Vol. 4 No. 2 (2024): Journal of AI-Assisted Scientific Discovery
Articles

Autonomous Vehicles and Smart Cities: Integrating AI to Improve Traffic Flow, Parking, and Environmental Impact

PDF
  • Jaswinder Singh
Jaswinder Singh
Director, Data Wiser Technologies Inc., Brampton, Canada
Cover

Published 06-08-2024

Keywords

  • autonomous vehicles,
  • smart cities,
  • AI,
  • traffic management,
  • parking optimization,
  • environmental impact
    • ...More
    Less
Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.

How to Cite

[1]
J. Singh, “Autonomous Vehicles and Smart Cities: Integrating AI to Improve Traffic Flow, Parking, and Environmental Impact ”, Journal of AI-Assisted Scientific Discovery, vol. 4, no. 2, pp. 65–105, Aug. 2024, Accessed: Nov. 24, 2024. [Online]. Available: https://scienceacadpress.com/index.php/jaasd/article/view/186

Abstract

This research paper investigates the integration of AI-powered autonomous vehicles with smart city infrastructures to address critical urban challenges, particularly in traffic management, parking optimization, and environmental sustainability. With the rise of urbanization and the subsequent increase in vehicular congestion, there is an imperative need for innovative solutions that leverage advanced technologies. Autonomous vehicles, equipped with cutting-edge artificial intelligence, machine learning algorithms, and real-time data processing capabilities, present a transformative potential for modern urban systems. Concurrently, smart cities, built upon interconnected sensors, data platforms, and Internet of Things (IoT) frameworks, provide a robust environment for integrating these autonomous systems. Together, they form a synergistic ecosystem aimed at optimizing urban mobility, reducing congestion, and enhancing the overall efficiency of city operations.

One of the central themes explored in this paper is the role of autonomous vehicles in improving traffic flow. Traditional traffic management systems, often reliant on human operators and static control systems, are becoming increasingly inadequate in managing the complexities of modern city environments. The advent of AI-driven autonomous vehicles offers an alternative, where vehicles can communicate with each other and with smart city infrastructures to optimize routes, reduce travel time, and alleviate congestion. Autonomous vehicle systems are equipped with sophisticated sensors, radar, and LIDAR technologies, which, combined with AI algorithms, enable real-time decision-making and adaptive control. By interacting with smart city traffic lights, road sensors, and cloud-based traffic management platforms, autonomous vehicles can dynamically adjust their speed, trajectory, and route, facilitating more efficient use of road networks. Furthermore, AI-based predictive models can forecast traffic patterns based on historical data and real-time inputs, enabling preemptive actions to mitigate traffic bottlenecks before they escalate.

The paper also delves into the impact of AI-driven autonomous vehicles on urban parking solutions. In densely populated urban areas, parking scarcity and inefficiency contribute significantly to traffic congestion and increased carbon emissions. Traditional parking management systems are static, leading to inefficient use of parking spaces and increased search time for drivers. Autonomous vehicles, when integrated with smart parking infrastructures, can address these inefficiencies. Through AI-enabled predictive analytics, autonomous vehicles can identify and navigate to available parking spaces without driver intervention, minimizing the time spent searching for parking. Furthermore, the adoption of shared autonomous vehicle fleets reduces the overall demand for parking, as these vehicles can be in continuous circulation rather than remaining idle in parking spaces. Smart cities, equipped with IoT-enabled parking sensors and centralized parking management platforms, can further optimize the allocation of parking resources, dynamically adjusting pricing and availability based on real-time demand. This integration not only improves urban mobility but also enhances land use efficiency, allowing cities to repurpose land previously dedicated to parking for more sustainable urban developments.

The environmental benefits of integrating AI-powered autonomous vehicles with smart city infrastructures form another critical focus of this paper. Urban transportation is one of the largest contributors to greenhouse gas emissions and air pollution. By improving traffic flow and reducing idle time, autonomous vehicles contribute to lower fuel consumption and reduced emissions. Moreover, many autonomous vehicle prototypes are being designed as electric vehicles (EVs), further aligning their adoption with global efforts to reduce reliance on fossil fuels. In combination with smart grid systems, autonomous electric vehicles can be integrated into broader sustainable energy strategies, including renewable energy sources and energy storage systems. For instance, autonomous vehicles can be programmed to charge during off-peak electricity demand periods, alleviating stress on the grid and promoting more efficient use of renewable energy. This paper explores case studies from cities that have successfully implemented such integrated systems, highlighting the environmental gains achieved through these initiatives.

The paper reviews several international case studies that demonstrate the real-world applications and benefits of integrating autonomous vehicles and smart city infrastructures. Examples include cities like Singapore, which has pioneered autonomous vehicle trials in conjunction with its smart city initiatives, and Helsinki, where autonomous buses are being tested as part of a broader effort to create a sustainable urban mobility system. These case studies underscore the importance of a multi-stakeholder approach, involving government agencies, technology developers, urban planners, and the public, to ensure the successful integration of autonomous vehicles into smart cities. Additionally, the paper discusses the challenges and limitations faced by these initiatives, such as regulatory hurdles, technological interoperability issues, and public acceptance. By examining these case studies, the paper provides valuable insights into the practical implementation strategies and potential roadblocks in the integration of AI-powered autonomous vehicles with smart city systems.

This research demonstrates that the integration of AI-powered autonomous vehicles with smart city infrastructures offers a comprehensive solution to several of the most pressing urban challenges, including traffic congestion, parking inefficiencies, and environmental degradation. By leveraging AI and machine learning technologies, autonomous vehicles can optimize traffic flow, improve parking systems, and contribute to the reduction of carbon emissions, thereby enhancing the overall quality of urban life. The paper highlights the importance of continued research and development in this field, particularly in addressing the technical, regulatory, and societal challenges that must be overcome to fully realize the potential of autonomous vehicles and smart cities. Furthermore, it calls for a concerted global effort to standardize technologies and frameworks that facilitate the seamless integration of these systems, ensuring that the benefits of AI-driven urban mobility are realized on a global scale.

PDF

Downloads

Download data is not yet available.

References

  1. G. R. C. de Almeida, A. F. A. de Almeida, and J. C. de Oliveira, "Autonomous vehicles and the smart city: An overview," Journal of Transportation Technologies, vol. 10, no. 1, pp. 23-34, 2020.
  2. D. S. M. Ferreira and C. A. G. de Souza, "The role of artificial intelligence in autonomous vehicles," Artificial Intelligence Review, vol. 54, no. 2, pp. 67-89, 2021.
  3. S. B. Shakibaei and J. S. Scott, "Traffic management using smart cities and autonomous vehicles," IEEE Transactions on Intelligent Transportation Systems, vol. 21, no. 8, pp. 3354-3363, Aug. 2020.
  4. Praveen, S. Phani, et al. "Revolutionizing Healthcare: A Comprehensive Framework for Personalized IoT and Cloud Computing-Driven Healthcare Services with Smart Biometric Identity Management." Journal of Intelligent Systems & Internet of Things 13.1 (2024).
  5. Jahangir, Zeib, et al. "From Data to Decisions: The AI Revolution in Diabetes Care." International Journal 10.5 (2023): 1162-1179.
  6. Kasaraneni, Ramana Kumar. "AI-Enhanced Virtual Screening for Drug Repurposing: Accelerating the Identification of New Uses for Existing Drugs." Hong Kong Journal of AI and Medicine 1.2 (2021): 129-161.
  7. Pattyam, Sandeep Pushyamitra. "Data Engineering for Business Intelligence: Techniques for ETL, Data Integration, and Real-Time Reporting." Hong Kong Journal of AI and Medicine 1.2 (2021): 1-54.
  8. Qureshi, Hamza Ahmed, et al. "Revolutionizing AI-driven Hypertension Care: A Review of Current Trends and Future Directions." Journal of Science & Technology 5.4 (2024): 99-132.
  9. Ahmad, Tanzeem, et al. "Hybrid Project Management: Combining Agile and Traditional Approaches." Distributed Learning and Broad Applications in Scientific Research 4 (2018): 122-145.
  10. Bonam, Venkata Sri Manoj, et al. "Secure Multi-Party Computation for Privacy-Preserving Data Analytics in Cybersecurity." Cybersecurity and Network Defense Research 1.1 (2021): 20-38.
  11. Sahu, Mohit Kumar. "AI-Based Supply Chain Optimization in Manufacturing: Enhancing Demand Forecasting and Inventory Management." Journal of Science & Technology 1.1 (2020): 424-464.
  12. Thota, Shashi, et al. "Federated Learning: Privacy-Preserving Collaborative Machine Learning." Distributed Learning and Broad Applications in Scientific Research 5 (2019): 168-190.
  13. Kodete, Chandra Shikhi, et al. "Hormonal Influences on Skeletal Muscle Function in Women across Life Stages: A Systematic Review." Muscles 3.3 (2024): 271-286.
  14. A. G. L. Meyer and H. R. C. Brown, "Integrating smart parking solutions in urban environments," Smart Cities, vol. 3, no. 2, pp. 134-145, 2020.
  15. M. C. Chan and T. S. H. Lam, "Real-time traffic management using data analytics and AI," IEEE Access, vol. 9, pp. 127308-127319, 2021.
  16. A. R. Bahrami and M. J. G. L. Moura, "The environmental impact of autonomous vehicles: A comprehensive review," Journal of Cleaner Production, vol. 279, p. 123456, 2021.
  17. J. Zhang, Y. Wang, and Z. Yang, "Smart city infrastructure for autonomous vehicles: Opportunities and challenges," Future Generation Computer Systems, vol. 114, pp. 168-178, 2021.
  18. C. B. R. Santos and P. H. J. H. Leite, "A systematic review of smart city initiatives for traffic optimization," Cities, vol. 109, pp. 1-12, 2021.
  19. S. K. Chakrabarti, M. M. Hassan, and R. K. Gupta, "Enhancing urban mobility with smart transportation systems," International Journal of Transport Development and Integration, vol. 3, no. 3, pp. 215-227, 2021.
  20. M. R. Al Shamsi, "Interoperability in smart city frameworks: A review of approaches," IEEE Communications Surveys & Tutorials, vol. 23, no. 1, pp. 45-67, 2021.
  21. C. E. T. Smith and P. A. Davis, "Challenges and opportunities for autonomous vehicles in smart cities," Transportation Research Part A: Policy and Practice, vol. 145, pp. 1-12, 2021.
  22. L. T. Phan and S. S. K. Mitra, "Exploring public acceptance of autonomous vehicles: A systematic literature review," Transportation Research Part F: Traffic Psychology and Behaviour, vol. 73, pp. 11-24, 2020.
  23. T. K. H. Liu and R. K. T. Lee, "Traffic flow optimization using autonomous vehicles in smart city environments," Journal of Urban Technology, vol. 27, no. 3, pp. 57-73, 2020.
  24. J. B. H. Decker and A. K. H. Chan, "Electric and hybrid autonomous vehicles in urban mobility: A review," IEEE Transactions on Vehicular Technology, vol. 70, no. 8, pp. 7301-7312, Aug. 2021.
  25. R. K. Gupta and V. N. V. Reddy, "Smart cities: Concepts, technologies, and the role of autonomous vehicles," Journal of Urban Planning and Development, vol. 147, no. 1, p. 04020056, 2021.
  26. F. A. A. H. Al-Juboori, "Innovative smart parking solutions: Enhancing urban planning," IEEE Access, vol. 9, pp. 123456-123465, 2021.
  27. H. S. Chang and Y. J. Lee, "Predictive analytics for traffic management in smart cities," Computers, Environment and Urban Systems, vol. 82, p. 101490, 2020.
  28. A. K. Majumder and S. S. K. Mitra, "Stakeholder engagement in smart city initiatives: The case of autonomous vehicles," Urban Studies, vol. 58, no. 3, pp. 568-582, 2021.
  29. B. M. S. S. Fernando and M. P. J. V. A. R. de Silva, "Emerging technologies for smart cities: Challenges and opportunities," IEEE Internet of Things Journal, vol. 7, no. 4, pp. 3245-3255, April 2020.
  30. N. K. H. Chan, T. M. P. Lam, and K. R. N. Lim, "The future of urban mobility: Integrating AI and smart city technologies," Journal of Urban Affairs, vol. 43, no. 5, pp. 689-705, 2021.

Similar Articles

You may also start an advanced similarity search for this article.