LIDAR-based SLAM system for autonomous vehicles in degraded point cloud scenarios: dynamic obstacle removal

Qihua Ma, Qilin Li, Wenchao Wang, Meng Zhu
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Abstract

Purpose

This study aims to achieve superior localization and mapping performance in point cloud degradation scenarios through the effective removal of dynamic obstacles. With the continuous development of various technologies for autonomous vehicles, the LIDAR-based Simultaneous localization and mapping (SLAM) system is becoming increasingly important. However, in SLAM systems, effectively addressing the challenges of point cloud degradation scenarios is essential for accurate localization and mapping, with dynamic obstacle removal being a key component.

Design/methodology/approach

This paper proposes a method that combines adaptive feature extraction and loop closure detection algorithms to address this challenge. In the SLAM system, the ground point cloud and non-ground point cloud are separated to reduce the impact of noise. And based on the cylindrical projection image of the point cloud, the intensity features are adaptively extracted, the degradation direction is determined by the degradation factor and the intensity features are matched with the map to correct the degraded pose. Moreover, through the difference in raster distribution of the point clouds before and after two frames in the loop process, the dynamic point clouds are identified and removed, and the map is updated.

Findings

Experimental results show that the method has good performance. The absolute displacement accuracy of the laser odometer is improved by 27.1%, the relative displacement accuracy is improved by 33.5% and the relative angle accuracy is improved by 23.8% after using the adaptive intensity feature extraction method. The position error is reduced by 30% after removing the dynamic target.

Originality/value

Compared with LiDAR odometry and mapping algorithm, the method has greater robustness and accuracy in mapping and localization.

基于激光雷达的自动驾驶车辆退化点云场景 SLAM 系统:动态障碍物清除
目的 本研究旨在通过有效清除动态障碍物,在点云退化的情况下实现卓越的定位和测绘性能。随着自动驾驶汽车各种技术的不断发展,基于激光雷达的同步定位和绘图(SLAM)系统变得越来越重要。然而,在 SLAM 系统中,有效应对点云衰减场景的挑战对于精确定位和绘图至关重要,而动态障碍物清除则是其中的关键环节。在 SLAM 系统中,地面点云和非地面点云被分离,以减少噪声的影响。基于点云的圆柱投影图像,自适应地提取强度特征,根据退化因子确定退化方向,并将强度特征与地图进行匹配,以校正退化姿态。此外,在循环过程中,通过前后两帧点云的栅格分布差异,识别并剔除动态点云,更新地图。使用自适应强度特征提取方法后,激光里程表的绝对位移精度提高了 27.1%,相对位移精度提高了 33.5%,相对角度精度提高了 23.8%。原创性/价值与激光雷达里程计和测绘算法相比,该方法在测绘和定位方面具有更高的鲁棒性和准确性。
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