A Connection-Oriented Entanglement Distribution Design in Quantum Networks

Li, Jian; Jia, Qidong; Xue, Kaiping; Wei, Dennis; Yu, Nenghai

doi:10.1109/tqe.2022.3176375

Cited by 11 publications

(8 citation statements)

References 52 publications

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“…Some connection-oriented protocols for entanglement distribution, suitable for asynchronous architectures, have been recently proposed in the literature, from which we point out [20]- [22]. One of the limits of these previous works is that they are tightly bonded to a single ESS, i.e.…”

Section: A Related Workmentioning

confidence: 99%

REDiP: Ranked Entanglement Distribution Protocol for the Quantum Internet

Bacciottini,

Lenzini,

Mingozzi

et al. 2024

IEEE Open J. Commun. Soc.

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The distribution of entangled qubit pairs to end nodes is the key requirement of a quantum network to enable qubit state transmission through quantum teleportation. Existing protocols for entanglement distribution fix a specific swapping order on the involved quantum repeaters and delegate entanglement purification to upper-layer protocols. This limitation is problematic because entangled states tend to degrade due to quantum noise, and they cannot be purified if their fidelity (i.e. quality) falls below a certain threshold. It is therefore of the utmost importance to co-plan entanglement swapping and purification to achieve a target end-to-end fidelity. In this work, we present the Ranked Entanglement Distribution Protocol (REDiP), which overcomes the aforementioned limits by including the "ranks" mechanism to configure the ordering of both purification and entanglement swapping steps. We show how REDiP can easily be configured to implement custom entanglement swapping and purification strategies, including (but not restricted to) those adopted in two recent works. We also propose an algorithm to estimate the bandwidth to allocate on every link of the REDiP path, and we provide a set of guidelines on how REDiP ranks can be configured depending on user requirements and hardware configuration. Such guidelines are driven by original insights into purification performance. We conduct simulations to verify our results and assess the impact of different REDiP configurations on the performance of a repeater network, in terms of throughput and fidelity.

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Section: A Related Workmentioning

confidence: 99%

REDiP: Ranked Entanglement Distribution Protocol for the Quantum Internet

Bacciottini,

Lenzini,

Mingozzi

et al. 2024

IEEE Open J. Commun. Soc.

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show abstract

“…Given the inevitable decoherence and volatile storage of entangled pairs, the protocol design of long-distance entanglement distribution plays a pivotal role in quantum networks. In [15], a connection-oriented protocol design was proposed for facilitating the development of quantum teleportation, where the associated real-time resource allocation and the provision of end-to-end rate guarantees were addressed. From a global perspective, quantum teleportation requires substantial further research before the pervasice roll-out of multi-protocol quantum networks.…”

Section: Multi-protocol Quantum Network Beyond Qkd: Open Issues and C...mentioning

confidence: 99%

From Single-Protocol to Large-Scale Multi-Protocol Quantum Networks

et al. 2022

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In the initial stage of the quantum Internet, most of the practical quantum networks have been deployed relying on diverse individual quantum key distribution (QKD) protocols. However, this single-protocol paradigm cannot fulfill the heterogeneous requirements of the users, hence limiting the marketpenetration of quantum networks. Given the recent advances in QKD protocols, the next generation quantum networks are expected to support both legacy and emerging QKD protocols. However, the evolution from single-protocol to multi-protocol quantum networks poses numerous challenging problems. As a remedy, we conceive a practical protocol translation framework for supporting this migration from single-protocol to large-scale multi-protocol quantum networks. Furthermore, we propose a programmable multi-functional relay node architecture for harmonizing the components of a suitable relay node. A pair of protocol translation policies are conceived for meeting the challenging security requirements of migration requests, which are compared to the single-protocol-based migration solutions both in terms of the translation success probability attained (i.e., the proportion of migration requests with successful protocol translation) and the average relaying risk probability encountered (i.e., the mean of the relaying risk probabilities of endto-end key negotiation in a quantum network). Finally, we highlight a suite of open problems in both quantum secure direct communication and quantum teleportation for research into future multi-protocol quantum networks. Hefei (2016/MDI) Vienna (2008/BB84, CV, SARG04, COW, BBM92) Bristol (2019/BB84) Bristol (2020/BBM92) Cambridge (2019/BB84) Bardonecchia-Santhià (2022/TF) Cambridge-Ipswich (2019/COW) Tokyo (2010/BB84, BBM92, DPS, SARG04) Madrid (2018/CV)

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“…As metrology needs for the Quantum Internet [4] are better understood, the construction of commercially relevant quantum traceable standards becomes essential. This includes the production of bespoke artefacts to calibrate reference Optical Time Domain Reflectors (OTDR's), Optical Frequency domain Reflectometers (OFDR) and Optical Continuous Wave Reflectometer (OCWR's), however, to achieve the dynamic ranges required (>>65dB), investment in state-of-the-art instrumentation and new methodologies is required to achieve meaningful uncertainties.…”

Section: Figure 1:e-2000 Connector Image Courtesy Ofmentioning

confidence: 99%

Characterization of Quantum Grade Interconnects

Ferguson¹,

Hall²,

Smith³

et al. 2022

J. Phys.: Conf. Ser.

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Quantum grade interconnects, which includes quantum grade optical fibre links and Quantum Photonic Integrated Circuits (QPICs), are rapidly developing components central to the successful development of the Quantum Internet and Quantum Key Distribution (QKD). These interconnects will present new metrological challenges that need to be addressed to ensure key support of future scientific and industrial development. Potential metrological solutions evolving alongside associated standardisation will ensure success and reliability of this advanced technology and provide key support to future scientific research and industrial manufacturing.

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A Connection-Oriented Entanglement Distribution Design in Quantum Networks

Cited by 11 publications

References 52 publications

REDiP: Ranked Entanglement Distribution Protocol for the Quantum Internet

REDiP: Ranked Entanglement Distribution Protocol for the Quantum Internet

From Single-Protocol to Large-Scale Multi-Protocol Quantum Networks

Characterization of Quantum Grade Interconnects

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