Abstract
In this chapter, we describe methods to ensure reliable information delivery to higher layers at the sink(s), while keeping overhead, retransmissions, and discarded information as low as possible. The basic mechanism to achieve this is typically ARQ (automatic repeat request), but many variants and additional mechanisms can be used.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Fujiwara T, Kasami T, Kitai A, Lin S (1985) On the undetected error probability for shortened Hamming codes. IEEE Trans Commun 33(6):570–574
Kalscheuer JM (2004) A selective automatic repeat request protocol for undersea acoustic links. Master’s thesis, Naval Postgraduate School, Monterey CA, USA
Rice J, Green D (2008) Underwater acoustic communications and networks for the US Navy’s Seaweb program. In: Proceedings of 2nd international conference on sensor technologies and applications (SENSORCOMM), Cap Esterel, France, pp 715–722
Rice J, Kalscheuer J (2011) A selective automatic request protocol for through-water acoustic links. In: Proceedings of the 4th UAM 2011, Kos, Greece
Stojanovic M (2005) Optimization of a data link protocol for an underwater acoustic channel. In: Proceedings of Oceans Europe 2005, IEEE, vol 1, Brest, France, pp 68–73
Tomasi B, Casari P, Badia L, Zorzi M (2010) A study of incremental redundancy hybrid ARQ over Markov channel models derived from experimental data. In: Proceedings of ACM WUWNet, Woods Hole, MA, USA
Johnson E, Kenney T, Chamberlain M, Furman W, Koski E, Leiby E, Wadsworth M (1998) US-MIL-STD-188-141B Appendix C—a unified 3rd generation HF messaging protocol. In: Proceedings of HF98, Nordic shortwave conference Fårö, Sweden, pp 5.1.1–5.1.30
NATO (2009) Annex C to STANAG 4538 ed. 1: technical specifications to ensure interoperability of an automatic radio control system for HF communication links
Chamberlain MW, Furman WN (2003) HF data link protocol enhancements based on STANAG 4538 and STANAG 4539, providing greater than 10 kbps throughput over 3 kHz channels. In: Proceedings of 9th international conference on HF Radio Systems and Techniques Bath, UK, pp 64–68
Mitzenmacher M (2004) Digital fountains: a survey and look forward. In: Proceedings of information theory workshop, ITW 2004, IEEE, San Antonio, TX, USA, pp 271–276
Bonello N, Chen S, Hanzo L (2011) Low-density parity-check codes and their rateless relatives. IEEE Communications Surveys & Tutorials,13(1):3–26
Shokrollahi A (2004) Raptor codes. In: Proceedings of international symposium on information theory, ISIT 2004. IEEE, Chicago, IL, USA, p 36
Xie P, Cui J-H (2006) SDRT: a reliable data transport protocol for underwater sensor networks. UCONN CSE technical report UbiNet-TR06-03, University of Connecticut
Casari P, Rossi M, Zorzi M (2008) Towards optimal broadcasting policies for HARQ based on fountain codes in underwater networks. In: Proceedings of 5th annual conference on wireless on demand network systems and services, Garmisch-Partenkirchen, Germany, IEEE, pp 11–19
Chan CYM, Motani M (2007) An integrated energy efficient data retrieval protocol for underwater delay tolerant networks. In: Proceedings of Oceans 2007 IEEE, Europe, Aberdeen, UK
Cao R, Yang L (2010) Decomposed Raptor codes for data-centric storage in underwater acoustic sensor networks. In: Proceedings of MTS/IEEE Oceans 2010, Seattle, WA, USA
Cao R, Yang L (2010) Short paper: reliable transport and storage protocol with fountain codes for underwater acoustic sensor networks. In: Proceedings of the fifth ACM international workshop on under water networks (WUWNet), Woods Hole, MA, USA
Stojanovic M (2007) Capacity of a relay acoustic channel. In: Proceedings of MTS/IEEE oceans 2007, Vancouver, BC, Canada, IEEE
Tan H-P, Seah WKG, Doyle L (2007) A multi-hop ARQ protocol for underwater acoustic networks. In: Proceedings of oceans 2007 Europe, Aberdeen, UK, IEEE
Valera A, Lee PWQ, Tan H-P, Liang H, Seah WKG (2009) Implementation and evaluation of multihop ARQ for reliable communications in underwater acoustic networks. In: Proceedings of Oceans 2009 Europe, Bremen, Germany, IEEE
Zhuang H, Tan H-P, Valera A, Bai Z (2010) Opportunistic ARQ with bidirectional overhearing for reliable multihop underwater networking. In: Proceedings of Oceans 2010 Asia, IEEE
Ahlswede R, Cai N, Robert Li S-Y, Yeung RW (2000) Network information flow. IEEE Trans Inf Theory 46(4):1204–1216
Katti S, Rahul H, Hu W, Katabi D, Médard M, Crowcroft J (2006) Xors in the air: practical wireless network coding. ACM SIGCOMM Comput Commun Rev 36(4):243–254
Asterjadhi A, Baldo N, Zorzi M (2009) A distributed network coded control channel for multi-hop cognitive radio networks. IEEE Netw 23(4):26
Guo Z, Xie P, Cui J-H, Wang B (2006) On applying network coding to underwater sensor networks. In: Proceedings of ACM WUWNet, Los Angeles, CA, USA, pp 109–112
Fragouli C, Yves Le Boudec J, Widmer J (2006) Network coding: an instant primer. ACM SIGCOMM Comput Commun Rev 36(1):63–68
Eugster P, Guerraoui R, Kermarrec AM, Massoulie L (2004) Epidemic information dissemination in distributed systems. Computer 37(5):60–67
Chou PA, Wu Y, Jain K (2003) Practical network coding. In: 41st Allerton conference on communication control and computing, Allerton, IL, USA
Fragouli C, Widmer J, Boudec JYL (2008) Efficient broadcasting using network coding. IEEE/ACM Trans Netw 16(2):450–463
Asterjadhi A, Fasolo E, Widmer J, Rossi M, Zorzi M (2010) Toward network coding-based protocols for data broadcasting in ad hoc wireless networks. IEEE Trans Wireless Commun 9(2):662–673
Ho T, Medard M, Koetter R, Karger DR, Effros M, Shi J, Leong B (2006) A random linear network coding approach to multicast. IEEE Trans Inf Theory 52(10):4413–4430
Omiwade S, Zheng R, Hua C (2008) Practical localized network coding in wireless mesh networks. In: Proceedings of IEEE SECON, San Francisco, CA USA, pp 332–340
Guo Z, Wang B, Xie P, Zeng W, Cui J-H (2009) Efficient error recovery with network coding in underwater sensor networks. Ad Hoc Netw 7:791–802
Chitre M, Soh W-S (2010) Network coding to combat packet loss in underwater networks. In: Proceedings of fifth ACM international workshop on underwater networks (WUWNet), Woods Hole, MA, USA
Lucani DE, Médard M, Stojanovic M (2007) Network coding schemes for underwater networks: the benefits of implicit acknowledgement. In: Proceedings of WUWNet 07, ACM, Montreal, QC, Canada, pp 25–32
Chirdchoo N, Chitre M, Soh W-S (2010) A study on network coding in underwater networks. In: Proceedings of MTS/IEEE Oceans 2010, Seattle, WA, USA, IEEE
Ochiai H, Mitran P, Poor HV, Tarokh V (2005) Collaborative beamforming for distributed wireless ad hoc sensor networks. IEEE Trans Signal Process 53(11):4110–4124
Mudumbai R, Barriac G, Madhow U (2007) On the feasibility of distributed beamforming in wireless networks. IEEE Trans Wireless Commun 6(5):1754–1763
Paul A, van Walree Geert Leus L (2009) Robust underwater telemetry with adaptive turbo multiband equalization. IEEE J Ocean Eng 34(4):645–655
Higley WJ, Roux P, Kuperman WA, Hodgkiss WS, Song HC, Akal T, Stevenson M (2005) Synthetic aperture time‐reversal communications in shallow water: experimental demonstration at sea. J Acoust Soc Am 118(4):2365–2372
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
Copyright information
© 2012 The authors
About this chapter
Cite this chapter
Otnes, R. et al. (2012). Logical Link Layer Topics. In: Underwater Acoustic Networking Techniques. SpringerBriefs in Electrical and Computer Engineering(). Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-25224-2_4
Download citation
DOI: https://doi.org/10.1007/978-3-642-25224-2_4
Published:
Publisher Name: Springer, Berlin, Heidelberg
Print ISBN: 978-3-642-25223-5
Online ISBN: 978-3-642-25224-2
eBook Packages: EngineeringEngineering (R0)