Abstract
Internet of things have emerged enough due to its applications in a wide range of fields such as governance, industry, healthcare, and smart environments (home, smart, cities, and so on). Internet of things–based networks connect smart devices ubiquitously. In such scenario, the role of wireless sensor networks becomes vital in order to enhance the ubiquity of the Internet of things devices with lower cost and easy deployment. The sensor nodes are limited in terms of energy storage, processing, and data storage capabilities, while their radio frequencies are very sensitive to noise and interference. These factors consequently threaten the energy consumption, lifetime, and throughput of network. One way to cope with energy consumption issue is energy harvesting techniques used in wireless sensor network–based Internet of things. However, some recent studies addressed the problems of clustering and routing in energy harvesting wireless sensor networks which either concentrate on energy efficiency or quality of service. There is a need of an adequate approach that can perform efficiently in terms of energy utilization as well as to ensure the quality of service. In this article, a novel protocol named energy-efficient multi-attribute-based clustering scheme (E2-MACH) is proposed which addresses the energy efficiency and communication reliability. It uses selection criteria of reliable cluster head based on a weighted function defined by multiple attributes such as link statistics, neighborhood density, current residual energy, and the rate of energy harvesting of nodes. The consideration of such parameters in cluster head selection helps to preserve the node’s energy and reduce its consumption by sending data over links possessing better signal-to-noise ratio and hence ensure minimum packet loss. The minimized packet loss ratio contributes toward enhanced network throughput, energy consumption, and lifetime with better service availability for Internet of things applications. A set of experiments using network simulator 2 revealed that our proposed approach outperforms the state-of-the-art low-energy adaptive clustering hierarchy and other recent protocols in terms of first-node death, overall energy consumption, and network throughput.
Highlights
With the significant advancement in communication technologies during the last three decades, sensing devices are increasingly growing for application in numerous domains
Our results show that E2MACH outperformed the existing techniques in terms of energy utilization, network stability, overall throughput, and network lifetime
DNi, SNRi, ECurr(i, r), and HRi represent the neighbor validation of this scheme is done through comparison density, average signal-to-noise ratio, current energy at of results with some recent protocols proposed in the round r, and energy harvesting rate of node i and literature.[27,33,39,40] defined by equations (9), (10), (5), and (7), respectively
Summary
With the significant advancement in communication technologies during the last three decades, sensing devices are increasingly growing for application in numerous domains. Due to the nature and architectural structure, application domain, and working environment of sensor nodes, IoT devices are likely to be restricted to operate with short-range communication, frequent path losses, considerable node-to-BS delay, and low packet delivery ratio. Along with other parameters, the signal-to-noise ratio (SNR) of wireless links is considered for nodes while selecting a CH In this manner, an optimal CH is selected which demonstrates better utilization of energy, preserves energy by reducing retransmissions of packets, minimizes end-to-end delay, and enhances throughput. An optimal CH is selected which demonstrates better utilization of energy, preserves energy by reducing retransmissions of packets, minimizes end-to-end delay, and enhances throughput These characteristics collectively ensure the reliable delivery of data packets and improved network lifetime. Section ‘‘Proposed scheme’’ describes the details of the proposed scheme along with the simulation details; results and discussion and comparison with existing schemes are given in section ‘‘Performance evaluations and results analysis.’’ section ‘‘Conclusion and directions for future work’’ presents the conclusion of the proposed scheme with some future directions
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