Abstract
The full-scale deployment of autonomous driving demands successful interaction with pedestrians and other vulnerable road users, which requires an understanding of their dynamic behavior and intention. Current research achieves this by estimating pedestrian’s trajectory mainly based on the gait and movement information in the past as well as other relevant scene information. However, the autonomous vehicles still struggle with such interactions since the visual features alone may not supply subtle details required to attain a superior understanding. The decision-making ability of the system can improve by incorporating human knowledge to guide the vision-based algorithms. In this paper, we adopt a novel approach to retrieve human knowledge from the natural text descriptions about the pedestrian-vehicle encounters, which is crucial to anticipate the pedestrian intention and is difficult for computer vision (CV) algorithms to capture automatically. We applied natural language processing (NLP) techniques on the aggregated description from different annotators to generate a temporal knowledge graph, which can achieve the changes of intention and the corresponding reasoning processes in a better resolution. In future work, we plan to show that in combination with video processing algorithms, the knowledge graph has the potential to aid the decision-making process to be more accurate by passively integrating the reasoning ability of humans.
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Elahi, M.F., Luo, X., Tian, R. (2020). A Framework for Modeling Knowledge Graphs via Processing Natural Descriptions of Vehicle-Pedestrian Interactions. In: Stephanidis, C., Duffy, V.G., Streitz, N., Konomi, S., Krömker, H. (eds) HCI International 2020 – Late Breaking Papers: Digital Human Modeling and Ergonomics, Mobility and Intelligent Environments. HCII 2020. Lecture Notes in Computer Science(), vol 12429. Springer, Cham. https://doi.org/10.1007/978-3-030-59987-4_4
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