and the so-called statistical seriation as a byproduct or our matrix viewpoint. We conjecture that the link suggests that collective deconvolution, as well as deconvolution with repeated measurements, is intrinsically much easier than usual deconvolution of a single distribution.
Cite
@article{arxiv.1803.03469,
title = {Deconvolution with Unknown Error Distribution Interpreted as Blind Isotonic Regression},
author = {Devavrat Shah and Dogyoon Song},
journal= {arXiv preprint arXiv:1803.03469},
year = {2020}
}
Comments
25 pages + 40 pages (appendix)