Abstract
Abstract. With the rapid development of autonomous vehicles (AV) and high-definition (HD) maps, up-to-date lane marking information is necessary. Over the years, several lane marking extraction approaches have been proposed with many of them based on accurate and dense Light Detection and Ranging (LiDAR) point cloud data collected by mobile mapping systems (MMS). This study proposes a normalized intensity thresholding strategy and a deep learning strategy with automatically generated labels. The former extracts lane markings directly from LiDAR point clouds while the latter utilizes 2D intensity images generated from the LiDAR point cloud. Additionally, the proposed approaches are also compared with state-of-the-art strategies such as original intensity thresholding and a deep learning approach based on manually established labels. Finally, each strategy is evaluated in asphalt and concrete pavements separately to assess their sensitivity to the nature of pavement surface. The results show that the deep learning model trained with automatically generated labels performs the best in both asphalt and concrete pavement area with an F1-score of 84.9% and 85.1%. In asphalt pavement area, original intensity thresholding strategy shows a lane marking extraction performance comparable to the other strategies while in concrete pavement area, it is significantly poor with an F1-score of 65.1%. Between the proposed normalized intensity thresholding and deep learning model trained with manually labeled data, the former performs better in asphalt pavement area while the latter obtains better results in concrete pavements.
Highlights
With the advent of autonomous vehicles (AV) and advanced driver assistance systems (ADAS), high-definition (HD) maps with lane-level details such as pedestrian crosswalks, signalized intersection, and bike lanes are necessary for navigation and route planning
In order to accurately evaluate the quality of lane markings, Light Detection and Ranging (LiDAR) point clouds are chosen in this research since they can be obtained in a short interval of time with high density and accuracy without being affected by weather, lighting, or occlusions
We first discuss the lookup table (LUT) generated from normalized intensity thresholding for each dataset and show how this strategy successfully reduces false positives in concrete pavement regions without affecting performance in asphalt areas
Summary
With the advent of autonomous vehicles (AV) and advanced driver assistance systems (ADAS), high-definition (HD) maps with lane-level details such as pedestrian crosswalks, signalized intersection, and bike lanes are necessary for navigation and route planning. It is required to provide detailed and up-to-date information about lane markings along the road surface. In order to accurately evaluate the quality of lane markings, LiDAR point clouds are chosen in this research since they can be obtained in a short interval of time with high density and accuracy without being affected by weather, lighting, or occlusions. The intensity information provided by LiDAR can be used to assess the quality of lane markings by departments of transportation for road maintenance operations. Since lane markings are retro-reflective materials painted on low albedo pavements (asphalt or concrete), the extraction using LiDAR point clouds mainly depends on intensity thresholding. Many researchers rasterized the point cloud into an intensity image for lane marking extraction to reduce computations. LiDAR data-based strategies can be classified into two categories based on input data: (1) 3D
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