Online pole segmentation on range images for long-term LiDAR localization in urban environments

Robust and accurate localization is a basic requirement for mobile autonomous systems. Pole-like objects, such as traffic signs, poles, and lamps are frequently used landmarks for localization in urban environments due to their local distinctiveness and long-term stability. In this paper, we present a novel, accurate, and fast pole extraction approach based on geometric features that runs online and has little computational demands. Our method performs all computations directly on range images generated from 3D LiDAR scans, which avoids processing 3D point clouds explicitly and enables fast pole extraction for each scan. We further use the extracted poles as pseudo labels to train a deep neural network for online range image-based pole segmentation. We test both our geometric and learning -based pole extraction methods for localization on different datasets with different LiDAR scanners, routes, and seasonal changes. The experimental results show that our methods outperform other state-of-the-art approaches. Moreover, boosted with pseudo pole labels extracted from multiple datasets, our learning-based method can run across different datasets and achieve even better localization results compared to our geometry-based method. We released our pole datasets to the public for evaluating the performance of pole extractors, as well as the implementation of our approach.(c) 2022 Elsevier B.V. All rights reserved.

Automated summary

This paper introduces a novel, accurate, and fast pole extraction approach based on geometric features. The method performs computations directly on range images generated from 3D LiDAR scans and uses the extracted poles as pseudo labels to train a deep neural network for online pole segmentation. Experimental results demonstrate that the proposed method outperforms other approaches in localization on different datasets and LiDAR scanners.