M. Flottmann, Marc Eisoldt, Julian Gaal, Marc Rothmann, M. Tassemeier, T. Wiemann, Mario Porrmann
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引用次数: 8
Abstract
Being one of the fundamental problems in autonomous robotics, SLAM (Simultaneous Localization and Mapping) algorithms have gained a lot of attention. Although numerous approaches have been presented for determining 6D poses in 3D environments, one of the main challenges that remains is the required combination of real-time processing and high energy efficiency. In this paper, a combination of CPU and FPGA processing is used to tackle this problem, utilizing a reconfigurable SoC. We present a complete solution for embedded LiDAR-based SLAM that uses a global Truncated Signed Distance Function (TSDF) as map representation. A hardware-in-the-loop environment with ROS integration enables efficient evaluation of new variants of algorithms and implementations. Based on benchmark data sets and real-world environments, we show that our approach compares well to established SLAM algorithms. Compared to a software implementation on a state-of-the-art PC, the proposed implementation achieves a 7-fold speed-up and requires 18 times less energy when using a Xilinx UltraScale+ XCZU15EG.
SLAM (Simultaneous Localization and Mapping)算法作为自主机器人的基础问题之一,受到了广泛的关注。尽管已经提出了许多方法来确定3D环境中的6D姿势,但仍然存在的主要挑战之一是需要将实时处理和高能效结合起来。在本文中,使用CPU和FPGA处理的组合来解决这个问题,利用可重构的SoC。我们提出了一个基于嵌入式激光雷达的SLAM的完整解决方案,该解决方案使用全局截断签名距离函数(TSDF)作为地图表示。具有ROS集成的硬件在环环境可以有效地评估算法和实现的新变体。基于基准数据集和现实世界环境,我们证明了我们的方法与已建立的SLAM算法相比较。与最先进的PC上的软件实现相比,当使用赛灵思UltraScale+ XCZU15EG时,拟议的实现实现了7倍的加速,所需的能量减少了18倍。
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