Abstract
We analyze the asymptotic cost of discovering a route within a flat ad hoc network and we show that one can discover a route with cost that is proportional only to the area of the network, which is independent of the number of network nodes. Furthermore, we show that this is optimal and that bordercasting (a query propagation protocol where a node retransmits a query to a set of nodes at some hop-distance away) possesses this density-independence property. We present the design of bordercast and the associated maintenance protocols, and we evaluate their performance. In particular, we highlight that the aggregation of local information by bordercasting at each network node is a fundamental building block for the construction of scalable protocols in flat ad hoc networks.
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Notes
The results are not expected to be significantly different for other transport-layer protocols.
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Acknowledgments
The work on this project was supported in part by the U.S. National Science Foundation under the grant numbers ANI-0329905 and CNS-0626751, by the DoD MURI (Multidisciplinary University Research Initiative) Program administered by the Office of Naval Research (ONR) under contract N00014-00-1-0564, and by the MURI Program administered by the Air Force Office of Scientific Research (AFOSR) under contract F49620-02-1-0217. The authors thank Robbert van Renesse, Benjamin Atkin, and Chaitanya Swamy for their ongoing help and valuable suggestions regarding this work. We also acknowledge Kelwin Tamtoro, Clifton Lin, Ben Viglietta, and Mark Fong for their work on various SWANS and JiST components. We are indebted to Alin Dobra and Paul Francis for allowing us to use their computational resources to run simulations.
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Haas, Z.J., Barr, R. Density-Independent, Scalable Search in Ad Hoc Networks. Int J Wireless Inf Networks 14, 93–105 (2007). https://doi.org/10.1007/s10776-006-0055-9
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DOI: https://doi.org/10.1007/s10776-006-0055-9