Abstract
Vehicular ad-hoc networks (VANETs) are highly mobile wireless ad hoc networks for vehicular safety and other commercial applications, whereby vehicles move non-randomly along roads while exchanging information with other vehicles and roadside infrastructures. Inter-vehicle communication (IVC) is achieved wirelessly using multihop communication, without access to fixed infrastructure. Rapid movement and frequent topology changes cause repeated link breakages, increasing the packet loss rate. Geographical routing protocols are suitable for VANETs. However, they select the node nearest to the destination node as a relay node within the transmission range, increasing the possibility of a local maximum and link loss because of high mobility and urban road characteristics. We propose a grid-based predictive geographical routing (GPGR) protocol, which overcomes these problems. GPGR uses map data to generate a road grid and to predict the moving position during the relay node selection process. GPGR divides roads into two-dimensional road grids and considers every possible node movement. By restricting the position prediction in the road grid sequence, GPGR can predict the next position of nodes and select the optimal relay node. Simulation results using ns-2 demonstrated performance improvements in terms of local maximum probability, packet delivery rate, and link breakage rate.
Highlights
Vehicular ad-hoc networks (VANETs) is a research field that is attracting growing attention
VANET has unique characteristics compared with MANET such as high node mobility and a rapidly changing network topology compared to mobile ad hoc network (MANET)
This paper presented a grid-based predictive geographical routing (GPGR) protocol for urban VANETs
Summary
VANET is a research field that is attracting growing attention. VANET provides both vehicle-to-infrastructure (V2I) communication and vehicle-to-vehicle (V2V) communication. Vehicle movements are constrained by roads, so GPSR that fails to consider urban environment characteristics is not suitable for VANET [3]. To solve this problem, greedy perimeter coordinator routing (GPCR) [5] and greedy perimeter urban routing (GPUR) [6] have been proposed as possible solutions. We assume that each vehicle knows its location by GPS, as with most related geographic routing protocols, and it uses a grid-based street map for road information. Our target was to improve the routing protocol for IVC, based on vehicle movement information including the position, direction, and velocity on the grid sequence.
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