Deep Learning for Autonomous Vehicle Sensor Error Correction

Authors

  • Dr. Esther Collings Professor of Information Systems, University of Cape Town, South Africa Author

Keywords:

deep learning (DL)-based methods

Abstract

The typical strategy for SIM involves three steps, namely, generation of the erroneous data, sensor fault Accompanying it thus the data has shown better pictorial representations. The papers are written so that it defines the output from the camera and the lidar. The temporal error profits error directly from the previous error of the sensor. The papers are written existing strategies of motion are previously used by authors to prove the weakness on approach. By making the stepwise on the relevant data it gives the specific details of all the datasets. The error correction notes the groups of below three different options involved. The most common strategy is duplication and comparison of one kind and the other kind are probability calculation.

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References

Pulimamidi, Rahul. "Leveraging IoT Devices for Improved Healthcare Accessibility in Remote Areas: An Exploration of Emerging Trends." Internet of Things and Edge Computing Journal 2.1 (2022): 20-30.

Tatineni, Sumanth, and Venkat Raviteja Boppana. "AI-Powered DevOps and MLOps Frameworks: Enhancing Collaboration, Automation, and Scalability in Machine Learning Pipelines." Journal of Artificial Intelligence Research and Applications 1.2 (2021): 58-88.

Ponnusamy, Sivakumar, and Dinesh Eswararaj. "Navigating the Modernization of Legacy Applications and Data: Effective Strategies and Best Practices." Asian Journal of Research in Computer Science 16.4 (2023): 239-256.

Shahane, Vishal. "Investigating the Efficacy of Machine Learning Models for Automated Failure Detection and Root Cause Analysis in Cloud Service Infrastructure." African Journal of Artificial Intelligence and Sustainable Development2.2 (2022): 26-51.

Muthusubramanian, Muthukrishnan, and Jawaharbabu Jeyaraman. "Data Engineering Innovations: Exploring the Intersection with Cloud Computing, Machine Learning, and AI." Journal of Knowledge Learning and Science Technology ISSN: 2959-6386 (online) 1.1 (2023): 76-84.

Tillu, Ravish, Bhargav Kumar Konidena, and Vathsala Periyasamy. "Navigating Regulatory Complexity: Leveraging AI/ML for Accurate Reporting." Journal of Knowledge Learning and Science Technology ISSN: 2959-6386 (online) 2.2 (2023): 149-166.

Sharma, Kapil Kumar, Manish Tomar, and Anish Tadimarri. "AI-driven marketing: Transforming sales processes for success in the digital age." Journal of Knowledge Learning and Science Technology ISSN: 2959-6386 (online) 2.2 (2023): 250-260.

Abouelyazid, Mahmoud. "Natural Language Processing for Automated Customer Support in E-Commerce: Advanced Techniques for Intent Recognition and Response Generation." Journal of AI-Assisted Scientific Discovery 2.1 (2022): 195-232.

Prabhod, Kummaragunta Joel. "Utilizing Foundation Models and Reinforcement Learning for Intelligent Robotics: Enhancing Autonomous Task Performance in Dynamic Environments." Journal of Artificial Intelligence Research 2.2 (2022): 1-20.

Tatineni, Sumanth, and Anirudh Mustyala. "AI-Powered Automation in DevOps for Intelligent Release Management: Techniques for Reducing Deployment Failures and Improving Software Quality." Advances in Deep Learning Techniques 1.1 (2021): 74-110.

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Published

30-06-2023

How to Cite

[1]
Dr. Esther Collings, “Deep Learning for Autonomous Vehicle Sensor Error Correction”, J. of Artificial Int. Research and App., vol. 3, no. 1, pp. 192–212, Jun. 2023, Accessed: Nov. 23, 2024. [Online]. Available: https://aimlstudies.co.uk/index.php/jaira/article/view/109

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