Power-aware routing in mobile ad hoc networks
MobiCom '98 Proceedings of the 4th annual ACM/IEEE international conference on Mobile computing and networking
PAMAS—power aware multi-access protocol with signalling for ad hoc networks
ACM SIGCOMM Computer Communication Review
Routing Mechanisms for Mobile Ad Hoc Networks Based on the Energy Drain Rate
IEEE Transactions on Mobile Computing
A prioritized battery-aware routing protocol for wireless ad hoc networks
MSWiM '05 Proceedings of the 8th ACM international symposium on Modeling, analysis and simulation of wireless and mobile systems
An Adaptive Quorum-Based Energy Conserving Protocol for IEEE 802.11 Ad Hoc Networks
IEEE Transactions on Mobile Computing
Mitigating the FloodingWaves Problem in Energy-Efficient Routing for MANETs
ICDCS '06 Proceedings of the 26th IEEE International Conference on Distributed Computing Systems
DSD '06 Proceedings of the 9th EUROMICRO Conference on Digital System Design
Performance Analysis of DSR & Extended DSR Protocols
AMS '08 Proceedings of the 2008 Second Asia International Conference on Modelling & Simulation (AMS)
Maximum battery life routing to support ubiquitous mobile computing in wireless ad hoc networks
IEEE Communications Magazine
Parallel approach of a bioinspired routing protocol for MANETs
International Journal of Ad Hoc and Ubiquitous Computing
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Mobile Ad Hoc Network (MANET) is a decentralised network, which consists of mobile nodes. In this paper, we propose an efficient routing algorithm for the MANETs. Here, we use two metrics namely minimum total transmission power and network connectivity over the network. The proposed work has been simulated using.Net and has compared with the existing algorithms such as DSR, Minimum Total Transmission Power Routing (MTPR) and Min-Max Battery Cost Routing (MMBCR). The simulation results have proved that the proposed model has reached at top position in terms of the number of nodes with zero-remaining energy and throughput. If the mobility of the node is 25 m/s, then the proposed model, MTPR model, MMBCR model and AODV model have transmitted 68%, 50%, 59% and 62% of the data packets, respectively. At 700 s, the number of nodes with zero-remaining energy in the proposed model is 5, whereas in the AODV model, MTPR model and MMBCR model the number of nodes with zero-remaining energy was 39, 22 and 7, respectively.