A New Zone Disjoint Multi Path Routing Algorithm to Increase Fault-Tolerant in Mobile Ad Hoc Networks

Abstract

In Mobile Ad-hoc Networks, there is no fixed infrastructure, router and station and so all network operations such as routing are being done with nodes. Some routing algorithms of Mobile Ad-hoc Networks perform routing in a multi-path manner and simultaneously discover and record a number of paths in a path discovery process. In these algorithms, it is possible to s end information to destination concurrently using several paths, in order t o balance the load in the network, increase end to end bandwidth, and decrease delay. In this case, selecting node disjoint paths is one of t he best options because of increasing error tolerability. G iven channel access mechanisms, sending information through completely disjoint paths is not fully independent. To solve the problem, we can use zone disjoint paths rather than node disjoint paths. Two paths are fully zone disjoint ones if none of the nodes in a path is adjacent to the nodes in the other. Methods have been proposed to discover zone disjoint paths; one of them is using directional antennas but these are not available in most of current facilities. The other method is Zone Disjoint Ad-hoc On-demand Multipath Distance (ZD AOMDV) which has high overload while routing and additionally we see the very high delay during path discovery phase. A new method will be proposed in this paper which has been applied in the proposed algorithm Improved Zone Multipath Ad-hoc On- demand Distance Vector (IZM AODV). In the algorithm, it is possible to discover zone disjoint paths using typical, omnidirectional antennas with minimum overload and delay in path discovery phase. In addition, these paths are used to send information concurrently. The proposed algorithm has been simulated in different scenarios using NS2 software and it has been examined and compared with multipath algorithms (AOMDV and ZD AOMDV) and basic algorithm (AODV). Routing overloads, sending packets successfully, and end to end delays have been improved compared to existing methods.