MIN3D

MultI-seNsor 3D mapping with an unmanned ground vehicle for mining applications

Robotic dataset for developing mobile mapping solutions for challenging, GNSS-denied and subterranean environments

Authors

Paweł Trybała, Jarosław Szrek, Fabio Remondino, Paulina Kujawa, Jacek Wodecki, Jan Blachowski, Radosław Zimroz

Abstract

The research potential in the field of mobile mapping technologies, particularly for specific applications, is hindered by several constraints. These include the need for costly hardware to collect data (possibly with automation using mobile platforms such as robots or drones), limited access to target sites with specific environmental conditions, and the establishment of a ground truth model for evaluating developed solutions. To address these challenges, the utilization of open datasets presents a viable solution. However, the availability of datasets that encompass truly demanding mixed indoor-outdoor and subterranean conditions is currently limited. To alleviate this issue, we propose the MIN3D dataset (MultI-seNsor 3D mapping with an unmanned ground vehicle for mining applications). This dataset was gathered using a wheeled mobile robot in two distinct locations: (i) textureless dark corridors within a university campus and (ii) tunnels of an underground site in Walim (Poland). It comprises around 150 GB of raw data, including images captured by multiple co-calibrated monocular and stereo cameras, a thermal camera, 2 LiDARs, and 3 inertial measurement units. Reliable ground truth point clouds were obtained using a survey-grade terrestrial laser scanner. By openly sharing this dataset, we aim to support the efforts of the scientific community in developing robust methods for navigation and mapping in challenging underground conditions. In the paper, we describe the collected data and provide an initial accuracy assessment of some visual- and LiDAR-based simultaneous localization and mapping (SLAM) algorithms for selected sequences. Encountered problems, open research questions and areas that could benefit from utilizing our dataset are discussed.

Main Contributions:

• Challenging scenes in indoor and underground conditions, targeting typical issues of subterranean environments: variable illumination, featureless or textureless areas, repeating or complex geometry.
• Simultaneously acquired data with many sensors (cameras, LiDAR scanners, IMUs) on a single robotic platform.
• High-quality reference point clouds, acquired with a survey-grade Terrestrial Laser Scanner.

Related papers

Trybała, P., Szrek, J., Remondino, F. et al. MIN3D Dataset: MultI-seNsor 3D Mapping with an Unmanned Ground Vehicle. PFG (2023).

Trybała, P., Szrek, J., Remondino, F. et al. CALIBRATION OF A MULTI-SENSOR WHEELED ROBOT FOR THE 3D MAPPING OF UNDERGROUND MINING TUNNELS. Int. Arch. Photogramm. Remote Sens. Spatial Inf. Sci., XLVIII-2/W2-2022, 135–142 (2022).

If you use our work, please cite:

@article{Trybala2023MIN3D,
  title = {MIN3D Dataset: MultI-seNsor 3D Mapping with an Unmanned Ground Vehicle},
  ISSN = {2512-2819},
  url = {http://dx.doi.org/10.1007/s41064-023-00260-0},
  DOI = {10.1007/s41064-023-00260-0},
  journal = {PFG – Journal of Photogrammetry,  Remote Sensing and Geoinformation Science},
  publisher = {Springer Science and Business Media LLC},
  author = {Trybała,  Paweł and Szrek,  Jarosław and Remondino,  Fabio and Kujawa,  Paulina and Wodecki,  Jacek and Blachowski,  Jan and Zimroz,  Radosław},
  year = {2023},
  month = oct 
}

@article{Trybala2022calibration,
  title = {CALIBRATION OF A MULTI-SENSOR WHEELED ROBOT FOR THE 3D MAPPING OF UNDERGROUND MINING TUNNELS},
  volume = {XLVIII-2/W2-2022},
  ISSN = {2194-9034},
  url = {http://dx.doi.org/10.5194/isprs-archives-XLVIII-2-W2-2022-135-2022},
  DOI = {10.5194/isprs-archives-xlviii-2-w2-2022-135-2022},
  journal = {The International Archives of the Photogrammetry,  Remote Sensing and Spatial Information Sciences},
  publisher = {Copernicus GmbH},
  author = {Trybała,  P. and Szrek,  J. and Remondino,  F. and Wodecki,  J. and Zimroz,  R.},
  year = {2022},
  month = dec,
  pages = {135–142}
}

Dataset

Sensor Setup

Sensor/Device	Model	Specification
Basler Stereo	acA1440-220um	2x720x540 px, 15 Hz
Intel RealSense RGB	D455	640x480 px, 15 Hz
Intel RealSense Stereo	D455	2x640x480 px, 15 Hz
Intel RealSense Depth	D455	640x480 px, 15 Hz
FLIR IR	VUE-640	640x512 px, 15 Hz
LiDAR#1	Livox Horizon	10 Hz, ~20 mm accuracy individual point timestamps
LiDAR#2	Velodyne VLP-16	10 Hz, ~20 mm accuracy, actuated (180° rotation)
IMU#1	Livox	6-axis, 200 Hz
IMU#2	RealSense	6-axis, 400 Hz
IMU#3	NGIMU	6-axis, 20 Hz
GT 3D Scanner	Riegl VZ-400i	~5 mm accuracy

Point clouds shared as .ply files

RGB/IR images as .png files

Depth maps: .png images, 16bit int - metric depth in millimeters

IMU data as .csv files

Ground Truth Point Clouds

Acquired with a Riegl VZ-400i TLS and registered with RiScan PRO

Data Sequences

Our dataset consists of 8 sequences in total.

University dataset

Sequence	1	2	3
Thumbnail
Features	Ground floor	Ground floor-outdoor loop	Multiple indoor loops with varying illumination
Size [GB]	26.1	22.1	18.9
Cameras
Basler stereo	uni_1_basler_left, uni_1_basler_right	uni_2_basler_left, uni_2_basler_right	uni_3_basler_left, uni_3_basler_right
RGB	uni_1_rgb	uni_2_rgb	uni_3_rgb
RealSense Stereo	uni_1_realsense_left, uni_1_realsense_right	uni_2_realsense_left, uni_2_realsense_right	uni_3_realsense_left, uni_3_realsense_right
RealSense Depth	uni_1_realsense_depth	uni_2_realsense_depth	uni_3_realsense_depth
RealSense RGB	uni_1_realsense_rgb	uni_2_realsense_rgb	uni_3_realsense_rgb
FLIR IR	uni_1_ir	uni_2_ir	uni_3_ir
IMUs
Livox internal IMU	uni_1_imu_livox	uni_2_imu_livox	uni_3_imu_livox
RealSense IMU	uni_1_imu_realsense	uni_2_imu_realsense	uni_3_imu_realsense
NGIMU	uni_1_ngimu_accelerations, uni_1_ngimu_euler_angles	uni_2_ngimu_accelerations, uni_2_ngimu_euler_angles	uni_3_ngimu_accelerations, uni_3_ngimu_euler_angles
LiDARs
Velodyne VLP-16	uni_1_velodyne	uni_2_velodyne	uni_3_velodyne
Livox	uni_1_livox	uni_2_livox	uni_3_livox
Ground truth
Riegl VZ-400i	uni_1_gt	uni_2_gt	uni_3_gt
Calibration data	calibration

Underground dataset

Sequence	1	2	3	4	5
Features	Main tunnel, forward pass	Main tunnel, return pass	Loop closures, complicated trajectory	Lost camera problem, loop closures	Side tunnel, less structured
Size [GB]	13.2	10.8	17.9	13.9	22.5
Cameras
Basler stereo	und_1_basler_left, und_1_basler_right	und_2_basler_left, und_2_basler_right	und_3_basler_left, und_3_basler_right	und_4_basler_left, und_4_basler_right	und_5_basler_left, und_5_basler_right
RGB	und_1_rgb	und_2_rgb	und_3_rgb	und_4_rgb	und_5_rgb
RealSense Stereo	und_1_realsense_left, und_1_realsense_right	und_2_realsense_left, und_2_realsense_right	und_3_realsense_left, und_3_realsense_right	und_4_realsense_left, und_4_realsense_right	und_5_realsense_left, und_5_realsense_right
RealSense Depth	und_1_realsense_depth	und_2_realsense_depth	und_3_realsense_depth	und_4_realsense_depth	und_5_realsense_depth
RealSense RGB	und_1_realsense_rgb	und_2_realsense_rgb	und_3_realsense_rgb	und_4_realsense_rgb	und_5_realsense_rgb
FLIR IR	und_1_ir	und_2_ir	und_3_ir	und_4_ir	und_5_ir
IMUs
Livox internal IMU	und_1_imu_livox	und_2_imu_livox	und_3_imu_livox	und_4_imu_livox	und_5_imu_livox
RealSense IMU	und_1_imu_realsense	und_2_imu_realsense	und_3_imu_realsense	und_4_imu_realsense	und_5_imu_realsense
NGIMU	und_1_ngimu_accelerations, und_1_ngimu_euler_angles	und_2_ngimu_accelerations, und_2_ngimu_euler_angles	und_3_ngimu_accelerations, und_3_ngimu_euler_angles	und_4_ngimu_accelerations, und_5_ngimu_euler_angles	und_5_ngimu_accelerations, und_5_ngimu_euler_angles
LiDARs
Velodyne VLP-16	und_1_velodyne	und_2_velodyne	und_3_velodyne	und_4_velodyne	und_5_velodyne
Livox	und_1_livox	und_2_livox	und_3_livox	und_4_livox	und_5_livox
Ground truth
Riegl VZ-400i	underground_gt (save as a .las file)
Calibration data (same as University)	calibration

Acknowledgements

The authors offer special thanks to Walimskie Drifts in Walim (https://sztolnie.pl) for making the facility available for data acquisition.

Funding

This work was partly supported by EIT RawMaterials GmbH within the activities of the AMICOS—Autonomous Monitoring and Control System for Mining Plants—project (Agreement No. 19018) and VOT3D—project (Agreement No. 21119). The work was also partly supported by the FAIR project, Piano Nazionale di Ripresa e Resilienza.

Contact

This dataset is provided for academic purposes. For any inquiries please contact <Paweł Trybała: ptrybala@fbk.eu>.

License

The data provided here is licensed under the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.