使用谱图小波的多机器人协作绘图框架

Lukas Bernreiter, Shehryar Khattak, Lionel Ott, Roland Siegwart, Marco Hutter, Cesar Cadena
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引用次数: 0

摘要

在探索大规模未知环境时,可以部署多个机器人进行协作绘图。每个机器人探索环境的一部分,并将机载姿态估计值和地图传送到中央服务器,以构建优化的全局多机器人地图。当然,由于机载里程计漂移、故障或退化等原因,机载估计值和服务器估计值之间可能会出现不一致。映射服务器可以通过计算成本高昂的操作(如机器人间闭环检测和多模式映射)来纠正和克服这些故障情况。但是,如果制图服务器不提供反馈,单个机器人就无法从协作地图中获益。虽然来自多机器人地图的服务器更新可以从战略上大大减轻机器人的任务,但由于其相关的计算和带宽成本,大多数现有工作都缺乏这种更新。在这一挑战的激励下,本文提出了一种新型协作映射框架,可实现机器人与映射服务器之间的全局映射一致性。我们特别提出了不同空间尺度的图谱分析,以检测机器人和服务器图之间的结构差异,并为单个机器人姿势图生成必要的约束。我们的方法专门查找与漂移原点相对应的节点,而不是误差过大的节点。我们利用几个真实世界的多机器人现场部署对我们提出的框架进行了全面分析和验证,结果表明机载系统的改进率高达 90%,并能从定位失败中恢复机载估计,甚至从其估计中的退化中恢复。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A framework for collaborative multi-robot mapping using spectral graph wavelets
The exploration of large-scale unknown environments can benefit from the deployment of multiple robots for collaborative mapping. Each robot explores a section of the environment and communicates onboard pose estimates and maps to a central server to build an optimized global multi-robot map. Naturally, inconsistencies can arise between onboard and server estimates due to onboard odometry drift, failures, or degeneracies. The mapping server can correct and overcome such failure cases using computationally expensive operations such as inter-robot loop closure detection and multi-modal mapping. However, the individual robots do not benefit from the collaborative map if the mapping server provides no feedback. Although server updates from the multi-robot map can greatly alleviate the robotic mission strategically, most existing work lacks them, due to their associated computational and bandwidth-related costs. Motivated by this challenge, this paper proposes a novel collaborative mapping framework that enables global mapping consistency among robots and the mapping server. In particular, we propose graph spectral analysis, at different spatial scales, to detect structural differences between robot and server graphs, and to generate necessary constraints for the individual robot pose graphs. Our approach specifically finds the nodes that correspond to the drift’s origin rather than the nodes where the error becomes too large. We thoroughly analyze and validate our proposed framework using several real-world multi-robot field deployments where we show improvements of the onboard system up to 90% and can recover the onboard estimation from localization failures and even from the degeneracies within its estimation.
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