Enhancing quantum state tomography: utilizing advanced statistical techniques for optimized quantum state reconstructions

IF 0.8 4区 物理与天体物理 Q3 PHYSICS, MULTIDISCIPLINARY Journal of the Korean Physical Society Pub Date : 2024-08-01 DOI:10.1007/s40042-024-01155-y
Jenefa Archpaul, Edward Naveen VijayaKumar, Manoranjitham Rajendran, Thompson Stephan, Punitha Stephan, Rishu Chhabra, Saurabh Agarwal, Wooguil Pak
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Abstract

Quantum state tomography (QST) forms the foundational framework in quantum computing, enabling precise characterization of quantum states through specialized measurement arrays. This is crucial for assessing the fidelity and coherence of quantum states in various quantum systems. The complexity and high dimensionality of quantum states require advanced statistical methods to meet modern quantum paradigms’ precision and computational needs, as traditional methods often struggle with inefficiencies and inaccuracies. Conventional approaches in QST typically use linear inversion and maximum likelihood estimators, which often face computational redundancies and perform sub-optimally in high-dimensional quantum architectures. This exposition introduces pioneering statistical methodologies that combine Bayesian Inference, Variational Quantum Eigensolver, and Quantum Neural Networks to achieve enhanced fidelity approximation. The analytical discussion is supported by synthetic quantum states, demonstrating the efficacy and applicability of these statistical methods across various quantum matrices. Preliminary empirical results show a significant increase in fidelity and a notable reduction in error margins, highlighting the potential of these advanced statistical methodologies in optimizing quantum state reconstructions. Additionally, leveraging the inherent symmetry properties in quantum systems could further improve the efficiency and accuracy of state reconstructions, offering additional pathways for advancing the field.

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增强量子态断层成像:利用先进统计技术优化量子态重构
量子态层析成像(QST)是量子计算的基础框架,可通过专门的测量阵列对量子态进行精确表征。这对于评估各种量子系统中量子态的保真度和相干性至关重要。量子态的复杂性和高维度要求采用先进的统计方法来满足现代量子范式的精度和计算需求,因为传统方法往往难以满足低效和不准确的要求。量子态统计的传统方法通常使用线性反演和最大似然估计器,这些方法往往面临计算冗余问题,在高维量子架构中的表现也不够理想。本论文介绍了开创性的统计方法,这些方法结合了贝叶斯推理、变量量子求解器和量子神经网络,以实现更高保真的近似。分析讨论得到了合成量子态的支持,证明了这些统计方法在各种量子矩阵中的有效性和适用性。初步实证结果表明,保真度显著提高,误差范围明显缩小,凸显了这些先进统计方法在优化量子态重构方面的潜力。此外,利用量子系统固有的对称特性可以进一步提高状态重构的效率和准确性,为推动该领域的发展提供更多途径。
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来源期刊
Journal of the Korean Physical Society
Journal of the Korean Physical Society PHYSICS, MULTIDISCIPLINARY-
CiteScore
1.20
自引率
16.70%
发文量
276
审稿时长
5.5 months
期刊介绍: The Journal of the Korean Physical Society (JKPS) covers all fields of physics spanning from statistical physics and condensed matter physics to particle physics. The manuscript to be published in JKPS is required to hold the originality, significance, and recent completeness. The journal is composed of Full paper, Letters, and Brief sections. In addition, featured articles with outstanding results are selected by the Editorial board and introduced in the online version. For emphasis on aspect of international journal, several world-distinguished researchers join the Editorial board. High quality of papers may be express-published when it is recommended or requested.
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