Resource-efficient algorithm for estimating the trace of quantum state powers

IF 5.1 2区物理与天体物理 Q1 PHYSICS, MULTIDISCIPLINARY

Quantum Pub Date : 2025-08-27 DOI:10.22331/q-2025-08-27-1832

Myeongjin Shin, Junseo Lee, Seungwoo Lee, Kabgyun Jeong

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引用次数: 0

Abstract

Estimating the trace of quantum state powers, $\text{Tr}(\rho^k)$, for $k$ identical quantum states is a fundamental task with numerous applications in quantum information processing, including nonlinear function estimation of quantum states and entanglement detection. On near-term quantum devices, reducing the required quantum circuit depth, the number of multi-qubit quantum operations, and the copies of the quantum state needed for such computations is crucial. In this work, inspired by the Newton-Girard method, we significantly improve upon existing results by introducing an algorithm that requires only $\mathcal{O}(\widetilde{r})$ qubits and $\mathcal{O}(\widetilde{r})$ multi-qubit gates, where $\widetilde{r} = \min\left\{\text{rank}(\rho), \left\lceil\ln\left({2k}/{\epsilon}\right)\right\rceil\right\}$. This approach is efficient, as it employs the $\tilde{r}$-entangled copy measurement instead of the conventional $k$-entangled copy measurement, while asymptotically preserving the known sample complexity upper bound. Furthermore, we prove that estimating $\{\text{Tr}(\rho^i)\}_{i=1}^{\tilde{r}}$ is sufficient to approximate $\text{Tr}(\rho^k)$ even for large integers $k \gt \widetilde{r}$. This leads to a rank-dependent complexity for solving the problem, providing an efficient algorithm for low-rank quantum states while also improving existing methods when the rank is unknown or when the state is not low-rank. Building upon these advantages, we extend our algorithm to the estimation of $\text{Tr}(M\rho^k)$ for arbitrary observables and $\text{Tr}(\rho^k \sigma^l)$ for multiple quantum states.

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估计量子态功率轨迹的资源高效算法

对于$k$相同的量子态，估计量子态功率的轨迹$\text{Tr}(\rho^k)$是量子信息处理中许多应用的基本任务，包括量子态的非线性函数估计和纠缠检测。在近期的量子设备中，减少所需的量子电路深度、多量子位量子运算的数量以及此类计算所需的量子态副本是至关重要的。在这项工作中，受牛顿-吉拉德方法的启发，我们通过引入一种只需要$\mathcal{O}(\widetilde{r})$量子比特和$\mathcal{O}(\widetilde{r})$多量子比特门的算法，显著改进了现有的结果，其中$\widetilde{r} = \min\left\{\text{rank}(\rho), \left\lceil\ln\left({2k}/{\epsilon}\right)\right\rceil\right\}$。这种方法是有效的，因为它采用$\tilde{r}$ -纠缠复制测量而不是传统的$k$ -纠缠复制测量，同时渐近地保持已知的样本复杂度上界。进一步证明了即使对于大整数$k \gt \widetilde{r}$，估计$\{\text{Tr}(\rho^i)\}_{i=1}^{\tilde{r}}$也足以近似$\text{Tr}(\rho^k)$。这导致了求解问题的秩依赖复杂性，为低秩量子态提供了一种有效的算法，同时也改进了秩未知或非低秩状态时的现有方法。基于这些优点，我们将算法扩展到任意可观测值的$\text{Tr}(M\rho^k)$估计和多量子态的$\text{Tr}(\rho^k \sigma^l)$估计。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Quantum Physics and Astronomy-Physics and Astronomy (miscellaneous)

CiteScore

9.20

自引率

10.90%

发文量

241

审稿时长

16 weeks

期刊介绍： Quantum is an open-access peer-reviewed journal for quantum science and related fields. Quantum is non-profit and community-run: an effort by researchers and for researchers to make science more open and publishing more transparent and efficient.