Securing the Internet of Things: Evaluating Machine Learning Algorithms for Detecting IoT Cyberattacks Using CIC-IoT2023 Dataset

Akinul Islam Jony, Arjun Kumar Bose Arnob
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引用次数: 1

Abstract

An increase in cyber threats directed at interconnected devices has resulted from the proliferation of the Internet of Things (IoT), which necessitates the implementation of comprehensive defenses against evolving attack vectors. This research investigates the utilization of machine learning (ML) prediction models to identify and defend against cyber-attacks targeting IoT networks. Central emphasis is placed on the thorough examination of the CIC-IoT2023 dataset, an extensive collection comprising a wide range of Distributed Denial of Service (DDoS) assaults on diverse IoT devices. This ensures the utilization of a practical and comprehensive benchmark for assessment. This study develops and compares four distinct machine learning models Logistic Regression (LR), K-Nearest Neighbors (KNN), Decision Tree (DT), and Random Forest (RF) to determine their effectiveness in detecting and preventing cyber threats to the Internet of Things (IoT). The comprehensive assessment incorporates a wide range of performance indicators, such as F1-score, accuracy, precision, and recall. Significantly, the results emphasize the superior performance of DT and RF, demonstrating exceptional accuracy rates of 0.9919 and 0.9916, correspondingly. The models demonstrate an outstanding capability to differentiate between benign and malicious packets, as supported by their high precision, recall, and F1 scores. The precision-recall curves and confusion matrices provide additional evidence that DT and RF are strong contenders in the field of IoT intrusion detection. Additionally, KNN demonstrates a noteworthy accuracy of 0.9380. On the other hand, LR demonstrates the least accuracy with a value of 0.8275, underscoring its inherent incapability to classify threats. In conjunction with the realistic and diverse characteristics of the CIC-IoT2023 dataset, the study's empirical assessments provide invaluable knowledge for determining the most effective machine learning algorithms and fortification strategies to protect IoT infrastructures. Furthermore, this study establishes ground-breaking suggestions for subsequent inquiries, urging the examination of unsupervised learning approaches and the incorporation of deep learning models to decipher complex patterns within IoT networks. These developments have the potential to strengthen cybersecurity protocols for Internet of Things (IoT) ecosystems, reduce the impact of emergent risks, and promote robust defense systems against ever-changing cyber challenges.
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确保物联网安全:利用 CIC-IoT2023 数据集评估用于检测物联网网络攻击的机器学习算法
随着物联网(IoT)的普及,针对互联设备的网络威胁不断增加,因此有必要针对不断变化的攻击载体实施全面防御。本研究探讨了如何利用机器学习(ML)预测模型来识别和防御针对物联网网络的网络攻击。研究重点是对 CIC-IoT2023 数据集进行彻底检查,该数据集收集了大量针对不同物联网设备的分布式拒绝服务 (DDoS) 攻击。这确保了利用实用而全面的基准进行评估。本研究开发并比较了四种不同的机器学习模型:逻辑回归 (LR)、K-近邻 (KNN)、决策树 (DT) 和随机森林 (RF),以确定它们在检测和预防物联网 (IoT) 网络威胁方面的有效性。综合评估包含了广泛的性能指标,如 F1 分数、准确度、精确度和召回率。值得注意的是,评估结果强调了 DT 和 RF 的卓越性能,准确率分别达到 0.9919 和 0.9916。这些模型在区分良性数据包和恶意数据包方面表现出卓越的能力,其高精度、召回率和 F1 分数也证明了这一点。精度-召回曲线和混淆矩阵进一步证明,DT 和 RF 是物联网入侵检测领域的有力竞争者。此外,KNN 的准确率高达 0.9380。另一方面,LR 的准确率最低,仅为 0.8275,这说明它本身就不具备对威胁进行分类的能力。结合 CIC-IoT2023 数据集的现实性和多样性特征,本研究的经验评估为确定最有效的机器学习算法和加固策略以保护物联网基础设施提供了宝贵的知识。此外,本研究还为后续研究提出了开创性的建议,敦促研究无监督学习方法和深度学习模型,以破解物联网网络中的复杂模式。这些发展有可能加强物联网(IoT)生态系统的网络安全协议,减少突发风险的影响,并促进强大的防御系统,以应对不断变化的网络挑战。
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