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Wireless Personal Communications

Erschienen in:

31.08.2016

Benchmarking and Modeling of Routing Protocols for Delay Tolerant Networks

verfasst von: Osman Khalid, Rao Naveed Bin Rais, Sajjad A. Madani

Erschienen in: Wireless Personal Communications | Ausgabe 3/2017

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Abstract

Delay Tolerant Networks (DTN) are deployed to establish communications in challenging environments with frequent disruptions and delays due to intermittently connecting nodes, such as sparsely distributed wireless sensor networks and mobile ad hoc networks. Routing in such networks is difficult as nodes have little information about the state of the network that has time evolving topology. Therefore, nodes must store, carry, and forward messages towards destinations during opportunistic contacts. In recent years, numerous simulation based studies have been conducted for DTN protocols under various platforms, parameters, and mobility scenarios. However, most of the evaluations were limited in terms of: (a) number of protocols compared, (b) simulation parameters, and (c) DTN scenarios. This paper performs a detailed comparative analysis of ten popular DTN routing protocols. The protocols are benchmarked for the performance metrics, such as: (a) delivery ratio, (b) latency, and (c) message overhead, under the variance of: (a) buffer capacity, (b) message size, (c) message rate, and (d) size of network. The simulation results provide a deeper insight into a protocol’s strengths and weaknesses under diverse network conditions. As a further contribution, we proposed enhancements in the models of three routing schemes for DTNs. The proposed schemes autonomously adapt to the varying network conditions to reduce the messages’ replication frequency by finding optimal routes for messages among sources and destinations nodes. Simulation results indicated significant improvement in performance of the proposed enhanced schemes.

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Delay-Tolerant Networking Working Group. (DTN). https://datatracker.ietf.org/wg/dtnwg/. Accessed May 2015.

Burleigh, S., Hooke, A., Torgerson, L., Fall, K., Cerf, V., Durst, B., et al. (2003). Delay-tolerant networking: An approach to interplanetary internet. IEEE Communication Magazine, 41(6), 128–136.CrossRef

Cadger, F., Curran, K., Santos, J., & Moffet, S. (2016). Location and mobility-aware routing for improving multimedia streaming performance in MANETs. Wireless Personal Communications, 86(3), 1653–1672.CrossRef

Jacquet, P., Muhlethaler, P., Clausen, T., Laouiti, A. & Qayyum, A. (2003). Optimized link state routing protocol (OLSR), RFC 3626, October 2003.

Perkins, C., Belding-Royer, E., & Das, S. (2003). Ad hoc on-demand distance vector (AODV) Routing. RFC 3561, July 2003.

Johnson, D. B., & Maltz, D. A. (1996). Dynamic source routing in ad hoc wireless networks. Imielinski and Korth, Eds.,Mobile Computing, Vol. 353, 1996.

Anjum, S. S., Noor, R. M., & Anisi, M. H. (2015). Review on MANET based communication for search and rescue operations. Wireless Personal Communications (pp. 1–22). First online: 22 December.

Cheng, R., Chen, N., Chou, Y., & Becvar, Z. (2015). Offloading multiple mobile data contents through opportunistic device-to-device communications. Wireless Personal Communications, 84(3), 1963–1979.CrossRef

Horng, G. (2015). Opportunistic content sharing scheme for distributed network in city environments. Wireless Personal Communications, 84(4), 2327–2350.CrossRef

10.

Balasubramanian, A., Levine, B., & Venkataramani, A. (2010). Replication routing in DTNs: A resource allocation approach. IEEE/ACM Transactions on Networking, 18(2), 596–609.CrossRef

11.

Spyropoulos, T., Turletti, T., & Obrazcka, K. (2009). Routing in delay tolerant networks comprising heterogeneous populations of nodes. IEEE Transaction on Mobile Computing, 8(8), 1132–1147.CrossRef

12.

Spyropoulos, T., Psounis, K., & Raghavendra, C. S. (2005). Spray and wait: An efficient routing scheme for intermittently connected mobile networks. In Proceedings of ACM WDTN (pp. 252–259).

13.

Spyropoulos, T., Psounis, K., & Raghavendra, C. S. (2007). Spray and focus: Efficient mobility-assisted routing for heterogeneous and correlated mobility. In Proceedings of the fifth IEEE international conference on pervasive computing and communications workshop, pp. 79–85.

14.

Spyropoulos, T., Rais, R. N. B., Turletti, T., Obraczka, K., & Vasilakos, A. (2010). Routing for disruption tolerant networks: taxonomy and design. ACM Journal Wireless Networks, 16(8), 2349–2370.CrossRef

15.

Yasmin, S., Rais, R. N. B., Qayyum, A. (2015). A multi-attribute routing protocol for opportunistic network environments. In Proceedings of 23rd international conference on computer communication and networks (ICCCN) (pp. 1–6).

16.

Lindgren, A., Doria, A., & Schelén, O. (2003). Probabilistic routing in intermittently connected networks. SIGMOBILE Mobile Computing and Communications Review, 7(3), 19–20.CrossRef

17.

Burgess, J., Gallagher, B., Jensen, D., & Neil Levine, B. (2006). MaxProp: Routing for vehicle-based disruption-tolerant networks. In Proceedings of IEEE infocom (pp. 1–11) April, 2006.

18.

Spyropoulos, T., Psounis, K., & Raghavendra, C. S. (2004). Single-copy routing in intermittently connected mobile networks. In Proceedings of sensor and ad hoc communications and networks (pp. 235–244).

19.

Hsu, Y.-F., & Chih-Lin, H. (2015). Erasure coding-based message forwarding to multiple destinations in intermittently connected networks. International Journal of Ad-Hoc and Ubiquitous Computing, 9(1), 75–85.CrossRef

20.

Kerdsri, J. & Wipusitwarakun, K. (2015). Dynamic rendezvous based routing algorithm on sparse opportunistic network environment. International Journal of Distributed Sensor Networks, 11(2). doi:10.1155/2015/819178.

21.

Yasmin, S., Rais, R. N. B., & Qayyum, A. (2016). Resource aware routing in heterogeneous. International Journal of Distributed Sensor Networks, 2016, 1–18.

22.

Ko, E., Kim, D., Park, H., Yeom, I., & Seo, E. (2015). An end-to-end rate control protocol for intermittently connected networks. Wireless Personal Communications, 84(1), 287–303.CrossRef

23.

Khalid, O., Khan, S. U., Kolodziej, J., Zhang, L., Li, J., Hayat, K., Madani, S. A., Wang, L., & Chen, D. (2012). A checkpoint based message forwarding approach for opportunistic communication. In European conference of modeling and simulation.

24.

Sandulescu, G., & Nadjm-Tehrani, S. (2008). Opportunistic DTN routing with window-aware adaptive replication. In Proceedings 4th Asian conference on internet engineering (pp. 103–112).

25.

Johari, S. R., Gupta, N., & Aneja, S. (2015). Experimental evaluation of routing schemes for intermittently connected wireless mobile networks. Wireless Personal Communications, 1–25. First online: 07 November 2015

26.

Cao, Y., & Sun, Z. (2013). Routing in delay/disruption tolerant networks: A taxonomy, survey and challenges. IEEE Communications Surveys and Tutorials, 15(2), 654–677.CrossRef

27.

Voyiatzis, A. G. (2012). A survey of delay- and disruption-tolerant networking applications. Journal of Internet Engineering, 5(1), 1–331.

28.

Keränen, A., Ott, J. & Kärkkäinen, T. (2009). The ONE simulator for DTN protocol evaluation. In Proceedings of 2nd international conference on simulation tools and techniques. doi.10.4108.

29.

Infocom06 connectivity traces on CRAWDAD website (2016). http://crawdad.cs.dartmouth.edu/meta.php?name=cambridge/haggle#N100C4

30.

Jain, S., Fall, K., & Patra, R. (2004). Routing in a delay tolerant network. In Proceedings of conference on applications, technologies, architectures, and protocols for computer communications (pp. 145–158).

31.

Vahdat, A., & Becker, D. (2000). Epidemic routing for partially connected ad hoc networks. Technical report CS-200006, Duke University.

32.

Ott, J., Keränen, A., & Hyytiä, E. (2011). BeachNet: Propagation-based information sharing in mostly static networks. In Proceedings of ACM ExtremeCom.

33.

Gardner, M. (1970). The fantastic combinations of John Conway’s new solitaire game life. Scientific American (pp. 120–123).

34.

OMNET++Simulator. https://omnetpp.org/. Accessed February 2016.

35.

NS-3 Simulator. https://www.nsnam.org/. Accessed February 2016.

36.

Aung, C. Y., Seet, B. C., Zhang, M., Xie, L. F., & Chong, P. H. J. (2015). A review of group mobility models for mobile ad hoc networks. Wireless Personal Communications, 85(3), 1317–1331.CrossRef

37.

OpenStreetMap (OSM) API website (2016). http://www.openstreetmap.org/

38.

OPENJUMP GIS Software http://www.openjump.org/. Accessed July 2015.

Titel: Benchmarking and Modeling of Routing Protocols for Delay Tolerant Networks
verfasst von: Osman Khalid
Rao Naveed Bin Rais
Sajjad A. Madani
Publikationsdatum: 31.08.2016
Verlag: Springer US
Erschienen in: Wireless Personal Communications / Ausgabe 3/2017
Print ISSN: 0929-6212
Elektronische ISSN: 1572-834X
DOI: https://doi.org/10.1007/s11277-016-3654-5

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