SLAM-RAMU:3D 激光雷达-IMU 终身 SLAM,具有重新定位和自主地图更新功能,可实现准确可靠的导航

Bushi Chen, Xunyu Zhong, Han Xie, Pengfei Peng, Huosheng Hu, Xungao Zhong, Qiang Liu
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引用次数: 0

摘要

目的自主移动机器人(AMR)在工业和服务领域发挥着至关重要的作用。本文旨在建立一个基于激光雷达的同步定位和绘图(SLAM)系统,供 AMR 使用,以克服在动态和变化环境中遇到的各种挑战。在映射过程中,使用迭代误差状态卡尔曼滤波法获得局部里程测量,同时使用后端环路检测和全局姿态图优化进行精确轨迹校正。此外,还加入了快速点云分割模块,以稳健地区分环境中的地面、墙壁和屋顶。分割后的点云随后用于生成 2.5D 网格图,特别强调地板检测,以过滤先验图并消除动态伪影。在定位过程中,设计了一种初始姿态对齐方法,该方法结合了二维分支和边界搜索以及三维迭代最近点注册。这种方法即使在具有相似特征的场景中也能确保高精度。随后,在先验地图上使用分割点云进行扫描到地图的注册。该系统还包括一个地图更新模块,可将历史点云分割结果考虑在内。研究结果在真实环境中对 SLAM-RAMU 系统的性能进行了评估,并与最先进的(SOTA)方法进行了比较。结果表明,SLAM-RAMU 可实现更高的制图质量和重新定位精度,并在面对动态障碍物和环境变化时表现出鲁棒性。原创性/价值在模拟和真实环境中,与其他 SOTA 方法相比,SLAM-RAMU 表现出更高的制图质量、更快的初始对准速度和更高的重复定位精度。
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SLAM-RAMU: 3D LiDAR-IMU lifelong SLAM with relocalization and autonomous map updating for accurate and reliable navigation

Purpose

Autonomous mobile robots (AMRs) play a crucial role in industrial and service fields. The paper aims to build a LiDAR-based simultaneous localization and mapping (SLAM) system used by AMRs to overcome challenges in dynamic and changing environments.

Design/methodology/approach

This research introduces SLAM-RAMU, a lifelong SLAM system that addresses these challenges by providing precise and consistent relocalization and autonomous map updating (RAMU). During the mapping process, local odometry is obtained using iterative error state Kalman filtering, while back-end loop detection and global pose graph optimization are used for accurate trajectory correction. In addition, a fast point cloud segmentation module is incorporated to robustly distinguish between floor, walls and roof in the environment. The segmented point clouds are then used to generate a 2.5D grid map, with particular emphasis on floor detection to filter the prior map and eliminate dynamic artifacts. In the positioning process, an initial pose alignment method is designed, which combines 2D branch-and-bound search with 3D iterative closest point registration. This method ensures high accuracy even in scenes with similar characteristics. Subsequently, scan-to-map registration is performed using the segmented point cloud on the prior map. The system also includes a map updating module that takes into account historical point cloud segmentation results. It selectively incorporates or excludes new point cloud data to ensure consistent reflection of the real environment in the map.

Findings

The performance of the SLAM-RAMU system was evaluated in real-world environments and compared against state-of-the-art (SOTA) methods. The results demonstrate that SLAM-RAMU achieves higher mapping quality and relocalization accuracy and exhibits robustness against dynamic obstacles and environmental changes.

Originality/value

Compared to other SOTA methods in simulation and real environments, SLAM-RAMU showed higher mapping quality, faster initial aligning speed and higher repeated localization accuracy.

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