A study of polarization compensation for quantum networks

Matej Peranić; Marcus Clark; Rui Wang; Sima Bahrani; Obada Alia; Sören Wengerowsky; Anton Radman; Martin Lončarić; Mario Stipčević; John Rarity; Reza Nejabati; Siddarth Koduru Joshi

doi:10.1140/epjqt/s40507-023-00187-w

A study of polarization compensation for quantum networks

Matej Peranić^*, Marcus Clark, Rui Wang, Sima Bahrani, Obada Alia, Sören Wengerowsky, Anton Radman, Martin Lončarić, Mario Stipčević, John Rarity, Reza Nejabati, Siddarth Koduru Joshi

^*Corresponding author for this work

Research output: Contribution to journal › Article (Academic Journal) › peer-review

11 Citations (Scopus)

Abstract

The information-theoretic unconditional security offered by quantum key distribution has spurred the development of larger quantum communication networks. However, as these networks grow so does the strong need to reduce complexity and overheads. Polarization-based entanglement distribution networks are a promising approach due to their scalability and no need for trusted nodes. Nevertheless, they are only viable if the birefringence of all-optical distribution fibres in the network is compensated to preserve the polarization-based quantum state. The brute force approach would require a few hundred fibre polarization controllers for even a moderately sized network. Instead, we propose and investigate four different realizations of polarization compensation schemes that can be used in quantum networks. We compare them based on the type of reference signals, complexity, effort, level of disruption to network operations and performance on a four-user quantum network.

Original language	English
Article number	30
Number of pages	11
Journal	EPJ Quantum Technology
Volume	10
Issue number	1
Early online date	17 Aug 2023
DOIs	https://doi.org/10.1140/epjqt/s40507-023-00187-w
Publication status	Published - Dec 2023

Bibliographical note

Publisher Copyright:
© 2023, Springer-Verlag GmbH Germany, part of Springer Nature.

Keywords

Entanglement
Polarization compensation
Quantum bit error rate
Quantum communication
Quantum networks

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title = "A study of polarization compensation for quantum networks",

abstract = "The information-theoretic unconditional security offered by quantum key distribution has spurred the development of larger quantum communication networks. However, as these networks grow so does the strong need to reduce complexity and overheads. Polarization-based entanglement distribution networks are a promising approach due to their scalability and no need for trusted nodes. Nevertheless, they are only viable if the birefringence of all-optical distribution fibres in the network is compensated to preserve the polarization-based quantum state. The brute force approach would require a few hundred fibre polarization controllers for even a moderately sized network. Instead, we propose and investigate four different realizations of polarization compensation schemes that can be used in quantum networks. We compare them based on the type of reference signals, complexity, effort, level of disruption to network operations and performance on a four-user quantum network.",

keywords = "Entanglement, Polarization compensation, Quantum bit error rate, Quantum communication, Quantum networks",

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year = "2023",

month = dec,

doi = "10.1140/epjqt/s40507-023-00187-w",

language = "English",

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AU - Peranić, Matej

AU - Clark, Marcus

AU - Wang, Rui

AU - Bahrani, Sima

AU - Alia, Obada

AU - Wengerowsky, Sören

AU - Radman, Anton

AU - Lončarić, Martin

AU - Stipčević, Mario

AU - Rarity, John

AU - Nejabati, Reza

AU - Joshi, Siddarth Koduru

PY - 2023/12

Y1 - 2023/12

N2 - The information-theoretic unconditional security offered by quantum key distribution has spurred the development of larger quantum communication networks. However, as these networks grow so does the strong need to reduce complexity and overheads. Polarization-based entanglement distribution networks are a promising approach due to their scalability and no need for trusted nodes. Nevertheless, they are only viable if the birefringence of all-optical distribution fibres in the network is compensated to preserve the polarization-based quantum state. The brute force approach would require a few hundred fibre polarization controllers for even a moderately sized network. Instead, we propose and investigate four different realizations of polarization compensation schemes that can be used in quantum networks. We compare them based on the type of reference signals, complexity, effort, level of disruption to network operations and performance on a four-user quantum network.

AB - The information-theoretic unconditional security offered by quantum key distribution has spurred the development of larger quantum communication networks. However, as these networks grow so does the strong need to reduce complexity and overheads. Polarization-based entanglement distribution networks are a promising approach due to their scalability and no need for trusted nodes. Nevertheless, they are only viable if the birefringence of all-optical distribution fibres in the network is compensated to preserve the polarization-based quantum state. The brute force approach would require a few hundred fibre polarization controllers for even a moderately sized network. Instead, we propose and investigate four different realizations of polarization compensation schemes that can be used in quantum networks. We compare them based on the type of reference signals, complexity, effort, level of disruption to network operations and performance on a four-user quantum network.

KW - Entanglement

KW - Polarization compensation

KW - Quantum bit error rate

KW - Quantum communication

KW - Quantum networks

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VL - 10

JO - EPJ Quantum Technology

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A study of polarization compensation for quantum networks

Abstract

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Keywords

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Programme Grant: Engineering Photonic Quantum Technologies.

MICROSTRUCTURED FIBRE FOR QUANTUM INFORMATION

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A study of polarization compensation for quantum networks

Abstract

Bibliographical note

Keywords

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Programme Grant: Engineering Photonic Quantum Technologies.

MICROSTRUCTURED FIBRE FOR QUANTUM INFORMATION

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