LabelFormer: Object Trajectory Refinement for Offboard Perception from LiDAR Point Clouds
CoRL 2023 A major bottleneck to scaling-up training of self-driving perception systems are the human annotations required for supervision. A promising alternative is to leverage "auto-labelling" offboard perception models that are trained to automatically generate annotations from raw LiDA...
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| creator | Yang, Anqi Joyce Casas, Sergio Dvornik, Nikita Segal, Sean Xiong, Yuwen Hu, Jordan Sir Kwang Fang, Carter Urtasun, Raquel |
| description | CoRL 2023 A major bottleneck to scaling-up training of self-driving perception systems
are the human annotations required for supervision. A promising alternative is
to leverage "auto-labelling" offboard perception models that are trained to
automatically generate annotations from raw LiDAR point clouds at a fraction of
the cost. Auto-labels are most commonly generated via a two-stage approach --
first objects are detected and tracked over time, and then each object
trajectory is passed to a learned refinement model to improve accuracy. Since
existing refinement models are overly complex and lack advanced temporal
reasoning capabilities, in this work we propose LabelFormer, a simple,
efficient, and effective trajectory-level refinement approach. Our approach
first encodes each frame's observations separately, then exploits
self-attention to reason about the trajectory with full temporal context, and
finally decodes the refined object size and per-frame poses. Evaluation on both
urban and highway datasets demonstrates that LabelFormer outperforms existing
works by a large margin. Finally, we show that training on a dataset augmented
with auto-labels generated by our method leads to improved downstream detection
performance compared to existing methods. Please visit the project website for
details https://waabi.ai/labelformer |
| doi_str_mv | 10.48550/arxiv.2311.01444 |
| format | Article |
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are the human annotations required for supervision. A promising alternative is
to leverage "auto-labelling" offboard perception models that are trained to
automatically generate annotations from raw LiDAR point clouds at a fraction of
the cost. Auto-labels are most commonly generated via a two-stage approach --
first objects are detected and tracked over time, and then each object
trajectory is passed to a learned refinement model to improve accuracy. Since
existing refinement models are overly complex and lack advanced temporal
reasoning capabilities, in this work we propose LabelFormer, a simple,
efficient, and effective trajectory-level refinement approach. Our approach
first encodes each frame's observations separately, then exploits
self-attention to reason about the trajectory with full temporal context, and
finally decodes the refined object size and per-frame poses. Evaluation on both
urban and highway datasets demonstrates that LabelFormer outperforms existing
works by a large margin. Finally, we show that training on a dataset augmented
with auto-labels generated by our method leads to improved downstream detection
performance compared to existing methods. Please visit the project website for
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are the human annotations required for supervision. A promising alternative is
to leverage "auto-labelling" offboard perception models that are trained to
automatically generate annotations from raw LiDAR point clouds at a fraction of
the cost. Auto-labels are most commonly generated via a two-stage approach --
first objects are detected and tracked over time, and then each object
trajectory is passed to a learned refinement model to improve accuracy. Since
existing refinement models are overly complex and lack advanced temporal
reasoning capabilities, in this work we propose LabelFormer, a simple,
efficient, and effective trajectory-level refinement approach. Our approach
first encodes each frame's observations separately, then exploits
self-attention to reason about the trajectory with full temporal context, and
finally decodes the refined object size and per-frame poses. Evaluation on both
urban and highway datasets demonstrates that LabelFormer outperforms existing
works by a large margin. Finally, we show that training on a dataset augmented
with auto-labels generated by our method leads to improved downstream detection
performance compared to existing methods. Please visit the project website for
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are the human annotations required for supervision. A promising alternative is
to leverage "auto-labelling" offboard perception models that are trained to
automatically generate annotations from raw LiDAR point clouds at a fraction of
the cost. Auto-labels are most commonly generated via a two-stage approach --
first objects are detected and tracked over time, and then each object
trajectory is passed to a learned refinement model to improve accuracy. Since
existing refinement models are overly complex and lack advanced temporal
reasoning capabilities, in this work we propose LabelFormer, a simple,
efficient, and effective trajectory-level refinement approach. Our approach
first encodes each frame's observations separately, then exploits
self-attention to reason about the trajectory with full temporal context, and
finally decodes the refined object size and per-frame poses. Evaluation on both
urban and highway datasets demonstrates that LabelFormer outperforms existing
works by a large margin. Finally, we show that training on a dataset augmented
with auto-labels generated by our method leads to improved downstream detection
performance compared to existing methods. Please visit the project website for
details https://waabi.ai/labelformer</abstract><doi>10.48550/arxiv.2311.01444</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Computer Science - Computer Vision and Pattern Recognition Computer Science - Robotics |
| title | LabelFormer: Object Trajectory Refinement for Offboard Perception from LiDAR Point Clouds |
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