Intrusion Detection Systems(IDSs) are critical for network security, detecting and mitigating malicious activities. A key challenge in IDS implementation is the high rate of false negatives, where attacks go undetecte...Intrusion Detection Systems(IDSs) are critical for network security, detecting and mitigating malicious activities. A key challenge in IDS implementation is the high rate of false negatives, where attacks go undetected, posing significant security risks. This study proposes an enhanced IDS model that integrates XG-boost, a robust gradient boosting algorithm, with Cat Swarm Optimization(CSO) to reduce false negatives and improve detection accuracy. XG-boost's scalability and performance make it ideal for managing complex network traffic data, while CSO optimizes XG-boost's hyperparameters by mimicking natural cat behaviors, ensuring optimal model performance. The proposed approach was evaluated using a benchmark dataset, demonstrating a notable reduction in false negatives compared to traditional IDS methods. The upgraded IDS also improve detection accuracy across various types of cyberattacks while maintaining a low false positive rate, crucial for minimizing disruptions to regular network operations. The optimized XG-boost model achieved an accuracy of 98%, with precision of 97.8% and an F1-score of 97.7%, significantly outperforming the non-optimized model(accuracy: 84.1%, precision: 86.5%, F1-score: 84.1%). These results highlight the effectiveness of the proposed method in real-world IDS deployment, where both security and operational efficiency are critical.展开更多
文摘Intrusion Detection Systems(IDSs) are critical for network security, detecting and mitigating malicious activities. A key challenge in IDS implementation is the high rate of false negatives, where attacks go undetected, posing significant security risks. This study proposes an enhanced IDS model that integrates XG-boost, a robust gradient boosting algorithm, with Cat Swarm Optimization(CSO) to reduce false negatives and improve detection accuracy. XG-boost's scalability and performance make it ideal for managing complex network traffic data, while CSO optimizes XG-boost's hyperparameters by mimicking natural cat behaviors, ensuring optimal model performance. The proposed approach was evaluated using a benchmark dataset, demonstrating a notable reduction in false negatives compared to traditional IDS methods. The upgraded IDS also improve detection accuracy across various types of cyberattacks while maintaining a low false positive rate, crucial for minimizing disruptions to regular network operations. The optimized XG-boost model achieved an accuracy of 98%, with precision of 97.8% and an F1-score of 97.7%, significantly outperforming the non-optimized model(accuracy: 84.1%, precision: 86.5%, F1-score: 84.1%). These results highlight the effectiveness of the proposed method in real-world IDS deployment, where both security and operational efficiency are critical.
