Deep learning-based hybrid dynamic modeling and improved handling stability assessment for autonomous vehicles at driving limits
This paper addresses the critical challenges of dynamic modeling and quantitative assessment of handling stability for autonomous vehicles (AVs). To meet the high safety standards in AVs, especially under conditions at driving limits, it is essential to employ precise dynamic models that match real-...
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sg-ntu-dr.10356-1824332025-02-03T02:04:03Z Deep learning-based hybrid dynamic modeling and improved handling stability assessment for autonomous vehicles at driving limits Cheng, Shuo Hu, Bin-Bin Wei, Henglai Li, Liang Lv, Chen School of Mechanical and Aerospace Engineering Engineering Handling stability Hybrid modeling This paper addresses the critical challenges of dynamic modeling and quantitative assessment of handling stability for autonomous vehicles (AVs). To meet the high safety standards in AVs, especially under conditions at driving limits, it is essential to employ precise dynamic models that match real-world system responses as closely as possible and provide reliable, quantitative evaluations of handling safety levels. We propose a deep learning-based hybrid dynamic modeling approach that integrates a designed recurrent neural network with vehicle physical models to enhance the traceability and interpretability of prevailing data-driven models. Utilizing recorded vehicle data, we first train the designed neural network to learn vehicle dynamic responses, thereby enhancing modeling accuracy. Then, the knowledge-based physical model and trained network model interact with each other and are mixed by exploiting the unscented Kalman filter. Furthermore, a comprehensive metric is developed to quantify the level of vehicle handling stability. We propose a multivariate dynamic representation to facilitate the analysis of complex vehicle dynamic behaviors. The mathematical definition of the handling safety metric is provided. Finally, hardware-in-the-loop (HIL) experiments are carried out to validate the proposed methods. Experimental results verify the effectiveness and better performance of the proposed hybrid dynamic model and handling safety metric. This work holds promising implications for accelerating the release and deployment of AVs. 2025-02-03T02:04:03Z 2025-02-03T02:04:03Z 2024 Journal Article Cheng, S., Hu, B., Wei, H., Li, L. & Lv, C. (2024). Deep learning-based hybrid dynamic modeling and improved handling stability assessment for autonomous vehicles at driving limits. IEEE Transactions On Vehicular Technology, 3515209-. https://dx.doi.org/10.1109/TVT.2024.3515209 0018-9545 https://hdl.handle.net/10356/182433 10.1109/TVT.2024.3515209 2-s2.0-85211986053 3515209 en IEEE Transactions on Vehicular Technology © 2024 IEEE. All rights reserved. |
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Engineering Handling stability Hybrid modeling |
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Engineering Handling stability Hybrid modeling Cheng, Shuo Hu, Bin-Bin Wei, Henglai Li, Liang Lv, Chen Deep learning-based hybrid dynamic modeling and improved handling stability assessment for autonomous vehicles at driving limits |
| description |
This paper addresses the critical challenges of dynamic modeling and quantitative assessment of handling stability for autonomous vehicles (AVs). To meet the high safety standards in AVs, especially under conditions at driving limits, it is essential to employ precise dynamic models that match real-world system responses as closely as possible and provide reliable, quantitative evaluations of handling safety levels. We propose a deep learning-based hybrid dynamic modeling approach that integrates a designed recurrent neural network with vehicle physical models to enhance the traceability and interpretability of prevailing data-driven models. Utilizing recorded vehicle data, we first train the designed neural network to learn vehicle dynamic responses, thereby enhancing modeling accuracy. Then, the knowledge-based physical model and trained network model interact with each other and are mixed by exploiting the unscented Kalman filter. Furthermore, a comprehensive metric is developed to quantify the level of vehicle handling stability. We propose a multivariate dynamic representation to facilitate the analysis of complex vehicle dynamic behaviors. The mathematical definition of the handling safety metric is provided. Finally, hardware-in-the-loop (HIL) experiments are carried out to validate the proposed methods. Experimental results verify the effectiveness and better performance of the proposed hybrid dynamic model and handling safety metric. This work holds promising implications for accelerating the release and deployment of AVs. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Cheng, Shuo Hu, Bin-Bin Wei, Henglai Li, Liang Lv, Chen |
| format |
Article |
| author |
Cheng, Shuo Hu, Bin-Bin Wei, Henglai Li, Liang Lv, Chen |
| author_sort |
Cheng, Shuo |
| title |
Deep learning-based hybrid dynamic modeling and improved handling stability assessment for autonomous vehicles at driving limits |
| title_short |
Deep learning-based hybrid dynamic modeling and improved handling stability assessment for autonomous vehicles at driving limits |
| title_full |
Deep learning-based hybrid dynamic modeling and improved handling stability assessment for autonomous vehicles at driving limits |
| title_fullStr |
Deep learning-based hybrid dynamic modeling and improved handling stability assessment for autonomous vehicles at driving limits |
| title_full_unstemmed |
Deep learning-based hybrid dynamic modeling and improved handling stability assessment for autonomous vehicles at driving limits |
| title_sort |
deep learning-based hybrid dynamic modeling and improved handling stability assessment for autonomous vehicles at driving limits |
| publishDate |
2025 |
| url |
https://hdl.handle.net/10356/182433 |
| _version_ |
1823108718225522688 |