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CARD: A Contact-based Architecture for Resource Discovery in Wireless Ad Hoc Networks

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Abstract

Traditional protocols for routing in ad hoc networks attempt to obtain optimal or shortest paths, and in doing so may incur significant route discovery overhead. Such approaches may be appropriate for routing long-lived transfers where the initial cost of route discovery may be amortized over the life of the connection. For short-lived connections, however, such as resource discovery and small transfers, traditional shortest path approaches may be quite inefficient. In this paper we propose a novel architecture, CARD, for resource discovery in large-scale wireless ad hoc networks. Our mechanism is suitable for resource discovery as well as routing very small data transfers or transactions in which the cost of data transfer is much smaller than the cost of route discovery. Our architecture avoids expensive mechanisms such as global flooding and complex hierarchy formation and does not require any location information. In CARD resources within the vicinity of a node, up to a limited number of hops, are discovered using a proactive scheme. For resources beyond the vicinity, each node maintains a few distant nodes called contacts. Contacts help in creating a small world in the network and provide an efficient way to query for distant resources. Using contacts, the network view (or reachability) of the nodes increases, reducing the discovery overhead and increasing the success rate. On the other hand, increasing the number of contacts also increases control overhead. We study such trade-off in depth and present mechanisms for contact selection and maintenance that attempt to increase reachability with reduced overhead. Our schemes adapt gracefully to network dynamics and mobility using soft-state periodic mechanisms to validate and recover paths to contacts. Our simulation results show that CARD is scalable and can be configured to provide desirable performance for various network sizes. Comparisons with other schemes show overhead savings reaching over 93% (vs. flooding) and 80% (vs. bordercasting or zone routing) for high query rates in large-scale networks.

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References

  1. L. Breslau, D. Estrin, K. Fall, S. Floyd, J. Heidemann, A. Helmy, P. Huang, S. McCanne, K. Varadhan, Y. Xu and H. Yu, Advances in network simulation, IEEE Computer (May 2000).

  2. T.-W. Chen and M. Gerla, Global state routing: A new routing scheme for ad-hoc wireless networks, in: Proc. of the IEEE Internat. Conf. on Communications (ICC) (1998).

  3. C.-C. Chiang, Routing in clustered multihop, mobile wireless networks with fading channel, in: Proc. of IEEE SICON'97 (April 1997).

  4. T. Clausen, P. Jacquet, A. Laouiti, P. Muhlethaler, A. Qayyum and L. Viennot, Optimized link state routing protocol, in: Proc. of IEEE INMIC (2001).

  5. Z. Haas and M. Pearlman, The zone routing protocol (ZRP) for ad hoc networks, IETF Internet draft for the Manet group (June 1999).

  6. W. Heinzelman, J. Kulik and H. Balakrishnan, Adaptive protocols for information dissemination in wireless sensor networks, in: The ACM MOBICOM Conf., Seattle, WA (August 1999).

  7. A. Helmy, Architectural framework for large-scale multicast in mobile ad hoc networks, IEEE Internat. Conf. on Communications (ICC), Vol. 4, New York (April 2002) pp. 2036–2042.

    Google Scholar 

  8. A. Helmy, Small worlds in wireless networks, IEEE Communications Letters 7(10) (2003) 490–492.

    Google Scholar 

  9. A. Helmy, Mobility-assisted resolution of queries in large-scale mobile sensor networks (MARQ), Computer Networks (Special Issue on Wireless Sensor Networks) 43(4) (2003) 437–458.

    Google Scholar 

  10. A. Helmy, TRANSFER: Transactions routing for ad-hoc networks with efficient energy, in: IEEE Global Communications Conf. (GLOBE-COM) (December 2003).

  11. A. Helmy, S. Garg, P. Pamu and N. Nahata, Contact-based architecture for resource discovery (CARD) in large scale MANets, in: IEEE/ACM IPDPS Internat. Workshop on Wireless, Mobile and Ad Hoc Networks (WMAN) (April 2003) pp. 219–227.

  12. C. Intanagonwiwat, R. Govindan and D. Estrin, Directed diffusion: A scalable and robust communication paradigm for sensor networks, in: ACM MobiCOM Conf. (August 2000).

  13. D.B. Johnson and D.A. Maltz, The dynamic source routing protocol for mobile ad hoc networks, IETF Internet draft (October 1999).

  14. J. Li, J. Jannotti, D. Couto, D. Karger and R. Morris, A scalable location service for geographic ad hoc routing, in: The ACM MOBICOM Conf. (2000).

  15. J. Liu, Q. Zhang, W. Zhu, J. Zhang and B. Li, A novel framework for QoS-aware resource discovery in MANets, in: IEEE Internat. Conf. on Communications (ICC) (May 2002).

  16. W. Lou and J. Wu, On reducing broadcast redundancy in ad hoc wireless networks, IEEE Transactions on Mobile Computing 1(2) (2002).

  17. M. Mitzenmacher, Compressed bloom filters, in: The Twentieth ACM Symposium on Principles of Distributed Computing (PODC) (August 2001).

  18. S. Murthy and J.J. Garcia-Luna-Aceves, An efficient routing protocol for wireless networks, Mobile Networks and Applications (Special Issue on Routing in Mobile Communication Networks) (October 1996).

  19. S. Ni, Y. Tseng, Y. Chen and J. Sheu, The broadcast Storm problem in a mobile ad hoc network, in: Proc. of the ACM MOBICOM Conf. (August 1999) pp. 151–162.

  20. M. Pearlman and Z. Haas, Determining the optimal configuration for the zone routing protocol, IEEE Journal on Selected Areas in Communications 8 (1999) 1395–1414.

    Google Scholar 

  21. C.E. Perkins and P. Bhagwat, Highly dynamic destination-sequenced distance-vector routing (DSDV) for mobile computers, ACMComputer Communications Review (October 1994) 234–244.

  22. C.E. Perkins, E.M. Royer and S.R. Das, Ad hoc on-demand distance vector routing, IETF Internet draft (October 1999).

  23. N. Sadagopan, B. Krishnamachari and A. Helmy, Active query forwarding in sensor networks (ACQUIRE), Ad Hoc Networks Journal (2004) to appear.

  24. N. Sadagopan, B. Krishnamachari and A. Helmy, The ACQUIRE mechanism for efficient querying in sensor networks, in: First IEEE Internat. Workshop on Sensor Network Protocols and Applications (SNPA), in conjunction with IEEE ICC, Anchorage (May 2003) pp. 149–155.

  25. S. Wang and A. Helmy, Effects of small transfers and traffic patterns on performance and cache efficacy of ad hoc routing, (poster), in: The ACM MOBICOM Conf. (The Ninth Annual Internat. Conf. on Mobile Computing and Networking), San Diego, CA (September 2003).

  26. D.J. Watts, The dynamics of networks between order and randomness, in: Small Worlds (Princeton Univ. Press, Princeton, 1999).

    Google Scholar 

  27. D. Watts and S. Strogatz, Collective dynamics of 'small-world' networks, Nature 393 (4 June 1998).

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Authors and Affiliations

  1. Electrical Engineering Department, University of Southern California, 3740 McClintock Avenue, EEB 232, Los Angeles, CA, 90089-2562, USA

    Ahmed Helmy, Saurabh Garg & Nitin Nahata

  2. Computer Science Department, University of Southern California, Los Angeles, CA, 90089-2562, USA

    Priyatham Pamu

Authors
  1. Ahmed Helmy
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  2. Saurabh Garg
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  3. Nitin Nahata
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  4. Priyatham Pamu
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Helmy, A., Garg, S., Nahata, N. et al. CARD: A Contact-based Architecture for Resource Discovery in Wireless Ad Hoc Networks. Mobile Networks and Applications 10, 99–113 (2005). https://doi.org/10.1023/B:MONE.0000048549.15371.53

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  • DOI: https://doi.org/10.1023/B:MONE.0000048549.15371.53

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