Your search keyword '"Andrew W. Sharpe"' showing total 61 results

1. Quantum secured Gigabit Passive Optical Networks.

Author

Bernd Fröhlich 0002, James F. Dynes, Marco Lucamarini, Andrew W. Sharpe, Simon W.-B. Tam, Zhiliang Yuan, and Andrew J. Shields

Published

2015

2. First quantum secured 10-Gb/s DWDM transmission over the same installed fibre.

Author

Iris Choi, Yu Rong Zhou, James F. Dynes, Zhiliang Yuan, Andreas Klar, Andrew W. Sharpe, Alan Plews, Marco Lucamarini, Christian Radig, Jorg Neubert, Helmut Griesser, Michael Eiselt, Christopher J. Chunnilall, Guillaume Lepert, Alastair Sinclair, Jörg-Peter Elbers, Andrew Lord, and Andrew J. Shields

Published

2014

3. A High Speed, Post-Processing Free, Quantum Random Number Generator

Author

James F. Dynes, Zhiliang Yuan, Andrew W. Sharpe, and Andrew J. Shields

Published

2008

4. Long-Term Test of a Fast and Compact Quantum Random Number Generator

Author

Alan Plews, James F. Dynes, Andrew J. Shields, Andrew W. Sharpe, Davide G. Marangon, Marco Lucamarini, and Zhiliang Yuan

Subjects

Pseudorandom number generator, Quantum Physics, Computer science, Random number generation, Monte Carlo method, Probabilistic logic, FOS: Physical sciences, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Atomic and Molecular Physics, and Optics, 010309 optics, Computer engineering, Quantum process, 0103 physical sciences, Hardware random number generator, Quantum Physics (quant-ph), 0210 nano-technology, Randomness, Generator (mathematics)

Abstract

Random numbers are an essential resource to many applications, including cryptography and Monte Carlo simulations. Quantum random number generators (QRNGs) represent the ultimate source of randomness, as the numbers are obtained by sampling a physical quantum process that is intrinsically probabilistic. However, they are yet to be widely employed to replace deterministic pseudo random number generators (PRNG) for practical applications. QRNGs are regarded as interesting devices. However they are slower than PRNGs for simulations and are typically seen as clumsy laboratory prototypes, prone to failures and unreliable for cryptographic applications. Here we overcome these limitations and demonstrate a compact and self-contained QRNG capable of generating random numbers at a pace of 8 Gbit/s uninterruptedly for 71 days. During this period, the physical parameters of the quantum process were monitored in real time by self-checking functions implemented in the generator itself. At the same time, the output random numbers were analyzed with the most stringent suites of statistical tests. The analysis shows that the QRNG under test sustained the continuous operation without physical instabilities or hardware failures. At the same time, the output random numbers were analyzed with the most stringent suites of statistical tests, which were passed during the whole operation time. This extensive trial demonstrates the reliability of a robustly designed QRNG and paves the way to its use in practical applications based on randomness., 8 pages, 7 figures

Published

2018

5. 10-Mb/s Quantum Key Distribution

Author

Marco Lucamarini, James F. Dynes, Zhiliang Yuan, Kazuaki Doi, Yoshimichi Tanizawa, Alex Dixon, Ririka Takahashi, Alan Plews, Andrew J. Shields, Hideaki Sato, Akira Murakami, Evan Lavelle, Mamko Kujiraoka, Winci W.-S. Tam, and Andrew W. Sharpe

Subjects

Quantum Physics, business.industry, Computer science, FOS: Physical sciences, 02 engineering and technology, Quantum key distribution, Avalanche photodiode, 01 natural sciences, Atomic and Molecular Physics, and Optics, Interferometry, 020210 optoelectronics & photonics, Quantum cryptography, Robustness (computer science), 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Photonics, Quantum Physics (quant-ph), 010306 general physics, business, Error detection and correction, BB84

Abstract

We report the first quantum key distribution (QKD) systems capable of delivering sustainable, real-time secure keys continuously at rates exceeding 10 Mb/s. To achieve such rates, we developed high speed post-processing modules, achieving maximum data throughputs of 60 MC/s, 55 Mb/s, and 108 Mb/s for standalone operation of sifting, error correction and privacy amplification modules, respectively. The photonic layer of the QKD systems features high-speed single photon detectors based on self-differencing InGaAs avalanche photodiodes, phase encoding using asymmetric Mach-Zehnder interferometer, and active stabilization of the interferometer phase and photon polarisation. An efficient variant of the decoy-state BB84 protocol is implemented for security analysis, with a large dataset size of $10^8$ bits selected to mitigate finite-size effects. Over a 2 dB channel, a record secure key rate of 13.72 Mb/s has been achieved averaged over 4.4 days of operation. We confirm the robustness and long-term stability on a second QKD system continuously running for 1 month without any user intervention., Comment: 7 pages, 8 figures, 1 table

Published

2018

6. Cambridge quantum network

Author

Richard V. Penty, Alan Plews, Joo Yeon Cho, H Greißer, Marco Lucamarini, Andrew W. Sharpe, Andrew J. Shields, J.-P. Elbers, Yoshimichi Tanizawa, Wws Tam, Ririka Takahashi, Zhiliang Yuan, Ian H. White, James F. Dynes, Adrian Wonfor, Alex Dixon, Sharpe, A. W. [0000-0003-0378-0885], Lucamarini, M. [0000-0002-7351-4622], Yuan, Z. L. [0000-0001-5276-9151], Dixon, A. R. [0000-0001-7628-4052], Apollo - University of Cambridge Repository, Sharpe, AW [0000-0003-0378-0885], Lucamarini, M [0000-0002-7351-4622], Yuan, ZL [0000-0001-5276-9151], and Dixon, AR [0000-0001-7628-4052]

Subjects

639/766/483/481, Computer Networks and Communications, Computer science, 639/166/987, Data theft, Quantum key distribution, Encryption, 01 natural sciences, lcsh:QA75.5-76.95, 5108 Quantum Physics, 010309 optics, Gigabit, 0103 physical sciences, Broadband, Computer Science (miscellaneous), Redundancy (engineering), Quantum information, 010306 general physics, Quantum network, business.industry, 639/624/1075/187, article, Statistical and Nonlinear Physics, lcsh:QC1-999, Computational Theory and Mathematics, lcsh:Electronic computers. Computer science, business, 51 Physical Sciences, lcsh:Physics, Computer network

Abstract

Future-proofing current fibre networks with quantum key distribution (QKD) is an attractive approach to combat the ever growing breaches of data theft. To succeed, this approach must offer broadband transport of quantum keys, efficient quantum key delivery and seamless user interaction, all within the existing fibre network. However, quantum networks to date either require dark fibres and/or offer bit rates inadequate for serving a large number of users. Here we report a city wide high-speed metropolitan QKD network—the Cambridge quantum network—operating on fibres already populated with high-bandwidth data traffic. We implement a robust key delivery layer to demonstrate essential network operation, as well as enabling encryption of 100 Gigabit per second (Gbps) simultaneous data traffic with rapidly refreshed quantum keys. Network resilience against link disruption is supported by high-QKD link rates and network link redundancy. We reveal that such a metropolitan network can support tens of thousands of users with key rates in excess of 1 kilobit per second (kbps) per user. Our result hence demonstrates a clear path for implementing quantum security in metropolitan fibre networks.

Published

2019

7. Quantum key distribution without detector vulnerabilities using optically seeded lasers

Author

Andrew W. Sharpe, Richard V. Penty, Zhiliang Yuan, Bernd Fröhlich, Marco Lucamarini, Andrew J. Shields, James F. Dynes, L. C. Comandar, and Swb Tam

Subjects

Physics, business.industry, Detector, Quantum sensor, Physics::Optics, Quantum imaging, Quantum key distribution, Laser, 01 natural sciences, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, law.invention, 010309 optics, Optics, Quantum cryptography, law, 0103 physical sciences, Key (cryptography), Optoelectronics, Quantum information, 010306 general physics, business, Computer Science::Cryptography and Security

Abstract

Quantum cryptography immune from detector attacks is realized by the development of a source of indistinguishable laser pulses based on optically seeded gain-switched lasers. Key rates exceeding 1 Mb s−1 are demonstrated in the finite-size regime.

Published

2016

8. Intrinsic mitigation of the after-gate attack in quantum key distribution through fast-gated delayed detection

Author

Andrew J. Shields, James F. Dynes, Marco Lucamarini, Amos Martinez, George Roberts, Alexander Koehler-Sidki, Andrew W. Sharpe, Zhiliang Yuan, and Apollo - University of Cambridge Repository

Subjects

Physics, Discrete mathematics, Quantum Physics, Physics - Instrumentation and Detectors, General Physics and Astronomy, FOS: Physical sciences, 02 engineering and technology, Instrumentation and Detectors (physics.ins-det), Quantum key distribution, 021001 nanoscience & nanotechnology, Special class, 01 natural sciences, Measure (mathematics), Imaging phantom, 5108 Quantum Physics, 5102 Atomic, Molecular and Optical Physics, 0103 physical sciences, 010306 general physics, 0210 nano-technology, Quantum Physics (quant-ph), 51 Physical Sciences, Optics (physics.optics), Physics - Optics, Computer Science::Cryptography and Security

Abstract

The information theoretic security promised by quantum key distribution (QKD) holds as long as the assumptions in the theoretical model match the parameters in the physical implementation. The superlinear behaviour of sensitive single-photon detectors represents one such mismatch and can pave the way to powerful attacks hindering the security of QKD systems, a prominent example being the after-gate attack. A longstanding tenet is that trapped carriers causing delayed detection can help mitigate this attack, but despite intensive scrutiny, it remains largely unproven. Here we approach this problem from a physical perspective and find new evidence to support a detector's secure response. We experimentally investigate two different carrier trapping mechanisms causing delayed detection in fast-gated semiconductor avalanche photodiodes, one arising from the multiplication layer, the other from the heterojunction interface between absorption and charge layers. The release of trapped carriers increases the quantum bit error rate measured under the after-gate attack above the typical QKD security threshold, thus favouring the detector's inherent security. This represents a significant step to avert quantum hacking of QKD systems., 8 pages, 6 figures

Published

2019

9. Testing the photon-number statistics of a quantum key distribution light source

Author

James F. Dynes, Andrew J. Shields, Andrew W. Sharpe, Marco Lucamarini, Zhiliang Yuan, K. A. Patel, and Martin B. Ward

Subjects

Quantum Physics, Photon, Photon statistics, Distribution (number theory), Random number generation, Computer science, FOS: Physical sciences, Quantum key distribution, 01 natural sciences, Atomic and Molecular Physics, and Optics, 010309 optics, 0103 physical sciences, Statistics, Key (cryptography), Coherent states, Quantum Physics (quant-ph), 010306 general physics, Quantum, Randomness

Abstract

A commonly held tenet is that lasers well above threshold emit photons in a coherent state, which follow a Poissonian statistics when measured in photon number. This feature is often exploited to build quantum-based random number generators or to derive the secure key rate of quantum key distribution systems. Hence the photon number distribution of the light source can directly impact the randomness and the security distilled from such devices. Here, we propose a method based on measuring correlation functions to experimentally characterise a light source's photon statistics and use it in the estimation of a quantum key distribution system's key rate. This promises to be a useful tool for the certification of quantum-related technologies., 11 pages, 7 figures

Published

2018

10. Intensity modulation as a preemptive measure against blinding of single-photon detectors based on self-differencing cancellation

Author

George Roberts, Marco Lucamarini, James F. Dynes, Andrew W. Sharpe, Zhiliang Yuan, Alexander Koehler-Sidki, Andrew J. Shields, Roberts, George [0000-0002-7318-0669], and Apollo - University of Cambridge Repository

Subjects

Physics, Quantum Physics, Physics - Instrumentation and Detectors, Blinding, Physics::Instrumentation and Detectors, business.industry, Photon detector, Measure (physics), FOS: Physical sciences, Instrumentation and Detectors (physics.ins-det), 01 natural sciences, 010309 optics, Optics, 5102 Atomic, Molecular and Optical Physics, 0103 physical sciences, Quantum information, Quantum Physics (quant-ph), 010306 general physics, business, 51 Physical Sciences, Intensity modulation

Abstract

Quantum key distribution is rising as an important cryptographic primitive for protecting the communication infrastructure in the digital era. However, its implementation security is often weakened by components whose behavior deviates from what is expected. Here, we analyse the response of a self-differencing avalanche photodiode, a key enabler for high speed quantum key distribution, to intense light shone from a continuous-wave laser. Under incorrect settings, the cancellation entailed by the self-differencing circuitry can make the detector insensitive to single photons. However, we experimentally demonstrate that even in such cases intensity modulation can be used as an effective measure to restore the detector's expected response to the input light.

Published

2018

11. Best-Practice Criteria for Practical Security of Self-Differencing Avalanche Photodiode Detectors in Quantum Key Distribution

Author

James F. Dynes, Andrew J. Shields, Zhiliang Yuan, George Roberts, Alexander Koehler-Sidki, Marco Lucamarini, Andrew W. Sharpe, Roberts, George [0000-0002-7318-0669], and Apollo - University of Cambridge Repository

Subjects

Photocurrent, Quantum Physics, APDS, Computer science, Capacitive sensing, Photon detector, Detector, General Physics and Astronomy, FOS: Physical sciences, 02 engineering and technology, Quantum key distribution, 021001 nanoscience & nanotechnology, Avalanche photodiode, 01 natural sciences, law.invention, 010309 optics, quant-ph, Robustness (computer science), law, 0103 physical sciences, Electronic engineering, 0210 nano-technology, Quantum Physics (quant-ph)

Abstract

© 2018 American Physical Society. Fast-gated avalanche photodiodes (APDs) are the most commonly used single photon detectors for high-bit-rate quantum key distribution (QKD). Their robustness against external attacks is crucial to the overall security of a QKD system, or even an entire QKD network. We investigate the behavior of a gigahertz-gated, self-differencing (In,Ga)As APD under strong illumination, a tactic Eve often uses to bring detectors under her control. Our experiment and modeling reveal that the negative feedback by the photocurrent safeguards the detector from being blinded through reducing its avalanche probability and/or strengthening the capacitive response. Based on this finding, we propose a set of best-practice criteria for designing and operating fast-gated APD detectors to ensure their practical security in QKD.

Published

2018

12. Birefringent Interferometry for Quantum Key Distribution

Author

Alan Plews, Zhiliang Yuan, Andrew J. Shields, Andrew W. Sharpe, Marco Lucamarini, Bernd Fröhlich, Amos Martinez, James F. Dynes, and Winci W.-S. Tam

Subjects

0301 basic medicine, Physics, Quantum network, Birefringence, business.industry, Quantum key distribution, Passive optical network, 03 medical and health sciences, Interferometry, 030104 developmental biology, Optics, Splitter, Drop (telecommunication), business, BB84

Abstract

We report quantum key distribution using an all-fiber, highly birefringent interferometer to implement the BB84 protocol. With this approach, we demonstrate point-to-point operation over 15.5 km drop fiber and an 8-port passive optical network splitter.

Published

2018

13. Setting best practice criteria for self-differencing avalanche photodiodes in quantum key distribution

Author

Seb J. Savory, Andrew W. Sharpe, George Roberts, Marco Lucamarini, Alexander Koehler-Sidki, James F. Dynes, Andrew J. Shields, and Zhiliang Yuan

Subjects

Physics, Physics::Instrumentation and Detectors, Detector, 02 engineering and technology, Quantum key distribution, 021001 nanoscience & nanotechnology, Avalanche photodiode, 01 natural sciences, 010309 optics, 0103 physical sciences, Key (cryptography), Electronic engineering, Automatic gain control, 0210 nano-technology, Sensitivity (electronics), Electronic circuit, Vulnerability (computing)

Abstract

In recent years, the security of avalanche photodiodes as single photon detectors for quantum key distribution has been subjected to much scrutiny. The most prominent example of this surrounds the vulnerability of such devices to blinding under strong illumination. We focus on self-differencing avalanche photodiodes, single photon detectors that have demonstrated count rates exceeding 1 GCounts/s resulting in secure key rates over 1 MBit/s. These detectors use a passive electronic circuit to cancel any periodic signals thereby enhancing detection sensitivity. However this intrinsic feature can be exploited by adversaries to gain control of the devices using illumination of a moderate intensity. Through careful experimental examinations, we define here a set of criteria for these detectors to avoid such attacks.

Published

2017

14. Novel technologies for quantum key distribution networks

Author

George Roberts, Bernd Fröhlich, Andrew W. Sharpe, Andrew J. Shields, Marco Lucamarini, Winci W.-S. Tam, James F. Dynes, Zhiliang Yuan, and Alan Plews

Subjects

Engineering, Optical fiber, business.industry, Transmitter, Fiber (computer science), 02 engineering and technology, Quantum key distribution, 021001 nanoscience & nanotechnology, 01 natural sciences, law.invention, law, 0103 physical sciences, 010306 general physics, 0210 nano-technology, business, Telecommunications, Computer network

Abstract

Quantum key distribution (QKD) has matured rapidly towards practical use for protecting fiber communication infrastructures due to its unique ability of transmitting information-theoretically secure digital keys. Here, we report key advances in QKD that allow modulator-free transmitter [1], application into existing fiber infrastructures [2,3] and cryogen-free long-distance operation [4].

Published

2017

15. Quantum key distribution with hacking countermeasures and long term field trial

Author

Yoshimichi Tanizawa, Marco Lucamarini, Bernd Fröhlich, Zhiliang Yuan, Andrew W. Sharpe, Andrew J. Shields, Winci W.-S. Tam, Alex Dixon, Mikio Fujiwara, Masahide Sasaki, Shinichi Kawamura, James F. Dynes, Hideaki Sato, and Alan Plews

Subjects

Multidisciplinary, Blinding, Exploit, Computer science, Science, Trojan horse, Quantum key distribution, Computer security, computer.software_genre, 01 natural sciences, Information-theoretic security, Article, 010309 optics, 0103 physical sciences, Key (cryptography), Medicine, Side channel attack, 010306 general physics, computer, Hacker

Abstract

Quantum key distribution’s (QKD’s) central and unique claim is information theoretic security. However there is an increasing understanding that the security of a QKD system relies not only on theoretical security proofs, but also on how closely the physical system matches the theoretical models and prevents attacks due to discrepancies. These side channel or hacking attacks exploit physical devices which do not necessarily behave precisely as the theory expects. As such there is a need for QKD systems to be demonstrated to provide security both in the theoretical and physical implementation. We report here a QKD system designed with this goal in mind, providing a more resilient target against possible hacking attacks including Trojan horse, detector blinding, phase randomisation and photon number splitting attacks. The QKD system was installed into a 45 km link of a metropolitan telecom network for a 2.5 month period, during which time the system operated continuously and distributed 1.33 Tbits of secure key data with a stable secure key rate over 200 kbit/s. In addition security is demonstrated against coherent attacks that are more general than the collective class of attacks usually considered.

Published

2017

16. Experimental measurement-device-independent quantum digital signatures

Author

James F. Dynes, Andrew J. Shields, Ittoop Vergheese Puthoor, George Roberts, Marco Lucamarini, Zhiliang Yuan, L. C. Comandar, Marcos Curty, Andrew W. Sharpe, Erika Andersson, Roberts, George [0000-0002-7318-0669], and Apollo - University of Cambridge Repository

Subjects

Computer science, Science, General Physics and Astronomy, FOS: Physical sciences, Statistical fluctuations, Quantum key distribution, 01 natural sciences, Article, General Biochemistry, Genetics and Molecular Biology, 010309 optics, Digital signature, 0103 physical sciences, Electronic engineering, 010306 general physics, lcsh:Science, Protocol (object-oriented programming), Quantum, Block (data storage), Computer Science::Cryptography and Security, Quantum Physics, Multidisciplinary, General Chemistry, Sample (graphics), Quantum digital signature, lcsh:Q, Quantum Physics (quant-ph)

Abstract

The development of quantum networks will be paramount towards practical and secure telecommunications. These networks will need to sign and distribute information between many parties with information-theoretic security, requiring both quantum digital signatures (QDS) and quantum key distribution (QKD). Here, we introduce and experimentally realise a quantum network architecture, where the nodes are fully connected using a minimum amount of physical links. The central node of the network can act either as a totally untrusted relay, connecting the end users via the recently introduced measurement-device-independent (MDI)-QKD, or as a trusted recipient directly communicating with the end users via QKD. Using this network, we perform a proof-of-principle demonstration of QDS mediated by MDI-QKD. For that, we devised an efficient protocol to distil multiple signatures from the same block of data, thus reducing the statistical fluctuations in the sample and greatly enhancing the final QDS rate in the finite-size scenario., Measurement-device-independent quantum digital signatures would allow a document to be signed and transferred with information-theoretic security. Here, the authors reach this goal using a reconfigurable quantum network where the central node can switch between trusted and untrusted operation.

Published

2017

17. A quantum access network

Author

Andrew W. Sharpe, Andrew J. Shields, Marco Lucamarini, James F. Dynes, Zhiliang Yuan, and Bernd Fröhlich

Subjects

Scheme (programming language), Quantum Physics, Quantum network, Multidisciplinary, Access network, SIMPLE (military communications protocol), business.industry, Computer science, Node (networking), FOS: Physical sciences, Quantum key distribution, Quantum information, Quantum Physics (quant-ph), business, computer, Information exchange, Physics - Optics, Optics (physics.optics), Computer network, computer.programming_language

Abstract

The theoretically proven security of quantum key distribution (QKD) could revolutionise how information exchange is protected in the future. Several field tests of QKD have proven it to be a reliable technology for cryptographic key exchange and have demonstrated nodal networks of point-to-point links. However, so far no convincing answer has been given to the question of how to extend the scope of QKD beyond niche applications in dedicated high security networks. Here we show that adopting simple and cost-effective telecommunication technologies to form a quantum access network can greatly expand the number of users in quantum networks and therefore vastly broaden their appeal. We are able to demonstrate that a high-speed single-photon detector positioned at a network node can be shared between up to 64 users for exchanging secret keys with the node, thereby significantly reducing the hardware requirements for each user added to the network. This point-to-multipoint architecture removes one of the main obstacles restricting the widespread application of QKD. It presents a viable method for realising multi-user QKD networks with resource efficiency and brings QKD closer to becoming the first widespread technology based on quantum physics., Comment: 6 pages, 4 figures

Published

2013

18. Long-distance quantum key distribution secure against coherent attacks

Author

Andrew J. Shields, Zhiliang Yuan, Andrew W. Sharpe, Bernd Fröhlich, Marco Lucamarini, Winci W.-S. Tam, L. C. Comandar, James F. Dynes, and Alan Plews

Subjects

Quantum Physics, business.industry, Computer science, FOS: Physical sciences, 02 engineering and technology, Quantum channel, Quantum key distribution, 021001 nanoscience & nanotechnology, Encryption, 01 natural sciences, Multiplexing, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Quantum cryptography, 0103 physical sciences, 010306 general physics, 0210 nano-technology, business, Quantum Physics (quant-ph), BB84, Secure transmission, Key exchange, Computer network

Abstract

Quantum key distribution (QKD) permits information-theoretically secure transmission of digital encryption keys, assuming that the behaviour of the devices employed for the key exchange can be reliably modelled and predicted. Remarkably, no assumptions have to be made on the capabilities of an eavesdropper other than that she is bounded by the laws of Nature, thus making the security of QKD "unconditional". However, unconditional security is hard to achieve in practice. For example, any experimental realisation can only collect finite data samples, leading to vulnerabilities against coherent attacks, the most general class of attacks, and for some protocols the theoretical proof of robustness against these attacks is still missing. For these reasons, in the past many QKD experiments have fallen short of implementing an unconditionally secure protocol and have instead considered limited attacking capabilities by the eavesdropper. Here, we explore the security of QKD against coherent attacks in the most challenging environment: the long-distance transmission of keys. We demonstrate that the BB84 protocol can provide positive key rates for distances up to 240 km without multiplexing of conventional signals, and up to 200 km with multiplexing. Useful key rates can be achieved even for the longest distances, using practical thermo-electrically cooled single-photon detectors., Comment: 6 pages, 3 figures, supplementary information

Published

2017

19. Ultra-high bandwidth quantum secured data transmission

Author

James F. Dynes, Bernd Fröhlich, Christian Radig, Andrew W. Sharpe, Zhiliang Yuan, Winci W.-S. Tam, Marco Lucamarini, Tim Edwards, Alan Plews, Andrew Straw, and Andrew J. Shields

Subjects

Optical fiber, Computer science, FOS: Physical sciences, Quantum key distribution, 01 natural sciences, Multiplexing, Article, law.invention, 010309 optics, law, 0103 physical sciences, Electronic engineering, Fiber, 010306 general physics, Quantum, Quantum Physics, Multidisciplinary, business.industry, Bandwidth (signal processing), Telecommunications network, Quantum cryptography, Photonics, business, Quantum Physics (quant-ph), Data transmission

Abstract

Quantum key distribution (QKD) provides an attractive means for securing communications in optical fibre networks. However, deployment of the technology has been hampered by the frequent need for dedicated dark fibres to segregate the very weak quantum signals from conventional traffic. Up until now the coexistence of QKD with data has been limited to bandwidths that are orders of magnitude below those commonly employed in fibre optic communication networks. Using an optimised wavelength divisional multiplexing scheme, we transport QKD and the prevalent 100 Gb/s data format in the forward direction over the same fibre for the first time. We show a full quantum encryption system operating with a bandwidth of 200 Gb/s over a 100 km fibre. Exploring the ultimate limits of the technology by experimental measurements of the Raman noise, we demonstrate it is feasible to combine QKD with 10 Tb/s of data over a 50 km link. These results suggest it will be possible to integrate QKD and other quantum photonic technologies into high bandwidth data communication infrastructures, thereby allowing their widespread deployment.

Published

2016

20. Quantum key distribution using in-line highly birefringent interferometers

Author

Winci W.-S. Tam, Andrew J. Shields, Alan Plews, Marco Lucamarini, Andrew W. Sharpe, James F. Dynes, Amos Martinez, Bernd Fröhlich, and Zhiliang Yuan

Subjects

Key generation, Access network, Physics and Astronomy (miscellaneous), Computer science, business.industry, 02 engineering and technology, Quantum key distribution, 021001 nanoscience & nanotechnology, 01 natural sciences, Passive optical network, Interferometry, Secure communication, Quantum cryptography, 0103 physical sciences, Electronic engineering, 010306 general physics, 0210 nano-technology, business, BB84

Abstract

Secure communication networks enabled by commercial quantum key distribution (QKD) are already available. However, their widespread deployment will require great efforts towards reducing the currently prohibitive cost of QKD systems. Here, we propose a compact and cost-effective alternative to the asymmetric Mach-Zehnder interferometer commonly used to implement phase encoding in the Bennett-Brassard 1984 (BB84) QKD protocol. Our solution consists of an all-fiber, in-line, highly birefringent interferometer (HBI). The HBI shows improved tolerance to length mismatches and a simpler assembly, making it particularly desirable for the fabrication of multi-user systems where several interferometers must have matched delays and where cost and space considerations can be most critical, such as quantum access networks. As a proof-of-principle, we demonstrate point-to-point QKD operation with HBIs over 15.5 km drop fiber and an 8-port passive optical network splitter. We achieve a secure key generation rate of 299.4 ± 16.4 kbit/s with a quantum bit error rate of 2.89 ± 0.31% for a continuous 25 h operation period.

Published

2018

21. Quantum secured gigabit optical access networks

Author

Zhiliang Yuan, Andrew W. Sharpe, James F. Dynes, Andrew J. Shields, Marco Lucamarini, Simon W.-B. Tam, and Bernd Fröhlich

Subjects

Computer science, FOS: Physical sciences, Quantum key distribution, 01 natural sciences, Multiplexing, Passive optical network, Article, 010309 optics, Gigabit, 0103 physical sciences, Fiber, Quantum information, 010306 general physics, Quantum, Quantum Physics, Multidisciplinary, Access network, business.industry, Noise (signal processing), Node (networking), Splitter, business, Quantum Physics (quant-ph), Physics - Optics, Computer network, Optics (physics.optics)

Abstract

Optical access networks connect multiple endpoints to a common network node via shared fibre infrastructure. They will play a vital role to scale up the number of users in quantum key distribution (QKD) networks. However, the presence of power splitters in the commonly used passive network architecture makes successful transmission of weak quantum signals challenging. This is especially true if QKD and data signals are multiplexed in the passive network. The splitter introduces an imbalance between quantum signal and Raman noise, which can prevent the recovery of the quantum signal completely. Here we introduce a method to overcome this limitation and demonstrate coexistence of multi-user QKD and full power data traffic from a gigabit passive optical network (GPON). The dual feeder implementation is compatible with standard GPON architectures and can support up to 128 users, highlighting that quantum protected GPON networks could be commonplace in the future., Comment: 11 pages, 5 figures

Published

2015

22. Quantum Secured Gigabit Passive Optical Networks

Author

Andrew J. Shields, Bernd Fröhlich, James F. Dynes, Andrew W. Sharpe, Marco Lucamarini, Zhiliang Yuan, and Simon W.-B. Tam

Subjects

Access network, business.industry, Computer science, Physics::Optics, Encryption, Signal, Passive optical network, Transmission (telecommunications), Secure communication, Gigabit, ComputerSystemsOrganization_MISCELLANEOUS, 10G-PON, business, Quantum, Computer Science::Cryptography and Security, Computer network

Abstract

We report transmission of a quantum signal alongside conventional Gigabit Passive Optical Network traffic in the same optical distribution network. Encryption keys generated from quantum signals enable provable secure communication in optical access networks.

Published

2015

23. Field trial of a quantum secured 10 Gb/s DWDM transmission system over a single installed fiber

Author

Christopher J. Chunnilall, Jorg-Peter Elbers, Yu Rong Zhou, Iris Choi, Helmut Griesser, Zhiliang Yuan, Andrew Lord, Alastair G. Sinclair, Christian Radig, Jorg Neubert, Guillaume Lepert, James F. Dynes, Marco Lucamarini, Alan Plews, Andrew W. Sharpe, Michael Eiselt, Andreas Klar, and Andrew J. Shields

Subjects

Quantum optics, Computer science, business.industry, Electrical engineering, Macroscopic quantum phenomena, Signal Processing, Computer-Assisted, Quantum channel, Equipment Design, Quantum key distribution, Encryption, Atomic and Molecular Physics, and Optics, Optics, Quantum cryptography, Wavelength-division multiplexing, Key (cryptography), Telecommunications, Computer-Aided Design, Fiber Optic Technology, business, Quantum, Computer Security

Abstract

We present results from the first field-trial of a quantum-secured DWDM transmission system, in which quantum key distribution (QKD) is combined with 4 × 10 Gb/s encrypted data and transmitted simultaneously over 26 km of field installed fiber. QKD is used to frequently refresh the key for AES-256 encryption of the 10 Gb/s data traffic. Scalability to over 40 DWDM channels is analyzed.

Published

2014

24. Room temperature single-photon detectors for high bit rate quantum key distribution

Author

Marco Lucamarini, Andrew J. Shields, Richard V. Penty, Bernd Fröhlich, Andrew W. Sharpe, L. C. Comandar, Zhiliang Yuan, K. A. Patel, and James F. Dynes

Subjects

Quantum Physics, Materials science, Physics and Astronomy (miscellaneous), business.industry, Physics::Instrumentation and Detectors, Detector, FOS: Physical sciences, Quantum key distribution, Avalanche photodiode, Wavelength, Bit (horse), Megabit, Optoelectronics, Electronics, business, Quantum Physics (quant-ph), Sensitivity (electronics)

Abstract

We report room temperature operation of telecom wavelength single-photon detectors for high bit rate quantum key distribution (QKD). Room temperature operation is achieved using InGaAs avalanche photodiodes integrated with electronics based on the self-differencing technique that increases avalanche discrimination sensitivity. Despite using room temperature detectors, we demonstrate QKD with record secure bit rates over a range of fiber lengths (e.g. 1.26 Mbit/s over 50 km). Furthermore, our results indicate that operating the detectors at room temperature increases the secure bit rate for short distances., 14 pages, 4 figures

Published

2014

25. GHz-gated InGaAs/InP single-photon detector with detection efficiency exceeding 55% at 1550 nm

Author

Andrew W. Sharpe, Richard V. Penty, Bernd Fröhlich, Marco Lucamarini, Andrew J. Shields, L. C. Comandar, Zhiliang Yuan, and James F. Dynes

Subjects

Quantum Physics, Materials science, APDS, business.industry, Photon detector, Detector, General Physics and Astronomy, FOS: Physical sciences, Dead time, Avalanche photodiode, Signal, law.invention, Amplitude, law, Optoelectronics, Transient (oscillation), business, Quantum Physics (quant-ph)

Abstract

We report on a gated single-photon detector based on InGaAs/InP avalanche photodiodes (APDs) with a single-photon detection efficiency exceeding 55% at 1550 nm. Our detector is gated at 1 GHz and employs the self-differencing technique for gate transient suppression. It can operate nearly dead time free, except for the one clock cycle dead time intrinsic to self-differencing, and we demonstrate a count rate of 500 Mcps. We present a careful analysis of the optimal driving conditions of the APD measured with a dead time free detector characterization setup. It is found that a shortened gate width of 360 ps together with an increased driving signal amplitude and operation at higher temperatures leads to improved performance of the detector. We achieve an afterpulse probability of 7% at 50% detection efficiency with dead time free measurement and a record efficiency for InGaAs/InP APDs of 55% at an afterpulse probability of only 10.2% with a moderate dead time of 10 ns., Comment: 10 pages, 4 figures

Published

2014

26. Efficient decoy-state quantum key distribution with quantified security

Author

Andrew W. Sharpe, Zhiliang Yuan, Andrew J. Shields, James F. Dynes, Marco Lucamarini, Richard V. Penty, K. A. Patel, Bernd Fröhlich, and Alex Dixon

Subjects

Quantum Physics, Decoy state, business.industry, Computer science, FOS: Physical sciences, Quantum key distribution, Atomic and Molecular Physics, and Optics, Key (cryptography), business, Security level, Decoy, Quantum Physics (quant-ph), Protocol (object-oriented programming), Computer network

Abstract

We analyse the finite-size security of the efficient Bennett-Brassard 1984 protocol implemented with decoy states and apply the results to a gigahertz-clocked quantum key distribution system. Despite the enhanced security level, the obtained secure key rates are the highest reported so far at all fibre distances., 18 pages, 5 figures, 2 tables

Published

2013

27. A Multi-User Quantum Access Network

Author

James F. Dynes, Andrew J. Shields, Bernd Fröhlich, Marco Lucamarini, Andrew W. Sharpe, and Zhiliang Yuan

Subjects

Physics, Quantum network, Access network, business.industry, Quantum sensor, Electrical engineering, Quantum channel, Quantum key distribution, Quantum amplifier, Quantum cryptography, business, Telecommunications, Quantum fluctuation, Computer Science::Information Theory

Abstract

We report stable operation of a multi-user Quantum Access Network over more than 24 hours. We connect multiple quantum transmitters to a single quantum receiver by pre-compensating all phase and polarisation fluctuations.

Published

2013

28. High bit rate quantum key distribution with 100 dB security

Author

James F. Dynes, Zhiliang Yuan, Marco Lucamarini, Andrew W. Sharpe, K. A. Patel, Richard V. Penty, Alex Dixon, Andrew J. Shields, and Bernd Fröhlich

Subjects

Physics, Quantum network, business.industry, Megabit, ComputerSystemsOrganization_MISCELLANEOUS, Bit rate, Electronic engineering, Quantum channel, Quantum key distribution, Telecommunications, business

Abstract

We report the operation of a gigahertz clocked quantum key distribution system featuring high composable and quantifiable security while maintaining more than 1 Mbit/s secure key rate over a 50 km quantum channel.

Published

2013

29. Coexistence of high-bit-rate quantum key distribution and data on optical fiber

Author

Richard V. Penty, Andrew J. Shields, Iris Choi, Andrew W. Sharpe, K. A. Patel, Zhiliang Yuan, James F. Dynes, and Alex Dixon

Subjects

Ethernet, Quantum Physics, Optical fiber, Computer science, business.industry, Physics, QC1-999, Fiber (computer science), FOS: Physical sciences, General Physics and Astronomy, Quantum key distribution, law.invention, Quantum cryptography, law, Key (cryptography), Range (statistics), Quantum Physics (quant-ph), business, Quantum, Computer network, Computer Science::Cryptography and Security

Abstract

Quantum key distribution (QKD) uniquely allows distribution of cryptographic keys with security verified by quantum mechanical limits. Both protocol execution and subsequent applications require the assistance of classical data communication channels. While using separate fibers is one option, it is economically more viable if data and quantum signals are simultaneously transmitted through a single fiber. However, noise-photon contamination arising from the intense data signal has severely restricted both the QKD distances and secure key rates. Here, we exploit a novel temporal-filtering effect for noise-photon rejection. This allows high-bit-rate QKD over fibers up to 90 km in length and populated with error-free bidirectional Gb/s data communications. With high-bit rate and range sufficient for important information infrastructures, such as smart cities and 10 Gbit Ethernet, QKD is a significant step closer towards wide-scale deployment in fiber networks., 7 pages, 5 figures

Published

2012

30. Gigacount/second photon detection with InGaAs avalanche photodiodes

Author

Andrew W. Sharpe, Andrew J. Shields, K. A. Patel, James F. Dynes, Richard V. Penty, and Zhiliang Yuan

Subjects

Physics, Photon, Physics - Instrumentation and Detectors, APDS, business.industry, Orders of magnitude (temperature), FOS: Physical sciences, Physics::Optics, Instrumentation and Detectors (physics.ins-det), Avalanche photodiode, Signal, law.invention, law, Optoelectronics, Electrical and Electronic Engineering, Quantum information, business, Sensitivity (electronics), Diode

Abstract

We demonstrate high count rate single photon detection at telecom wavelengths using a thermoelectrically-cooled semiconductor diode. Our device consists of a single InGaAs avalanche photodiode driven by a 2 GHz gating frequency signal and coupled to a tuneable self-differencing circuit for enhanced detection sensitivity. We find the count rate is linear with the photon flux in the single photon detection regime over approximately four orders of magnitude, and saturates at 1 gigacount/s at high photon fluxes. This result highlights promising potential for APDs in high bit rate quantum information applications., Electronics Letters (2012)

Published

2012

31. Multiplexed Classical and Quantum Transmission for High Bitrate Quantum Key Distribution Systems

Author

Zhiliang Yuan, Andrew J. Shields, Alex Dixon, Iris Choi, K. A. Patel, Andrew W. Sharpe, James F. Dynes, and Richard V. Penty

Subjects

Physics, business.industry, Optical performance monitoring, Quantum key distribution, Passive optical network, Multiplexing, Computer Science::Hardware Architecture, Optics, Quantum cryptography, Transmission (telecommunications), Time-division multiplexing, Electronic engineering, Hardware_ARITHMETICANDLOGICSTRUCTURES, Statistical time division multiplexing, business, Computer Science::Information Theory

Abstract

We report the operation of a gigahertz clocked quantum key distribution system, with two classical data communication channels using coarse wavelength division multiplexing over a record fibre distance of 80km.

Published

2012

32. Single photon detection for high bit rate quantum communication

Author

Zhiliang Yuan, Andrew J. Shields, Andrew W. Sharpe, James F. Dynes, and Alex Dixon

Subjects

Physics, chemistry.chemical_compound, Photon, System deployment, chemistry, Physics::Instrumentation and Detectors, Detector, Electronic engineering, Quantum key distribution, Quantum information, Quantum information science, Avalanche photodiode, Indium gallium arsenide

Abstract

Quantum communication, in particular, quantum key distribution (QKD) is moving ever closer to real world implementation. However, for successful QKD system deployment, the QKD system components must be robustly designed and feature highly reliable operation. In this paper we focus on one important aspect of any quantum communication system: the single photon detector. In particular our interest is centered upon the InGaAs avalanche photodiode (APD) single photon detector operating in a self-differencing (SD) mode. Such a detector features high clock frequencies of up to 3GHz, high photon count rates as well as detection efficiencies approaching 20% with low afterpulsing. We show successful operation of a high bit rate QKD system using this SD-APD technology in a real world fiber network.

Published

2011

33. Gigacounts/s photon detection and its applications

Author

Andrew W. Sharpe, Alex Dixon, Andrew J. Shields, Zhiliang Yuan, and James F. Dynes

Subjects

Physics, business.industry, Quantum key distribution, Avalanche photodiode, Photon counting, Gallium arsenide, chemistry.chemical_compound, Optics, Single-photon avalanche diode, chemistry, Optoelectronics, business, Quantum information science, Photon detection

Abstract

We report gigacounts/s photon counting using self-differencing InGaAs avalanche photodiodes. Its application to quantum key distribution has enabled a secure key-rate of 1Mb/s over 50km in laboratory and 304kb/s over 45km in the field-test.

Published

2011

34. Probing higher order correlations of the photon field with photon number resolving avalanche photodiodes

Author

Andrew J. Shields, Andrew W. Sharpe, O. Thomas, Zhiliang Yuan, and James F. Dynes

Subjects

Photon, Statistics as Topic, FOS: Physical sciences, Physics::Optics, 02 engineering and technology, 7. Clean energy, 01 natural sciences, Photon field, law.invention, Photometry, Optics, law, 0103 physical sciences, Sensitivity (control systems), Radiometry, 010306 general physics, Quantum information science, Physics, Photons, Quantum Physics, Photon statistics, business.industry, Order (ring theory), Equipment Design, 021001 nanoscience & nanotechnology, Avalanche photodiode, Atomic and Molecular Physics, and Optics, Photodiode, Equipment Failure Analysis, Semiconductors, Computer-Aided Design, Quantum Physics (quant-ph), 0210 nano-technology, business

Abstract

We demonstrate the use of two high speed avalanche photodiodes in exploring higher order photon correlations. By employing the photon number resolving capability of the photodiodes the response to higher order photon coincidences can be measured. As an example we show experimentally the sensitivity to higher order correlations for three types of photon sources with distinct photon statistics. This higher order correlation technique could be used as a low cost and compact tool for quantifying the degree of correlation of photon sources employed in quantum information science.

Published

2011

35. Continuous operation of high bit rate quantum key distribution

Author

James F. Dynes, Andrew J. Shields, Andrew W. Sharpe, Alex Dixon, and Zhiliang Yuan

Subjects

Quantum Physics, Physics and Astronomy (miscellaneous), Continuous operation, FOS: Physical sciences, Quantum key distribution, Topology, Polarization (waves), Interferometry, Path length, Megabit, Bit rate, Quantum Physics (quant-ph), Mathematics, Key size

Abstract

We demonstrate a quantum key distribution with a secure bit rate exceeding 1 Mbit/s over 50 km fiber averaged over a continuous 36-hours period. Continuous operation of high bit rates is achieved using feedback systems to control path length difference and polarization in the interferometer and the timing of the detection windows. High bit rates and continuous operation allows finite key size effects to be strongly reduced, achieving a key extraction efficiency of 96% compared to keys of infinite lengths., four pages, four figures

Published

2010

36. Actively Stabilised Quantum Key Distribution Operating Continuously at 1 Mbit/s

Author

Andrew W. Sharpe, Andrew J. Shields, Zhiliang Yuan, James F. Dynes, and Alex Dixon

Subjects

Physics, Quantum optics, Quantum cryptography, business.industry, Megabit, Continuous operation, Electrical engineering, Optoelectronics, Quantum channel, Quantum key distribution, Photonics, Quantum information, business

Abstract

We report the continuous operation of an actively stabilised gigahertz clocked quantum key distribution (QKD) system, with an average secure key rate of 1 Mbit/s over a distance of 50 km.

Published

2010

37. Multi-Gigahertz Photon Counting Using InGaAs APDs

Author

Andrew J. Shields, Andrew W. Sharpe, James F. Dynes, Zhiliang Yuan, and Alex Dixon

Subjects

Quantum optics, Physics, APDS, Physics::Instrumentation and Detectors, business.industry, Quantum key distribution, Avalanche photodiode, Photon counting, law.invention, Semiconductor laser theory, Optics, Quantum cryptography, law, Optoelectronics, Quantum efficiency, business

Abstract

We demonstrate multi-gigahertz photon-counting at 1550nm using self-differencing In-GaAs APDs. The quantum efficiency is characterized as 23.5% at an afterpulse probability of 4.84%. The device will further increase the bit-rate for fiber quantum key distribution.

Published

2010

38. Efficient photon number detection with silicon avalanche photodiodes

Author

O. Thomas, Andrew J. Shields, James F. Dynes, Zhiliang Yuan, and Andrew W. Sharpe

Subjects

Photon, Physics - Instrumentation and Detectors, Physics and Astronomy (miscellaneous), Silicon, Physics::Instrumentation and Detectors, Photodetector, chemistry.chemical_element, Physics::Optics, FOS: Physical sciences, law.invention, Optics, Silicon photomultiplier, law, Controlled NOT gate, Quantum optics, Physics, Bell state, Quantum network, Quantum Physics, Condensed Matter - Materials Science, business.industry, Photoresistor, Detector, Materials Science (cond-mat.mtrl-sci), Instrumentation and Detectors (physics.ins-det), Avalanche photodiode, Photodiode, Single-photon avalanche diode, chemistry, Qubit, Optoelectronics, Photonics, business, Quantum Physics (quant-ph), Quantum teleportation, Visible spectrum, Voltage

Abstract

We demonstrate an efficient photon number detector for visible wavelengths using a silicon avalanche photodiode. Under subnanosecond gating, the device is able to resolve up to four photons in an incident optical pulse. The detection efficiency at 600 nm is measured to be 73.8%, corresponding to an avalanche probability of 91.1% of the absorbed photons, with a dark count probability below 1.1x10^{-6} per gate. With this performance and operation close to room temperature, fast-gated silicon avalanche photodiodes are ideal for optical quantum information processing that requires single-shot photon number detection.

Published

2010

39. Multi-gigahertz operation of photon counting InGaAs avalanche photodiodes

Author

Alex Dixon, Andrew J. Shields, Zhiliang Yuan, Andrew W. Sharpe, and James F. Dynes

Subjects

Physics, Quantum Physics, Physics - Instrumentation and Detectors, Physics and Astronomy (miscellaneous), business.industry, FOS: Physical sciences, 02 engineering and technology, Instrumentation and Detectors (physics.ins-det), Quantum key distribution, 021001 nanoscience & nanotechnology, Avalanche photodiode, 01 natural sciences, 7. Clean energy, Photon counting, 010309 optics, Wavelength, 0103 physical sciences, Bit rate, Optoelectronics, Fiber, 0210 nano-technology, business, Quantum Physics (quant-ph), Photon detection

Abstract

We report a 2 GHz operation of InGaAs avalanche photodiodes for efficient single photon detection at telecom wavelengths. Employing a self-differencing circuit that incorporates tuneability in both frequency and arm balancing, extremely weak avalanches can now be sensed so as to suppress afterpulsing. The afterpulse probability is characterized as 4.84% and 1.42% for a photon detection efficiency of 23.5% and 11.8%, respectively. The device will further increase the secure bit rate for fiber wavelength quantum key distribution., Comment: 4 pages, 4 figures

Published

2010

40. Evolution of locally excited avalanches in semiconductors

Author

James F. Dynes, Andrew W. Sharpe, Zhiliang Yuan, and Andrew J. Shields

Subjects

Physics - Instrumentation and Detectors, Physics and Astronomy (miscellaneous), Physics::Instrumentation and Detectors, FOS: Physical sciences, 01 natural sciences, Noise (electronics), law.invention, 010309 optics, law, 0103 physical sciences, 010302 applied physics, Physics, Quantum Physics, Condensed Matter - Materials Science, business.industry, Amplifier, Photoresistor, Materials Science (cond-mat.mtrl-sci), Instrumentation and Detectors (physics.ins-det), Avalanche photodiode, Photodiode, Computational physics, Semiconductor, Excited state, business, Quantum Physics (quant-ph), Realization (systems)

Abstract

We show that semiconductor avalanche photodiodes can exhibit diminutive amplification noise during the early evolution of avalanches. The noise is so low that the number of locally excited charges that seed each avalanche can be resolved. These findings constitute an important step towards realization of a solid-state noiseless amplifier for quantum information processing. Moreover, we believe that the experimental setup used, i.e., time-resolving locally excited avalanches, will become a useful tool for optimizing the number resolution.

Published

2010

41. Gigahertz decoy quantum key distribution with 1 Mbit/s secure key rate

Author

Andrew J. Shields, Andrew W. Sharpe, James F. Dynes, Alex Dixon, and Zhiliang Yuan

Subjects

Quantum Physics, business.industry, Computer science, Detector, Electrical engineering, FOS: Physical sciences, Reproducibility of Results, Signal Processing, Computer-Assisted, Equipment Design, Quantum key distribution, Avalanche photodiode, Sensitivity and Specificity, Atomic and Molecular Physics, and Optics, Equipment Failure Analysis, Computer Communication Networks, Megabit, Key (cryptography), Computer-Aided Design, Quantum Theory, business, Decoy, Quantum Physics (quant-ph), Microwaves, Computer Security

Abstract

We report the first gigahertz clocked decoy-protocol quantum key distribution (QKD). Record key rates have been achieved thanks to the use of self-differencing InGaAs avalanche photodiodes designed specifically for high speed single photon detection. The system is characterized with a secure key rate of 1.02 Mbit/s for a fiber distance of 20 km and 10.1 kbit/s for 100 km. As the present advance relies upon compact non-cryogenic detectors, it opens the door towards practical and low cost QKD systems to secure broadband communication in future., Comment: 14 pages, 3 figures

Published

2009

42. Ultrashort dead time of photon-counting InGaAs avalanche photodiodes

Author

Anthony J. Bennett, Andrew W. Sharpe, Alex Dixon, James F. Dynes, Andrew J. Shields, and Zhiliang Yuan

Subjects

Physics, Quantum Physics, Physics - Instrumentation and Detectors, Physics and Astronomy (miscellaneous), business.industry, Physics::Instrumentation and Detectors, Detector, FOS: Physical sciences, Physics::Optics, Instrumentation and Detectors (physics.ins-det), Dead time, Laser, Avalanche photodiode, Photon counting, law.invention, Semiconductor laser theory, Photodiode, law, Optoelectronics, Photonics, Quantum Physics (quant-ph), business

Abstract

We report a 1.036 GHz gated Geiger mode InGaAs avalanche photodiode with a detection dead time of just 1.93 ns. This is demonstrated by full recovery of the detection efficiency two gate cycles after a detection event, as well as a measured maximum detection rate of 497 MHz. As an application, we measure the second order correlation function $g^{(2)}$ of the emission from a diode laser with a single detector which works reliably at high speed owing to the extremely short dead time of the detector. The device is ideal for high bit rate fiber wavelength quantum key distribution and photonic quantum computing., 10 pages, 4 figures. Updated to published version

Published

2009

43. Megabit per Second Quantum Key Distribution Using Practical InGaAs APDs

Author

Andrew W. Sharpe, Zhiliang Yuan, Andrew J. Shields, Alex Dixon, and James F. Dynes

Subjects

Physics, APDS, business.industry, Quantum key distribution, Avalanche photodiode, law.invention, chemistry.chemical_compound, Optics, chemistry, Quantum cryptography, law, Megabit, Key (cryptography), Optoelectronics, Quantum information, business, Indium gallium arsenide

Abstract

We report the first gigahertz clocked decoy-protocol quantum key distribution (QKD) system, with a record secure key rate of 1.02 Mbit/s over a fiber distance of 20 km and 10.1 kbit/s over 100 km.

Published

2009

44. The SECOQC quantum key distribution network in Vienna

Author

Harald Weinfurter, Jérôme Lodewyck, A. Marhold, Thomas Länger, Simon Fossier, Patrick Trinkler, Henning Weier, Momtchil Peev, Andreas Happe, Christoph Pacher, Matthieu Legre, Nicolas Gisin, Y. Hasani, Hannes Hübel, Jan Bouda, Alexander Treiber, Fabien Vannel, Claudio Barreiro, Sebastian Nauerth, Michael Hentschel, Anton Zeilinger, Andreas Poppe, O. Maurhart, T. Debuisschert, G. Ribordy, W. Boxleitner, Mehrdad Dianati, M. Suda, Norbert Lütkenhaus, J-B. Page, M. Furst, C. Tamas, Roland Lieger, L. Monat, Ilse Wimberger, Yann Thoma, Sandrine Fasel, Hugo Zbinden, E. Querasser, Zhiliang Yuan, Thomas Themel, Thomas Matyus, James F. Dynes, Andrew J. Shields, Eleni Diamanti, G. Humer, Thomas Lorünser, Damien Stucki, S. Robyr, Andrew W. Sharpe, Louis Salvail, J. D. Gautier, Rosa Tualle-Brouri, Romain Alléaume, Rob Thew, Nino Walenta, Philippe Grangier, Barreiro, Claudio, Fasel, Sandrine, Gisin, Nicolas, Legre, Matthieu, Stucki, Damien, Thew, Rob, Trinkler, Patrick, Vannel, Fabien, Zbinden, Hugo, Austrian Institute of Technology [Vienna] (AIT), Laboratoire Traitement et Communication de l'Information (LTCI), Télécom ParisTech-Institut Mines-Télécom [Paris] (IMT)-Centre National de la Recherche Scientifique (CNRS), Télécom ParisTech, Group of Applied Physics [Geneva] (GAP), University of Geneva [Switzerland], Faculty of Informatics [Brno] (FI / MUNI), Masaryk University [Brno] (MUNI), Thales Research and Technology [Palaiseau], THALES, Laboratoire Charles Fabry de l'Institut d'Optique / Optique quantique, Laboratoire Charles Fabry de l'Institut d'Optique (LCFIO), Centre National de la Recherche Scientifique (CNRS)-Institut d'Optique Graduate School (IOGS)-Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS)-Institut d'Optique Graduate School (IOGS)-Université Paris-Sud - Paris 11 (UP11), University of Surrey (UNIS), Toshiba Research Europe Ltd, Department für Physik, Ludwig-Maximilians-Universität München (LMU), ID Quantique (IDQ), Institute for Quantum Optics and Quantum Information, Austrian Academy of Sciences (OeAW), Quantum Optics, Quantum Nanophysics and Quantum Information, University of Vienna [Vienna], Systèmes de Référence Temps Espace (SYRTE), Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS), Institute for Quantum Computing [Waterloo] (IQC), University of Waterloo [Waterloo], Institute of Theoretical Physics, Friedrich-Alexander Universität Erlangen-Nürnberg (FAU), Bearingpoint INFONOVA GmbH, Département d'Informatique et de Recherche Opérationnelle [Montreal] (DIRO), Université de Montréal (UdeM), Max-Planck-Institut für Quantenoptik (MPQ), Max-Planck-Gesellschaft, Siemens AG Österreich, Institute for Quantum Optics and Quantum Information [Innsbruck] (IQOQI), Université de Genève = University of Geneva (UNIGE), THALES [France], and Université Paris-Sud - Paris 11 (UP11)-Institut d'Optique Graduate School (IOGS)-Centre National de la Recherche Scientifique (CNRS)-Université Paris-Sud - Paris 11 (UP11)-Institut d'Optique Graduate School (IOGS)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Physics, business.industry, Node (networking), General Physics and Astronomy, Cryptography, ddc:500.2, Quantum key distribution, Encryption, 01 natural sciences, Information-theoretic security, 010309 optics, Quantum cryptography, Secure communication, [PHYS.QPHY]Physics [physics]/Quantum Physics [quant-ph], 0103 physical sciences, Key (cryptography), ddc:530, 010306 general physics, business, Computer network

Abstract

In this paper, we present the quantum key distribution (QKD) network designed and implemented by the European project SEcure COmmunication based on Quantum Cryptography (SECOQC) (2004–2008), unifying the efforts of 41 research and industrial organizations. The paper summarizes the SECOQC approach to QKD networks with a focus on the trusted repeater paradigm. It discusses the architecture and functionality of the SECOQC trusted repeater prototype, which has been put into operation in Vienna in 2008 and publicly demonstrated in the framework of a SECOQC QKD conference held from October 8 to 10, 2008. The demonstration involved one-time pad encrypted telephone communication, a secure (AES encryption protected) video-conference with all deployed nodes and a number of rerouting experiments, highlighting basic mechanisms of the SECOQC network functionality.The paper gives an overview of the eight point-to-point network links in the prototype and their underlying technology: three plug and play systems by id Quantique, a one way weak pulse system from Toshiba Research in the UK, a coherent one-way system by GAP Optique with the participation of id Quantique and the AIT Austrian Institute of Technology (formerly ARCAustrian Research Centers GmbH—ARC is now operating under the new name AIT Austrian Institute of Technology GmbH following a restructuring initiative.), an entangled photons system by the University of Vienna and the AIT, a continuous-variables system by Centre National de la Recherche Scientifique (CNRS) and THALES Research and Technology with the participation of Université Libre de Bruxelles, and a free space link by the Ludwig Maximillians University in Munich connecting two nodes situated in adjacent buildings (line of sight 80 m). The average link length is between 20 and 30 km, the longest link being 83 km.The paper presents the architecture and functionality of the principal networking agent—the SECOQC node module, which enables the authentic classical communication required for key distillation, manages the generated key material, determines a communication path between any destinations in the network, and realizes end-to-end secure transport of key material between these destinations.The paper also illustrates the operation of the network in a number of typical exploitation regimes and gives an initial estimate of the network transmission capacity, defined as the maximum amount of key that can be exchanged, or alternatively the amount of information that can be transmitted with information theoretic security, between two arbitrary nodes.

Published

2009

45. Gigahertz Quantum Key Distribution With 1 Mbit/s Secure Key Rate Using Decoy Pulses

Author

Andrew W. Sharpe, Andrew J. Shields, James F. Dynes, Alex Dixon, and Zhiliang Yuan

Subjects

Quantum optics, Physics, Interferometry, Quantum cryptography, Megabit, Electronic engineering, Key (cryptography), Quantum channel, Quantum key distribution, Decoy

Abstract

We report the first gigahertz clocked decoy-protocol quantum key distribution (QKD) system, with a record secure key rate of 1.02 Mbit/s over a fibre distance of 20 km and 10.1 kbit/s over 100 km.

Published

2009

46. A High Speed, Post-Processing Free, Quantum Random Number Generator

Author

Andrew W. Sharpe, Andrew J. Shields, Zhiliang Yuan, and James F. Dynes

Subjects

Physics, FOS: Computer and information sciences, Quantum Physics, Coherence time, Computer Science - Cryptography and Security, Photon, Physics and Astronomy (miscellaneous), business.industry, FOS: Physical sciences, Gating, Photodiode, law.invention, Optics, law, Hardware random number generator, Wave function, business, Quantum Physics (quant-ph), Photon detection, Cryptography and Security (cs.CR), Statistical hypothesis testing

Abstract

A quantum random number generator (QRNG) based on gated single photon detection of an InGaAs photodiode at GHz frequency is demonstrated. Owing to the extremely long coherence time of each photon, each photons' wavefuntion extends over many gating cycles of the photodiode. The collapse of the photon wavefunction on random gating cycles as well as photon random arrival time detection events are used to generate sequences of random bits at a rate of 4.01 megabits/s. Importantly, the random outputs are intrinsically bias-free and require no post-processing procedure to pass random number statistical tests, making this QRNG an extremely simple device.

Published

2008

47. Gigahertz quantum key distribution with InGaAs avalanche photodiodes

Author

Zhiliang Yuan, Andrew J. Shields, Alex Dixon, Andrew W. Sharpe, and James F. Dynes

Subjects

Physics, Quantum Physics, Physics and Astronomy (miscellaneous), APDS, business.industry, Detector, FOS: Physical sciences, Quantum key distribution, Avalanche photodiode, Noise (electronics), law.invention, law, Bit rate, Dispersion (optics), Optoelectronics, business, Quantum Physics (quant-ph)

Abstract

We report a demonstration of quantum key distribution (QKD) at GHz clock rates with InGaAs avalanche photodiodes (APDs) operating in a self-differencing mode. Such a mode of operation allows detection of extremely weak avalanches so that the detector afterpulse noise is sufficiently suppressed. The system is characterized by a secure bit rate of 2.37 Mbps at 5.6 km and 27.9 kbps at 65.5 km when the fiber dispersion is not compensated. After compensating the fiber dispersion, the QKD distance is extended to 101 km, resulting in a secure key rate of 2.88 kbps. Our results suggest that InGaAs APDs are very well suited to GHz QKD applications., Comment: 4 pages, 4 figures

Published

2008

48. Practical quantum key distribution over 60 hours at an optical fiber distance of 20km using weak and vacuum decoy pulses for enhanced security

Author

Andrew J. Shields, Andrew W. Sharpe, James F. Dynes, and Zhiliang Yuan

Subjects

Physics, Quantitative Biology::Biomolecules, Quantum Physics, Optical fiber, business.industry, Quantitative Biology::Molecular Networks, FOS: Physical sciences, Quantum key distribution, Quantitative Biology::Genomics, Atomic and Molecular Physics, and Optics, law.invention, Pulse (physics), Quantitative Biology::Quantitative Methods, Optics, law, Key (cryptography), Fiber, A fibers, business, Decoy, Quantum Physics (quant-ph)

Abstract

Experimental one-way decoy pulse quantum key distribution running continuously for 60 hours is demonstrated over a fiber distance of 20km. We employ a decoy protocol which involves one weak decoy pulse and a vacuum pulse. The obtained secret key rate is on average over 10kbps. This is the highest rate reported using this decoy protocol over this fiber distance and duration., Accepted for publication in Optics Express

Published

2007

49. Unconditionally secure one-way quantum key distribution using decoy pulses

Author

Andrew J. Shields, Andrew W. Sharpe, Zhiliang Yuan, and James F. Dynes

Subjects

Quantum optics, Physics, Optics, business.industry, Optical communication, Key (cryptography), Quantum key distribution, business, Decoy, Topology, Order of magnitude, Pulse-width modulation, Pulse (physics)

Abstract

Experimental one-way decoy quantum key distribution (QKD) is reported as a function of distance up to 25.3km. The high key rates obtained exceed one order of magnitude more than QKD performed without decoy pulse exchange.

Published

2007

50. High speed single photon detection in the near-infrared

Author

Andrew W. Sharpe, Zhiliang Yuan, Andrew J. Shields, and Beata Kardynal

Subjects

Physics, Quantum Physics, Physics - Instrumentation and Detectors, Physics and Astronomy (miscellaneous), APDS, business.industry, Near-infrared spectroscopy, Detector, Photodetector, FOS: Physical sciences, Sense (electronics), Instrumentation and Detectors (physics.ins-det), Avalanche photodiode, Noise (electronics), law.invention, Gallium arsenide, chemistry.chemical_compound, chemistry, law, Optoelectronics, business, Quantum Physics (quant-ph), Physics - Optics, Optics (physics.optics)

Abstract

InGaAs avalanche photodiodes (APDs) are convenient for single photon detection in the near infrared (NIR) including the fiber communication bands (1.31∕1.55μm). However, to suppress afterpulse noise due to trapped avalanche charge, they must be gated with megahertz repetition frequencies, thereby severely limiting the count rate in NIR applications. Here, the authors show gating frequencies for InGaAs APDs well beyond 1GHz. Using a self-differencing technique to sense much weaker avalanches, the authors reduce drastically afterpulse noise. At 1.25GHz, they obtain a detection efficiency of 10.8% with an afterpulse probability of 6.16%. In addition, the detector features low jitter (55ps) and a count rate of 100MHz.

Published

2007