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Smart city article details
| Title | Smart Energy Management Using Vehicle-To-Vehicle And Vehicle-To-Everything |
|---|---|
| ID_Doc | 50836 |
| Authors | Hira S.; Hira S. |
| Year | 2024 |
| Published | Artificial Intelligence-Empowered Modern Electric Vehicles in Smart Grid Systems: Fundamentals, Technologies, and Solutions |
| DOI | http://dx.doi.org/10.1016/B978-0-443-23814-7.00010-9 |
| Abstract | This chapter explores the potential of vehicle-to-vehicle (V2V) communication to enable smarter energy management in transportation systems. It provides technical overview of V2V protocols and architecture that allow real-time data exchange between vehicles to optimize energy use. Through case studies, the chapter demonstrates V2V communication’s role in facilitating cooperative algorithms and intelligent decision-making among vehicles to improve traffic flow, reduce congestion, and enhance fuel efficiency. Case studies also validate feasibility of leveraging V2V and vehicle-to-everything (V2X) communication for electric vehicle (EV) charging coordination and smart city energy optimization, while revealing real-world implementation challenges. Key factors such as communication infrastructure, cybersecurity, privacy, and regulations associated with V2V adoption are discussed. The chapter offers insights for stakeholders to harness V2V communication in creating efficient, sustainable transportation energy ecosystems. It serves as a catalyst for reimagining energy management leveraging V2V communication. Several practical case studies are presented to validate the feasibility of leveraging V2V and V2X communication for smarter energy management. A case study analyzing V2V and vehicle-to-infrastructure (V2I) communication for EVs in Khobar, Saudi Arabia, found that continuous data exchange between EVs and charging stations could enable dynamic coordination of charging slots based on availability and battery levels. However, challenges such as network congestion must be addressed, especially as EV adoption increases. Additional case studies showcase how V2X-enabled smart city energy management allows EVs to charge during renewable energy surplus and discharge power to the grid during peak demand as a grid balancing mechanism. The case studies affirm the potential of V2V and V2X communication to enhance energy utilization, efficiency, and sustainability while revealing real-world implementation barriers related to large-scale deployment. The chapter discusses critical factors such as communication infrastructure, cybersecurity, privacy, and regulatory considerations associated with adopting V2V communication for energy management. It offers valuable insights for energy and transportation sector stakeholders into harnessing V2V communication to create smarter, more efficient energy ecosystems. By embracing the concepts in this chapter, organizations can unlock the full potential of V2V communication to shape a more sustainable energy future. “Smart Energy Management” serves as a catalyst for reimagining energy management processes and leveraging the power of V2V communication to shape a greener and more efficient future. © 2024 by Elsevier Inc. All rights reserved, including those for text and data mining, AI training, and similar technologies. |
| Author Keywords | energy efficiency; energy optimization; fuel efficiency; smart energy management; Smart energy management, V2V communication, energy optimization, traffic flow, fuel efficiency, sustainability, energy efficiency; sustainability; traffic flow; V2V communication |
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