Derandomized shallow shadows: Efficient Pauli learning with bounded-depth circuits
Abstract
Efficiently estimating large numbers of non-commuting observables is an important subroutine of many quantum science tasks. We present the derandomized shallow shadows (DSS) algorithm for efficiently learning a large set of non-commuting observables, using shallow circuits to rotate into measurement bases. Exploiting tensor network techniques to ensure polynomial scaling of classical resources, our algorithm outputs a set of shallow measurement circuits that approximately minimizes the sample complexity of estimating a given set of Pauli strings. We numerically demonstrate systematic improvement, in comparison with state-of-the-art techniques, for energy estimation of quantum chemistry benchmarks and verification of quantum many-body systems, and we observe DSS's performance consistently improves as one allows deeper measurement circuits. These results indicate that in addition to being an efficient, low-depth, stand-alone algorithm, DSS can also benefit many larger quantum algorithms requiring estimation of multiple non-commuting observables.
Cite
@article{arxiv.2412.18973,
title = {Derandomized shallow shadows: Efficient Pauli learning with bounded-depth circuits},
author = {Katherine Van Kirk and Christian Kokail and Jonathan Kunjummen and Hong-Ye Hu and Yanting Teng and Madelyn Cain and Jacob Taylor and Susanne F. Yelin and Hannes Pichler and Mikhail Lukin},
journal= {arXiv preprint arXiv:2412.18973},
year = {2024}
}
Comments
10+29 pages, 9 figures