Eavesdropping on practical quantum cryptography

Mark S. Williamson, Vlatko Vedral

Type: Article

Publication Date: 2003-01-01

Citations: 3

DOI: https://doi.org/10.1080/0950034031000077542

Abstract

Practical implementations of quantum cryptography use attenuated laser pulses as the signal source rather than single photons. The channels used to transmit are also lossy. Here we give a simple derivation of two beamsplitting attacks on quantum cryptographic systems using laser pulses, either coherent or mixed states with any mean photon number. We also give a simple derivation of a photon-number splitting attack, the most advanced, both in terms of performance and technology required. We find bounds on the maximum disturbance for a given mean photon number and observed channel transmission efficiency for which a secret key can be distilled. We start by reviewing two incoherent attacks that can be used on single photon quantum cryptographic systems. These results are then adapted to systems that use laser pulses and lossy channels.

Locations

arXiv (Cornell University) - View - PDF
Journal of Modern Optics - View

Similar Works

Action	Title	Year	Authors
+ PDF Chat	Eavesdropping on practical quantum cryptography	2003	Mark S. Williamson Vlatkovedral
+ PDF Chat	Security of decoy-state protocols for general photon-number-splitting attacks	2013	Rolando D. Somma Richard Hughes
+ PDF Chat	Beating the Photon-Number-Splitting Attack in Practical Quantum Cryptography	2005	Xiang‐Bin Wang
+	Security of quantum key distribution with imperfect phase randomisation	2022	Guillermo Currás-Lorenzo Shlok Nahar Norbert Lütkenhaus Kiyoshi Tamaki Marcos Curty
+ PDF Chat	Security of the decoy state method for quantum key distribution	2020	А. С. Трушечкин Evgeniy O. Kiktenko D. A. Kronberg Aleksey K. Fedorov
+	Laser damage creates backdoors in quantum communications	2015	Vadim Makarov Jean‐Philippe Bourgoin Poompong Chaiwongkhot Mathieu Gagné Thomas Jennewein Sarah Kaiser Raman Kashyap Matthieu Legré Carter Minshull Shihan Sajeed
+	Optimizing Decoy State Enabled Quantum Key Distribution Systems to Maximize Quantum Throughput and Detect Photon Number Splitting Attacks with High Confidence	2016	Logan O. Mailloux Michael R. Grimaila Douglas D. Hodson Ryan Engle Colin V. McLaughlin Gerald Baumgartner
+ PDF Chat	Security of quantum key distribution with imperfect phase randomisation	2023	Guillermo Currás-Lorenzo Shlok Nahar Norbert Lütkenhaus Kiyoshi Tamaki Marcos Curty
+	Vulnerability analysis of coherent quantum cryptography protocols towards to an active beam-splitting attack.	2016	D. A. Kronberg Evgeniy O. Kiktenko Aleksey K. Fedorov Yury Kurochkin
+ PDF Chat	Security of practical modulator-free quantum key distribution	2024	Álvaro Navarrete Víctor Zapatero Marcos Curty
+	Enhancing practical security of quantum key distribution with a few decoy states	2005	Jim Harrington Jean Ettinger Richard Hughes J. E. Nordholt
+ PDF Chat	Upper Security Bounds for Coherent-One-Way Quantum Key Distribution	2020	J. González-Payo Róbert Trényi Weilong Wang Marcos Curty
+ PDF Chat	Quantum cryptography beyond key distribution: theory and experiment	2024	Mathieu Bozzio Claude Crépeau Petros Wallden Philip Walther
+ PDF Chat	Faint laser quantum key distribution: eavesdropping exploiting multiphoton pulses	2001	Stéphane Félix Nicolas Gisin André Stefanov Hugo Zbinden
+	Fundamental Insecurity of Multi-Photon Sources Under Photon-Number Splitting Attacks in Quantum Key Distribution	2012	Horace P. Yuen
+ PDF Chat	Quantified effects of the laser-seeding attack in quantum key distribution	2023	V. Lovic Davide G. Marangon Peter R. Smith Robert I. Woodward Andrew J. Shields
+ PDF Chat	Unconditionally secure one-way quantum key distribution using decoy pulses	2007	Zhiliang Yuan A. W. Sharpe A. J. Shields
+ PDF Chat	Achieving Ultimate Noise Tolerance in Quantum Communication	2021	Frédéric Bouchard Duncan England Philip J. Bustard Kate Fenwick Ebrahim Karimi Khabat Heshami Benjamin J. Sussman
+ PDF Chat	Coherent-pulse implementations of quantum cryptography protocols resistant to photon-number-splitting attacks	2004	Antonio Acín Nicolas Gisin Valerio Scarani
+ PDF Chat	Forty Thousand Kilometers Under Quantum Protection	2023	N. S. Kirsanov Valeria Pastushenko Alexey Kodukhov Michael Yarovikov Asel Sagingalieva D. A. Kronberg Markus Pflitsch Valerii Vinokur

Works That Cite This (0)

Action	Title	Year	Authors

Works Cited by This (0)

Action	Title	Year	Authors