International Journal of Sensors Wireless Communications and Control - Online First

As a communication paradigm that bridges the gap between virtual and physical spaces, the Internet of Things (IoT) has quickly gained popularity in recent years. In order to supplement the provisions made by security protocols, a network-based intrusion detection system (IDS) has emerged as a standard component of network architecture. IDSs monitor and detect cyber threats continuously throughout the network lifetime.

The main contribution is the development of a two-level neural network model that optimizes the number of neurons and features in the hidden layers, achieving superior accuracy in anomaly detection. Its include the utilization of deep anomaly detection (DAD) to protect networks from unknown threats without requiring rule modifications. The research also emphasizes the importance of feature extraction and selection, employing parallel deep models for segmenting attacks. The proposed supervised technique enables simultaneous feature selection using parallel models, enhancing the accuracy of IDS designs. A novel hybrid technique combining Deep Auto Encoders (DAEs) and DeepNets is proposed for intrusion detection.

The research present a data preprocessing stage, converting symbolic and quantitative data into real-valued vectors and normalizing them. Feature extraction involves utilizing DAEs to learn concise representations of datasets. The deep network architecture, including multilayer perceptrons and activation functions, is employed for feature extraction and classification. The proposed approach utilizes a DeepNets in the final stage in order to improve the rate of 97% accurate outputs and make it possible to achieve greatly accelerated execution durations.

When measured against the performances of other approaches to the extraction of features, the performance of the deep network platform is superior.