Article

A Mobile Delay-Tolerant Approach to Long-Term Energy-Efficient Underwater Sensor Networking

Authors:

E. Magistretti,

A. CorradiAuthors Info & Claims

Proceedings of the 2007 IEEE Wireless Communications and Networking Conference

Pages 2866 - 2871

https://doi.org/10.1109/WCNC.2007.531

Published: 01 March 2007 Publication History

Abstract

Underwater environment represents a challenging and promising application scenario for sensor networks. Due to hard constraints imposed by acoustic communications and to high power consumption of acoustic modems, in underwater sensor networks (USN) energy saving becomes even more critical than in traditional sensor networks. In this paper the authors propose delay-tolerant data dolphin (DDD), an approach to apply delay-tolerant networking in the resource-constrained underwater environment. DDD exploits the mobility of a small number of capable collector nodes (namely dolphins) to harvest information sensed by low power sensor devices, while saving sensor battery power. DDD avoids energy-expensive multi-hop relaying by requiring sensors to perform only one-hop transmissions when a dolphin is within their transmission range. The paper presents simulation results to evaluate the effectiveness of randomly moving dolphins for data collection.

References

[1]

I. Akyildiz, D. Pompili, and T. Melodia. Underwater acoustic sensor networks: research challenges. In Elsevier Journal of Ad Hoc Networks, volume 3, pages 257-281, Mar. 2005.

[2]

S. Burleigh, K. Fall, V. Cerf, R. Durst, K. Scott, H. Weiss, L. Torgerson, and A. Hooke. Delay-Tolerant Networking: an Approach to Interplanetary Internet. In IEEE Communications Magazine, volume 41, pages 128-137, Jun. 2003.

Digital Library

[3]

T. Clausen, P. Jacquet, and L. Viennot. Comparative study of cbr and tcp performance of manet routing protocols. In IEEE MESA, Jan. 2002. ETSI.

[4]

J.-H. Cui, J. Kong, M. Gerla, and S. Zhou. Challenges: Building Scalable Mobile Underwater Wireless Sensor Networks for Aquatic Applications. In. IEEE Network, volume 20, pages 12-18, May-Jun. 2006.

Digital Library

[5]

K. Fall. A delay-tolerant network architecture for challenged internets. In ACM SIGCOMM'03, Aug. 2003.

Digital Library

[6]

L. Freitag, M. Grund, S. Singh, J. Partan, P. Koski, and K. Ball. The whoi micro-modem.: An acoustic communications and navigation system for multiple platforms. In IEEE/MTS OCEANS Conference, Sept. 2005.

[7]

A. Goel, S. Rai, and B. Krishnamachari. Sharp thresholds For monotone properties in random geometric graph. In ACM STOC04, Jun. 2004.

Digital Library

[8]

J. Heidemann, Y. Li, A. Syed, J. Wills, and W. Ye. Underwater sensor networking: Research challenges and potential applications . In USC/ISI Technical Report ISI-TR-2005, 2005.

[9]

R. Humston, D. B. Olson, and J. S. Ault. Behavioral Assumptions in Models of Fish Movement and Their Influence on Population Dynamics. In Transactions of the America Fisheries Society, volume 10, pages 1304-1328, Jun. 2004.

[10]

D. B. Kilfoyle and A. B. Baggeroer. The State of the Art in Underwater Acoustic Telemetry. IEEE Journal of Oceanic Engineering, OE-25(1):4-27, January 2000.

[11]

J.-Y. LeBoudec and M. Vojnovic. Perfect Simulation, and Stationarity of a Class of Mobility Models. In IEEE Infocom '05, Mar. 2005.

[12]

LinkQuest, Inc. Underwater Acoustic Modems. http://www.link-quest .com/html/uwm_hr.pdf.

[13]

E. Magistretti, J. Kong, U. Lee, M. Gerla, and P. Bellavista. Mobile Delay-tolerant Approach to Long-term Energy-Efficient Underwater Sensor Networks. In UCLA Technical Report, 2006.

[14]

Crossbow Mica 2 Motes. http://www.xbow.com/Products/Product_pdf.files/ Wireless_pdf/MICA2_OEM_Edition_Datasheet.pdf.

[15]

S. PalChaudhuri, J.-Y. LeBoudec, and M. Vojnovic. Perfect Simulations of Random Trip Models. In 38th Annual Simulation, Symposium, Apr. 2005.

Digital Library

[16]

J. Proakis, E. Sozer, J. Rice, and M. Stojanovic. Shallow Water Acoustic Networks. In IEEE Communications Magazine, volume 39, pages 114-119, Nov. 2001.

Digital Library

[17]

The Qualnet Simulator. http:://www.scalable-networks.com.

[18]

T. Small and Z. J. Haas. The Shared Wireless Infestation Model - A New Ad Hoc Networking Paradigm (or Where There is a Whale, There is a Way). In ACM MOBIHOC'03, Jun. 2003.

Digital Library

[19]

L. F. M. Vieira, J. Kong, U. Lee, and M. Gerla. Analysis of Aloha Protocols for Underwater Acoustic Sensor Networks. In ACM WUWNET'06 ?Poster available at http://wuwnet.engr.uconn.edu/wipposters/luiz.alaha.pdf, Sept. 2006.

[20]

J. Wills, W. Ye, and J. Heidemann. Low-Power Acoustic Modem for Dense Underwater Sensor Networks. In ACM WUWNET'06, Sept. 2006.

Digital Library

[21]

W. Zhao, M. Ammar, and E. Zegura. A Message Ferrying Approach for Data Delivery in Sparse Mobile Ad Hoc Networks. In ACM MOBIHOC'04, May 2004.

Digital Library

Cited By

Ayaz MAbdullah AFaye IBatira Y(2019)An efficient Dynamic Addressing based routing protocol for Underwater Wireless Sensor NetworksComputer Communications10.1016/j.comcom.2011.11.01435:4(475-486)Online publication date: 4-Jan-2019
https://dl.acm.org/doi/10.1016/j.comcom.2011.11.014
Lee UKong JGerla MPark JMagistretti E(2018)Time-critical underwater sensor diffusion with no proactive exchanges and negligible reactive floodsAd Hoc Networks10.1016/j.adhoc.2007.02.0125:6(943-958)Online publication date: 27-Dec-2018
https://dl.acm.org/doi/10.1016/j.adhoc.2007.02.012
Ayaz MBaig IAbdullah AFaye I(2011)ReviewJournal of Network and Computer Applications10.1016/j.jnca.2011.06.00934:6(1908-1927)Online publication date: 1-Nov-2011
https://dl.acm.org/doi/10.1016/j.jnca.2011.06.009

A Mobile Delay-Tolerant Approach to Long-Term Energy-Efficient Underwater Sensor Networking
1. Hardware
  1. Communication hardware, interfaces and storage
2. Networks
  1. Network types

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cover image Guide Proceedings

Proceedings of the 2007 IEEE Wireless Communications and Networking Conference

March 2007

4451 pages

ISBN:1424406587

Copyright © 2007.

Publisher

IEEE Computer Society

United States

Publication History

Published: 01 March 2007

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Cited By

Ayaz MAbdullah AFaye IBatira Y(2019)An efficient Dynamic Addressing based routing protocol for Underwater Wireless Sensor NetworksComputer Communications10.1016/j.comcom.2011.11.01435:4(475-486)Online publication date: 4-Jan-2019
https://dl.acm.org/doi/10.1016/j.comcom.2011.11.014
Lee UKong JGerla MPark JMagistretti E(2018)Time-critical underwater sensor diffusion with no proactive exchanges and negligible reactive floodsAd Hoc Networks10.1016/j.adhoc.2007.02.0125:6(943-958)Online publication date: 27-Dec-2018
https://dl.acm.org/doi/10.1016/j.adhoc.2007.02.012
Ayaz MBaig IAbdullah AFaye I(2011)ReviewJournal of Network and Computer Applications10.1016/j.jnca.2011.06.00934:6(1908-1927)Online publication date: 1-Nov-2011
https://dl.acm.org/doi/10.1016/j.jnca.2011.06.009

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