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Main Authors: Yang, Zetong, Chen, Li, Sun, Yanan, Li, Hongyang
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2312.17655
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author Yang, Zetong
Chen, Li
Sun, Yanan
Li, Hongyang
author_facet Yang, Zetong
Chen, Li
Sun, Yanan
Li, Hongyang
contents In contrast to extensive studies on general vision, pre-training for scalable visual autonomous driving remains seldom explored. Visual autonomous driving applications require features encompassing semantics, 3D geometry, and temporal information simultaneously for joint perception, prediction, and planning, posing dramatic challenges for pre-training. To resolve this, we bring up a new pre-training task termed as visual point cloud forecasting - predicting future point clouds from historical visual input. The key merit of this task captures the synergic learning of semantics, 3D structures, and temporal dynamics. Hence it shows superiority in various downstream tasks. To cope with this new problem, we present ViDAR, a general model to pre-train downstream visual encoders. It first extracts historical embeddings by the encoder. These representations are then transformed to 3D geometric space via a novel Latent Rendering operator for future point cloud prediction. Experiments show significant gain in downstream tasks, e.g., 3.1% NDS on 3D detection, ~10% error reduction on motion forecasting, and ~15% less collision rate on planning.
format Preprint
id arxiv_https___arxiv_org_abs_2312_17655
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Visual Point Cloud Forecasting enables Scalable Autonomous Driving
Yang, Zetong
Chen, Li
Sun, Yanan
Li, Hongyang
Computer Vision and Pattern Recognition
In contrast to extensive studies on general vision, pre-training for scalable visual autonomous driving remains seldom explored. Visual autonomous driving applications require features encompassing semantics, 3D geometry, and temporal information simultaneously for joint perception, prediction, and planning, posing dramatic challenges for pre-training. To resolve this, we bring up a new pre-training task termed as visual point cloud forecasting - predicting future point clouds from historical visual input. The key merit of this task captures the synergic learning of semantics, 3D structures, and temporal dynamics. Hence it shows superiority in various downstream tasks. To cope with this new problem, we present ViDAR, a general model to pre-train downstream visual encoders. It first extracts historical embeddings by the encoder. These representations are then transformed to 3D geometric space via a novel Latent Rendering operator for future point cloud prediction. Experiments show significant gain in downstream tasks, e.g., 3.1% NDS on 3D detection, ~10% error reduction on motion forecasting, and ~15% less collision rate on planning.
title Visual Point Cloud Forecasting enables Scalable Autonomous Driving
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2312.17655