Abstract
Wireless sensor networks (WSNs) are one of the fundamental infrastructures for Internet of Things (IoTs) technology. Efficient energy consumption is one of the greatest challenges in WSNs because of its resource-constrained sensor nodes (SNs). Clustering techniques can significantly help resolve this issue and extend the network’s lifespan. In clustering, WSN is divided into various clusters, and a cluster head (CH) is selected in each cluster. The selection of appropriate CHs highly influences the clustering technique, and poor cluster structures lead toward the early death of WSNs. In this paper, we propose an energy-efficient clustering and cluster head selection technique for next-generation wireless sensor networks (NG-WSNs). The proposed clustering approach is based on the midpoint technique, considering residual energy and distance among nodes. It distributes the sensors uniformly creating balanced clusters, and uses multihop communication for distant CHs to the base station (BS). We consider a four-layer hierarchical network composed of SNs, CHs, unmanned aerial vehicle (UAV), and BS. The UAV brings the advantage of flexibility and mobility; it shortens the communication range of sensors, which leads to an extended lifetime. Finally, a simulated annealing algorithm is applied for the optimal trajectory of the UAV according to the ground sensor network. The experimental results show that the proposed approach outperforms with respect to energy efficiency and network lifetime when compared with state-of-the-art techniques from recent literature.
Highlights
IntroductionThe rapid growth and intensive development in the areas of wireless communication and computation science, including wireless sensor networks (WSNs) and other related technologies, is increasingly being used to satisfy evolving user requirements [1,2,3]
To evaluate the performance of the proposed algorithm, simulations are conducted on MATLAB and the proposed approach is compared to similar studies from the literature
The analysis includes a comparison with existing approaches for different network parameters and characteristics such as energy consumption, number of living nodes, and the wireless sensor networks (WSNs)’s data collection integrity
Summary
The rapid growth and intensive development in the areas of wireless communication and computation science, including wireless sensor networks (WSNs) and other related technologies, is increasingly being used to satisfy evolving user requirements [1,2,3]. WSNs have increased flexibility in terms of maintenance and deployment when compared to conventional sensor networks. Due to the high demand and efficient scalability of WSNs, it has invaded numerous sectors. It has a prominent place in every corner of society, in applications such as smart cities, industry 4.0, precise agriculture, and farming management [4,5,6]. WSNs have the attributes of significance and superiority and have been implemented in several domains due to increased flexibility and low cost. WSNs play a pivotal role in environmental monitoring by gathering critical environmental parameters such as temperature, noise, fire detection, pollution, among many others. [7,8,9]
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