Your search keyword '"Lim, Charles"' showing total 8 results

1. Improved coherent one-way quantum key distribution for high-loss channels

Author

Lavie, Emilien and Lim, Charles C. -W.

Subjects

Quantum Physics, FOS: Physical sciences, General Physics and Astronomy, Quantum Physics (quant-ph)

Abstract

The coherent one-way (COW) quantum key distribution (QKD) is a highly practical quantum communication protocol that is currently deployed in off-the-shelves products. However, despite its simplicity and widespread use, the security of COW-QKD is still an open problem. This is largely due to its unique security feature based on inter-signal phase distribution, which makes it very difficult to analyze using standard security proof techniques. Here, to overcome this problem, we present a simple variant of COW-QKD and prove its security in the infinite-key limit. The proposed modifications only involve an additional vacuum tail signal following every encoded signal and a balanced beam-splitter for passive measurement basis choice. Remarkably, the resulting key rate of our protocol is comparable with both the existing upper-bound on COW-QKD key rate and the secure key rate of the coherent-state BB84 protocol. Our findings therefore suggest that the secured deployment of COW-QKD systems in high loss optical networks is indeed feasible with minimal adaptations applied to its hardware and software., 14 pages, 5 figures. All comments are welcome

Published

2022

2. Security of device-independent quantum key distribution protocols: a review

Author

Primaatmaja, Ignatius W., Goh, Koon Tong, Tan, Ernest Y. -Z., Khoo, John T. -F., Ghorai, Shouvik, and Lim, Charles C. -W.

Subjects

Quantum Physics, Physics and Astronomy (miscellaneous), FOS: Physical sciences, Quantum Physics (quant-ph), Atomic and Molecular Physics, and Optics

Abstract

Device-independent quantum key distribution (DI-QKD) is often seen as the ultimate key exchange protocol in terms of security, as it can be performed securely with uncharacterised black-box devices. The advent of DI-QKD closes several loopholes and side-channels that plague current QKD systems. While implementing DI-QKD protocols is technically challenging, there have been recent proof-of-principle demonstrations, resulting from the progress made in both theory and experiments. In this review, we will provide an introduction to DI-QKD, an overview of the related experiments performed, and the theory and techniques required to analyse its security. We conclude with an outlook on future DI-QKD research., Review article, 47 pages, 3 figures. Accepted in Quantum

Published

2023

3. Experimental device-independent quantum key distribution between distant users

Author

Zhang, Wei, van Leent, Tim, Redeker, Kai, Garthoff, Robert, Schwonnek, Rene, Fertig, Florian, Eppelt, Sebastian, Scarani, Valerio, Lim, Charles C. -W., and Weinfurter, Harald

Subjects

Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

Device-independent quantum key distribution (DIQKD) is the art of using untrusted devices to establish secret keys over an untrusted channel. So far, the real-world implementation of DIQKD remains a major challenge, as it requires the demonstration of a loophole-free Bell test across two remote locations with very high quality entanglement to ensure secure key exchange. Here, we demonstrate for the first time the distribution of a secure key -- based on asymptotic security estimates -- in a fully device-independent way between two users separated by 400 metres. The experiment is based on heralded entanglement between two independently trapped single Rubidium 87 atoms. The implementation of a robust DIQKD protocol indicates an expected secret key rate of r=0.07 per entanglement generation event and r>0 with a probability error of 3%. Furthermore, we analyse the experiment's capability to distribute a secret key with finite-size security against collective attacks., 16 pages

Published

2021

4. Improved DIQKD protocols with finite-size analysis

Author

Tan, Ernest Y. -Z., Sekatski, Pavel, Bancal, Jean-Daniel, Schwonnek, René, Renner, Renato, Sangouard, Nicolas, Lim, Charles C. -W., Institut de Physique Théorique - UMR CNRS 3681 (IPHT), and Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS)

Subjects

Quantum Physics, noise, [PHYS.QPHY]Physics [physics]/Quantum Physics [quant-ph], Physics and Astronomy (miscellaneous), finite size, quantum key distribution, binary, FOS: Physical sciences, Quantum Physics (quant-ph), preprocessing, Atomic and Molecular Physics, and Optics

Abstract

The security of finite-length keys is essential for the implementation of device-independent quantum key distribution (DIQKD). Presently, there are several finite-size DIQKD security proofs, but they are mostly focused on standard DIQKD protocols and do not directly apply to the recent improved DIQKD protocols based on noisy preprocessing, random key measurements, and modified CHSH inequalities. Here, we provide a general finite-size security proof that can simultaneously encompass these approaches, using tighter finite-size bounds than previous analyses. In doing so, we develop a method to compute tight lower bounds on the asymptotic keyrate for any such DIQKD protocol with binary inputs and outputs. With this, we show that positive asymptotic keyrates are achievable up to depolarizing noise values of $9.33\%$, exceeding all previously known noise thresholds. We also develop a modification to random-key-measurement protocols, using a pre-shared seed followed by a "seed recovery" step, which yields substantially higher net key generation rates by essentially removing the sifting factor. Some of our results may also improve the keyrates of device-independent randomness expansion., Comment: Corrected error in Chernoff bound formula

Published

2022

5. Loss-tolerant quantum key distribution with a twist

Author

Bourassa, J. Eli, Primaatmaja, Ignatius William, Lim, Charles Ci Wen, and Lo, Hoi-Kwong

Subjects

Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph), Computer Science::Cryptography and Security

Abstract

The security of measurement device-independent quantum key distribution (MDI QKD) relies on a thorough characterization of one's optical source output, especially any noise in the state preparation process. Here, we provide an extension of the loss-tolerant protocol [Phys. Rev. A 90, 052314 (2014)], a leading proof technique for analyzing the security of QKD, to MDI QKD protocols that employ mixed signal states. We first reframe the core of the proof technique, noting its generalization to treat $d$-dimensional signal encodings. Concentrating on the qubit signal state case, we find that the mixed states can be interpreted as providing Alice and Bob with a virtual shield system they can employ to reduce Eve's knowledge of the secret key. We then introduce a simple semidefinite programming method for optimizing the virtual operations they can perform on the shield system to yield a higher key rate, along with an example calculation of fundamentally achievable key rates in the case of random polarization modulation error., 15 pages, 3 figures (including supplementary materials). Comments welcome

Published

2020

6. Computing secure key rates for quantum key distribution with untrusted devices

Author

Tan, Ernest Y. -Z., Schwonnek, Ren��, Goh, Koon Tong, Primaatmaja, Ignatius William, and Lim, Charles C. -W.

Subjects

Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

Device-independent quantum key distribution (DIQKD) provides the strongest form of secure key exchange, using only the input-output statistics of the devices to achieve information-theoretic security. Although the basic security principles of DIQKD are now well-understood, it remains a technical challenge to derive reliable and robust security bounds for advanced DIQKD protocols that go beyond the previous results based on violations of the CHSH inequality. In this work, we present a framework based on semi-definite programming that gives reliable lower bounds on the asymptotic secret key rate of any QKD protocol using untrusted devices. In particular, our method can in principle be utilized to find achievable secret key rates for any DIQKD protocol, based on the full input-output probability distribution or any choice of Bell inequality. Our method also extends to other DI cryptographic tasks., Improved proof of strong duality. Close to published version

Published

2019

7. Detector-device-independent QKD: security analysis and fast implementation

Author

Boaron, Alberto, Korzh, Boris, Houlmann, Raphael, Boso, Gianluca, Lim, Charles Ci Wen, Martin, Anthony, and Zbinden, Hugo

Subjects

Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

One of the most pressing issues in quantum key distribution (QKD) is the problem of detector side- channel attacks. To overcome this problem, researchers proposed an elegant "time-reversal" QKD protocol called measurement-device-independent QKD (MDI-QKD), which is based on time-reversed entanglement swapping. However, MDI-QKD is more challenging to implement than standard point- to-point QKD. Recently, an intermediary QKD protocol called detector-device-independent QKD (DDI-QKD) has been proposed to overcome the drawbacks of MDI-QKD, with the hope that it would eventually lead to a more efficient detector side-channel-free QKD system. Here, we analyze the security of DDI-QKD and elucidate its security assumptions. We find that DDI-QKD is not equivalent to MDI-QKD, but its security can be demonstrated with reasonable assumptions. On the more practical side, we consider the feasibility of DDI-QKD and present a fast experimental demonstration (clocked at 625 MHz), capable of secret key exchange up to more than 90 km., 9 pages, 4 figures

Published

2016

8. A fast and versatile QKD system with hardware key distillation and wavelength multiplexing

Author

Walenta, Nino, Burg, Andreas, Caselunghe, Dario, Constantin, Jeremy, Gisin, Nicolas, Guinnard, Olivier, Houlmann, Raphael, Junod, Pascal, Korzh, Boris, Kulesza, Natalia, Legré, Matthieu, Lim, Charles Ci Wen, Lunghi, Tommaso, Monat, Laurent, Portmann, Christopher, Soucarros, Mathilde, Trinkler, Patrick, Trolliet, Gregory, Vannel, Fabien, and Zbinden, Hugo

Subjects

Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

We present a 625 MHz clocked coherent one-way quantum key distribution (QKD) system which continuously distributes secret keys over an optical fibre link. To support high secret key rates, we implemented a fast hardware key distillation engine which allows for key distillation rates up to 4 Mbps in real time. The system employs wavelength multiplexing in order to run over only a single optical fibre and is compactly integrated in 19-inch 2U racks. We optimized the system considering a security analysis that respects finite-key-size effects, authentication costs, and system errors. Using fast gated InGaAs single photon detectors, we reliably distribute secret keys with rates up to 140 kbps and over 25 km of optical fibre, for a security parameter of 4E-9.

Published

2013