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Lane Attention: Predicting Vehicles' Moving Trajectories by Learning Their Attention over Lanes

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arxiv 1909.13377 v2 pith:O3MXVCH5 submitted 2019-09-29 cs.LG cs.CVcs.ROstat.ML

Lane Attention: Predicting Vehicles' Moving Trajectories by Learning Their Attention over Lanes

classification cs.LG cs.CVcs.ROstat.ML
keywords attentionmovingvehicleautonomousdriverdrivinggraphintention
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Accurately forecasting the future movements of surrounding vehicles is essential for safe and efficient operations of autonomous driving cars. This task is difficult because a vehicle's moving trajectory is greatly determined by its driver's intention, which is often hard to estimate. By leveraging attention mechanisms along with long short-term memory (LSTM) networks, this work learns the relation between a driver's intention and the vehicle's changing positions relative to road infrastructures, and uses it to guide the prediction. Different from other state-of-the-art solutions, our work treats the on-road lanes as non-Euclidean structures, unfolds the vehicle's moving history to form a spatio-temporal graph, and uses methods from Graph Neural Networks to solve the problem. Not only is our approach a pioneering attempt in using non-Euclidean methods to process static environmental features around a predicted object, our model also outperforms other state-of-the-art models in several metrics. The practicability and interpretability analysis of the model shows great potential for large-scale deployment in various autonomous driving systems in addition to our own.

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