Conversion of depth images into planar laserscans considering obstacle height for collision free 2D robot navigation

2021 European Conference on Mobile Robots (ECMR) Pub Date : 2021-08-01 DOI:10.1109/ecmr50962.2021.9568795

Stephan Sandfuchs, Moritz P. Heimbach, J. Weber, M. Schmidt

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引用次数: 2

Abstract

Mobile robots have become popular in many application areas over the last few decades. In order to perceive their environment in which they move autonomously, various sensors such as depth cameras are used. The processing of 3D information from depth images is very computationally expensive due to the large amount of data. However, for many mobile robots, navigation in a simplified 2D world is sufficient. For this purpose, the depth images of the environment can first be reduced to 2D information in the form of a laserscan line and then processed with algorithms for localization and mapping. This paper improves an existing algorithm that converts depth images into laserscans and tests it on a real robot in a real world scenario. In contrast to the original algorithm, the improved algorithm considers 3D information such as the height of the robot and obstacles when creating the laserscan line. This allows a mobile robot to navigate in a simplified 2D world without colliding with obstacles in the real 3D world. Since processing the 3D information is computationally expensive, the algorithm was optimized to be executable on low-cost single-board computers.

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无碰撞机器人导航中考虑障碍物高度的深度图像到平面激光扫描图像的转换

在过去的几十年里，移动机器人在许多应用领域都很受欢迎。为了感知它们自主移动的环境，使用了各种传感器，如深度相机。从深度图像中处理三维信息，由于数据量大，计算成本非常高。然而，对于许多移动机器人来说，在简化的二维世界中导航就足够了。为此，可以首先将环境的深度图像以激光扫描线的形式简化为二维信息，然后使用定位和映射算法进行处理。本文改进了现有的将深度图像转换为激光扫描的算法，并在真实世界场景中的真实机器人上进行了测试。与原始算法相比，改进算法在创建激光扫描线时考虑了机器人高度和障碍物等三维信息。这使得移动机器人可以在简化的2D世界中导航，而不会与真实的3D世界中的障碍物发生碰撞。由于处理三维信息的计算成本很高，因此该算法经过优化，可以在低成本的单板计算机上执行。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2021 European Conference on Mobile Robots (ECMR)

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