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Spatial–temporal compression and recovery in a wireless sensor network in an underground tunnel environment
- 作者:Bin He (1)
Yonggang Li (1)
Hongwei Huang (2)
Haifeng Tang (1)
- 关键词:Wireless sensor network ; Structural health monitoring ; Spatial–temporal compression
- 刊名:Knowledge and Information Systems
- 出版年:2014
- 出版时间:November 2014
- 年:2014
- 卷:41
- 期:2
- 页码:449-465
- 全文大小:1,057 KB
- 参考文献:1. Hada A, Soga K, Liu R, Wassell I (2012) Lagrangian heuristic method for the wireless sensor network design problem in railway structural health monitoring. Mech Syst Signal Process 28:20-5 CrossRef
2. Hirai C, Soga K (2010) An experimental model of relay development planning tool for wireless sensor network system to monitor civil engineering structure. In: Proceeding of the 19th LASTED international conference parallel and distributed computing and network (PDCN 2010), Innsbruck, Austria, pp 164-71
3. Stajano F, Hoult N, Wassell I, Bennett P, Middleton C, Soga K (2010) Smart bridges, Smart tunnels: transforming wireless sensor networks from research prototypes into robust engineering Infrastructure. Ad Hoc Netw 8(8):872-88 CrossRef
4. Bocca M, Eriksson L, Mahmood A, Jantti R, Kullaa J (2011) A synchronized wireless sensor network for experimental modal analysis in structural health monitoring. Comput-Aided Civil Infrastruct Eng 26(7):483-99 CrossRef
5. Tanner N, Wait J, Farrar C, Sohn H (2003) Structural health monitoring using modular wireless sensors. Intell Mater Syst Struct 14(1):43-6 CrossRef
6. Lynch JP, Loh KJ (2006) A summary review of wireless sensors and sensor networks for structural health monitoring. Shock Vib Digest 38(2):91-28 CrossRef
7. Bandyopadhyay S, Tian Q, Coyle E (2005) Spatial-temporal sampling rates and energy efficient in wireless sensor networks. IEEE/ACM Trans Netw 13(6):1339-352 CrossRef
8. Akyildiz IF, Su W, Sankarasubramaniam Y, Cayirci E (2002) Wireless sensor networks: a survey. Comput Netw 38(4):393-22 CrossRef
9. Wu XD, Kumar V, Quinlan JR, Ghosh J, Yang Q, Motoda H, Ng A, Liu B, Yu PS (2008) Top 10 algorithms in data mining. Knowl Inf Syst 14(1):1-7 CrossRef
10. Yick J, Muckherjee B, Ghosal D (2008) Wireless sensor network survey. Comput Netw 52(12):2292-330 CrossRef
11. Sadler C, Martonosi M (2006) Data compression algorithms for energy-constrained devices in delay tolerant networks. In: Proceedings of the 4th international conference on embeded networked sensor systems. SenSys
12. Ciancio A, Pattem S, Ortega, A, Krishnamachari B (2006) Energy-efficient data representation and routing for wireless sensor networks based on a distributed wavelet compression algorithm. In: Proceedings of the fifth international conference on information processing in sensor networks, pp 309-16
13. Li JL, Alregib G (2007) Rate-constrained distributed estimation in wireless sensor network. IEEE Trans Signal Process 55(5):1634-643 CrossRef
14. Marcelloni F, Vecchio M (2010) Enabling energy-efficient and lossy aware data compression in wireless sensor networks by multi-objective evolutionary optimization. Inf Sci 180(10):1924-941 CrossRef
15. Donoho DL (2006) Compressive sensing. IEEE Trans Inf Theory 52(4):1289-306 CrossRef
16. Ji Sh, Xue Y, Carin L (2008) Bayesian compressive sensing. IEEE Trans Signal Process 56(6):2346-356 CrossRef
17. Luo C, Sun J, Wu F, Chen CW (2009) Compressive data gathering for large-scale wireless sensor networks. In: Proceedings of the 15th annual international conference on mobile computing and networking, pp 145-56
18. Vuran MC, Akan OB, Akyildiz IF (2004) Spatial-temporal correlation: theory and applications for wireless sensor networks. Comput Netw J 45(3):245-59 Huang (2)
Haifeng Tang (1)
1. The College of Electronics and Information Engineering, Tongji University, Shanghai, China
2. The College of Civil Engineering of Tongji University, Shanghai, China
- ISSN:0219-3116
文摘
In an exciting new application, wireless sensor networks (WSNs) are increasingly being deployed to monitor the structure health of underground subway tunnels, promising many advantages over traditional monitoring methods. As a result, ensuring efficient data communication, transmission, and storage have become a huge challenge for these systems as they try to cope with ever increasing quantities of data collected by ever growing numbers of sensor nodes. A key approach of managing big data in WSNs is through data compression. Reducing the volume of data traveling between sensor nodes can reduce the high energy cost of data transmission, as well as save space for storage of big data. In this paper, we propose an algorithm for the compression of spatial–temporal data from one data type of sensor node in a WSN deployed in an underground tunnel. The proposed algorithm works efficiently because it considers temporal as well as spatial features of sensor data. A recovery process is required for recovering the data with a close approximation to the original data form nodes. We validate the proposed recovery technique through computational experiments carried out using the data acquired from a real WSN.
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