Integration of physical phenomena into an experiment-based propagation model

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Integration of physical phenomena into an experiment-based propagation model

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International Workshop on Modeling Analysis and Simulation of Wireless and Mobile Systems archive
Proceedings of the 3rd ACM international workshop on Performance evaluation of wireless ad hoc, sensor and ubiquitous networks table of contents

Terromolinos, Spain

SESSION: Service, mobility, topology, channel modeling table of contents

Pages: 98 - 105

Year of Publication: 2006

ISBN:1-59593-487-1

Authors

Dominique Dhoutaut	Laboratoire d'informatique de l'Université de Franche-Comté, Montbéliard, France
Anthony Régis	Laboratoire d'informatique de l'Université de Franche-Comté, Montbéliard, France
François Spies	Laboratoire d'informatique de l'Université de Franche-Comté, Montbéliard, France

Sponsors

ACM: Association for Computing Machinery
SIGSIM: ACM Special Interest Group on Simulation and Modeling

Publisher

ACM New York, NY, USA

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ABSTRACT

Ad hoc networks heavily rely on simulations to develop and test new protocols or applications. Impact of radio propagation models is often neglected. Simulated losses consequently exhibit relatively simple behaviors whereas they are in reality tied to obstacles, mobility and external interference sources. Moreover, the way losses do appear in multi-hop ad hoc networks has great and complex effects on upper layer protocols. Using characterization of losses in real world experimentations, we propose a propagation model called shadowing-pattern which aims at providing more reality-like losses. Finally we highlight the effects of our new model on multi-hop scenarios

REFERENCES

Note: OCR errors may be found in this Reference List extracted from the full text article. ACM has opted to expose the complete List rather than only correct and linked references.

	1	Belur V. Dasarathy. Nearest neighbor (NN) Norms: NN pattern classification techniques IEEE Computer Society Press, 1991.
	2	Network simulator 2, http://www.isi.edu/nsnam/ns/.
	3	Qualnet, http://www.qualnet.com.
	4	Opnet modeler, http://www.mil3.com.
	5	Global Mobile Information Systems Simulation Library (GloMoSim), http://pcl.cs.ucla.edu/projects/glomosim/.
	6	Füsun Özgüner,ümit Özgüner, Oscar Takeshita, Keith Redmill, Yiting Liu, and GÖkhan Korkmaz. A simulation study of an intersection collision warning system. In Proceedings of the International workshop on ITS Telecommunications Singapore, june 2004.
	7	H. T. Friis. A note on a simple transmission formula. Proc. IRE 34, 1946.
	8	Illya Stepanov, Daniel Herrscher, and Kurt Rothermel. On the impact of radio propagation models on manet simulation results. In Proceedings of the 7th IFIP International Conference on Mobile and Wireless Communication Networks (MWCN 2005) Marrakech, Morocco, september 2005.
	9	G. de la Roche, R. Rebeyrotte, Katia Runser, and Jean-Marie Gorce. A new strategy for indoor propagation fast computation with mr-fdpf algorithm. In IASTED International Conference on Antennas, Radar and Wave Propagation (ARP) Banff, Alberta, Canada, July 2005.
	10	Nicolas Eude, Bertrand Ducourthial, and Mohamed Shawsky. Enhancing ns-2 simulator for high mobility ad hoc networks in car-to-car communication context. In Proceedings of the 7th IFIP International Conference on Mobile and Wireless Communications Networks (MWCN 2005) Morocco, september 2005.
	11	Syed A. Khayam, S. Karande, Hayder Radha, and D. Loguinov. Performance analysis and modeling of errors and losses over 802.11b lans for high-bitrate real-time multimedia. In Signal processing: Image Communication volume 18, no. 7, pages 575--595, San Diego, 2003.
	12	Almudena Konrad , Ben Y. Zhao , Anthony D. Joseph , Reiner Ludwig, A Markov-based channel model algorithm for wireless networks, Proceedings of the 4th ACM international workshop on Modeling, analysis and simulation of wireless and mobile systems, p.28-36, July 2001, Rome, Italy [doi>10.1145/381591.381602]
	13	Syed A. Khayam , Hayder Radha, Markov-based modeling of wireless local area networks, Proceedings of the 6th ACM international workshop on Modeling analysis and simulation of wireless and mobile systems, September 19-19, 2003, San Diego, CA, USA [doi>10.1145/940991.941009]
	14	Chiping Tang , Philip K. McKinley, Modeling multicast packet losses in wireless LANs, Proceedings of the 6th ACM international workshop on Modeling analysis and simulation of wireless and mobile systems, September 19-19, 2003, San Diego, CA, USA [doi>10.1145/940991.941015]