Abstract
Wireless Sensor Networks (WSNs) consist of spatially distributed sensor nodes that monitor and transmit data to the base station. Wireless sensor networks are widely used in environmental monitoring, smart cities, healthcare, and disaster management applications. However, the major disadvantage of WSNs is their excessive energy consumption, which shortens their lifetime and limits their data integrity. Traditional methods face redundant retransmissions and collision problems which lead to congestion and fast energy consumption. To overcome these problems, a novel Secure Clustering and Sleep-Wakeup based Energy Efficient Routing using Fennec fox optimized deep learning (SCS-EEF) framework has been proposed to reduce energy usage and increase network lifetime in WSN. Fuzzy C Means based Balanced Iterative Reducing and Clustering Using Hierarchies (Fuzzy-BIRCH) clustering is employed in the proposed framework to improve cluster formation and reduce communication costs. To enhance energy efficiency, Fennec Fox Optimization (FFO) is used for optimal cluster head selection (CHS) with fair energy distribution across nodes and to reduce premature node failures. An energy-saving dynamic sleep-wakeup schedule is proposed to eliminate redundant transmissions. The hybrid Temporal Convolutional Network-based Bidirectional Gated Recurrent Unit (TCN-BiGRU) network predicts multipath routes through the classification of data into emergency and non-emergency. The proposed framework reduces energy consumption by 39.3%, 29.2%, and 26.1% over HBWCO, IBORSDFFNL, and EER-CGHHOA, respectively. Furthermore, the proposed model reduces latency by 10.7%, 9.42%, and 7.4% over HBWCO, IBORSDFFNL, and EER-CGHHOA, respectively.