Abstract
Lane markings are one of the essential elements of road information, which is useful for a wide range of transportation applications. Several studies have been conducted to extract lane markings through intensity thresholding of Light Detection and Ranging (LiDAR) point clouds acquired by mobile mapping systems (MMS). This paper proposes an intensity thresholding strategy using unsupervised intensity normalization and a deep learning strategy using automatically labeled training data for lane marking extraction. For comparative evaluation, original intensity thresholding and deep learning using manually established labels strategies are also implemented. A pavement surface-based assessment of lane marking extraction by the four strategies is conducted in asphalt and concrete pavement areas covered by MMS equipped with multiple LiDAR scanners. Additionally, the extracted lane markings are used for lane width estimation and reporting lane marking gaps along various highways. The normalized intensity thresholding leads to a better lane marking extraction with an F1-score of 78.9% in comparison to the original intensity thresholding with an F1-score of 72.3%. On the other hand, the deep learning model trained with automatically generated labels achieves a higher F1-score of 85.9% than the one trained on manually established labels with an F1-score of 75.1%. In concrete pavement area, the normalized intensity thresholding and both deep learning strategies obtain better lane marking extraction (i.e., lane markings along longer segments of the highway have been extracted) than the original intensity thresholding approach. For the lane width results, more estimates are observed, especially in areas with poor edge lane marking, using the two deep learning models when compared with the intensity thresholding strategies due to the higher recall rates for the former. The outcome of the proposed strategies is used to develop a framework for reporting lane marking gap regions, which can be subsequently visualized in RGB imagery to identify their cause.
Highlights
Reliable identification of lane markings—including dash lines, edge lines, arrows, and crosswalk markings—is important for autonomous driving and driver assistance systems (ADAS) applications
Lane marking extraction through intensity thresholding of Light Detection and Ranging (LiDAR)-based mapping systems (MMS) point clouds has traditionally suffered from the problem of large false positives
In order to address these challenges, normalized intensity thresholding and deep learning strategies with automatically generated labels are proposed for extracting lane markings from LiDAR-based MMS point clouds
Summary
Reliable identification of lane markings—including dash lines, edge lines, arrows, and crosswalk markings—is important for autonomous driving and driver assistance systems (ADAS) applications. Lane marking extraction has become an essential process for many transportation applications. Several studies have been proposed to extract lane markings from imagery acquired by terrestrial and airborne platforms. Hernandez et al [1] extracted lane markings using vehicle-based imagery. Jung et al [2] detected lane markings from vehicle-based imagery. They first generated spatiotemporal imagery by accumulating the pixels on a horizontal scanline along a time axis for each frame. Azimi et al [3] proposed an Aerial LaneNet, a fully convolutional neural network (CNN) [4], for detecting lane markings in aerial imagery. Lane markings in imagery could be occluded by vehicles and other human-made features. The size and resolution of available imagery limit the ability to detect all lane markings
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
