Predicting quantum channels over general product distributions
Abstract
We investigate the problem of predicting the output behavior of unknown quantum channels. Given query access to an -qubit channel and an observable , we aim to learn the mapping \begin{equation*} \rho \mapsto \mathrm{Tr}(O E[\rho]) \end{equation*} to within a small error for most sampled from a distribution . Previously, Huang, Chen, and Preskill proved a surprising result that even if is arbitrary, this task can be solved in time roughly , where is the target prediction error. However, their guarantee applied only to input distributions invariant under all single-qubit Clifford gates, and their algorithm fails for important cases such as general product distributions over product states . In this work, we propose a new approach that achieves accurate prediction over essentially any product distribution , provided it is not "classical" in which case there is a trivial exponential lower bound. Our method employs a "biased Pauli analysis," analogous to classical biased Fourier analysis. Implementing this approach requires overcoming several challenges unique to the quantum setting, including the lack of a basis with appropriate orthogonality properties. The techniques we develop to address these issues may have broader applications in quantum information.
Cite
@article{arxiv.2409.03684,
title = {Predicting quantum channels over general product distributions},
author = {Sitan Chen and Jaume de Dios Pont and Jun-Ting Hsieh and Hsin-Yuan Huang and Jane Lange and Jerry Li},
journal= {arXiv preprint arXiv:2409.03684},
year = {2024}
}
Comments
20 pages, comments welcome