Volume 9 , Issue 2 , PP: 120-129, 2023 | Cite this article as | XML | Html | PDF | Full Length Article
Firas Abedi 1 * , Osama Yaseen M. Al-Rawi 2 , H. R. Alkhayyat 3 , Rabei Raad Ali 4 , Mohammed Almohamadi 5 , Fatima Hashim Abbas 6 , Wisam Subhi Al-Dayyeni 7
Doi: https://doi.org/10.54216/JISIoT.090209
Vehicular ad-hoc network (VANETs) is a promising technology that is used in the maximum of the applications of intelligent transport systems (ITS). VANETs become more attractive due to their communication methods such as vehicle-to-vehicle (V2V) and vehicle-to-roadside unit (RSU) communication. VANETs consist of a few special features such as unpredictable mobility, dynamic inter-vehicle spacing, high speed and so on which make communication ineffective. These features network delay and routing overhead increased which affects the stability and reliability of the network. In this paper Path Scheduling and Bandwidth Utilization for VANETs (PSBU-VANETs) are proposed. Through the path scheduling process, the changing topologies are predicted that the prediction path is scheduled for data transmission which leads to reduce the delay and overhead of the network. Through the effective utilization of bandwidth, the throughput and delivery rate of the network are increased. The simulation is performed in NS2 and SUMO and to measure the outcome the parameters which are considered are packet delivery ratio, end-to-end delay, routing overhead, and throughput. To perform a comparative analysis the results of the proposed PSBU-VANETs are compared with the earlier research works such as TDG-VANETs and ICB-VANETs. The proposed PSBU-VANETs achieve a high packet delivery ratio and throughput as well as lower end-to-end delay and routing overhead when compared with the earlier approaches.
vehicular ad-hoc network , intelligent transport system , vehicle-to-vehicle , and vehicle-to-road side unit.
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