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Main Authors: Guo, Xianda, Zhang, Ruijun, Duan, Yiqun, Wang, Ruilin, Poggi, Matteo, Zhou, Keyuan, Zheng, Wenzhao, Huang, Wenke, Xu, Gangwei, Peng, Yanlun, Si, Yuan, Zou, Qin
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2508.13977
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author Guo, Xianda
Zhang, Ruijun
Duan, Yiqun
Wang, Ruilin
Poggi, Matteo
Zhou, Keyuan
Zheng, Wenzhao
Huang, Wenke
Xu, Gangwei
Peng, Yanlun
Si, Yuan
Zou, Qin
author_facet Guo, Xianda
Zhang, Ruijun
Duan, Yiqun
Wang, Ruilin
Poggi, Matteo
Zhou, Keyuan
Zheng, Wenzhao
Huang, Wenke
Xu, Gangwei
Peng, Yanlun
Si, Yuan
Zou, Qin
contents Depth estimation is a fundamental component of spatial perception for autonomous driving and other unmanned systems operating in open urban environments. Existing depth datasets such as KITTI, nuScenes, and DDAD have advanced the field but are limited in diversity and scalability, and benchmark performance on them is approaching saturation. A less discussed constraint is \emph{sensor economics}: the bespoke multi-LiDAR rigs behind these datasets are expensive, power-hungry, and difficult to replicate at fleet scale, which caps the geographic and temporal diversity that any single benchmark can cover. We present ROVR, a large-scale, diverse, and cost-efficient depth dataset designed to capture the complexity of real-world driving. ROVR comprises 200K high-resolution frames across highway, rural, and urban scenarios, spanning day/night cycles and adverse weather conditions, collected across North America, Europe, and Asia. We additionally release the calibration, synchronization, preprocessing, and privacy pipeline so that the platform can be reproduced by third parties. The lightweight acquisition pipeline enables scalable collection, while sparse but statistically sufficient ground truth -- validated by a density ablation -- supports robust model training. Extensive ablation studies further characterize performance across scene types, illumination, weather conditions, and ground-truth sparsity levels, and identify three qualitatively distinct failure modes -- photometric collapse, geometric confusion, and range saturation -- that current architectures share. The dataset, data loaders, calibration and privacy pipelines, and evaluation code are publicly available at \url{https://xiandaguo.net/ROVR-Open-Dataset}.
format Preprint
id arxiv_https___arxiv_org_abs_2508_13977
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle ROVR-Open-Dataset: A Large-Scale Depth Dataset for Autonomous Driving
Guo, Xianda
Zhang, Ruijun
Duan, Yiqun
Wang, Ruilin
Poggi, Matteo
Zhou, Keyuan
Zheng, Wenzhao
Huang, Wenke
Xu, Gangwei
Peng, Yanlun
Si, Yuan
Zou, Qin
Computer Vision and Pattern Recognition
Depth estimation is a fundamental component of spatial perception for autonomous driving and other unmanned systems operating in open urban environments. Existing depth datasets such as KITTI, nuScenes, and DDAD have advanced the field but are limited in diversity and scalability, and benchmark performance on them is approaching saturation. A less discussed constraint is \emph{sensor economics}: the bespoke multi-LiDAR rigs behind these datasets are expensive, power-hungry, and difficult to replicate at fleet scale, which caps the geographic and temporal diversity that any single benchmark can cover. We present ROVR, a large-scale, diverse, and cost-efficient depth dataset designed to capture the complexity of real-world driving. ROVR comprises 200K high-resolution frames across highway, rural, and urban scenarios, spanning day/night cycles and adverse weather conditions, collected across North America, Europe, and Asia. We additionally release the calibration, synchronization, preprocessing, and privacy pipeline so that the platform can be reproduced by third parties. The lightweight acquisition pipeline enables scalable collection, while sparse but statistically sufficient ground truth -- validated by a density ablation -- supports robust model training. Extensive ablation studies further characterize performance across scene types, illumination, weather conditions, and ground-truth sparsity levels, and identify three qualitatively distinct failure modes -- photometric collapse, geometric confusion, and range saturation -- that current architectures share. The dataset, data loaders, calibration and privacy pipelines, and evaluation code are publicly available at \url{https://xiandaguo.net/ROVR-Open-Dataset}.
title ROVR-Open-Dataset: A Large-Scale Depth Dataset for Autonomous Driving
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2508.13977