Abstract

Generally, the risks associated with malicious threats are increasing for the Internet of Things (IoT) and its related applications due to dependency on the Internet and the minimal resource availability of IoT devices. Thus, anomaly-based intrusion detection models for IoT networks are vital. Distinct detection methodologies need to be developed for the Industrial Internet of Things (IIoT) network as threat detection is a significant expectation of stakeholders. Machine learning approaches are considered to be evolving techniques that learn with experience, and such approaches have resulted in superior performance in various applications, such as pattern recognition, outlier analysis, and speech recognition. Traditional techniques and tools are not adequate to secure IIoT networks due to the use of various protocols in industrial systems and restricted possibilities of upgradation. In this paper, the objective is to develop a two-phase anomaly detection model to enhance the reliability of an IIoT network. In the first phase, SVM and Naïve Bayes, are integrated using an ensemble blending technique. K-fold cross-validation is performed while training the data with different training and testing ratios to obtain optimized training and test sets. Ensemble blending uses a random forest technique to predict class labels. An Artificial Neural Network (ANN) classifier that uses the Adam optimizer to achieve better accuracy is also used for prediction. In the second phase, both the ANN and random forest results are fed to the model’s classification unit, and the highest accuracy value is considered the final result. The proposed model is tested on standard IoT attack datasets, such as WUSTL_IIOT-2018, N_BaIoT, and Bot_IoT. The highest accuracy obtained is 99%. A comparative analysis of the proposed model using state-of-the-art ensemble techniques is performed to demonstrate the superiority of the results. The results also demonstrate that the proposed model outperforms traditional techniques and thus improves the reliability of an IIoT network.

Highlights

  • The number of Internet of Things (IoT) devices and connected devices is estimated to be more than 15 billion, and up to 50 billion connected IoT devices are expected by 2022

  • Machine learning approaches are considered to be evolving techniques that learn with experience, and such approaches have resulted in superior performance in various applications, such as pattern recognition, outlier analysis, and speech recognition

  • The objective is to develop a two-phase anomaly detection model to enhance the reliability of an Industrial Internet of Things (IIoT) network

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Summary

Introduction

The number of IoT devices and connected devices is estimated to be more than 15 billion, and up to 50 billion connected IoT devices are expected by 2022. Development of huge numbers of IoT devices combined with the pressure to deliver IoT devices to market in a timely and competitive manner has increased attention on privacy and security issues. With the continuous development of CPMSs, significant security concerns have been raised in relation to the Industrial IoT (IIoT), which is characterized by real-time monitoring, automated systems, smart connections, and collaborative machines [1]. The fourth layer is the cloud layer, which performs analytics, reporting, and planning based on data captured from the IIoT devices. IIoT devices are vulnerable to various types of attacks, such as DDoS, DoS, tampering, spoofing, privilege escalation, and IoT botnet attacks [2]

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