Related papers: Private Communication over a Bosonic Compound Channel

Private Communication over a Bosonic Compound Channel

URL: http://arxiv.org/abs/2411.10292v1
Date: Fri, 15 Nov 2024 15:49:33 GMT
Title: Private Communication over a Bosonic Compound Channel
Authors: Florian Seitz, Matteo Rosati, Ángeles Vázquez-Castro, Janis Nötzel,
Abstract summary: We prove a capacity formula for the bosonic compound wiretap channel using the binary phase shift keying alphabet. We are able to quantify in this work exactly how channel uncertainty penalizes data transmission rates.
Score: 7.849709311008473
License:
Abstract: It is a common belief that quantum key distribution systems are the one and only information-theoretically secure physical layer security protocol that enables secure data transmission without a need for the legitimate parties to have any channel knowledge. It is also known that this high security profile results in severe rate restrictions for the parties utilizing the quantum key distribution systems. This observation raises the question of whether quantifying the level of ignorance of the legitimate parties with regard to the channel parameters may enable us to navigate the large gray zone between insecure but highly performant systems on the one side and perfectly secure but highly non-performant systems on the other side. Indeed, by proving a capacity formula for the bosonic compound wiretap channel using the binary phase shift keying alphabet, we are able to quantify in this work exactly how channel uncertainty penalizes data transmission rates.

Related papers

Security Enhancement of Quantum Communication in Space-Air-Ground Integrated Networks [7.404591865944407]
Quantum teleportation achieves the transmission of quantum states through quantum channels. We propose a practical solution that ensures secure information transmission even in the presence of errors in both classical and quantum channels.
arXiv Detail & Related papers (2024-10-22T14:27:21Z)
Unconditionally secure key distribution without quantum channel [0.76146285961466]
Currently, the quantum scheme stands as the only known method for achieving unconditionally secure key distribution. We propose another key distribution scheme with unconditional security, named probability key distribution, that promises users between any two distances to generate a fixed and high secret key rate. Non-local entangled states can be generated, identified and measured in the equivalent virtual protocol and can be used to extract secret keys.
arXiv Detail & Related papers (2024-08-24T15:13:14Z)
Physical Layer Deception with Non-Orthogonal Multiplexing [52.11755709248891]
We propose a novel framework of physical layer deception (PLD) to actively counteract wiretapping attempts. PLD combines PLS with deception technologies to actively counteract wiretapping attempts. We prove the validity of the PLD framework with in-depth analyses and demonstrate its superiority over conventional PLS approaches.
arXiv Detail & Related papers (2024-06-30T16:17:39Z)
Eavesdropper localization for quantum and classical channels via nonlinear scattering [58.720142291102135]
Quantum key distribution (QKD) offers theoretical security based on the laws of physics. We present a novel approach to eavesdropper location that can be employed in quantum as well as classical channels. We demonstrate that our approach outperforms conventional OTDR in the task of localizing an evanescent outcoupling of 1% with cm precision inside standard optical fibers.
arXiv Detail & Related papers (2023-06-25T21:06:27Z)
Practical quantum secure direct communication with squeezed states [55.41644538483948]
We report the first table-top experimental demonstration of a CV-QSDC system and assess its security. This realization paves the way into future threat-less quantum metropolitan networks, compatible with coexisting advanced wavelength division multiplexing (WDM) systems.
arXiv Detail & Related papers (2023-06-25T19:23:42Z)
Fault-tolerant Coding for Entanglement-Assisted Communication [46.0607942851373]
This paper studies the study of fault-tolerant channel coding for quantum channels. We use techniques from fault-tolerant quantum computing to establish coding theorems for sending classical and quantum information in this scenario. We extend these methods to the case of entanglement-assisted communication, in particular proving that the fault-tolerant capacity approaches the usual capacity when the gate error approaches zero.
arXiv Detail & Related papers (2022-10-06T14:09:16Z)
Semantic Security with Infinite Dimensional Quantum Eavesdropping Channel [1.5070870469725095]
We propose a new proof method for direct coding theorems for wiretap channels. The method yields errors that decay exponentially with increasing block lengths. It provides a guarantee of a quantum version of semantic security.
arXiv Detail & Related papers (2022-05-16T13:25:56Z)
Modulation leakage-free continuous-variable quantum key distribution [1.8268488712787332]
Continuous-variable (CV) QKD based on coherent states is an attractive scheme for secure communication. This work is a step towards protecting CVQKD systems against practical imperfections of physical devices and operational limitations without performance degradation.
arXiv Detail & Related papers (2022-05-15T10:07:19Z)
Efficient Quantum Digital Signatures without Symmetrization Step [7.848038078036641]
Quantum digital signatures (QDS) exploit quantum laws to guarantee non-repudiation, unforgeability and transferability of messages. Current QDS protocols face two major restrictions, including the requirement of the symmetrization step. We present an efficient QDS protocol to overcome these issues by utilizing the classical post-processing operation called post-matching method.
arXiv Detail & Related papers (2021-04-08T01:54:50Z)
Backflash Light as a Security Vulnerability in Quantum Key Distribution Systems [77.34726150561087]
We review the security vulnerabilities of quantum key distribution (QKD) systems. We mainly focus on a particular effect known as backflash light, which can be a source of eavesdropping attacks.
arXiv Detail & Related papers (2020-03-23T18:23:12Z)
Semantic Security for Quantum Wiretap Channels [68.24747267214373]
We consider the problem of semantic security via classical-quantum and quantum wiretap channels. We use explicit constructions to transform a non-secure code into a semantically secure code, achieving capacity by means of biregular irreducible functions.
arXiv Detail & Related papers (2020-01-16T09:55:49Z)

This list is automatically generated from the titles and abstracts of the papers in this site.