Abstract
Creating 3D models of the static environment is an important task for the advancement of driver assistance systems and autonomous driving. In this work, a static reference map is created from a Mobile Mapping “light detection and ranging” (LiDAR) dataset. The data was obtained in 14 measurement runs from March to October 2017 in Hannover and consists in total of about 15 billion points. The point cloud data are first segmented by region growing and then processed by a random forest classification, which divides the segments into the five static classes (“facade”, “pole”, “fence”, “traffic sign”, and “vegetation”) and three dynamic classes (“vehicle”, “bicycle”, “person”) with an overall accuracy of 94%. All static objects are entered into a voxel grid, to compare different measurement epochs directly. In the next step, the classified voxels are combined with the result of a visibility analysis. Therefore, we use a ray tracing algorithm to detect traversed voxels and differentiate between empty space and occlusion. Each voxel is classified as suitable for the static reference map or not by its object class and its occupation state during different epochs. Thereby, we avoid to eliminate static voxels which were occluded in some of the measurement runs (e.g. parts of a building occluded by a tree). However, segments that are only temporarily present and connected to static objects, such as scaffolds or awnings on buildings, are not included in the reference map. Overall, the combination of the classification with the subsequent entry of the classes into a voxel grid provides good and useful results that can be updated by including new measurement data.
Highlights
Driver assistance systems and functions of semi-automated driving are already an integral part of new vehicles and help to relieve the driver to increase road safety
Research is tending more and more towards autonomous vehicles that can automatically recognise obstacles and react . 52% of the worldwide patents in the field of automated driving come from Germany and the development potential is still enormous and wide-ranging (Eckstein et al 2018)
Dynamic objects can be analysed, e.g. to detect parking lots or areas which are often crowded with pedestrians
Summary
Driver assistance systems and functions of semi-automated driving are already an integral part of new vehicles and help to relieve the driver to increase road safety. 52% of the worldwide patents in the field of automated driving come from Germany and the development potential is still enormous and wide-ranging (Eckstein et al 2018). When using these systems, it is essential that they have a highly accurate and up-to-date 3D model of the environment that can integrate changes. The first step to create such a model is to record the environment One approach for this is Mobile Mapping, in which the environment is measured, e.g. by mobile laser scanners, cameras or a combination of both. As a result the individual elements are each assigned to a class Dynamic objects can be analysed, e.g. to detect parking lots or areas which are often crowded with pedestrians
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