Threshold detection statistics of bosonic states br

J. F. F. Bulmer; S. Paesani; R. S. Chadwick; N. Quesada

doi:10.1103/PhysRevA.106.043712

Threshold detection statistics of bosonic states br

J. F. F. Bulmer^*, S. Paesani, R. S. Chadwick, N. Quesada

^*Corresponding author for this work

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Research output: Contribution to journal › Journal article › peer-review

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Abstract

In quantum photonics, threshold detectors, distinguishing between vacuum and one or more photons, such as superconducting nanowires and avalanche photodiodes, are routinely used to measure Fock and Gaussian states of light. Despite being the standard measurement scheme, there is no general closed form expression for measurement probabilities with threshold detectors, unless accepting coarse approximations or combinatorially scaling summations. Here, we present new matrix functions to fill this gap. We develop the Bristolian and the loop Torontonian functions for threshold detection of Fock and displaced Gaussian states, respectively, and connect them to each other and to existing matrix functions. By providing a unified picture of bosonic statistics for most quantum states of light, we provide novel tools for the design and analysis of photonic quantum technologies.

Original language	English
Article number	043712
Journal	Physical Review A
Volume	106
Issue number	4
Number of pages	14
ISSN	2469-9926
DOIs	https://doi.org/10.1103/PhysRevA.106.043712
Publication status	Published - 17 Oct 2022

Keywords

QUANTUM COMPUTATION

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10.1103/PhysRevA.106.043712

PhysRevA.106.043712Final published version, 4.24 MB

https://arxiv.org/pdf/2202.04600.pdf

Cite this

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title = "Threshold detection statistics of bosonic states br",

abstract = "In quantum photonics, threshold detectors, distinguishing between vacuum and one or more photons, such as superconducting nanowires and avalanche photodiodes, are routinely used to measure Fock and Gaussian states of light. Despite being the standard measurement scheme, there is no general closed form expression for measurement probabilities with threshold detectors, unless accepting coarse approximations or combinatorially scaling summations. Here, we present new matrix functions to fill this gap. We develop the Bristolian and the loop Torontonian functions for threshold detection of Fock and displaced Gaussian states, respectively, and connect them to each other and to existing matrix functions. By providing a unified picture of bosonic statistics for most quantum states of light, we provide novel tools for the design and analysis of photonic quantum technologies.",

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T1 - Threshold detection statistics of bosonic states br

AU - Bulmer, J. F. F.

AU - Paesani, S.

AU - Chadwick, R. S.

AU - Quesada, N.

PY - 2022/10/17

Y1 - 2022/10/17

N2 - In quantum photonics, threshold detectors, distinguishing between vacuum and one or more photons, such as superconducting nanowires and avalanche photodiodes, are routinely used to measure Fock and Gaussian states of light. Despite being the standard measurement scheme, there is no general closed form expression for measurement probabilities with threshold detectors, unless accepting coarse approximations or combinatorially scaling summations. Here, we present new matrix functions to fill this gap. We develop the Bristolian and the loop Torontonian functions for threshold detection of Fock and displaced Gaussian states, respectively, and connect them to each other and to existing matrix functions. By providing a unified picture of bosonic statistics for most quantum states of light, we provide novel tools for the design and analysis of photonic quantum technologies.

AB - In quantum photonics, threshold detectors, distinguishing between vacuum and one or more photons, such as superconducting nanowires and avalanche photodiodes, are routinely used to measure Fock and Gaussian states of light. Despite being the standard measurement scheme, there is no general closed form expression for measurement probabilities with threshold detectors, unless accepting coarse approximations or combinatorially scaling summations. Here, we present new matrix functions to fill this gap. We develop the Bristolian and the loop Torontonian functions for threshold detection of Fock and displaced Gaussian states, respectively, and connect them to each other and to existing matrix functions. By providing a unified picture of bosonic statistics for most quantum states of light, we provide novel tools for the design and analysis of photonic quantum technologies.

KW - QUANTUM COMPUTATION

U2 - 10.1103/PhysRevA.106.043712

DO - 10.1103/PhysRevA.106.043712

M3 - Journal article

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JO - Physical Review A - Atomic, Molecular, and Optical Physics

JF - Physical Review A - Atomic, Molecular, and Optical Physics

SN - 1050-2947

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