Abstract

This paper addresses poor cluster formation and frequent Cluster Head (CH) failure issues of underwater sensor networks by proposing an energy-efficient hierarchical topology-aware clustering routing (EEHTAC) protocol. In this paper, fault-tolerant backup clustering (FTBC) algorithms and multi-parameter cluster formation (MPCF) model were developed for the EEHTAC operation. The MPCF model tackles the issue of poor cluster formation performance by integrating multiple parameters to achieve effective clustering process. The FTBC algorithms tackle the issue of frequent CH failures to avoid interruption in data transmission. Performance of the MPCF model was evaluated using normal, high-fault, and high routing overhead network scenarios. Performance metrics employed for this analysis are temporal topology variation ratio (TTVR), CH load distribution (CLD), and cluster stability (STB). Obtained results show that operating with a CH retention period of 90s achieves better CH duty cycling per round and improves the MPCF process with values of 25.69%, 55.56%, and 60% for TTVR, CLD, and STB respectively. Performance of the FTBC-based EEHTAC was evaluated relative to Energy-balanced Unequal Layering Clustering (EULC) protocol. Performance indicators adopted for this evaluation are routing overhead (Ω), end to end delay (Δ), CH failures recovered (CFR), CH failures detected (CFD), received packets (θ), and energy consumption (Σ). With reference to the best obtained values, EEHTAC demonstrated performance improvement of58.40%, 29.94%,81.33%, 28.02%, 86.65%, and 54.35% over EULC variants in terms of Ω, Δ,CFR, CFD, θ, and Σ respectively. Obtained results displayed that the MPCF model is efficient for cluster formation performance and the FTBC-based EEHTACprotocolcan perform effectively well against an existing CBR protocol.

Highlights

  • Recent innovations in Internet of underwater things (IoUT) have enhanced the performance of underwater sensor networks (UWSNs) [1, 2, 19, 31]

  • Fault-tolerant backup clustering (FTBC) algorithms and multi-parameter cluster formation (MPCF) model were developed for the efficient hierarchical topology-aware clustering routing (EEHTAC) operation

  • The MPCF model tackles the issue of poor cluster formation performance by integrating multiple parameters to achieve effective clustering process

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Summary

INTRODUCTION

Recent innovations in Internet of underwater things (IoUT) have enhanced the performance of underwater sensor networks (UWSNs) [1, 2, 19, 31]. Emerging UWSNs are expected to perform collaborative target monitoring in order to fully realize a smart connected network of subaquatic sensors with intelligent computing, massive data processing, self-learning and adaptive decision-making capabilities [4, 5, 23, 26] Due to these technological enhancements, IoUT solutions are practically considered as an indispensable ingredient and essential asset for realizing smart cities [6, 7, 36, 47, 51]. The performance of CBR protocols for SCUWSNs is limited by frequent cluster head (CH) failures and poor cluster formation performance due to the conventional multi-hop data acquisition technique [7, 27, 40, 44] This paper addresses these cluster-related problems by proposing an energy-efficient hierarchical topology-aware clustering (EEHTAC) protocol for SC-UWSNs. In this paper, fault-tolerant backup clustering (FTBC) algorithms and multi-parameter cluster formation (MPCF) model were developed for the EEHTAC operation.

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