English

Pauli error estimation via Population Recovery

Quantum Physics 2021-09-29 v2

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 nn-qubit channel to precision ϵ\epsilon in \ell_\infty using just O(1/ϵ2)log(n/ϵ)O(1/\epsilon^2) \log(n/\epsilon) 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 O(1/ϵ)O(1/\epsilon) 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 1/4\le 1/4. We then consider the case where the noise channel is close to the identity, meaning that the no-error outcome occurs with probability 1η1-\eta. In the regime of small η\eta we extend our algorithm to achieve multiplicative precision 1±ϵ1 \pm \epsilon (i.e., additive precision ϵη\epsilon \eta) using just O(1ϵ2η)log(n/ϵ)O\bigl(\frac{1}{\epsilon^2 \eta}\bigr) \log(n/\epsilon) applications of the channel.

Keywords

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

R2 v1 2026-06-24T01:51:14.570Z