Abstract
Vehicular ad hoc networks (VANETs) enable the timely broadcast dissemination of event-driven messages to interested vehicles. Especially when dealing with broadcast communication, data dissemination protocols must achieve a high degree of scalability due to frequent deviations in the network density. In dense networks, suppression techniques are designed to prevent the so-called broadcast storm problem. In sparse networks, protocols incorporate store-carry-forward mechanisms to take advantage of the mobility of vehicles to store and relay messages until a new opportunity for dissemination emerges. Despite numerous efforts, most related works focus on either highway or urban scenarios, but not both. Highways are mostly addressed with a single directional dissemination. For urban scenarios, protocols mostly concentrate on either using infrastructure or developing methods for selecting vehicles to perform the store-carry-forward task. In both cases, dense networks are dealt with suppression techniques that are not optimal for multi-directional dissemination. To fill this gap, we present an infrastructure-less protocol that combines a generalized time slot scheme based on directional sectors and a store-carry-forward algorithm to support multi-directional data dissemination. By means of simulations, we show that our protocol scales properly in various network densities in both realistic highway and urban scenarios. Most importantly, it outperforms state-of-the-art protocols in terms of delivery ratio, end-to-end delay, and number of transmissions. Compared to these solutions, our protocol presents up to seven times lower number of transmissions in dense highway scenarios.
Highlights
Vehicular ad hoc networks (VANETs) are expected to serve as support to the development of a wide range of applications related to safety, transport efficiency, and even infotainment [1]
Setting an unbounded value for the number of entries k is obviously unadvisable, we evaluate the total overhead when the maximum list size possible is allowed for each network density
Adaptive Multi-directional data Dissemination (AMD) combines a generalized time slot scheme based on directional sectors and a storecarry-forward algorithm to support multi-directional data dissemination
Summary
Vehicular ad hoc networks (VANETs) are expected to serve as support to the development of a wide range of applications related to safety, transport efficiency, and even infotainment [1]. Time slot density control : to cope with dense networks, we propose a time slot suppression scheme, where the final goal is to select only the farthest vehicles in each direction considered for dissemination This time slot assignment is done by following our solution previously presented in [4], where we exploit positioning information of one-hop neighbors to control with precision the time slots’ density. Our focus is rather on evaluating the new aspects of generalizing our approach to a multi-directional dissemination in both highway and urban scenarios In this line, one potential source of error lies in the estimation of the number of directional sectors whenever the required mapping information is inaccurate or unavailable. We elaborate further on these consequences later in the performance evaluation section
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