：Quantum Fisher information width in quantum metrology论文

本文主要研究内容

作者（2019）在《Quantum Fisher information width in quantum metrology》一文中研究指出：In scenarios of quantum metrology, the unitary parametrization process often depends on space directions. How to characterize the sensitivity of parameter estimation to space directions is a natural question. We propose the concept of the quantum Fisher information(QFI) width, which is the difference between the maximum and minimum values of the QFI, to quantitatively study the sensitivity. We find that Fock states, the bosonic coherent states, and the displaced Fock states all have zero widths, indicating that QFI is completely inert over all directions, while the width for the spin state with all spins down or up is equal to the number of particles, so this concept will enable us to choose appropriate directions to make unitary transformation to obtain larger QFI.The QFI width of the displaced quantum states is found to be independent of the magnitude of the displacement for both spin and bosonic systems. We also find some relations between the QFI width and squeezing parameters.

Abstract

In scenarios of quantum metrology, the unitary parametrization process often depends on space directions. How to characterize the sensitivity of parameter estimation to space directions is a natural question. We propose the concept of the quantum Fisher information(QFI) width, which is the difference between the maximum and minimum values of the QFI, to quantitatively study the sensitivity. We find that Fock states, the bosonic coherent states, and the displaced Fock states all have zero widths, indicating that QFI is completely inert over all directions, while the width for the spin state with all spins down or up is equal to the number of particles, so this concept will enable us to choose appropriate directions to make unitary transformation to obtain larger QFI.The QFI width of the displaced quantum states is found to be independent of the magnitude of the displacement for both spin and bosonic systems. We also find some relations between the QFI width and squeezing parameters.

论文参考文献

[1].Quantum metrology[J]. 项国勇,郭光灿. Chinese Physics B.2013(11)

[2].Experimental demonstration of nonlinear quantum metrology with optimal quantum state[J]. Xinfang Nie,Jiahao Huang,Zhaokai Li,Wenqiang Zheng,Chaohong Lee,Xinhua Peng,Jiangfeng Du. Science Bulletin.2018(08)

[3].Model based reference metrology for dimensional characterization of micro- and nanostructures[J]. B. Bodermann,H. Bosse. Optoelectronics Letters.2008(02)

[4].Towards quantum-enhanced precision measurements:Promise and challenges[J]. 张利剑,肖敏. Chinese Physics B.2013(11)

[5].Quantum Light Source from Semiconductors[J]. Xiulai Xu,Jin-Shi Xu. Journal of Semiconductors.2019(10)

[6].Precision measurement and frequency metrology with ultracold atoms[J]. Xibo Zhang,Jun Ye. National Science Review.2016(02)

[7].JOS OUR LATEST SPECIAL ISSUES[J]. Journal of Semiconductors.2019(11)

[8].The Influence of Quantum Technology on the Development of Metrology and Measuring Science[J]. ZHANG Tieli,MIAO Yinxiao. Aerospace China.2016(03)

[9].Quantum metrology with a non-Markovian qubit system[J]. 黄江,师文庆,谢玉萍,徐国保,巫慧娴. Chinese Physics B.2018(12)

[10].Quantum metrology with two-mode squeezed thermal state: Parity detection and phase sensitivity[J]. 李恒梅,徐学翔,袁洪春,王震. Chinese Physics B.2016(10)

论文详细介绍

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标签：Science China(Physics; Mechanics & Astronomy)2019年04期论文;

：Quantum Fisher information width in quantum metrology论文

本文主要研究内容

Abstract

论文参考文献

论文详细介绍

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