Quatro++: Robust global registration exploiting ground segmentation for loop closing in LiDAR SLAM

Quatro++: Robust global registration exploiting ground segmentation for loop closing in LiDAR SLAM

Global registration is a fundamental task that estimates the relative pose between two viewpoints of 3D point clouds. However, there are two issues that degrade the performance of global registration in LiDAR SLAM: one is the sparsity issue and the other is degeneracy. The sparsity issue is caused b...

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Bibliographic Details
Published in:The International journal of robotics research Vol. 43; no. 5; pp. 685 - 715
Main Authors: Lim, Hyungtae, Kim, Beomsoo, Kim, Daebeom, Mason Lee, Eungchang, Myung, Hyun
Format: Journal Article
Language:English
Published: London, England SAGE Publications 01-04-2024
SAGE PUBLICATIONS, INC
Subjects:
Lidar
Outliers (statistics)
Performance degradation
Registration
Robustness
Segmentation
Sparsity
Three dimensional models
3D point cloud
global registration
LiDAR SLAM
ground segmentation
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Summary:Global registration is a fundamental task that estimates the relative pose between two viewpoints of 3D point clouds. However, there are two issues that degrade the performance of global registration in LiDAR SLAM: one is the sparsity issue and the other is degeneracy. The sparsity issue is caused by the sparse characteristics of the 3D point cloud measurements in a mechanically spinning LiDAR sensor. The degeneracy issue sometimes occurs because the outlier-rejection methods reject too many correspondences, leaving less than three inliers. These two issues have become more severe as the pose discrepancy between the two viewpoints of 3D point clouds becomes greater. To tackle these problems, we propose a robust global registration framework, called Quatro++. Extending our previous work that solely focused on the global registration itself, we address the robust global registration in terms of the loop closing in LiDAR SLAM. To this end, ground segmentation is exploited to achieve robust global registration. Through the experiments, we demonstrate that our proposed method shows a higher success rate than the state-of-the-art global registration methods, overcoming the sparsity and degeneracy issues. In addition, we show that ground segmentation significantly helps to increase the success rate for the ground vehicles. Finally, we apply our proposed method to the loop closing module in LiDAR SLAM and confirm that the quality of the loop constraints is improved, showing more precise mapping results. Therefore, the experimental evidence corroborated the suitability of our method as an initial alignment in the loop closing. Our code is available at https://quatro-plusplus.github.io.
ISSN:0278-3649
1741-3176
DOI:10.1177/02783649231207654