Software defined network implementation of multi-node adaptive novel quantum key distribution protocol

Software defined network implementation of multi-node adaptive novel quantum key distribution protocol

Access to information can destroy nations and change the course of history altogether. Communication is very important, and in today's internet age, nothing moves without real-time information support. For securing communication, a commonly know technique is to use cryptography and public chann...

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Bibliographic Details
Main Authors: Hardeer Kaur, Jai Sukh Paul Singh
Format: Article
Language:English
Published: AIMS Press 2024-09-01
Series:AIMS Electronics and Electrical Engineering
Subjects:
quantum mechanics
entanglement
quantum protocol
quantum simulator
quantum communication
Online Access:https://www.aimspress.com/article/doi/10.3934/electreng.2024020
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Summary:Access to information can destroy nations and change the course of history altogether. Communication is very important, and in today's internet age, nothing moves without real-time information support. For securing communication, a commonly know technique is to use cryptography and public channels. Engineers have been working to create a better and more secure cryptographic system. Quantum key distribution stands at the top of this security system. Although QKD, based on principles of physics, provides a near-perfect security solution. It has a few drawbacks of its own, like low key generation rates and vulnerability to cyberattacks. Owning to these limitations, authors propose an adaptive quantum key distribution system based on software-defined networks. The authors propose to introduce redundancy in the key generation, thereby increasing the key generation rate and improving the resilience to cyberattacks. A performance comparison of novel quantum key distribution was done with BB84 and B92 quantum key distribution protocols.
ISSN:2578-1588

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