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Bibliographic Details
Main Authors: Madani, Pooria, McGregor, Carolyn
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2501.06319
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author Madani, Pooria
McGregor, Carolyn
author_facet Madani, Pooria
McGregor, Carolyn
contents In this paper, we introduce a novel authentication scheme for satellite nodes based on quantum entanglement and measurement noise profiles. Our approach leverages the unique noise characteristics exhibited by each satellite's quantum optical communication system to create a distinctive "quantum noise fingerprint." This fingerprint is used for node authentication within a satellite constellation, offering a quantum-safe alternative to traditional cryptographic methods. The proposed scheme consists of a training phase, where each satellite engages in a training exercise with its neighbors to compile noise profiles, and an online authentication phase, where these profiles are used for real-time authentication. Our method addresses the inherent challenges of implementing cryptographic-based schemes in space, such as key management and distribution, by exploiting the fundamental properties of quantum mechanics and the unavoidable imperfections in quantum systems. This approach enhances the security and reliability of satellite communication networks, providing a robust solution to the authentication challenges in satellite constellations. We validated and tested several hypotheses for this approach using IBM System One quantum computers.
format Preprint
id arxiv_https___arxiv_org_abs_2501_06319
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Quantum Entanglement and Measurement Noise: A Novel Approach to Satellite Node Authentication
Madani, Pooria
McGregor, Carolyn
Quantum Physics
Cryptography and Security
In this paper, we introduce a novel authentication scheme for satellite nodes based on quantum entanglement and measurement noise profiles. Our approach leverages the unique noise characteristics exhibited by each satellite's quantum optical communication system to create a distinctive "quantum noise fingerprint." This fingerprint is used for node authentication within a satellite constellation, offering a quantum-safe alternative to traditional cryptographic methods. The proposed scheme consists of a training phase, where each satellite engages in a training exercise with its neighbors to compile noise profiles, and an online authentication phase, where these profiles are used for real-time authentication. Our method addresses the inherent challenges of implementing cryptographic-based schemes in space, such as key management and distribution, by exploiting the fundamental properties of quantum mechanics and the unavoidable imperfections in quantum systems. This approach enhances the security and reliability of satellite communication networks, providing a robust solution to the authentication challenges in satellite constellations. We validated and tested several hypotheses for this approach using IBM System One quantum computers.
title Quantum Entanglement and Measurement Noise: A Novel Approach to Satellite Node Authentication
topic Quantum Physics
Cryptography and Security
url https://arxiv.org/abs/2501.06319