A Quantum Algorithm Framework for Discrete Probability Distributions with Applications to R\'enyi Entropy Estimation
Abstract
Estimating statistical properties is fundamental in statistics and computer science. In this paper, we propose a unified quantum algorithm framework for estimating properties of discrete probability distributions, with estimating R\'enyi entropies as specific examples. In particular, given a quantum oracle that prepares an -dimensional quantum state , for and , our algorithm framework estimates -R\'enyi entropy to within additive error with probability at least using and queries, respectively. This improves the best known dependence in as well as the joint dependence between and . Technically, our quantum algorithms combine quantum singular value transformation, quantum annealing, and variable-time amplitude estimation. We believe that our algorithm framework is of general interest and has wide applications.
Cite
@article{arxiv.2212.01571,
title = {A Quantum Algorithm Framework for Discrete Probability Distributions with Applications to R\'enyi Entropy Estimation},
author = {Xinzhao Wang and Shengyu Zhang and Tongyang Li},
journal= {arXiv preprint arXiv:2212.01571},
year = {2024}
}
Comments
to be published in IEEE Transactions on Information Theory