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Main Authors: Yao, Chen, Ge, Yangtao, Shi, Guowei, Wang, Zirui, Yang, Ningbo, Zhu, Zheng, Wei, Hexiang, Zhao, Yuntian, Wu, Jing, Jia, Zhenzhong
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2403.16875
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author Yao, Chen
Ge, Yangtao
Shi, Guowei
Wang, Zirui
Yang, Ningbo
Zhu, Zheng
Wei, Hexiang
Zhao, Yuntian
Wu, Jing
Jia, Zhenzhong
author_facet Yao, Chen
Ge, Yangtao
Shi, Guowei
Wang, Zirui
Yang, Ningbo
Zhu, Zheng
Wei, Hexiang
Zhao, Yuntian
Wu, Jing
Jia, Zhenzhong
contents Terrain-aware perception holds the potential to improve the robustness and accuracy of autonomous robot navigation in the wilds, thereby facilitating effective off-road traversals. However, the lack of multi-modal perception across various motion patterns hinders the solutions of Simultaneous Localization And Mapping (SLAM), especially when confronting non-geometric hazards in demanding landscapes. In this paper, we first propose a Terrain-Aware multI-modaL (TAIL) dataset tailored to deformable and sandy terrains. It incorporates various types of robotic proprioception and distinct ground interactions for the unique challenges and benchmark of multi-sensor fusion SLAM. The versatile sensor suite comprises stereo frame cameras, multiple ground-pointing RGB-D cameras, a rotating 3D LiDAR, an IMU, and an RTK device. This ensemble is hardware-synchronized, well-calibrated, and self-contained. Utilizing both wheeled and quadrupedal locomotion, we efficiently collect comprehensive sequences to capture rich unstructured scenarios. It spans the spectrum of scope, terrain interactions, scene changes, ground-level properties, and dynamic robot characteristics. We benchmark several state-of-the-art SLAM methods against ground truth and provide performance validations. Corresponding challenges and limitations are also reported. All associated resources are accessible upon request at \url{https://tailrobot.github.io/}.
format Preprint
id arxiv_https___arxiv_org_abs_2403_16875
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle TAIL: A Terrain-Aware Multi-Modal SLAM Dataset for Robot Locomotion in Deformable Granular Environments
Yao, Chen
Ge, Yangtao
Shi, Guowei
Wang, Zirui
Yang, Ningbo
Zhu, Zheng
Wei, Hexiang
Zhao, Yuntian
Wu, Jing
Jia, Zhenzhong
Robotics
Terrain-aware perception holds the potential to improve the robustness and accuracy of autonomous robot navigation in the wilds, thereby facilitating effective off-road traversals. However, the lack of multi-modal perception across various motion patterns hinders the solutions of Simultaneous Localization And Mapping (SLAM), especially when confronting non-geometric hazards in demanding landscapes. In this paper, we first propose a Terrain-Aware multI-modaL (TAIL) dataset tailored to deformable and sandy terrains. It incorporates various types of robotic proprioception and distinct ground interactions for the unique challenges and benchmark of multi-sensor fusion SLAM. The versatile sensor suite comprises stereo frame cameras, multiple ground-pointing RGB-D cameras, a rotating 3D LiDAR, an IMU, and an RTK device. This ensemble is hardware-synchronized, well-calibrated, and self-contained. Utilizing both wheeled and quadrupedal locomotion, we efficiently collect comprehensive sequences to capture rich unstructured scenarios. It spans the spectrum of scope, terrain interactions, scene changes, ground-level properties, and dynamic robot characteristics. We benchmark several state-of-the-art SLAM methods against ground truth and provide performance validations. Corresponding challenges and limitations are also reported. All associated resources are accessible upon request at \url{https://tailrobot.github.io/}.
title TAIL: A Terrain-Aware Multi-Modal SLAM Dataset for Robot Locomotion in Deformable Granular Environments
topic Robotics
url https://arxiv.org/abs/2403.16875