Pauli error estimation via Population Recovery
Abstract
Motivated by estimation of quantum noise models, we study the problem of learning a Pauli channel, or more generally the Pauli error rates of an arbitrary channel. By employing a novel reduction to the "Population Recovery" problem, we give an extremely simple algorithm that learns the Pauli error rates of an -qubit channel to precision in using just applications of the channel. This is optimal up to the logarithmic factors. Our algorithm uses only unentangled state preparation and measurements, and the post-measurement classical runtime is just an factor larger than the measurement data size. It is also impervious to a limited model of measurement noise where heralded measurement failures occur independently with probability . We then consider the case where the noise channel is close to the identity, meaning that the no-error outcome occurs with probability . In the regime of small we extend our algorithm to achieve multiplicative precision (i.e., additive precision ) using just applications of the channel.
Cite
@article{arxiv.2105.02885,
title = {Pauli error estimation via Population Recovery},
author = {Steven T. Flammia and Ryan O'Donnell},
journal= {arXiv preprint arXiv:2105.02885},
year = {2021}
}
Comments
19 pages. v1: Preliminary version in TQC 2021. v2: Journal version with some additional references and background on Pauli channel estimation. Source code available at https://github.com/sflammia/PauliPopRec