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Main Authors: Tang, Hailiang, Zhang, Tisheng, Wang, Liqiang, Ding, Xin, Yuan, Man, Xiang, Zhiyu, Chen, Jujin, Bian, Yuhan, Liu, Shuangyan, Wang, Yuqing, Wang, Guan, Niu, Xiaoji
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2508.11485
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author Tang, Hailiang
Zhang, Tisheng
Wang, Liqiang
Ding, Xin
Yuan, Man
Xiang, Zhiyu
Chen, Jujin
Bian, Yuhan
Liu, Shuangyan
Wang, Yuqing
Wang, Guan
Niu, Xiaoji
author_facet Tang, Hailiang
Zhang, Tisheng
Wang, Liqiang
Ding, Xin
Yuan, Man
Xiang, Zhiyu
Chen, Jujin
Bian, Yuhan
Liu, Shuangyan
Wang, Yuqing
Wang, Guan
Niu, Xiaoji
contents Accurate and reliable navigation is crucial for autonomous unmanned ground vehicle (UGV). However, current UGV datasets fall short in meeting the demands for advancing navigation and mapping techniques due to limitations in sensor configuration, time synchronization, ground truth, and scenario diversity. To address these challenges, we present i2Nav-Robot, a large-scale dataset designed for multi-sensor fusion navigation and mapping in indoor-outdoor environments. We integrate multi-modal sensors, including the newest front-view and 360-degree solid-state LiDARs, 4-dimensional (4D) radar, stereo cameras, odometer, global navigation satellite system (GNSS) receiver, and inertial measurement units (IMU) on an omnidirectional wheeled robot. Accurate timestamps are obtained through both online hardware synchronization and offline calibration for all sensors. The dataset includes ten larger-scale sequences covering diverse UGV operating scenarios, such as outdoor streets, and indoor parking lots, with a total length of about 17060 meters. High-frequency ground truth, with centimeter-level accuracy for position, is derived from post-processing integrated navigation methods using a navigation-grade IMU. The proposed i2Nav-Robot dataset is evaluated by more than ten open-sourced multi-sensor fusion systems, and it has proven to have superior data quality.
format Preprint
id arxiv_https___arxiv_org_abs_2508_11485
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle i2Nav-Robot: A Large-Scale Indoor-Outdoor Robot Dataset for Multi-Sensor Fusion Navigation and Mapping
Tang, Hailiang
Zhang, Tisheng
Wang, Liqiang
Ding, Xin
Yuan, Man
Xiang, Zhiyu
Chen, Jujin
Bian, Yuhan
Liu, Shuangyan
Wang, Yuqing
Wang, Guan
Niu, Xiaoji
Robotics
Accurate and reliable navigation is crucial for autonomous unmanned ground vehicle (UGV). However, current UGV datasets fall short in meeting the demands for advancing navigation and mapping techniques due to limitations in sensor configuration, time synchronization, ground truth, and scenario diversity. To address these challenges, we present i2Nav-Robot, a large-scale dataset designed for multi-sensor fusion navigation and mapping in indoor-outdoor environments. We integrate multi-modal sensors, including the newest front-view and 360-degree solid-state LiDARs, 4-dimensional (4D) radar, stereo cameras, odometer, global navigation satellite system (GNSS) receiver, and inertial measurement units (IMU) on an omnidirectional wheeled robot. Accurate timestamps are obtained through both online hardware synchronization and offline calibration for all sensors. The dataset includes ten larger-scale sequences covering diverse UGV operating scenarios, such as outdoor streets, and indoor parking lots, with a total length of about 17060 meters. High-frequency ground truth, with centimeter-level accuracy for position, is derived from post-processing integrated navigation methods using a navigation-grade IMU. The proposed i2Nav-Robot dataset is evaluated by more than ten open-sourced multi-sensor fusion systems, and it has proven to have superior data quality.
title i2Nav-Robot: A Large-Scale Indoor-Outdoor Robot Dataset for Multi-Sensor Fusion Navigation and Mapping
topic Robotics
url https://arxiv.org/abs/2508.11485