Time-Efficient Quantum Entropy Estimator via Samplizer

Abstract

Entropy is a measure of the randomness of a system. Estimating the entropy of a quantum state is a basic problem in quantum information. In this paper, we introduce a time-efficient quantum approach to estimating the von Neumann entropy S() and R\'enyi entropy Sα() of an N-dimensional quantum state , given access to independent samples of . Specifically, we provide the following: 1. A quantum estimator for S() with time complexity O(N2), improving the prior best time complexity O(N6) by Acharya, Issa, Shende, and Wagner (2020) and Bavarian, Mehraba, and Wright (2016). 2. A quantum estimator for Sα() with time complexity O(N4/α-2) for 0<α<1 and O(N4-2/α) for α>1, improving the prior best time complexity O(N6/α) for 0<α<1 and O(N6) for α>1 by Acharya, Issa, Shende, and Wagner (2020), though at a cost of a slightly larger sample complexity. Moreover, these estimators are naturally extensible to the low-rank case. We also provide a sample lower bound for estimating Sα(). Technically, our method is quite different from the previous ones that are based on weak Schur sampling and Young diagrams. At the heart of our construction, is a novel tool called samplizer, which can "samplize" a quantum query algorithm to a quantum algorithm with similar behavior using only samples of quantum states; this suggests a unified framework for estimating quantum entropies. Specifically, when a quantum oracle U block-encodes a mixed quantum state , any quantum query algorithm using Q queries to U can be samplized to a δ-close (in the diamond norm) quantum algorithm using (Q2/δ) samples of . Moreover, this samplization is proven to be optimal, up to a polylogarithmic factor.