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168 results on '"Wonfor, Adrian"'

1. Dilated space-and-wavelength selective crosspoint optical switch

Author

Zhang, Ziyao, Chen, Minjia, Ma, Rui, Sun, Bohao, Wonfor, Adrian, Penty, Richard, and Cheng, Qixiang

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Photonic integrated switches that are both space and wavelength selective are a highly promising technology for data-intensive applications as they benefit from multi-dimensional manipulation of optical signals. However, scaling these switches normally poses stringent challenges such as increased fabrication complexity and control difficulties, due to the growing number of switching elements. In this work, we propose a novel dilated crosspoint topology, which efficiently handles both space and wavelength selective switching, while reducing the required switching element count by an order of magnitude compared to reported designs. To the best of our knowledge, our design requires the fewest switching elements for an equivalent routing paths number and it fully cancels the first-order in-band crosstalk. We demonstrate such an ultra-compact space-and-wavelength-selective switch (SWSS) at a scale of 4{\times}4{\times}4{\lambda} on the silicon-on-insulator (SOI) platform. Experimental results reveal that the switch achieves an insertion loss ranging from 2.3 dB to 8.6 dB and crosstalk levels in between -35.3 dB and -59.7 dB. The add-drop microring-resonators (MRRs) are equipped with micro-heaters, exhibiting a rise and fall time of 46 {\mu}s and 0.33 {\mu}s, respectively. These performance characteristics highlight the switch's ultra-low element count and crosstalk with low insertion loss, making it a promising candidate for advanced data center applications.

Published
2024

3. I/O-efficient iterative matrix inversion with photonic integrated circuits

Author

Chen, Minjia, Wang, Yizhi, Yao, Chunhui, Wonfor, Adrian, Yang, Shuai, Penty, Richard, and Cheng, Qixiang

Subjects
Computer Science - Emerging Technologies, Physics - Optics
Abstract

Photonic integrated circuits have been extensively explored for optical processing with the aim of breaking the speed bottleneck of digital electronics. However, the input/output (IO) bottleneck remains one of the key barriers. Here we report a novel photonic iterative processor (PIP) for matrix-inversion-intensive applications. The direct reuse of inputted data in the optical domain unlocks the potential to break the IO bottleneck. We demonstrate notable IO advantages with a lossless PIP for real-valued matrix inversion and integral-differential equation solving, as well as a coherent PIP with optical loops integrated on-chip, enabling complex-valued computation and a net inversion time of 1.2 ns. Furthermore, we estimate at least an order of magnitude enhancement in IO efficiency of a PIP over photonic single-pass processors and the state-of-the-art electronic processors for reservoir training tasks and MIMO precoding tasks, indicating the huge potential of PIP technology in practical applications.

Published
2023

4. Long-Range QKD without Trusted Nodes is Not Possible with Current Technology

Author

Huttner, Bruno, Alléaume, Romain, Diamanti, Eleni, Fröwis, Florian, Grangier, Philippe, Hübel, Hannes, Martin, Vicente, Poppe, Andreas, Slater, Joshua A., Spiller, Tim, Tittel, Wolfgang, Tranier, Benoit, Wonfor, Adrian, and Zbinden, Hugo

Subjects
Quantum Physics, Computer Science - Cryptography and Security
Abstract

A recently published patent (https://www.ipo.gov.uk/p-ipsum/Case/PublicationNumber/GB2590064) has claimed the development of a novel quantum key distribution protocol purporting to achieve long-range quantum security without trusted nodes and without use of quantum repeaters. Here we present a straightforward analysis of this claim, and reach the conclusion that it is largely unfounded., Comment: 9 pages, 2 figures and 1 table

Published
2022
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5. High-bandwidth perovskite photonic sources on silicon

Author

Ren, Aobo, Wang, Hao, Dai, Linjie, Xia, Junfei, Bai, Xinyu, Butler-Caddle, Edward, Smith, Joel A., Lai, Huagui, Ye, Junzhi, Li, Xiang, Zhan, Shijie, Yao, Chunhui, Li, Zewei, Tang, Mingchu, Liu, Xueping, Bi, Jinxin, Li, Bowei, Kai, Shen, Chen, Rui, Yan, Han, Hong, Jintao, Yuan, Liming, Marko, Igor P., Wonfor, Adrian, Fu, Fan, Hindmarsh, Steven A., Sanchez, Ana M., Lloyd-Hughes, James, Sweeney, Stephen J., Rao, Akshay, Greenham, Neil C., Wu, Jiang, Li, Yanrong, Cheng, Qixiang, Friend, Richard H., Penty, Richard V., White, Ian H., Snaith, Henry J., and Zhang, Wei

Published
2023
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7. 5G Network Slicing with QKD and Quantum-Safe Security

Author

Wright, Paul, White, Catherine, Parker, Ryan C., Pegon, Jean-Sébastien, Menchetti, Marco, Pearse, Joseph, Bahrami, Arash, Moroz, Anastasia, Wonfor, Adrian, Penty, Richard V., Spiller, Timothy P., and Lord, Andrew

Subjects
Computer Science - Networking and Internet Architecture, Quantum Physics
Abstract

We demonstrate how the 5G network slicing model can be extended to address data security requirements. In this work we demonstrate two different slice configurations, with different encryption requirements, representing two diverse use-cases for 5G networking: namely, an enterprise application hosted at a metro network site, and a content delivery network. We create a modified software-defined networking (SDN) orchestrator which calculates and provisions network slices according to the requirements, including encryption backed by quantum key distribution (QKD), or other methods. Slices are automatically provisioned by SDN orchestration of network resources, allowing selection of encrypted links as appropriate, including those which use standard Diffie-Hellman key exchange, QKD and quantum-resistant algorithms (QRAs), as well as no encryption at all. We show that the set-up and tear-down times of the network slices takes of the order of 1-2 minutes, which is an order of magnitude improvement over manually provisioning a link today., Comment: 9 pages, 7 figures

Published
2020
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8. Experimental demonstration of single-shot quantum and classical signal transmission on single wavelength optical pulse

Author

Kumar, Rupesh, Wonfor, Adrian, Penty, Richard, Spiller, Tim, and White, Ian

Subjects
Quantum Physics
Abstract

Advances in highly sensitive detection techniques for classical coherent communication systems have reduced the received signal power requirements to a few photons per bit. At this level one can take advantage of the quantum noise to create secure communication, using continuous variable quantum key distribution (CV-QKD). In this work therefore we embed CV-QKD signals within classical signals and transmit classical data and secure keys simultaneously over 25km of optical fibre. This is achieved by using a novel coherent displacement state generator, which has the potential for being used in a wide range of quantum optical experiments. This approach removes the need for separate channels for quantum communication systems and allows reduced system bandwidth for a given communications specification. This demonstration therefore demonstrates a way of implementing direct quantum physical layer security within a conventional classical communications system, offering a major advance in term of practical and low cost implementation., Comment: 7 pages, 3 figures

Published
2019

9. Continuous variable quantum key distribution with multi-mode signals for noisy detectors

Author

Kumar, Rupesh, Tang, Xinke, Wonfor, Adrian, Penty, Richard, and White, Ian

Subjects
Quantum Physics
Abstract

This paper proposes a multi-mode Gaussian modulated continuous variable quantum key distribution (CV-QKD) scheme able to operate at high bandwidth despite using conventional noisy, coherent detectors. We demonstrate enhancement in shotnoise sensitivity as well as reduction in the electronic noise variance of the coherent receiver of the multi-mode CV-QKD system. A proof-of-concept simulation is presented using multiple modes; this demonstrates an increase in signal-to-noise ratio and secure key rate at various transmission distances with increasing signal modes., Comment: 13 pages, 4 figures

Published
2019
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11. Reference Pulse Attack on Continuous-Variable Quantum Key Distribution with Local Local Oscillator under trusted phase noise

Author

Ren, Shengjun, Kumar, Rupesh, Wonfor, Adrian, Tang, Xinke, Penty, Richard, and White, Ian

Subjects
Quantum Physics
Abstract

We show that partially trusting the phase noise associated with estimation uncertainty in a LLO CVQKD system allows one to exchange higher secure key rates than in the case of untrusted phase noise. However, this opens a security loophole through the manipulation of the reference pulse amplitude. We label this as "reference pulse attack" which is applicable to all LLO-CVQKD systems if the phase noise is trusted. We show that, at the optimal reference pulse intensity level, Eve achieves unity attack efficiency at 23.8km and 32.0km while using lossless and 0.14dB/km loss channels, respectively, for her attack. However, in order to maintain the performance enhancement from partially trusting the phase noise, countermeasures have been proposed. As a result, the LLO-CVQKD system with partially trusted phase noise owns a superior key rate at 20km by an order 9.5, and extended transmission distance by 45%, than that of the phase noise untrusted system., Comment: 15 pages, 8 figures, comments welcome

Published
2017
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12. 200 Gb/s/λ Bidirectional Coherent PON Solutions Demonstrated Over Field Installed Fiber

Author

Kovacs, Istvan Bence, Faruk, Md. Saifuddin, Wonfor, Adrian, and Savory, Seb J.

Abstract

We demonstrate 200 Gb/s bidirectional coherent PON solutions using a simplified optical network unit (ONU) over 19 km of field-installed fiber. The ONU receiver is a single-polarization heterodyne detector with either a balanced or a single-ended photodetector and the transmitter is based on dual-polarization electro-absorption modulated laser (EML). The optical line terminal (OLT) uses standard dual-polarization coherent transceivers. The downstream solutions achieve 37 dB and 30.5 dB power budget for the receiver with balanced and single-ended photodiodes, respectively. For the upstream, two line rates have been investigated: 200 Gb/s/ $\lambda $ for symmetrical transmission and 100 Gb/s/ $\lambda $ for asymmetric transmission achieving a power budget of 30.1 dB and 40.9 dB respectively.

Published
2024
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18. Performance Analysis on Co-existence of COWQKD and Classical DWDM Channels Transmission in UK National Quantum Networks

Author

Wonfor, Adrian, Penty, Richard, Wonfor, Adrian [0000-0003-2219-7900], Penty, Richard [0000-0003-4605-1455], Lord, Andrew [0000-0002-9585-2956], Kumar, Rupesh [0000-0002-6813-6401], and Apollo - University of Cambridge Repository

Subjects
5102 Atomic, Molecular and Optical Physics, 51 Physical Sciences, 40 Engineering
Abstract

—To analyse and evaluate the physical layer performance of a UK national quantum network (UKQNtel) utilising COW-QKD, in O band, integrated with 500 Gb/s encrypted data, in C band, over 121 km between BT Labs and the University of Cambridge, a theoretical model encompassing COW-QKD and Raman scattering noise is developed and fitted with real-world experimental data. Different physical mechanisms underpinning the link performance are identified and discussed. The model developed in this work also provides a preliminary technical guidance for future UKQNtel upgrade and expansion, as well as potentially useful insights for quantum-secured networks design prior to practical deployment.

Published
2023

20. Direct Iterative Photonic Integrated Matrix Inverter

Author

Chen, Minjia, Yao, Chunhui, Wonfor, Adrian, Yang, Shuai, Holm, Mark, Cheng, Qixiang, and Penty, Richard

Abstract

We demonstrate the first chip-based real-valued direct photonic matrix inverter using coherent sources. At a rate of 2×105 inversions/s, a 16×16 diagonal matrix and a 2×2 arbitrary matrix are inverted with 99.2% and 93.7% accuracy. © 2022 The Author(s)

Published
2023
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23. Quantum Key Distribution Post-processing: A Heterogeneous Computing Perspective

Author

Li, He, Wonfor, Adrian, Weerasinghe, Weerasinghe, Alhussein, Muataz, Gong, Yupeng, and Penty, Richard

Abstract

Recent experimental demonstrations of quantum key distribution (QKD) have caught worldwide attention for their ability to transmit encryption keys. Current commercial QKD typically uses discrete optical components, resulting in systems which are typically sized to fit within telecommunications racks. Widespread deployment of QKD systems will require low-SWaP (i.e., Size, Weight, and Power) QKD systems, thus Photonic Integration is seen as a key enabler of widespread adoption. QKD post-processing systems play a significant role in the distillation and high-speed generation of secure keys for discrete variable (DV) or continuous variable (CV) QKD protocols. Interest in using heterogeneous computing techniques for QKD post-processing is growing, owing to the emergence of domain-specific hardware accelerators for efficient quantum information processing applications. We hence discuss in a tutorial manner the principles and techniques of QKD post-processing. Characteristics of representative heterogeneous platforms for QKD post-processing implementations are compared, along with a review of the state-of-the-art QKD post-processing accelerators.

Published
2022

24. Long-range QKD without trusted nodes is not possible with current technology

Author

Huttner, Bruno, primary, Alléaume, Romain, additional, Diamanti, Eleni, additional, Fröwis, Florian, additional, Grangier, Philippe, additional, Hübel, Hannes, additional, Martin, Vicente, additional, Poppe, Andreas, additional, Slater, Joshua A., additional, Spiller, Tim, additional, Tittel, Wolfgang, additional, Tranier, Benoit, additional, Wonfor, Adrian, additional, and Zbinden, Hugo, additional

Published
2022
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28. NFV orchestration over disaggregated metro optical networks with end-to-end multi-layer slicing enabling crowdsourced live video streaming

Author

Muqaddas, Abubakar Siddique, primary, Tessinari, Rodrigo Stange, additional, Casellas, Ramon, additional, Garrich, Miquel, additional, Hugues-Salas, Emilio, additional, González de Dios, Óscar, additional, Luque, Lourdes, additional, Giorgetti, Alessio, additional, Sgambelluri, Andrea, additional, Cugini, Filippo, additional, Moreno-Muro, Francisco-Javier, additional, Morro, Roberto, additional, Farrow, Kristan, additional, Wonfor, Adrian, additional, Channegowda, Mayur, additional, Pavón-Mariño, Pablo, additional, Lord, Andrew, additional, Nejabati, Reza, additional, and Simeonidou, Dimitra, additional

Published
2021
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30. Quantum networks in the UK

Author

Wonfor, Adrian, primary, White, Catherine, additional, Lord, Andrew, additional, Nejabati, Reza, additional, Spiller, Timothy P., additional, Dynes, James F., additional, Shields, Andrew J., additional, and Penty, Richard V., additional

Published
2021
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31. 5G network slicing with QKD and quantum-safe security

Author

Wright, Paul, primary, White, Catherine, additional, Parker, Ryan C., additional, Pegon, Jean-Sébastien, additional, Menchetti, Marco, additional, Pearse, Joseph, additional, Bahrami, Arash, additional, Moroz, Anastasia, additional, Wonfor, Adrian, additional, Penty, Richard V., additional, Spiller, Timothy P., additional, and Lord, Andrew, additional

Published
2021
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39. 40Gbits −1 Data Transmission in an Installed Optical Link Encrypted Using Physical Layer Security Seeded by Quantum Key Distribution.

Author

Wang, Kexin, Tang, Xinke, Wonfor, Adrian, Collins, Robert, Buller, Gerald, Penty, Richard, White, Ian, and Wang, Xu

Abstract

Data security plays an increasingly important role in modern telecommunications. The advent of quantum computational processors presents a significant threat to today's widely employed public key encryption algorithms, necessitating the adoption of new approaches to data encryption. Whilst quantum key distribution guarantees unconditional security for cryptographic key exchange in optical communication networks, the data rate is slow (Mbit/s), especially when compared to conventional optical communication. Here we present a highly secure encryption approach in which the encryption key, generated by quantum key distribution at a rate of up to 2.9 Mbit/s, was used to seed physical layer encryption performed using time domain spectral phase encoding (TDSPE). This allowed us to demonstrate encrypted 40 Gbit/s quadrature phase shift keyed data communications over 52.3 km of installed optical fiber, which cannot be eavesdropped using brute force computational attacks. Any attempt to eavesdrop the encrypted signal in the physical layer is highly time-sensitive – the phase states must be measured and decrypted prior to optical signal attenuation, which means that the attack procedure typically needs to be completed within a few milliseconds. This work represents the first example of quantum-enhanced physical layer encryption at realistic optical data rates that is fully secure from brute force computational attacks and the first demonstration of TDSPE using continuous-wave laser source and quadrature phase shift key modulation. [ABSTRACT FROM AUTHOR]

Published
2021
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