Fuzzy Based Priority Ad Hoc on Demand Multipath Distance Vector Stable Routing Protocol
Fuzzy Based Priority Ad Hoc on Demand Multipath Distance Vector Stable Routing Protocol |
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| © 2022 by IJETT Journal | ||
| Volume-70 Issue-2 |
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| Year of Publication : 2022 | ||
| Authors : Swati Atri, Sanjay Tyagi |
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| DOI : 10.14445/22315381/IJETT-V70I2P237 | ||
How to Cite?
Swati Atri, Sanjay Tyagi, "Fuzzy Based Priority Ad Hoc on Demand Multipath Distance Vector Stable Routing Protocol," International Journal of Engineering Trends and Technology, vol. 70, no. 3, pp. 327-333, 2022. Crossref, https://doi.org/10.14445/22315381/IJETT-V70I2P237
Abstract
Mobile ad-hoc networks are the most uncertain type of network. Uncertainty occurs due to the mobile nature of the nodes; continuous consumption of energy and bandwidth results in an unpredictable state of nodes. In this situation, making an efficient, reliable and stable route selection is a challenging task and an open research problem aiming to provide continuous and consistent transfer of data among the source and the destination node. Multipath routing protocol ensures reliable communication by providing multiple paths between source and destination nodes. Choosing the best one among different alternative paths is the problem addressed by this paper. For this purpose, fuzzy logic (multi-valued logic) has been used. Fuzzy logic is a soft computing technique that is able to make precise and accurate decisions in multivariable, uncertain and imprecise situations. Here, firstly Multipath Priority Based Route Discovery Mechanism (MPRDM) has been used to generate multiple paths between the two nodes participating in the communication. MPRDM calculates the individual priority value for every RREP packet and assigns it to the different obtained routes. Further, in this paper, fuzzy logic has been used for designing fuzzy route selection controller for the Fuzzy Logic Based Stable Route Selection mechanism (FLSRSM), which calculates the stability value of different routes based on priority value, average mobility and residual energy along the paths FLSRSM is able to make a selection of best stable path based on the highest value of stability metric. This mechanism has been used to propose fuzzy-based priority ad-hoc on-demand multipath distance vector stable routing protocol (FPAOMDV) that provide stability reliability and selects the route that has a sufficient amount of energy to hold continuous data transfer. In Simulation results on NS2, the proposed protocol outperforms other compared routing protocols in terms of delay, throughput, PDR and overhead.
Keywords
Fuzzy Logic, Multi-path, Networks, Priority, Soft Computing, Route Discovery, Stability.
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