Deep Learning for Autonomous Driving

Enhancing Object Detection and Scene Understanding

Authors

  • Emily Roberts Assistant Professor, Department of Electrical Engineering, Massachusetts Institute of Technology, Cambridge, MA, USA Author

Keywords:

Deep learning, autonomous driving, object detection, scene understanding, convolutional neural networks, real-time processing

Abstract

The advent of autonomous driving technologies has transformed the automotive industry, promising safer and more efficient transportation systems. A pivotal component of these technologies is the ability to perceive and understand the vehicle's environment through advanced object detection and scene understanding algorithms. This paper discusses the role of deep learning in enhancing these capabilities, focusing on the use of convolutional neural networks (CNNs), recurrent neural networks (RNNs), and other state-of-the-art architectures. By leveraging large datasets, real-time processing capabilities, and advanced training techniques, deep learning algorithms can significantly improve the accuracy of object detection and scene understanding in autonomous vehicles. The implications of these advancements for safety, efficiency, and the future of transportation are also examined. Additionally, the challenges associated with deploying these algorithms in real-world scenarios, such as dealing with diverse environmental conditions and ensuring robustness against adversarial attacks, are addressed. The paper concludes with future directions for research in deep learning for autonomous driving, emphasizing the need for ongoing innovation in this critical area of technology.

Downloads

Download data is not yet available.

References

Gayam, Swaroop Reddy. "Deep Learning for Predictive Maintenance: Advanced Techniques for Fault Detection, Prognostics, and Maintenance Scheduling in Industrial Systems." Journal of Deep Learning in Genomic Data Analysis 2.1 (2022): 53-85.

Venkata, Ashok Kumar Pamidi, et al. "Reinforcement Learning for Autonomous Systems: Practical Implementations in Robotics." Distributed Learning and Broad Applications in Scientific Research 4 (2018): 146-157.

Nimmagadda, Venkata Siva Prakash. "Artificial Intelligence for Supply Chain Visibility and Transparency in Retail: Advanced Techniques, Models, and Real-World Case Studies." Journal of Machine Learning in Pharmaceutical Research 3.1 (2023): 87-120.

Putha, Sudharshan. "AI-Driven Predictive Maintenance for Smart Manufacturing: Enhancing Equipment Reliability and Reducing Downtime." Journal of Deep Learning in Genomic Data Analysis 2.1 (2022): 160-203.

Sahu, Mohit Kumar. "Advanced AI Techniques for Predictive Maintenance in Autonomous Vehicles: Enhancing Reliability and Safety." Journal of AI in Healthcare and Medicine 2.1 (2022): 263-304.

Kondapaka, Krishna Kanth. "AI-Driven Predictive Maintenance for Insured Assets: Advanced Techniques, Applications, and Real-World Case Studies." Journal of AI in Healthcare and Medicine 1.2 (2021): 146-187.

Kasaraneni, Ramana Kumar. "AI-Enhanced Telematics Systems for Fleet Management: Optimizing Route Planning and Resource Allocation." Journal of AI in Healthcare and Medicine 1.2 (2021): 187-222.

Pattyam, Sandeep Pushyamitra. "Artificial Intelligence in Cybersecurity: Advanced Methods for Threat Detection, Risk Assessment, and Incident Response." Journal of AI in Healthcare and Medicine 1.2 (2021): 83-108.

Ahmad, Tanzeem, et al. "Explainable AI: Interpreting Deep Learning Models for Decision Support." Advances in Deep Learning Techniques 4.1 (2024): 80-108.

Zhang, Y., & Li, Z. (2018). Real-time semantic segmentation for autonomous driving. Proceedings of the IEEE International Conference on Robotics and Automation (pp. 2551-2558).

Geng, J., Liu, Z., & Liu, Q. (2020). Graph neural networks for scene understanding in autonomous driving. IEEE Transactions on Intelligent Transportation Systems, 22(6), 3482-3490.

Wu, Y., Zhang, C., & Zhang, Y. (2020). RNN-based trajectory prediction for autonomous vehicles. IEEE Transactions on Intelligent Transportation Systems, 21(3), 1294-1302.

Goodfellow, I., Shlens, J., & Szegedy, C. (2014). Explaining and harnessing adversarial examples. Proceedings of the International Conference on Learning Representations.

Chen, G., & Yao, L. (2021). Adversarial attacks on deep learning: A survey. IEEE Transactions on Neural Networks and Learning Systems, 32(4), 1604-1620.

Doshi-Velez, F., & Kim, B. (2017). Towards a rigorous science of interpretable machine learning. Proceedings of the 34th International Conference on Machine Learning (pp. 1232-1240).

Shalev-Shwartz, S., & Ben-David, S. (2014). Understanding machine learning: From theory to algorithms. Cambridge University Press.

Kahn, L., & Tschannen, M. (2020). The future of autonomous vehicles: Regulations and policy. IEEE Robotics & Automation Magazine, 27(4), 52-63.

Machireddy, Jeshwanth Reddy. "Data-Driven Insights: Analyzing the Effects of Underutilized HRAs and HSAs on Healthcare Spending and Insurance Efficiency." Journal of Bioinformatics and Artificial Intelligence 1.1 (2021): 450-470.

Geng, X., & Zhang, S. (2020). Hybrid AI for autonomous vehicles: Integration of traditional methods and deep learning. IEEE Transactions on Intelligent Transportation Systems, 21(3), 1303-1314.

Hwang, S., & Lee, J. (2021). Simulating autonomous driving scenarios for deep learning training. IEEE Transactions on Intelligent Transportation Systems, 22(4), 2101-2112.

Downloads

Published

13-12-2023

How to Cite

[1]
E. Roberts, “Deep Learning for Autonomous Driving: Enhancing Object Detection and Scene Understanding”, Distrib Learn Broad Appl Sci Res, vol. 9, pp. 392–399, Dec. 2023, Accessed: Nov. 23, 2024. [Online]. Available: https://dlabi.org/index.php/journal/article/view/149

Similar Articles

81-90 of 160

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