Journal of Mobile Computing, Communications & Mobile Networks

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The reactive routing protocols got much significance because of their low storage requirements and high mobility. In this paper, three routing protocols AODV, DSR and DYMO are analyzed and simulation results evaluated on grid-based routing have been presented and compared by using QualNet simulator on the basis of performance metrics such as throughput, average jitter, average end-to-end delay, signals transmitted and ACK packets sent. The grids are distributed that tracks mobile node location in ad-hoc networks. Grid-based routing protocol uses reactive mechanisms to build routing paths. In addition, the grid partitioning of a network naturally aggregates nodes into non-overlapping grid cells. The mobile network can be modeled as a fixed pattern network of occupied grid cells. The grid cells do not move but may change their state between “on” and “off” according to their occupancy. The occupancy of a grid cell depends on not the mobility of nodes but the density of nodes.

Ad-hoc network, MANET, grid, AODV, DSR, DYMO

Jayakumar G, Gopinath G. Performance comparison of MANET protocol based on Manhattan grid model. Journal of Mobile Communications. 2008; 2(1): 18–26p.

Shah S, et al. Performance evaluation of ad-hoc routing protocols using NS-2 simulation. Conf. of Mobile and Pervasive Computing. 2008.

Sham-ul-Arfeen, et al. Performance evaluation of MANET routing protocols using scenario based mobility models. Innovative Algorithms and Techniques in Automation, Industrial Electronics and Telecommunications. Springer; 2007; 419–24p.

Joa-Ng M, Lu I.-T. A peer-to-peer zone based two level link state routing for mobile ad hoc networks. IEEE Journal on Selected Areas in Communications. 1999; 17(8): 1415–25p.

Amir A, Armstrong J, Berstis V, et al. Introduction to grid computing with globus. IBM Redbook. October 1, 2002. Retrieved September 24, 2004, from http://publib-b. Boulder. Ibm.com/abstracts/sg246895.htm?open.

Hieu C, Kim D, Hong C, et al. On-demand multi-path balancing in wireless mesh networks. International Conference on Information Networking. 2009; ICOLN. Issue Date: 21–24.

Broch J, Johnson D, Maltz D. Dynamic source routing protocol for mobile ad hoc networks. IETF Internet Draft. 2004.

Charles E, Belding-Royer E, Chakeres I. Ad-hoc on-demand distance vector routing. IETF Internet Draft. 2003.

Perkins C, Royer EB, Das S. Ad hoc on-demand distance vector (AODV) routing. IETF Internet Draft. 2003

Renato M. de Moraes, Hamid R. Sadjadpour, Garcia-Luna-Aceves JJ. Throughput Delay Analysis of Mobile Ad

hoc Networks with a Multi copy Relaying Strategy. Jan 2005.

Mobile AdHoc Networking Working Group-AODV. http://www.ietf.org/rfc/rfc3561.txt

David BJ, David AM. Dynamic Source Routing in Adhoc Wireless Networks. Kluwer Academic Publishers. 1996; 5: 153–81p.

Siva Ram C, Murthy BS Manoj. Adhoc Wireless Networks, Architectures and Protocols. 2004.

Thaper Vivek, Jain Bindyia, Sahni Varsha. Performance analysis of adhoc routing protocols using random waypoint mobility model in wireless sensor networks. International Journal on Computer Science and Engineering (IJCSE). August 2011; 3(8): 3059–60p. (ISSN:0975-3397).

Chakeres, CenGen, WiChorus, et al. Dynamic MANET on-demand (DYMO) routing [z]. Internet Progress. July 26, 2010.

Budhiraja Archie, Garg Roopali. Performance comparison of dynamic mobile ad hoc network on-demand multipath routing protocol with AODV. International Journal of Scientific & Engineering Research. November-2011; 2(11): 9p. (ISSN 2229-5518).

QualNet documentation. QualNet 6.1 Model Library: Advanced Wireless.