English

Quantum algorithms for estimating quantum entropies

Quantum Physics 2023-10-13 v1

Abstract

The von Neumann and quantum R\'enyi entropies characterize fundamental properties of quantum systems and lead to theoretical and practical applications in many fields. Quantum algorithms for estimating quantum entropies, using a quantum query model that prepares the purification of the input state, have been established in the literature. {However, constructing such a model is almost as hard as state tomography.} In this paper, we propose quantum algorithms to estimate the von Neumann and quantum α\alpha-R\'enyi entropies of an nn-qubit quantum state ρ\rho using independent copies of the input state. We also show how to efficiently construct the quantum circuits for {quantum entropy estimation} using primitive single/two-qubit gates. We prove that the number of required copies scales polynomially in 1/ϵ1/\epsilon and 1/Λ1/\Lambda, where ϵ\epsilon denotes the additive precision and Λ\Lambda denotes the lower bound on all non-zero eigenvalues. Notably, our method outperforms previous methods in the aspect of practicality since it does not require any quantum query oracles, which are usually necessary for previous methods. Furthermore, we conduct experiments to show the efficacy of our algorithms to single-qubit states and study the noise robustness. We also discuss the applications to some quantum states of practical interest as well as some meaningful tasks such as quantum Gibbs state preparation and entanglement estimation.

Keywords

Cite

@article{arxiv.2203.02386,
  title  = {Quantum algorithms for estimating quantum entropies},
  author = {Youle Wang and Benchi Zhao and Xin Wang},
  journal= {arXiv preprint arXiv:2203.02386},
  year   = {2023}
}

Comments

36 pages, 8 figures

R2 v1 2026-06-24T10:02:19.583Z