Keywords
Autonomous Vehicle Fleet Coordination
How to Cite
Abstract
In recent years, the relevance of autonomous vehicles has increased greatly. In combination with the increase in shared mobility services, autonomous vehicles could provide a shift towards more sustainable transport systems. However, typical transport-related fundamental challenges such as scalability, large and sudden demand peaks, regional seasonal variations, and high goals for traffic system efficiency have persisted. To efficiently realize autonomous demand-responsive mobility concepts, research is needed on innovative methods for the coordination of vehicle fleets, introducing new ideas.
The recent advances in computer technology have created applications for machine learning research in many digital platforms, including intelligent and autonomous transportation systems. The classroom implementation of a relatively small-scale demand-responsive autonomous vehicle fleet constitutes a complex optimization problem that can be tackled with a learned agent. Applications at this level have the ability to impact society broadly. In traffic psychology, it has been repeatedly hypothesized that traffic automation would be beneficial. Advancements in this area have great potential in improving road traffic efficiency, safety, and comfort. In addition, the above coordination solutions are generic, with no application-specific requirement for on-road evaluation. In this work, we specifically focus on ML-based techniques to solve the vehicle coordination problem. In a broader sense, we try to answer the generic challenges in autonomous vehicle fleet coordination at microscopic levels, involving the assumptions of autonomy and closed vehicle fleets in urban areas.
References
Tamanampudi, Venkata Mohit. "Automating CI/CD Pipelines with Machine Learning Algorithms: Optimizing Build and Deployment Processes in DevOps Ecosystems." Distributed Learning and Broad Applications in Scientific Research 5 (2019): 810-849.
Pal, Dheeraj Kumar Dukhiram, et al. "AI-Assisted Project Management: Enhancing Decision-Making and Forecasting." Journal of Artificial Intelligence Research 3.2 (2023): 146-171.
Kodete, Chandra Shikhi, et al. "Determining the efficacy of machine learning strategies in quelling cyber security threats: Evidence from selected literatures." Asian Journal of Research in Computer Science 17.8 (2024): 24-33.
Singh, Jaswinder. "The Rise of Synthetic Data: Enhancing AI and Machine Learning Model Training to Address Data Scarcity and Mitigate Privacy Risks." Journal of Artificial Intelligence Research and Applications 1.2 (2021): 292-332.
Alluri, Venkat Rama Raju, et al. "Serverless Computing for DevOps: Practical Use Cases and Performance Analysis." Distributed Learning and Broad Applications in Scientific Research 4 (2018): 158-180.
Machireddy, Jeshwanth Reddy. "Revolutionizing Claims Processing in the Healthcare Industry: The Expanding Role of Automation and AI." Hong Kong Journal of AI and Medicine 2.1 (2022): 10-36.
Tamanampudi, Venkata Mohit. "Autonomous AI Agents for Continuous Deployment Pipelines: Using Machine Learning for Automated Code Testing and Release Management in DevOps." Australian Journal of Machine Learning Research & Applications 3.1 (2023): 557-600.
J. Singh, “How RAG Models are Revolutionizing Question-Answering Systems: Advancing Healthcare, Legal, and Customer Support Domains”, Distrib Learn Broad Appl Sci Res, vol. 5, pp. 850–866, Jul. 2019
S. Kumari, “AI-Enhanced Mobile Platform Optimization: Leveraging Machine Learning for Predictive Maintenance, Performance Tuning, and Security Hardening ”, Cybersecurity & Net. Def. Research, vol. 4, no. 1, pp. 29–49, Aug. 2024
Tamanampudi, Venkata Mohit. "Leveraging Machine Learning for Dynamic Resource Allocation in DevOps: A Scalable Approach to Managing Microservices Architectures." Journal of Science & Technology 1.1 (2020): 709-748.