Learning Lane Graph Representations for Motion Forecasting
About
We propose a motion forecasting model that exploits a novel structured map representation as well as actor-map interactions. Instead of encoding vectorized maps as raster images, we construct a lane graph from raw map data to explicitly preserve the map structure. To capture the complex topology and long range dependencies of the lane graph, we propose LaneGCN which extends graph convolutions with multiple adjacency matrices and along-lane dilation. To capture the complex interactions between actors and maps, we exploit a fusion network consisting of four types of interactions, actor-to-lane, lane-to-lane, lane-to-actor and actor-to-actor. Powered by LaneGCN and actor-map interactions, our model is able to predict accurate and realistic multi-modal trajectories. Our approach significantly outperforms the state-of-the-art on the large scale Argoverse motion forecasting benchmark.
Related benchmarks
| Task | Dataset | Result | Rank | |
|---|---|---|---|---|
| Trajectory Prediction | nuScenes Prediction Challenge (test) | minADE (K=10)0.95 | 37 | |
| Trajectory Prediction | Argoverse (test) | Min ADE0.8679 | 36 | |
| Motion forecasting | Argoverse 1 (test) | b-minFDE (K=6)2.05 | 30 | |
| Motion forecasting | Argoverse 1.0 (val) | minFDE61.08 | 29 | |
| Motion forecasting | Argoverse Motion Forecasting 1.1 (test) | minADE (K=1)1.71 | 27 | |
| Trajectory Prediction | Waymo Open Motion Dataset (WOMD) (test) | minADE0.7632 | 24 | |
| Motion Prediction | Argoverse official leaderboard (test) | minADE (1 step)1.7 | 18 | |
| Trajectory Prediction | Argoverse 1.0 (test) | minADE (k=6)0.87 | 15 | |
| Trajectory Prediction | Argoverse Motion Forecasting Leaderboard 1.0 (test) | minADE (6)0.87 | 12 | |
| Trajectory Prediction | Argoverse (val) | ADE (original)0.71 | 12 |