AI is used in network security to detect and prevent cyber threats and attacks. It utilizes machine learning algorithms and anomaly detection techniques to analyze network traffic, identify suspicious activities, and enhance real-time threat detection and response, bolstering the overall security of computer networks.
Researchers envision a 6G future with ultra-fast, low-latency networks driven by AI, but heightened security risks demand innovative quantum-safe protections and privacy safeguards.
Researchers developed a CNN-based deep learning model to enhance intrusion detection in virtual networks, addressing the unique challenges of encapsulation and dynamic environments.
Researchers introduced a federated learning-based intrusion detection system for IoT networks, improving security and data privacy. The system outperformed traditional models by reducing false positives and safeguarding data, marking a significant advancement in IoT security technology.
Researchers have utilized AI and IoT voice devices to advance sports training feature recognition, employing sensors for real-time data transmission and analysis. This approach successfully identifies movement patterns and predicts athlete states, enhancing training effectiveness.
Researchers proposed a fusion algorithm merging Lightning Search Algorithm (LSA) with Support Vector Machine (SVM) technology, forming an advanced Power Network Security Risk Evaluation Model (PNSREM), achieving high accuracy, low error rates, and rapid convergence. Empirical validation demonstrated its superiority, empowering preemptive threat identification, ensuring uninterrupted power system operation, and highlighting its potential for real-world application in enhancing power network security.
This article delves into the innovative approach of Network Security Offloading in Vehicle-to-Fog-to-Cloud (NSO-VFC), proposed by researchers from Islamic Azad University, Iran, to address the crucial challenge of securing data offloading in the Internet of Vehicles (IoV) within a fog-cloud federation. By leveraging fog computing and incorporating features such as nonce-based authentication and session key generation, NSO-VFC promises to enhance security, communication performance, and cost-efficiency in IoV environments, paving the way for safer roads, efficient traffic management, and improved environmental monitoring.
Researchers unveil the vulnerability of modern vehicles' controller area networks (CANs) to cyber threats and introduce a comprehensive guide to open CAN intrusion detection system (IDS) datasets. The ROAD dataset emerges as a benchmark, offering over 3.5 hours of realistic vehicle CAN data with diverse attacks, addressing the need for comparability and assessment of IDS approaches against subtle, advanced cyber threats in the automotive industry.
This research paper introduces an ensemble learning model, combining extreme gradient boosting (XGBoost) and random forest (RF) algorithms, to optimize bank marketing strategies. By leveraging financial datasets, the model demonstrates superior accuracy, achieving a 91% accuracy rate and outperforming other algorithms, leading to substantial sales growth (25.67%) and increased customer satisfaction (20.52%). The study provides valuable insights for banking decision-makers seeking to enhance marketing precision and customer relationships.
Korean researchers introduce a groundbreaking framework marrying Explainable AI (XAI) and Zero-Trust Architecture (ZTA) for robust cyberdefense in marine communication networks. Their deep neural network, Zero-Trust Network Intrusion Detection System (NIDS), not only exhibits remarkable accuracy in classifying cyber threats but also integrates XAI methodologies, SHAP and LIME, to provide interpretable insights. This innovative approach fosters transparency and collaboration between AI systems and human experts, promising enhanced cybersecurity in marine, and potentially other, critical infrastructures.
This research introduces TabNet-IDS, an innovative Intrusion Detection System for IoT networks. The model leverages deep learning and attentive mechanisms to enhance security in IoT systems, achieving high accuracy rates on various datasets while maintaining model interpretability, thus serving as a promising tool for safeguarding networked devices.
Researchers introduce an innovative AI-driven approach to bolster the security of Internet of Things (IoT) networks using Particle Swarm Optimization (PSO) penetration testing. The study demonstrates the superiority of swarm-based penetration testing over traditional linear methods in identifying vulnerabilities within IoT networks, offering promising solutions for IoT security in diverse settings, including smart homes, industrial IoT, and military environments.
This cutting-edge research explores a novel deep learning approach for network intrusion detection using a smaller feature vector. Achieving higher accuracy and reduced computational complexity, this method offers significant advancements in cybersecurity defense against evolving threats.
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