A Quantum Internet Architecture

Meter, Rodney Van; Ryosuke, Satoh,; Benchasattabuse, Naphan; Matsuo, Takaaki; Hajdušek, Michal; Satoh, Takahiko; Nagayama, Shota; Suzuki, Shigeya

doi:10.1109/qce53715.2022.00055

Cited by 27 publications

(10 citation statements)

References 68 publications

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“…3. We note that lines denote the mean of the total rewards over the different trials, whereas shading areas denote the standard deviation of the different trials 4 . We extend the set of policies by considering -along with the optimal and the two sub-optimal policies already considered in the previous experiment -20 random policies.…”

Section: Performance Evaluationmentioning

confidence: 99%

When Entanglement Meets Classical Communications: Quantum Teleportation for the Quantum Internet

Cacciapuoti

Caleffi

Meter

et al. 2020

IEEE Trans. Commun.

182

173

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Quantum Teleportation is the key communication functionality of the Quantum Internet, allowing the "transmission" of qubits without the physical transfer of the particle storing the qubit. Quantum teleportation is facilitated by the action of quantum entanglement, a somewhat counter-intuitive physical phenomenon with no direct counterpart in the classical word. As a consequence, the very concept of the classical communication system model has to be redesigned to account for the peculiarities of quantum teleportation. This redesign is a crucial prerequisite for constructing any effective quantum communication protocol. The aim of this manuscript is to shed light on this key concept, with the objective of allowing the reader: i) to appreciate the fundamental differences between the transmission of classical information versus the teleportation of quantum information; ii) to understand the communications functionalities underlying quantum teleportation, and to grasp the challenges in the design and practical employment of these functionalities; iii) to acknowledge that quantum information is subject to the deleterious effects of a noise process termed as quantum decoherence. This imperfection has no direct counterpart in the classical world; iv) to recognize how to contribute to the design and employment of the Quantum Internet.

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Section: Performance Evaluationmentioning

confidence: 99%

When Entanglement Meets Classical Communications: Quantum Teleportation for the Quantum Internet

Cacciapuoti

Caleffi

Meter

et al. 2020

IEEE Trans. Commun.

182

173

View full text Add to dashboard Cite

show abstract

“…This layer also manages the distribution of entangled quantum systems in the network. For more information on quantum internet stack, refer [14]- [16].…”

Section: Quantum Synchronization As Plsimentioning

confidence: 99%

Network Time Synchronization as a Quantum Physical Layer Service

Nunavath,

Garbugli,

Nande

et al. 2024

Preprint

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“…BQC is based on cryptographic algorithms that can enable quantum computation on encrypted data and provide correct solutions without revealing the input, computation, and output to the quantum computer [199]. BQC will also be a major use case of the future quantum internet where a client can carry out quantum processing on the data qubits without revealing its contents to the server [19,44,200,201]. A recent work has demonstrated BQC using the measurement-based quantum computing framework for implementing Deutsch and Gover's algorithm [202].…”

Section: Blind Quantum Computing and Quantum Blockchain For 6gmentioning

confidence: 99%

The quantum internet: A synergy of quantum information technologies and 6G networks

Rozenman,

Kundu,

Liu

et al. 2023

IET Quantum Communication

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The quantum internet is a cutting‐edge paradigm that uses the unique characteristics of quantum technology to radically alter communication networks. This new network type is expected to collaborate with 6G networks, creating a synergy that will fundamentally alter how we communicate, engage, and trade information. The improved security, increased speed, and increased network capacity of the quantum internet will lead to the emergence of a broad variety of new applications and services. The current state of quantum technology and its integration with 6G networks are summarised in this study, with an emphasis on the key challenges and untapped possibilities. The main goal is to get knowledge about how the quantum internet might impact communication in the future and alter several economic and societal sectors.

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A Quantum Internet Architecture

Cited by 27 publications

References 68 publications

When Entanglement Meets Classical Communications: Quantum Teleportation for the Quantum Internet

When Entanglement Meets Classical Communications: Quantum Teleportation for the Quantum Internet

Network Time Synchronization as a Quantum Physical Layer Service

The quantum internet: A synergy of quantum information technologies and 6G networks

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