Authors: Laurent Enel, Franck Guillem

Abstract:

This paper considers the benefits gained by using an efficient quality of service management such as DiffServ technique to improve the performance of military communications. Low delay and no blockage must be achieved especially for real time tactical data. All traffic flows generated by different applications do not need same bandwidth, same latency, same error ratio and this scalable technique of packet management based on priority levels is analysed. End to end architectures supporting various traffic flows and including lowbandwidth and high-delay HF or SHF military links as well as unprotected Internet sub domains are studied. A tuning of Diffserv parameters is proposed in accordance with different loads of various traffic and different operational situations.

Keywords: Military data networks, Quality of service, Tacticalsystems.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1335388

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 2016

References:

[1] Marek Kwiatkowski, "a concept of differentiated services architecture supporting military oriented quality of service", journal of telecommunications and information technology, fev 2003.
[2] L. Enel, F. X. Arques, "Embedded secured networks simulation", IEEE/IMACS Multiconference on Computational Engineering in Systems Applications (CESA-03), Lille, 9-11 Juillet 2003.
[3] Glenn A. Briceno, D. J. Shyy, Jinglin Wu, "A study of TCP performance for mobile Satcom system over blocking conditions" , IEEE milcom-03, oct 2003.
[4] D.A. Barsaleau, M. Tummala, "Testing of Diffserv parformance over a U.S. navy satellite communication network", IEEE Milcom-04, 2004.
[5] Ch. Alspaugh, A.K. Legaspi, "A violation of order: IP-QoS for tactical traffic", IEEE Milcom-02, 2002.
[6] L. Enel, L. Martinet, "Caractérisation de flux et qualité de service pour systèmes de combat futurs", Annales des télécommunications, N┬░7-8 vol 60, 2005.
[7] J. Hopkins, "The Cooperative Engagement Capability", Apl. Technical Digest, Volume 16, Number 4, 1995.
[8] D.C. Schmidt and al, "Towards adaptive and reflective middleware for network-centric combat systems", CrossTalk, Novembre 2001.
[9] D. G. Kallgreen, J. G. Smaal, "IP unicast/multicast operation over stanag 5066", IEEE Milcom-01, oct 2001.
[10] Committee on Network-Centric Naval Forces, Naval Studies Board, National Research Council, Network-Centric Naval Forces: A Transition Strategy for Enhancing Operational Capabilities, The national academies press, 2000.
[11] L. Enel, F. Guillem, "Application of ATM Network Techniques to New Naval Combat Systems", IEEE/ICTTA-04, Damas, 04/2004.
[12] D. Grossman, "New Terminology and Clarifications for DiffServ", Request for Comment (RFC), N┬░3260, 2002.
[13] H. Schulzrinne and al, "RTP: A Transport Protocol for Real-Time Applications" , Request For Comment (RFC) , N┬░3550, 2003.
[14] P. C. Nolin, "Pursuing Interoperability: The Need for Transatlantic Technological Cohesion", NATO 2006 spring session committee report 071 STC 06 E, 2006.
[15] Li Li, Louise Lamont, "Support real-time interactive session applications over a tactical mobile ad hoc network", IEEE milcom-05, Oct 2005.
[16] Wenjing Lou, Wei Liu, Yuguang Fang, "Spread: improving network security by multipath routing", IEEE milcom-03, Oct 2003.