Jean-François Lalonde, R. Unnikrishnan, N. Vandapel, M. Hebert
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引用次数: 93
Abstract
Three-dimensional ladar data are commonly used to perform scene understanding for outdoor mobile robots, specifically in natural terrain. One effective method is to classify points using features based on local point cloud distribution into surfaces, linear structures or clutter volumes. But the local features are computed using 3D points within a support-volume. Local and global point density variations and the presence of multiple manifolds make the problem of selecting the size of this support volume, or scale, challenging. In this paper, we adopt an approach inspired by recent developments in computational geometry (Mitra et al., 2005) and investigate the problem of automatic data-driven scale selection to improve point cloud classification. The approach is validated with results using data from different sensors in various environments classified into different terrain types (vegetation, solid surface and linear structure).
三维雷达数据通常用于户外移动机器人的场景理解,特别是在自然地形中。一种有效的方法是利用基于局部点云分布的特征将点分类为曲面、线性结构或杂波体。但局部特征是使用支撑体内的3D点计算的。局部和全局点密度的变化以及多个流形的存在使得选择支持体积的大小或规模的问题具有挑战性。在本文中,我们采用了一种受计算几何最新发展启发的方法(Mitra et al., 2005),并研究了自动数据驱动的尺度选择问题,以改进点云分类。利用不同环境(植被、固体表面和线性结构)中不同传感器的数据对该方法进行了验证。
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