An Improved Implementation Approach for Quantum Phase Estimation on Quantum Computers

Hamed Mohammadbagherpoor, Young-Hyun Oh, P. Dreher, Anand Singh, Xianqing Yu, A. J. Rindos
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引用次数: 19

Abstract

Quantum phase estimation (QPE) is one of the core algorithms for quantum computing. It has been extensively studied and applied in a variety of quantum applications such as the Shor's factoring algorithm, quantum sampling algorithms and the calculation of the eigenvalues of unitary matrices. The QPE algorithm has been combined with Kitaev's algorithm and the inverse quantum Fourier transform (IQFT) which are utilized as a fundamental component of such quantum algorithms. In this paper, we explore the computational challenges of implementing QPE algorithms on noisy intermediate-scale quantum (NISQ) machines using the IBM Q Experience (e.g., the IBMQX4, 5-qubit quantum computing hardware platform). Our experimental results indicate that the accuracy of finding the phase using these QPE algorithms is severely constrained by the NISQ computer's physical characteristics such as coherence time and error rates. To mitigate these physical limitations, we propose implementing a modified solution by reducing the number of controlled rotation gates and phase shift operations, thereby increasing the accuracy of the finding phase in near-term quantum computers.
量子计算机上量子相位估计的改进实现方法
量子相位估计(QPE)是量子计算的核心算法之一。它在各种量子应用中得到了广泛的研究和应用,如Shor的因式分解算法、量子采样算法和酉矩阵特征值的计算。QPE算法与Kitaev算法和反量子傅立叶变换(IQFT)相结合,作为这种量子算法的基本组成部分。在本文中,我们探讨了使用IBMQ Experience(例如,IBMQX4, 5量子位量子计算硬件平台)在嘈杂的中等规模量子(NISQ)机器上实现QPE算法的计算挑战。我们的实验结果表明,使用这些QPE算法查找相位的准确性受到NISQ计算机的物理特性(如相干时间和错误率)的严重限制。为了减轻这些物理限制,我们提出了一种改进的解决方案,通过减少受控旋转门和相移操作的数量,从而提高近期量子计算机中发现相位的准确性。
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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