STF: Spatial Temporal Fusion for Trajectory Prediction
November 29, 2023 Β· Declared Dead Β· π International Conference on Mechatronics and Machine Vision in Practice
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Authors
Pengqian Han, Jiamou Liu, Tianzhe Bao, Yifei Wang
arXiv ID
2311.18149
Category
cs.CV: Computer Vision
Citations
5
Venue
International Conference on Mechatronics and Machine Vision in Practice
Last Checked
4 months ago
Abstract
Trajectory prediction is a challenging task that aims to predict the future trajectory of vehicles or pedestrians over a short time horizon based on their historical positions. The main reason is that the trajectory is a kind of complex data, including spatial and temporal information, which is crucial for accurate prediction. Intuitively, the more information the model can capture, the more precise the future trajectory can be predicted. However, previous works based on deep learning methods processed spatial and temporal information separately, leading to inadequate spatial information capture, which means they failed to capture the complete spatial information. Therefore, it is of significance to capture information more fully and effectively on vehicle interactions. In this study, we introduced an integrated 3D graph that incorporates both spatial and temporal edges. Based on this, we proposed the integrated 3D graph, which considers the cross-time interaction information. In specific, we design a Spatial-Temporal Fusion (STF) model including Multi-layer perceptions (MLP) and Graph Attention (GAT) to capture the spatial and temporal information historical trajectories simultaneously on the 3D graph. Our experiment on the ApolloScape Trajectory Datasets shows that the proposed STF outperforms several baseline methods, especially on the long-time-horizon trajectory prediction.
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