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The Journal of Supercomputing
Erschienen in: The Journal of Supercomputing 12/2015

01.12.2015

Distributed lifetime coverage optimization protocol in wireless sensor networks

verfasst von: Ali Kadhum Idrees, Karine Deschinkel, Michel Salomon, Raphaël Couturier

Erschienen in: The Journal of Supercomputing | Ausgabe 12/2015

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Abstract

One of the main research challenges faced in Wireless Sensor Networks (WSNs) is to preserve continuously and effectively the coverage of an area (or region) of interest to be monitored, while simultaneously preventing as much as possible a network failure due to battery-depleted nodes. In this paper, we propose a protocol, called distributed lifetime coverage optimization protocol (DiLCO), which maintains the coverage and improves the lifetime of a wireless sensor network. First, we partition the area of interest into subregions using a classical divide-and-conquer method. Our DiLCO protocol is then distributed on the sensor nodes in each subregion in a second step. To fulfill our objective, the proposed protocol combines two effective techniques: a leader election in each subregion, followed by an optimization-based node activity scheduling performed by each elected leader. This two-step process takes place periodically, to choose a small set of nodes remaining active for sensing during a time slot. Each set is built to ensure coverage at a low energy cost, allowing to optimize the network lifetime. Simulations are conducted using the discrete event simulator OMNET++. We refer to the characteristics of a Medusa II sensor for the energy consumption and the computation time. In comparison with two other existing methods, our approach is able to increase the WSN lifetime and provides improved coverage performances.
Vorheriger Artikel Analytical performance model for mobile network operator cloud
Nächster Artikel Thermal analysis of stochastic DVFS-enabled multicore real-time systems

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Literatur
1.
Akyildiz IF, Su W, Sankarasubramaniam Y, Cayirci E (2002) A survey on sensor networks. IEEE Commun Mag 40(8):102–114CrossRef
2.
Akyildiz IF, Vuran MC (2010) Wireless sensor networks, vol 4. Wiley, New YorkCrossRef
3.
Berman P, Calinescu G (2004) Power efficient monitoring management in sensor networks. In: Proceedings of IEEE wireless communication and networking conference (WCNC’04), pp 2329–2334
4.
Cardei M, Du D-Z (2005) Improving wireless sensor network lifetime through power aware organization. Wirel Netw 11(3):333–340CrossRef
5.
Cardei M, Thai MT, Li Y, Wu W (2005) Energy-efficient target coverage in wireless sensor networks. In: INFOCOM 2005. 24th annual joint conference of the IEEE computer and communications societies. Proceedings IEEE, vol 3. IEEE, pp 1976–1984
6.
Castaño F, Rossi A, Sevaux M, Velasco N (2013) A column generation approach to extend lifetime in wireless sensor networks with coverage and connectivity constraints. Comput Oper Res 52(Part B):220–230
7.
Conti M, Giordano S (2014) Mobile ad hoc networking: milestones, challenges, and new research directions. Commun Mag IEEE 52(1):85–96CrossRef
8.
Deng X, Yu D, Yu J, Chen C (2012) Transforming area coverage to target coverage to maintain coverage and connectivity for wireless sensor networks. Int J Distrib Sens Netw 2012:254318. doi:10.​1155/​2012/​254318
9.
Deschinkel K (2012) A column generation based heuristic to extend lifetime in wireless sensor network. Sens Transducers J 14–2:242–253
10.
Heinzelman WR, Chandrakasan A, Balakrishnan H (2000) Energy-efficient communication protocol for wireless microsensor networks. In: 33rd annual Hawaii international conference on system sciences (HICSS-33), 4–7 January 2000, Maui, Hawaii. IEEE Computer Society, USA
11.
Idrees AK, Deschinkel K, Salomon M, Couturier R (2014) Coverage and lifetime optimization in heterogeneous energy wireless sensor networks. In: ICN 2014, the thirteenth international conference on networks, pp 49–54
12.
Jaggi N, Abouzeid AA (2006) Energy-efficient connected coverage in wireless sensor networks. In: Proceeding of 4th Asian international mobile computing conference AMOC2006
13.
Kim H, Cobb JA (2013) Maximum lifetime of reinforced barrier-coverage in wireless sensor networks. In: 2013 19th IEEE international conference on networks (ICON). IEEE, pp 1–6
14.
Kumar S, Lai TH, Arora A (2005) Barrier coverage with wireless sensors. In: Proceedings of the 11th annual international conference on mobile computing and networking, MobiCom ’05, New York, NY, USA, ACM, pp 284–298
15.
Li M, Vasilakos AV (2013) A survey on topology control in wireless sensor networks: taxonomy, comparative study, and open issues. Proc IEEE 101(12) 2538–2557
16.
Ling H, Znati T (2009) Energy efficient adaptive sensing for dynamic coverage in wireless sensor networks. In: Wireless communications and networking conference, 2009. WCNC 2009. IEEE. IEEE, pp 1–6
17.
18.
Misra S, Kumar MP, Obaidat MS (2011) Connectivity preserving localized coverage algorithm for area monitoring using wireless sensor networks. Comput Commun 34(12):1484–1496CrossRef
19.
Nayak A, Stojmenovic I (2010) Wireless sensor and actuator networks: algorithms and protocols for scalable coordination and data communication. Wiley, New YorkCrossRef
20.
Padmavathy TV, Chitra M (2010) Extending the network lifetime of wireless sensor networks using residual energy extraction-hybrid scheduling algorithm. Int J Commun Netw Syst Sci 3(1):98–106
21.
Pedraza F, Medaglia AL, Garcia A (2006) Efficient coverage algorithms for wireless sensor networks. In: Proceedings of the 2006 systems and information engineering design symposium, pp 78–83
22.
Qu Y, Georgakopoulos SV (2013) A distributed area coverage algorithm for maintenance of randomly distributed sensors with adjustable sensing range. In: Global communications conference (GLOBECOM), 2013 IEEE. IEEE, pp 286–291
23.
Raghunathan V, Schurgers C, Park S, Srivastava MB (2002) Energy-aware wireless microsensor networks. Signal Process Mag IEEE 19(2):40–50CrossRef
24.
Ramesh K, Somasundaram K (2011) A comparative study of clusterhead selection algorithms in wireless sensor networks. Int J Comput Sci Eng Surv 2(4):153–164
25.
Rault T, Bouabdallah A, Challal Y (2014) Energy efficiency in wireless sensor networks: a top-down survey. Comput Netw 67:104–122CrossRef
26.
Rossi A, Singh A, Sevaux M (2012) An exact approach for maximizing the lifetime of sensor networks with adjustable sensing ranges. Comput Oper Res 39(12):3166–3176MathSciNetCrossRef
27.
28.
Vu CT (2009) Distributed energy-efficient solutions for area coverage problems in wireless sensor networks. PhD thesis, Georgia State University
29.
Vu C, Gao S, Deshmukh W, Li Y (2006) Distributed energy-efficient scheduling approach for k-coverage in wireless sensor networks. In: MILCOM, vol 0, pp 1–7
30.
Xing X, Li J, Wang G (2010) Integer programming scheme for target coverage in heterogeneous wireless sensor networks. In: 2010 Sixth international conference on mobile ad-hoc and sensor networks (MSN), pp 79–84
31.
Xu Y, Heidemann J, Estrin D (2001) Geography-informed energy conservation for ad hoc routing. In: Proceedings of the 7th annual international conference on mobile computing and networking. ACM, pp 70–84
32.
Yang C, Chin K-W (2014) Novel algorithms for complete targets coverage in energy harvesting wireless sensor networks. IEEE Commun Lett 18(1):118–121CrossRef
33.
Yang C, Chin K-W (2014) A novel distributed algorithm for complete targets coverage in energy harvesting wireless sensor networks. In: IEEE ICC 2014—ad-hoc and sensor networking symposium. IEEE, pp 361–366
34.
Yang M, Liu J (2014) A maximum lifetime coverage algorithm based on linear programming. J Inf Hiding Multimed Signal Process Ubiquitous Int 5(2):296–301
35.
Zhang H, Hou JC (2005) Maintaining sensing coverage and connectivity in large sensor networks. Ad Hoc Sens Wirel Netw 1(1–2):89–124
36.
Zorbas D, Glynos D, Kotzanikolaou P, Douligeris C (2010) Solving coverage problems in wireless sensor networks using cover sets. Ad Hoc Netw 8(4):400–415CrossRef
Metadaten
Titel
Distributed lifetime coverage optimization protocol in wireless sensor networks
verfasst von
Ali Kadhum Idrees
Karine Deschinkel
Michel Salomon
Raphaël Couturier
Publikationsdatum
01.12.2015
Verlag
Springer US
Erschienen in
The Journal of Supercomputing / Ausgabe 12/2015
Print ISSN: 0920-8542
Elektronische ISSN: 1573-0484
DOI
https://doi.org/10.1007/s11227-015-1558-x

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