近端设备上的量子振幅估算算法:实用指南

Q2 Physics and Astronomy Quantum Reports Pub Date : 2023-12-24 DOI:10.3390/quantum6010001
Marco Maronese, Massimiliano Incudini, Luca Asproni, Enrico Prati
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引用次数: 0

摘要

量子振幅估计(QAE)算法是一种重要的量子算法,旨在实现四倍速度提升。在实现容错量子计算之前,与经典蒙特卡洛(MC)相比,量子计算的竞争力仍难以企及。我们已经开发出了替代方法,以便在需要更少资源的同时保持有利的理论缩放。我们在数值积分任务中比较了标准 QAE 算法和两个噪声中间量子(NISQ)友好版本的 QAE 算法,并以 Metropolis-Hastings 的蒙特卡罗技术作为经典基准。分别从估计误差与样本数、计算时间和求解所需的量子电路长度的函数关系对算法进行了评估。我们在一台 11 量子位阱离子量子计算机上测试了两种 QAE 替代方案的有效性,以验证哪种方案能首先加快积分估计问题的速度。我们得出的结论是,相位估算常规方法更可取。事实上,最大似然估计保证了量子电路长度与积分估计精度之间的最佳权衡,并具有更强的抗噪能力。
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The Quantum Amplitude Estimation Algorithms on Near-Term Devices: A Practical Guide
The Quantum Amplitude Estimation (QAE) algorithm is a major quantum algorithm designed to achieve a quadratic speed-up. Until fault-tolerant quantum computing is achieved, being competitive over classical Monte Carlo (MC) remains elusive. Alternative methods have been developed so as to require fewer resources while maintaining an advantageous theoretical scaling. We compared the standard QAE algorithm with two Noisy Intermediate-Scale Quantum (NISQ)-friendly versions of QAE on a numerical integration task, with the Monte Carlo technique of Metropolis–Hastings as a classical benchmark. The algorithms were evaluated in terms of the estimation error as a function of the number of samples, computational time, and length of the quantum circuits required by the solutions, respectively. The effectiveness of the two QAE alternatives was tested on an 11-qubit trapped-ion quantum computer in order to verify which solution can first provide a speed-up in the integral estimation problems. We concluded that an alternative approach is preferable with respect to employing the phase estimation routine. Indeed, the Maximum Likelihood estimation guaranteed the best trade-off between the length of the quantum circuits and the precision in the integral estimation, as well as greater resistance to noise.
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来源期刊
Quantum Reports
Quantum Reports Physics and Astronomy-Physics and Astronomy (miscellaneous)
CiteScore
3.30
自引率
0.00%
发文量
33
审稿时长
10 weeks
期刊最新文献
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