Self-Adaption of Quantum Key Distribution Devices to Changing Working Conditions

Sandra König; Stefan Rass

Self-Adaption of Quantum Key Distribution Devices to Changing Working Conditions

Sandra König
, Stefan Rass

University of Klagenfurt

Publikation: Beitrag in Buch oder Tagungsband › Vortrag mit Beitrag in Tagungsband › Begutachtung

Abstract

Quantum key distribution (QKD) draws security from the ability to detect eavesdroppers upon the incident of “unnaturally high” quantum bit error rates (QBER) during the protocol. This presumes that a working QKD device implementation needs to be calibrated with its own individual and characteristic channel noise that is observed in any case, especially when there is no eavesdropper. This natural noise level influences the idle QBER, and is in turn dependent on the device’s working conditions. This work describes a statistical approach to construct a model that can be used to continuously compute the normal QBER, based on current (and changing) working conditions. The model is thus meant as a tool to refine the theoretical QBER threshold specific to the given QKD protocol, based on empirical data obtained under the given environmental conditions. More importantly, it allows the QKD-device to self-recalibrate under changing working conditions.

Originalsprache	Englisch
Titel	Proceedings of the International Conference on Quanum-, Nanon and Microtechnology (ICQNM), 2014
Redakteure/-innen	Victor Ovchinnikov, Vladimir Privman
Seiten	1-7
Seitenumfang	7
Publikationsstatus	Veröffentlicht - 2014
Veranstaltung	ICQNM 2014 : The Eighth International Conference on Quantum, Nano/Bio, and Micro Technologies - Lisbon, Portugal, Lisbon, Portugal Dauer: 16 Nov. 2014 → 20 Nov. 2014

Konferenz

Konferenz	ICQNM 2014 : The Eighth International Conference on Quantum, Nano/Bio, and Micro Technologies
Land/Gebiet	Portugal
Stadt	Lisbon
Zeitraum	16/11/14 → 20/11/14

Research Field

Cyber Security

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icqnm_2014_full

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@inproceedings{5a8689f0262f48618d6f5329985ab644,

title = "Self-Adaption of Quantum Key Distribution Devices to Changing Working Conditions",

abstract = "Quantum key distribution (QKD) draws security from the ability to detect eavesdroppers upon the incident of “unnaturally high” quantum bit error rates (QBER) during the protocol. This presumes that a working QKD device implementation needs to be calibrated with its own individual and characteristic channel noise that is observed in any case, especially when there is no eavesdropper. This natural noise level influences the idle QBER, and is in turn dependent on the device{\textquoteright}s working conditions. This work describes a statistical approach to construct a model that can be used to continuously compute the normal QBER, based on current (and changing) working conditions. The model is thus meant as a tool to refine the theoretical QBER threshold specific to the given QKD protocol, based on empirical data obtained under the given environmental conditions. More importantly, it allows the QKD-device to self-recalibrate under changing working conditions.",

author = "Sandra K{\"o}nig and Stefan Rass",

year = "2014",

language = "English",

isbn = "978-1-61208-380-3",

pages = "1--7",

editor = "Ovchinnikov, \{Victor \} and Privman, \{Vladimir \}",

booktitle = "Proceedings of the International Conference on Quanum-, Nanon and Microtechnology (ICQNM), 2014",

note = "ICQNM 2014 : The Eighth International Conference on Quantum, Nano/Bio, and Micro Technologies ; Conference date: 16-11-2014 Through 20-11-2014",

}

König, S & Rass, S 2014, Self-Adaption of Quantum Key Distribution Devices to Changing Working Conditions. in V Ovchinnikov & V Privman (Hrsg.), Proceedings of the International Conference on Quanum-, Nanon and Microtechnology (ICQNM), 2014. S. 1-7, ICQNM 2014 : The Eighth International Conference on Quantum, Nano/Bio, and Micro Technologies, Lisbon, Portugal, 16/11/14.

Self-Adaption of Quantum Key Distribution Devices to Changing Working Conditions. / König, Sandra; Rass, Stefan.
Proceedings of the International Conference on Quanum-, Nanon and Microtechnology (ICQNM), 2014. Hrsg. / Victor Ovchinnikov; Vladimir Privman. 2014. S. 1-7.

Publikation: Beitrag in Buch oder Tagungsband › Vortrag mit Beitrag in Tagungsband › Begutachtung

TY - GEN

T1 - Self-Adaption of Quantum Key Distribution Devices to Changing Working Conditions

AU - König, Sandra

AU - Rass, Stefan

PY - 2014

Y1 - 2014

N2 - Quantum key distribution (QKD) draws security from the ability to detect eavesdroppers upon the incident of “unnaturally high” quantum bit error rates (QBER) during the protocol. This presumes that a working QKD device implementation needs to be calibrated with its own individual and characteristic channel noise that is observed in any case, especially when there is no eavesdropper. This natural noise level influences the idle QBER, and is in turn dependent on the device’s working conditions. This work describes a statistical approach to construct a model that can be used to continuously compute the normal QBER, based on current (and changing) working conditions. The model is thus meant as a tool to refine the theoretical QBER threshold specific to the given QKD protocol, based on empirical data obtained under the given environmental conditions. More importantly, it allows the QKD-device to self-recalibrate under changing working conditions.

AB - Quantum key distribution (QKD) draws security from the ability to detect eavesdroppers upon the incident of “unnaturally high” quantum bit error rates (QBER) during the protocol. This presumes that a working QKD device implementation needs to be calibrated with its own individual and characteristic channel noise that is observed in any case, especially when there is no eavesdropper. This natural noise level influences the idle QBER, and is in turn dependent on the device’s working conditions. This work describes a statistical approach to construct a model that can be used to continuously compute the normal QBER, based on current (and changing) working conditions. The model is thus meant as a tool to refine the theoretical QBER threshold specific to the given QKD protocol, based on empirical data obtained under the given environmental conditions. More importantly, it allows the QKD-device to self-recalibrate under changing working conditions.

M3 - Conference Proceedings with Oral Presentation

SN - 978-1-61208-380-3

SP - 1

EP - 7

BT - Proceedings of the International Conference on Quanum-, Nanon and Microtechnology (ICQNM), 2014

A2 - Ovchinnikov, Victor

A2 - Privman, Vladimir

T2 - ICQNM 2014 : The Eighth International Conference on Quantum, Nano/Bio, and Micro Technologies

Y2 - 16 November 2014 through 20 November 2014

ER -

Self-Adaption of Quantum Key Distribution Devices to Changing Working Conditions

Abstract

Konferenz

Research Field

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