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Main Authors: Bellante, Armando, Fioravanti, Tommaso, Carminati, Michele, Zanero, Stefano, Luongo, Alessandro
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2502.11173
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author Bellante, Armando
Fioravanti, Tommaso
Carminati, Michele
Zanero, Stefano
Luongo, Alessandro
author_facet Bellante, Armando
Fioravanti, Tommaso
Carminati, Michele
Zanero, Stefano
Luongo, Alessandro
contents Quantum computing promises to revolutionize our understanding of the limits of computation, and its implications in cryptography have long been evident. Today, cryptographers are actively devising post-quantum solutions to counter the threats posed by quantum-enabled adversaries. Meanwhile, quantum scientists are innovating quantum protocols to empower defenders. However, the broader impact of quantum computing and quantum machine learning (QML) on other cybersecurity domains still needs to be explored. In this work, we investigate the potential impact of QML on cybersecurity applications of traditional ML. First, we explore the potential advantages of quantum computing in machine learning problems specifically related to cybersecurity. Then, we describe a methodology to quantify the future impact of fault-tolerant QML algorithms on real-world problems. As a case study, we apply our approach to standard methods and datasets in network intrusion detection, one of the most studied applications of machine learning in cybersecurity. Our results provide insight into the conditions for obtaining a quantum advantage and the need for future quantum hardware and software advancements.
format Preprint
id arxiv_https___arxiv_org_abs_2502_11173
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Evaluating the Potential of Quantum Machine Learning in Cybersecurity: A Case-Study on PCA-based Intrusion Detection Systems
Bellante, Armando
Fioravanti, Tommaso
Carminati, Michele
Zanero, Stefano
Luongo, Alessandro
Quantum Physics
Cryptography and Security
Machine Learning
Networking and Internet Architecture
Quantum computing promises to revolutionize our understanding of the limits of computation, and its implications in cryptography have long been evident. Today, cryptographers are actively devising post-quantum solutions to counter the threats posed by quantum-enabled adversaries. Meanwhile, quantum scientists are innovating quantum protocols to empower defenders. However, the broader impact of quantum computing and quantum machine learning (QML) on other cybersecurity domains still needs to be explored. In this work, we investigate the potential impact of QML on cybersecurity applications of traditional ML. First, we explore the potential advantages of quantum computing in machine learning problems specifically related to cybersecurity. Then, we describe a methodology to quantify the future impact of fault-tolerant QML algorithms on real-world problems. As a case study, we apply our approach to standard methods and datasets in network intrusion detection, one of the most studied applications of machine learning in cybersecurity. Our results provide insight into the conditions for obtaining a quantum advantage and the need for future quantum hardware and software advancements.
title Evaluating the Potential of Quantum Machine Learning in Cybersecurity: A Case-Study on PCA-based Intrusion Detection Systems
topic Quantum Physics
Cryptography and Security
Machine Learning
Networking and Internet Architecture
url https://arxiv.org/abs/2502.11173