Abstract

The rapid development and integration of connected and autonomous vehicle (CAV) networks into modern transportation infrastructures have ushered in a new era of intelligent traffic management. Leveraging the capabilities of artificial intelligence (AI) for real-time traffic management within these networks presents a promising avenue for reducing traffic congestion, optimizing vehicle routing, and responding to incidents with greater efficiency. This research investigates the development and application of advanced machine learning (ML) models to address three key challenges in CAV networks: traffic prediction, route optimization, and incident response. The overarching objective is to enhance the efficiency, safety, and responsiveness of urban and highway traffic systems, particularly as CAV networks become increasingly prevalent.

Central to this study is the use of AI-driven predictive models that forecast traffic patterns based on a variety of data inputs, including real-time vehicle telemetry, historical traffic data, environmental conditions, and external factors such as weather or road infrastructure changes. These models, primarily driven by deep learning techniques, recurrent neural networks (RNNs), and reinforcement learning (RL) algorithms, allow for dynamic predictions of traffic congestion and flow patterns. Accurate traffic prediction in real-time enables preemptive measures, facilitating smoother traffic flow and reducing bottlenecks, particularly in high-density urban areas and critical traffic corridors. This research also examines the adaptability of AI models in the face of unforeseen disruptions, such as accidents or road closures, demonstrating their capacity to improve situational awareness and expedite decision-making.

In addition to traffic prediction, the study delves into AI-enhanced route optimization. Route planning for CAVs requires a highly complex and adaptive framework that accounts for real-time data, predictive traffic patterns, and individual vehicle characteristics such as fuel efficiency and destination. The proposed AI-based optimization techniques, including heuristic algorithms, genetic algorithms, and optimization-driven deep reinforcement learning (DRL), are designed to provide CAVs with the most efficient and safe routes, minimizing travel time and fuel consumption. This capability is particularly critical in large-scale CAV networks where the cumulative effects of route inefficiencies can contribute to substantial delays, increased fuel consumption, and heightened accident risks.

Moreover, AI can significantly improve incident response strategies within CAV networks by automating the identification and management of traffic incidents in real-time. This involves the development of sophisticated algorithms capable of detecting abnormal traffic patterns, such as sudden decelerations or lane obstructions, and coordinating a rapid, system-wide response to minimize the disruption. AI-powered decision-making systems, using deep reinforcement learning and multi-agent systems, provide an autonomous mechanism for rerouting vehicles around incidents, notifying emergency services, and adjusting traffic signals or road use policies to restore traffic flow swiftly and safely. Such systems are instrumental in reducing the frequency and impact of secondary accidents, thereby contributing to the overall safety and reliability of CAV networks.

The research also highlights the integration of connected vehicle (CV) technologies, which enable seamless communication between vehicles and infrastructure, further enhancing the effectiveness of AI-driven traffic management systems. Vehicle-to-vehicle (V2V) and vehicle-to-infrastructure (V2I) communication protocols allow for the sharing of critical data across the network, providing a holistic view of traffic conditions and enabling coordinated, large-scale interventions. Through AI, CAVs and traffic management systems can collaboratively respond to dynamic conditions, proactively manage traffic flows, and reduce response times to incidents, ultimately leading to safer and more efficient transportation networks.

To substantiate the effectiveness of these AI-based approaches, this paper will present case studies and simulations based on real-world data from urban traffic networks and CAV testbeds. These studies demonstrate the tangible benefits of AI in reducing travel times, improving fuel efficiency, and enhancing the overall safety of CAV networks. Furthermore, the research addresses the technical challenges associated with deploying AI in real-time environments, including the computational complexity of large-scale CAV networks, the need for high-speed data processing, and the reliability of predictive models under varying traffic conditions. Solutions to these challenges are explored through advancements in edge computing, distributed AI systems, and the incorporation of advanced communication technologies such as 5G, which enable real-time data processing and high-speed communication between vehicles and infrastructure.