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Peer-to-Peer Networking and Applications
Erschienen in: Peer-to-Peer Networking and Applications 6/2020

18.06.2020

A novel multi-objective optimization strategy for enhancing quality of service in IoT-enabled WSN applications

verfasst von: A. Prasanth, S. Jayachitra

Erschienen in: Peer-to-Peer Networking and Applications | Ausgabe 6/2020

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Abstract

In today’s world, the Internet of Things (IoT) has become more relevant owing to the growth in smart grid, smart city and smart home applications. Network sustainability is considered as a significant characteristic for IoT based applications. Wireless Sensor Network (WSN) offers such network sustainability where WSN is acted as the subnets in the IoT model. However, the multi-objectives like coverage, connectivity and energy consumption are required to improve the quality of service in IoT based WSN (IWSN) model. An appropriate optimization strategy of these multi-objective facilitates the better development of IWSN. In this paper, the Adaptive Coverage and Connectivity (ACC) scheme is proposed to attain the efficient IWSN model. It employs two underlying methodologies in which the first method provides the optimal coverage to all target objects and its mathematical model guarantees the coverage rate. The second method deals with connectivity and energy consumption of the network. The experimental results manifest that, unlike existing schemes, the proposed ACC scheme can sustain the network for a prolonged time.
Vorheriger Artikel Correction to: Reliable data dissemination for the internet of things using Harris hawks optimization
Nächster Artikel SINR based association algorithm for indoor device-to-device communication networks

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Literatur
1.
Ghasempour A (2019) Internet of things in smart grid: architecture, applications, services, key technologies, and challenges. Inventions 4:22CrossRef
2.
Ullah A, Said G, Sher M, Ning H (2020) Fog-assisted secure healthcare data aggregation scheme in IoT-enabled WSN. Peer Peer Netw Appl 13:163–174
3.
Behera TM, Mohapatra SK, Samal UC, Khan MS, Daneshmand M, Gandomi AH (2019) Residual energy based cluster-head selection in WSNs for IoT application. IEEE Internet Things J 6:5132–5139CrossRef
4.
Carreno R, Aguilar V, Pacheco D, Acevedo M (2019) An IoT expert system Shell in block-chain technology with ELM as inference engine. Int J Inf Technol Decis Mak 18:87–104CrossRef
5.
He Y, Han G, Wang H (2019) A sector-based random routing scheme for protecting the source location privacy in WSNs for the internet of things. Futur Gener Comput Syst 96:438–448CrossRef
6.
Zakariayi S, Babaie S (2019) DEHCIC: a distributed energy-aware hexagon based clustering algorithm to improve coverage in wireless sensor networks. Peer Peer Netw Appl 12(4):689–704CrossRef
7.
Romero E, Blesa J, Araujo A (2019) An adaptive energy aware strategy based on game theory to add privacy in the physical layer for cognitive WSNs. Ad Hoc Netw 92:101800CrossRef
8.
Wu J, Chen Z, Wu J (2020) An energy efficient data transmission approach for low-duty-cycle wireless sensor networks. Peer Peer Netw Appl 13:255–268CrossRef
9.
Prasanth A, Pavalarajan S (2020) Implementation of efficient intra-and inter-zone routing for extending network consistency in wireless sensor networks. J Circuit Syst Comp 29:1–25CrossRef
10.
Sharma G, Rajesh A, Babu L, Mohan E (2019) Three-dimensional localization in anisotropic wireless sensor networks using fuzzy logic system. Ad Hoc Sens Wirel Netw 45:29–57
11.
Senouci MR, Mellouk A (2019) A robust uncertainty-aware cluster-based deployment approach for WSNs: coverage, connectivity, and lifespan. J Netw Comput Appl 146:102414CrossRef
12.
Prasanth A, Pavalarajan S (2019) Zone-based sink mobility in wireless sensor networks. Sens Rev 39:874–880CrossRef
13.
Farhat A, Guyeux C, Haddad M, Hakem M (2020) Energy-efficiency and coverage quality management for reliable diagnostics in wireless sensor networks. Int J Sens Netw 32:127–138CrossRef
14.
Kavidha V, Ananthakumaran S (2019) Novel energy-efficient secure routing protocol for wireless sensor networks with Mobile sink. Peer Peer Netw Appl 12:881–892CrossRef
15.
Boukerche A, Sun P (2018) Connectivity and coverage based protocols for wireless sensor networks. Ad Hoc Netw 80:54–69CrossRef
16.
Zygowski C, Jaekel A (2020) Optimal path planning strategies for monitoring coverage holes in wireless sensor networks. Ad Hoc Netw 96:101990CrossRef
17.
Chakraborty S, Goyala NK, Mahapatrac S, Sohb S (2020) A Monte-Carlo Markov chain approach for coverage-area reliability of mobile wireless sensor networks with multistate nodes. Reliab Eng Syst Saf 193:106662CrossRef
18.
Binh H, Hanh N, Quan L, Nghia N, Dey N (2020) Metaheuristics for maximization of obstacles constrained area coverage in heterogeneous wireless sensor networks. Appl Soft Comput 86:105939CrossRef
19.
Hajjej F, Hamdi M, Ejbali R, Zaied M (2020) A distributed coverage hole recovery approach based on reinforcement learning for wireless sensor networks. Ad Hoc Netw 101:102082CrossRef
20.
Kabakulak B (2019) Sensor and sink placement, scheduling and routing algorithms for connected coverage of wireless sensor networks. Ad Hoc Netw 86:83–102CrossRef
21.
Nguyen P, Hanh N, Khuong N (2019) Node placement for connected target coverage in wireless sensor networks with dynamic sinks. Pervasive Mob Comput 59:101070CrossRef
22.
Etancelin J, Fabbri A, Guinand F, Rosalie M (2019) DACYCLEM: a decentralized algorithm for maximizing coverage and lifetime in a Mobile wireless sensor network. Ad Hoc Netw 87:174–187CrossRef
23.
Elhoseny M, Tharwat A, Yuan X, Hassanien A (2018) Optimizing K-coverage of mobile WSNs. Expert Syst Appl 92:142–153CrossRef
24.
Xu Y, Ding O, Qu R, Li K (2018) Hybrid multi-objective evolutionary algorithms based on decomposition for wireless sensor network coverage optimization. Appl Soft Comput 68:268–282CrossRef
25.
Dahiya S, Singh PK (2018) Optimized Mobile sink based grid coverage-aware sensor deployment and link quality based routing in wireless sensor networks. Int J Electron Commun 89:191–196CrossRef
26.
Mostafaei H, Montieri A, Persico V, Pescape A (2017) A sleep scheduling approach based on learning automata for WSN partial coverage. J Netw Comput Appl 80:67–78CrossRef
27.
Guptaa SK, Kuilab P, Jana PK (2016) Genetic algorithm approach for k-coverage and m-connected node placement in target based wireless sensor networks. Comput Electr Eng 56:544–556
28.
Torkestani JA (2013) An adaptive energy-efficient area coverage algorithm for wireless sensor networks. Ad Hoc Netw 11:1655–1666CrossRef
29.
Cardei M, Wu J (2006) Energy-efficient coverage problems in wireless adhoc sensor networks. Comput Commun 29:413–420CrossRef
30.
Mostafaei H (2015) Stochastic barrier coverage in wireless sensor networks based on distributed learning automata. Comput Commun 55:51–61CrossRef
31.
Kumar CS, Lai T (2010) Local barrier coverage in wireless sensor networks. IEEE Trans Mob Comput 9:491–504CrossRef
32.
Yardibi T, Karasan E (2010) A distributed activity scheduling algorithm for wireless sensor networks with partial coverage. Wirel Netw 16:213–225CrossRef
33.
Yetgin H, Cheung KK, El-Hajjar M, Hanzo L (2017) A survey of network lifetime maximization techniques in wireless sensor networks. IEEE Commun Surv Tutor 19:828–854CrossRef
34.
Sun G, Liu Y, Li H, Wang A, Liang S (2018) A novel connectivity and coverage algorithm based on shortest path for wireless sensor networks. Comput Electr Eng 71:1025–1039
35.
Samie M, Dragffy G, Tyrrell AM (2013) Novel bio-inspired approach for fault-tolerant VLSI systems. IEEE Trans Very Large Scale Integr (VLSI) Syst 21:1878–1891CrossRef
Metadaten
Titel
A novel multi-objective optimization strategy for enhancing quality of service in IoT-enabled WSN applications
verfasst von
A. Prasanth
S. Jayachitra
Publikationsdatum
18.06.2020
Verlag
Springer US
Erschienen in
Peer-to-Peer Networking and Applications / Ausgabe 6/2020
Print ISSN: 1936-6442
Elektronische ISSN: 1936-6450
DOI
https://doi.org/10.1007/s12083-020-00945-y

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