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Wireless Networks
Erschienen in: Wireless Networks 6/2014

01.08.2014

Dynamic traffic-aware routing algorithm for multi-sink wireless sensor networks

verfasst von: Do Duy Tan, Dong-Seong Kim

Erschienen in: Wireless Networks | Ausgabe 6/2014

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Abstract

In this paper, a distributed traffic-balancing routing algorithm is proposed for multi-sink wireless sensor networks that effectively distributes traffic from sources to sinks. Each node has a gradient field that is used to decide on a neighbor node to reach a sink. The node’s gradient index contains (1) the distance cost from a source to a respective sink, and (2) traffic information from neighboring nodes. The proposed algorithm considers the traffic being faced by surrounding neighbors before forwarding packets to any sink using gradient search for routing and providing a balance between optimal paths and possible congestion on routes toward those sinks. The key objective of this work is to achieve traffic-balancing by detecting congested areas along the route and distributing packets along paths that have idle and underloaded nodes. Extensive simulations conducted to evaluate the performance of the proposed scheme indicate that it effectively reduces the overall packet delay, energy consumption and improves the packet delivery ratio under heavy traffic.
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Literatur
1.
Akkaya, K., & Younis, M. (2005) A survey on routing protocols for wireless sensor networks. Ad Hoc Networks, 3, 325–349.CrossRef
2.
Al-Karaki, J., & Kamal, A. (2004). Routing techniques in wireless sensor networks: A survey. IEEE Wireless Communications, 11(6), 6–28.CrossRef
3.
Basu, A., Lin, A., & Ramanathan, S. (2003) Routing using potentials: A dynamic traffic-aware routing algorithm. In Proceedings of the 2003 conference on applications, technologies, architectures, and protocols for computer communications, SIGCOMM, pp. 37–48.
4.
5.
Dinh, N. Q., Hoa, T. D., & Kim, D. S. (2011). Distributed traffic aware routing with multiple sinks in wireless sensor networks. In 9th IEEE international conference on industrial informatics (INDIN), pp. 404 –409.
6.
Gao, D., Zheng, T., Zhang, S., & Yang, O. W. W. (2010). Improved gradient-based micro sensor routing protocol with node sleep scheduling in wireless sensor networks. In IEEE 72nd vehicular technology conference fall (VTC 2010-Fall), pp. 1–5.
7.
Heinzelman, W., Chandrakasan, A., & Balakrishnan, H. (2000). Energy-efficient communication protocol for wireless microsensor networks. In Proceedings of the 33rd annual Hawaii international conference on system sciences, Vol. 2, p. 10.
8.
Heo, J., Hong, J., & Cho, Y. (2009). EARQ: Energy aware routing for real-time and reliable communication in wireless industrial sensor networks. IEEE Transactions on Industrial Informatics, 5 (1), 3–11.CrossRef
9.
Huang, P., Chen, H., Xing, G., & Tan, Y. (2009). SGF: A state-free gradient-based forwarding protocol for wireless sensor networks. ACM Transactions on Sensor Networks (TOSN), 5, 14:1–14:25.CrossRef
10.
IETF ROLL WG. (2010). RPL: Routing protocol for low power and lossy networks. In IETF internet-draft. IETF ROLL WG, March 8.
11.
Intanagonwiwat, C., Govindan, R., Estrin D., Heidemann, J., & Silva, F., (2003). Directed diffusion for wireless sensor networking. IEEE/ACM Transactions on Networking, 11(1), 2–16.CrossRef
12.
Kanavalli, A., Jayashree, M., Shenoy, P., Venugopal, K., & Patnaik, L. (2008). Hop by hop congestion control system for adhoc networks. In IEEE region 10 conference TENCON, pp. 1–4.
13.
Li, Y., Chen, C. S., Song, Y. Q., Wang, Z., & Sun, Y. (2009). Enhancing real-time delivery in wireless sensor networks with two-hop information. IEEE Transactions on Industrial Informatics, 5 (2), 113–122.CrossRef
14.
Mei, A., Piroso, N., & Vavala, B. (2012). Fine grained load balancing in multi-hop wireless networks. Journal of Parallel and Distributed Computing, 72 (4), 475–488.CrossRef
15.
Mottola, L., & Picco, G. (2011). Muster: Adaptive energy-aware multisink routing in wireless sensor networks. IEEE Transactions on Mobile Computing, 10(12), 1694–1709.CrossRef
16.
Park, C., & Jung, I. (2010). Traffic-aware routing protocol for wireless sensor networks. In International conference on information science and applications (ICISA), pp. 1 –8.
17.
Pussente, R. M., & Barbosa, V. C. (2009). An algorithm for clock synchronization with the gradient property in sensor networks. Journal of Parallel and Distributed Computing, 69 (3), 261–265.CrossRef
18.
Quang, P. T. A., & Kim, D. S. (2012). Enhancing real-time delivery of gradient routing for industrial wireless sensor networks. IEEE Transactions on Industrial Informatics, 8(1), 61–68.CrossRef
19.
Ren, F., He, T., Das, S., & Lin, C. (2011). Traffic-aware dynamic routing to alleviate congestion in wireless sensor networks. IEEE Transactions on Parallel and Distributed Systems, 22(9) ,1585–1599.CrossRef
20.
Schurgers, C., & Srivastava, M. (2001). Energy efficient routing in wireless sensor networks. In IEEE military communications conference, Vol. 1, pp. 357–361.
21.
Shah-Mansouri, V., Mohsenian-Rad, A. H., & Wong, V. (2009). Lexicographically optimal routing for wireless sensor networks with multiple sinks. IEEE Transactions on Vehicular Technology, 58(3), 1490–1500.CrossRef
22.
Slama, I., Jouaber, B., & Zeghlache, D. (2008). Energy efficient scheme for large scale wireless sensor networks with multiple sinks. In Wireless communications and networking conference, pp. 2367–2372.
23.
Suhonen, J., Kuorilehto, M., Hannikainen, M., & Hamalainen, T. (2006). Cost-aware dynamic routing protocol for wireless sensor networks-design and prototype experiments. In IEEE 17th international symposium on personal, indoor and mobile radio communications, pp. 1–5.
24.
Torfs, T., Sterken, T., Brebels, S., Santana, J., van den Hoven , R., Spiering, V. et al. (2013). Low power wireless sensor network for building monitoring. IEEE Sensors Journal, 13(3), 909–915.CrossRef
25.
yih Wan C., & Eisenman S. B. (2003). CODA congestion detection and avoidance in sensor networks (pp. 266–279). New york: ACM Press.
26.
Watteyne, T., Pister, K., Barthel, D., Dohler, M., & Auge-Blum, I. (2009). Implementation of gradient routing in wireless sensor networks. In Proceedings of the 28th IEEE conference on global telecommunications, GLOBECOM, pp. 5331–5336.
27.
Yang, J., Zhang, C., Li, X., Huang, Y., Fu, S., & Acevedo, M. (2010). Integration of wireless sensor networks in environmental monitoring cyber infrastructure. Wireless Networks, 16 (4), 1091–1108.CrossRef
28.
Yoo, H., Shim, M., Kim, D., & Kim, K. H. (2010). GLOBAL: A gradient-based routing protocol for load-balancing in large-scale wireless sensor networks with multiple sinks. In IEEE symposium on computers and communications (ISCC), pp. 556–562.
Metadaten
Titel
Dynamic traffic-aware routing algorithm for multi-sink wireless sensor networks
verfasst von
Do Duy Tan
Dong-Seong Kim
Publikationsdatum
01.08.2014
Verlag
Springer US
Erschienen in
Wireless Networks / Ausgabe 6/2014
Print ISSN: 1022-0038
Elektronische ISSN: 1572-8196
DOI
https://doi.org/10.1007/s11276-013-0672-z

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