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Peer-to-Peer Networking and Applications
Erschienen in: Peer-to-Peer Networking and Applications 3/2019

31.08.2018

An efficient coverage hole-healing algorithm for area-coverage improvements in mobile sensor networks

verfasst von: Chakchai So-In, Tri Gia Nguyen, Nhu Gia Nguyen

Erschienen in: Peer-to-Peer Networking and Applications | Ausgabe 3/2019

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Abstract

Maximizing network coverage is among the key factors in designing efficient sensor-deployment algorithms for wireless sensor networks (WSNs). In this study, we consider a WSN in which mobile sensor nodes (SNs) are randomly deployed over a two-dimensional region with the existence of coverage holes due to the absence of any SNs. To improve the network coverage, we thus propose a novel distributed deployment algorithm – coverage hole-healing algorithm (CHHA) – to maximize the area coverage by healing the coverage holes such that the total SN moving distance is minimized. Once the network is formed after an initial random placement of the SNs, CHHA is applied to detect coverage holes, including hole-boundary SNs, based on computational geometry, i.e., Delaunay triangulation. The distributed deployment feature of CHHA applies a concept to virtual forces that is used to decide the movement of mobile SNs to heal the coverage holes. The simulation results show that our proposed algorithm is capable of exact detection of coverage holes in addition to area-coverage improvement by healing the holes. The results also demonstrate the effectiveness of CHHA compared with other competitive approaches, namely, VFA, VEDGE, and HEAL, in terms of total moving distance.
Vorheriger Artikel Editorial: Network coverage: From theory to practice
Nächster Artikel Multi working sets alternate covering scheme for continuous partial coverage in WSNs

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Literatur
1.
Akyildiz IF, Vuran MC (2010) Wireless sensor networks. John Wiley & Sons
2.
Cordeiro CM, Agrawal DP (2006) Ad hoc & sensor networks: theory and applications. World Scientific Publishing
3.
Dargie W, Poellabauer C (2010) Fundamentals of wireless sensor networks: theory and practice. John Wiley & Sons
4.
Nguyen TG, So-In C (2016) An energy-efficient point-coverage-aware clustering protocol in wireless sensor networks. Int J Ad Hoc Ubiq Co 28(3):148–167
5.
Huang CF, Tseng YC (2005) The coverage problem in a wireless sensor network. Mobile Netw Appl 10:519–528CrossRef
6.
Wang B (2010) Coverage control in sensor networks. Computer Communications and Networks
7.
Wang Z, Cao Q, Qi H, Chen H, Wang Q (2017) Cost-effective barrier coverage formation in heterogeneous wireless sensor networks. Ad Hoc Netw 64:65–79CrossRef
8.
Al-Karaki JN, Gawanmeh A (2017) The optimal deployment, coverage, and connectivity problems in wireless sensor networks: revisited. IEEE Access 5:18051–18065CrossRef
9.
Wang Y, Wu S, Chen Z, Gao X, Chen G (2017) Coverage problem with uncertain properties in wireless sensor networks: a survey. Comput Netw 123:200–232CrossRef
10.
Sangwan A, Singh RP (2015) Survey on coverage problems in wireless sensor networks. Wirel Pers Commun 80(4):1475–1500CrossRef
11.
Wang Z, Chen H, Cao Q, Qi H, Wang Z, Wang Q (2017) Achieving location error tolerant barrier coverage for wireless sensor networks. Comput Netw 112:314–328CrossRef
12.
Nguyen TG, So-In C, Nguyen NG, Phoemphon S (2017) A novel energy-efficient clustering protocol with area coverage awareness for wireless sensor networks. Peer Peer Netw Appl 10(3):519–536CrossRef
13.
Sibley G, Rahimi M, Sukhatme G (2002) Robomote: a tiny mobile robot platform for large-scale ad-hoc sensor networks. Proc of the IEEE Int Conf Robot 2:1143–1148
14.
Laibowitz M, Paradiso J (2005) Parasitic mobility for pervasive sensor networks. Proc of 3rd Int Conf on Per Co (PERVASIVE’05) 255–278
15.
Senouci MR, Mellouk A (2016) Deploying wireless sensor networks: theory and practice. Elsevier Ltd
16.
Abdollahzadeh S, Navimipour N (2016) Deployment strategies in the wireless sensor network: a comprehensive review. Comput Commun 91–92:1–16CrossRef
17.
Bartolini N, Calamoneri T, La Porta TF, Silvestri S (2011) Autonomous deployment of heterogeneous mobile sensors. IEEE T Mobile Comput 10(6):753–766
18.
Nguyen TG, So-In C, Nguyen NG (2017) Barrier coverage deployment algorithms for mobile sensor networks. J Internet Technol 8(7):1689–1699
19.
Wang G, Cao G, La Porta T (2006) Movement-assisted sensor deployment. IEEE T Mobile Comput 5(6):640–652
20.
Zou Y, Chakrabarty K (2003) Sensor deployment and target localization based on virtual forces. IEEE INFOCOM 23rd Annual Joint Conf of the IEEE Comp and Commun Societies 1293–1303
21.
Mahboubi H, Moezzi K, Aghdam AG, Sayrafian-Pour K, Marbukh V (2014) Distributed deployment algorithms for improved coverage in a network of wireless mobile sensors. IEEE T Ind Inform 10(1):163–174
22.
Senouci MR, Mellouk A, Assnoune K (2014) Localized movement-assisted sensor deployment algorithm for hole detection and healing. IEEE T Parall Distr 25(5):1267–1277
23.
Ghosh A (2004) Estimating coverage holes and enhancing coverage in mixed sensor networks. Proc of the IEEE Int Conf on Local Comp Netw 68–76
24.
Fang Q, Gao J, Guibas LJ (2006) Locating and bypassing holes in sensor networks. Mobile Netw Appl 11(2):187–200
25.
Wang G, Cao G, Berman P, Porta TFL (2007) Bidding protocols for deploying mobile sensors. IEEE T Mobile Comput 6(5):515–528
26.
Ma HC, Sahoo PK, Chen YW (2011) Computational geometry based distributed coverage hole detection protocol for the wireless sensor networks. J Netw Comput Appl 34(2011):1743–1756CrossRef
27.
Li W, Zhang W (2015) Coverage hole and boundary nodes detection in wireless sensor networks. J Netw Comp Appl 48:35–43CrossRef
28.
Li W, Wu Y (2016) Tree-based coverage hole detection and healing method in wireless sensor networks. Comput Netw 103:33–43CrossRef
29.
Wang Y, Wu S, Gao X, Wu F, Chen G (2017) Minimizing mobile sensor movements to form a line Kcoverage. Peer Peer Netw Appl 10(4):1063–1078
30.
Nguyen TG, So-In C, Nguyen NG (2018) Distributed deployment algorithm for barrier coverage in mobile sensor networks. IEEE Access 6:21042–21052
31.
Yu X, Liu N, Huang W, et al. (2013) A node deployment algorithm based on Van Der Waals force in wireless sensor networks. Inter J of Distr Sensor Netw 1–8
32.
Yoon Y, Kim YH (2013) An efficient genetic algorithm for maximum coverage deployment in wireless sensor networks. IEEE T Cybernetics 43(5):1473–1483
33.
Mahboubi H, Moezzi K, Aghdam AG, Sayrafian-Pour K (2014) Distributed deployment algorithms for efficient coverage in a network of mobile sensors with nonidentical sensing capabilities. IEEE Trans Veh Technol 63(8):3998–4016CrossRefMATH
34.
Zhang H, Hou JC (2005) Maintaining sensing coverage and connectivity in large sensor networks. Ad Hoc & Sens Wirel Ne 1(1–2):89–124
35.
36.
Silvestri S, Goss K (2017) MobiBar: an autonomous deployment algorithm for barrier coverage with mobile sensors. Ad Hoc Netw 54:111–129CrossRef
37.
Locateli M, Raber U (2002) Packing equal circles in a square: a deterministic global optimization approach. Discret Appl Math 122:139–166MathSciNetCrossRefMATH
38.
Chakrabarty K, Iyengar SS, Qi H, Cho E (2002) Grid coverage for surveillance and target location in distributed sensor networks. IEEE T Comput 51:1448–1453
39.
Heinzelman WB, Chandrakasan AP, Balakrishnan H (2002) An application-specific protocol architecture for wireless microsensor networks. IEEE T Wirel Commun 1(4):660–670
40.
Li X, Calinescu G, Wan P, Wang Y (2003) Localized Delaunay triangulation with applications in wireless ad hoc networks. IEEE T Parall Distr 14(10):1035–1047
Metadaten
Titel
An efficient coverage hole-healing algorithm for area-coverage improvements in mobile sensor networks
verfasst von
Chakchai So-In
Tri Gia Nguyen
Nhu Gia Nguyen
Publikationsdatum
31.08.2018
Verlag
Springer US
Erschienen in
Peer-to-Peer Networking and Applications / Ausgabe 3/2019
Print ISSN: 1936-6442
Elektronische ISSN: 1936-6450
DOI
https://doi.org/10.1007/s12083-018-0675-8

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EditorialNotes

Editorial: Network coverage: From theory to practice