Abstract
The Internet of Things (IoT) has eventually evolved into a more promising service provisioning paradigm, namely, Social Internet of Things (SIoT). Social Internet of Vehicles (SIoV) symbolizes a multitude of components from the existing Vehicular Ad-Hoc Networks (VANETs) such as OBUs, RSUs, and cloud devices that necessitate energy for proper functioning. It is speculated that the connected devices will surpass the 40 billion mark in the year 2022 in which the devices related to ITS will constitute a significant part. Therefore, the ever-increasing number of components increases the communication hopping that results in the immense escalation of energy consumption. However, the energy consumption at the object level increases due to individual communication, storage, and processing capabilities. The existing research in SIoV is focused on providing state-of-the-art services and applications; however, a significant goal of energy efficiency is largely ignored. Therefore, extensive research needs to be performed to come up with an energy-efficient framework for a scalable SIoV system to meet the future requirements of ITS. Consequently, this study proposed, simulated, and evaluated an energy-aware efficient deployment of RSUs scheme. The proposed scheme is based on network energy, data acquisition energy, and data processing energy. To achieve efficiency in terms of energy, traveling salesman problem with ant colony optimization algorithm are utilized. The experiments are performed in an urban scenario with different numbers of RSUs. The outcomes of the experiments exhibited promising results in energy gain and energy consumption having implications for society and consumers at large.
Highlights
Vehicular Ad-Hoc Networks (VANETs) [1] deploy vehicle to vehicle (V2V) and vehicle to infrastructure (V2I) communication to facilitate a wide range of applications Such as safety, navigation, routing, emergency healthcare, and infotainment
The advancements in network technology and the use of the internet allows the researchers to conceptualize the Internet of Vehicles (IoV) to develop applications that were not possible in traditional VANETs due to lack of all-time connectivity and unavailability of the internet [3]
IoV allows each network object to connect to the internet; making it possible for potentially all OBUs, RSUs, and network users to share information resulting in a saleable communication environment
Summary
VANETs [1] deploy vehicle to vehicle (V2V) and vehicle to infrastructure (V2I) communication to facilitate a wide range of applications Such as safety, navigation, routing, emergency healthcare, and infotainment. These applications are developed using VANETs due to the ability of VANETs to handle different topologies and management of continuously changing network densities. The effective utilization of VANETs is essential due to encouraging possible applications that includes both V2I and V2V communications Both V2I and V2V communications are established in urban, suburban and highway environments with a wide range of specific topological features [2]. IoV allows each network object to connect to the internet; making it possible for potentially all OBUs, RSUs, and network users (passenger and drivers etc.) to share information resulting in a saleable communication environment
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