Papers
Topics
Authors
Recent
Gemini 2.5 Flash
Gemini 2.5 Flash
167 tokens/sec
GPT-4o
7 tokens/sec
Gemini 2.5 Pro Pro
42 tokens/sec
o3 Pro
4 tokens/sec
GPT-4.1 Pro
38 tokens/sec
DeepSeek R1 via Azure Pro
28 tokens/sec
2000 character limit reached

Evaluation of automated driving system safety metrics with logged vehicle trajectory data (2401.01501v1)

Published 3 Jan 2024 in cs.RO

Abstract: Real-time safety metrics are important for the automated driving system (ADS) to assess the risk of driving situations and to assist the decision-making. Although a number of real-time safety metrics have been proposed in the literature, systematic performance evaluation of these safety metrics has been lacking. As different behavioral assumptions are adopted in different safety metrics, it is difficult to compare the safety metrics and evaluate their performance. To overcome this challenge, in this study, we propose an evaluation framework utilizing logged vehicle trajectory data, in that vehicle trajectories for both subject vehicle (SV) and background vehicles (BVs) are obtained and the prediction errors caused by behavioral assumptions can be eliminated. Specifically, we examine whether the SV is in a collision unavoidable situation at each moment, given all near-future trajectories of BVs. In this way, we level the ground for a fair comparison of different safety metrics, as a good safety metric should always alarm in advance to the collision unavoidable moment. When trajectory data from a large number of trips are available, we can systematically evaluate and compare different metrics' statistical performance. In the case study, three representative real-time safety metrics, including the time-to-collision (TTC), the PEGASUS Criticality Metric (PCM), and the Model Predictive Instantaneous Safety Metric (MPrISM), are evaluated using a large-scale simulated trajectory dataset. The proposed evaluation framework is important for researchers, practitioners, and regulators to characterize different metrics, and to select appropriate metrics for different applications. Moreover, by conducting failure analysis on moments when a safety metric failed, we can identify its potential weaknesses which are valuable for its potential refinements and improvements.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (34)
  1. J. C. Hayward, “Near miss determination through use of a scale of danger,” 1972.
  2. P. Junietz, F. Bonakdar, B. Klamann, and H. Winner, “Criticality metric for the safety validation of automated driving using model predictive trajectory optimization,” in 2018 21st International Conference on Intelligent Transportation Systems (ITSC).   IEEE, 2018, pp. 60–65.
  3. B. Weng, S. J. Rao, E. Deosthale, S. Schnelle, and F. Barickman, “Model predictive instantaneous safety metric for evaluation of automated driving systems,” in 2020 IEEE Intelligent Vehicles Symposium (IV).   IEEE, 2020, pp. 1899–1906.
  4. SAE international, “Taxonomy and definitions for terms related to driving automation systems for on-road motor vehicles,” SAE, 2021.
  5. S. Shalev-Shwartz, S. Shammah, and A. Shashua, “On a formal model of safe and scalable self-driving cars,” arXiv preprint arXiv:1708.06374, 2017.
  6. D. Nistér, H.-L. Lee, J. Ng, and Y. Wang, “The safety force field,” NVIDIA White Paper, 2019.
  7. C. Pek, S. Manzinger, M. Koschi, and M. Althoff, “Using online verification to prevent autonomous vehicles from causing accidents,” Nature Machine Intelligence, vol. 2, no. 9, pp. 518–528, 2020.
  8. M. Althoff, O. Stursberg, and M. Buss, “Model-based probabilistic collision detection in autonomous driving,” IEEE Transactions on Intelligent Transportation Systems, vol. 10, no. 2, pp. 299–310, 2009.
  9. M. Schreier, V. Willert, and J. Adamy, “An integrated approach to maneuver-based trajectory prediction and criticality assessment in arbitrary road environments,” IEEE Transactions on Intelligent Transportation Systems, vol. 17, no. 10, pp. 2751–2766, 2016.
  10. S. Feng, X. Yan, H. Sun, Y. Feng, and H. X. Liu, “Intelligent driving intelligence test for autonomous vehicles with naturalistic and adversarial environment,” Nature communications, vol. 12, no. 1, pp. 1–14, 2021.
  11. B. Weng, “A class of model predictive safety performance metrics for driving behavior evaluation,” in 2021 IEEE International Intelligent Transportation Systems Conference (ITSC).   IEEE, 2021, pp. 180–187.
  12. B. Weng, L. Capito, Ü. Özgüner, and K. Redmill, “A finite-sampling, operational domain specific, and provably unbiased connected and automated vehicle safety metric,” IEEE Transactions on Intelligent Transportation Systems, 2022.
  13. H. Singh, B. Weng, S. J. Rao, and D. Elsasser, “A diversity analysis of safety metrics comparing vehicle performance in the lead-vehicle interaction regime,” arXiv preprint arXiv:2306.14657, 2023.
  14. J. Dahl, G. R. de Campos, C. Olsson, and J. Fredriksson, “Collision avoidance: A literature review on threat-assessment techniques,” IEEE Transactions on Intelligent Vehicles, vol. 4, no. 1, pp. 101–113, 2018.
  15. J. Wishart, S. Como, M. Elli, B. Russo, J. Weast, N. Altekar, E. James, and Y. Chen, “Driving safety performance assessment metrics for ads-equipped vehicles,” SAE Technical Paper, vol. 2, no. 2020-01-1206, 2020.
  16. Y. Li, Y. Zheng, B. Morys, S. Pan, J. Wang, and K. Li, “Threat assessment techniques in intelligent vehicles: A comparative survey,” IEEE Intelligent Transportation Systems Magazine, 2020.
  17. C. Wang, Y. Xie, H. Huang, and P. Liu, “A review of surrogate safety measures and their applications in connected and automated vehicles safety modeling,” Accident Analysis & Prevention, vol. 157, p. 106157, 2021.
  18. K. Lee and H. Peng, “Evaluation of automotive forward collision warning and collision avoidance algorithms,” Vehicle system dynamics, vol. 43, no. 10, pp. 735–751, 2005.
  19. E. van Nunen, F. Esposto, A. K. Saberi, and J.-P. Paardekooper, “Evaluation of safety indicators for truck platooning,” in 2017 IEEE Intelligent Vehicles Symposium (IV).   IEEE, 2017, pp. 1013–1018.
  20. A. Papadoulis, M. Quddus, and M. Imprialou, “Evaluating the safety impact of connected and autonomous vehicles on motorways,” Accident Analysis & Prevention, vol. 124, pp. 12–22, 2019.
  21. N. Virdi, H. Grzybowska, S. T. Waller, and V. Dixit, “A safety assessment of mixed fleets with connected and autonomous vehicles using the surrogate safety assessment module,” Accident Analysis & Prevention, vol. 131, pp. 95–111, 2019.
  22. Gurobi Optimization, LLC, “Gurobi Optimizer Reference Manual,” 2021. [Online]. Available: https://www.gurobi.com
  23. P. A. Lopez, M. Behrisch, L. Bieker-Walz, J. Erdmann, Y.-P. Flötteröd, R. Hilbrich, L. Lücken, J. Rummel, P. Wagner, and E. WieBner, “Microscopic traffic simulation using SUMO,” in 2018 21st International Conference on Intelligent Transportation Systems (ITSC).   IEEE, 2018, pp. 2575–2582.
  24. Wikipedia contributors, “Confusion matrix,” https://en.wikipedia.org/wiki/Confusion_matrix, 2021, [Online].
  25. T. Fawcett, “An introduction to roc analysis,” Pattern recognition letters, vol. 27, no. 8, pp. 861–874, 2006.
  26. J. Davis and M. Goadrich, “The relationship between precision-recall and roc curves,” in Proceedings of the 23rd international conference on Machine learning, 2006, pp. 233–240.
  27. “PEGASUS Research Project,” 2022. [Online]. Available: https://www.pegasusprojekt.de/en/about-PEGASUS
  28. H. Van Hasselt, A. Guez, and D. Silver, “Deep reinforcement learning with double q-learning,” in Proceedings of the AAAI conference on artificial intelligence, vol. 30, no. 1, 2016.
  29. Z. Wang, T. Schaul, M. Hessel, H. Hasselt, M. Lanctot, and N. Freitas, “Dueling network architectures for deep reinforcement learning,” in International conference on machine learning.   PMLR, 2016, pp. 1995–2003.
  30. D. Bezzina and J. Sayer, “Safety pilot model deployment: Test conductor team report,” Report No. DOT HS, vol. 812, no. 171, p. 18, 2014.
  31. X. Yan, S. Feng, H. Sun, and H. X. Liu, “Distributionally consistent simulation of naturalistic driving environment for autonomous vehicle testing,” arXiv preprint arXiv:2101.02828, 2021.
  32. National Center for Statistics and Analysis, “Traffic safety facts 2018 annual report: A compilation of motor vehicle crash data (report no. dot hs 812 981),” United States. Department of Transportation. National Highway Traffic Safety Administration, Tech. Rep., 2020.
  33. Z. Zou, R. Zhang, S. Shen, G. Pandey, P. Chakravarty, A. Parchami, and H. X. Liu, “Real-time full-stack traffic scene perception for autonomous driving with roadside cameras,” in 2022 International Conference on Robotics and Automation (ICRA).   IEEE, 2022, pp. 890–896.
  34. R. Zhang, Z. Zou, S. Shen, and H. X. Liu, “Design, implementation, and evaluation of a roadside cooperative perception system,” Transportation research record, vol. 2676, no. 11, pp. 273–284, 2022.
Citations (2)
View on Semantic Scholar

Summary

We haven't generated a summary for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Summarize Now