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Main Authors: Wu, Jianshi, Zhu, Minghang, Liu, Dunqiang, Li, Wen, Ao, Sheng, Shen, Siqi, Wen, Chenglu, Wang, Cheng
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.11355
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author Wu, Jianshi
Zhu, Minghang
Liu, Dunqiang
Li, Wen
Ao, Sheng
Shen, Siqi
Wen, Chenglu
Wang, Cheng
author_facet Wu, Jianshi
Zhu, Minghang
Liu, Dunqiang
Li, Wen
Ao, Sheng
Shen, Siqi
Wen, Chenglu
Wang, Cheng
contents LiDAR relocalization has attracted increasing attention as it can deliver accurate 6-DoF pose estimation in complex 3D environments. Recent learning-based regression methods offer efficient solutions by directly predicting global poses without the need for explicit map storage. However, these methods often struggle in challenging scenes due to their equal treatment of all predicted points, which is vulnerable to noise and outliers. In this paper, we propose LEADER, a robust LiDAR-based relocalization framework enhanced by a simple, yet effective geometric encoder. Specifically, a Robust Projection-based Geometric Encoder architecture which captures multi-scale geometric features is first presented to enhance descriptiveness in geometric representation. A Truncated Relative Reliability loss is then formulated to model point-wise ambiguity and mitigate the influence of unreliable predictions. Extensive experiments on the Oxford RobotCar and NCLT datasets demonstrate that LEADER outperforms state-of-the-art methods, achieving 24.1% and 73.9% relative reductions in position error over existing techniques, respectively. The source code is released on https://github.com/JiansW/LEADER.
format Preprint
id arxiv_https___arxiv_org_abs_2604_11355
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle LEADER: Learning Reliable Local-to-Global Correspondences for LiDAR Relocalization
Wu, Jianshi
Zhu, Minghang
Liu, Dunqiang
Li, Wen
Ao, Sheng
Shen, Siqi
Wen, Chenglu
Wang, Cheng
Computer Vision and Pattern Recognition
LiDAR relocalization has attracted increasing attention as it can deliver accurate 6-DoF pose estimation in complex 3D environments. Recent learning-based regression methods offer efficient solutions by directly predicting global poses without the need for explicit map storage. However, these methods often struggle in challenging scenes due to their equal treatment of all predicted points, which is vulnerable to noise and outliers. In this paper, we propose LEADER, a robust LiDAR-based relocalization framework enhanced by a simple, yet effective geometric encoder. Specifically, a Robust Projection-based Geometric Encoder architecture which captures multi-scale geometric features is first presented to enhance descriptiveness in geometric representation. A Truncated Relative Reliability loss is then formulated to model point-wise ambiguity and mitigate the influence of unreliable predictions. Extensive experiments on the Oxford RobotCar and NCLT datasets demonstrate that LEADER outperforms state-of-the-art methods, achieving 24.1% and 73.9% relative reductions in position error over existing techniques, respectively. The source code is released on https://github.com/JiansW/LEADER.
title LEADER: Learning Reliable Local-to-Global Correspondences for LiDAR Relocalization
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2604.11355