Abstract
Over the past few decades, pavement markings have played a key role in intelligent vehicle applications such as guidance, navigation, and control. However, there are still serious issues facing the problem of lane marking detection. For example, problems include excessive processing time and false detection due to similarities in color and edges between traffic signs (channeling lines, stop lines, crosswalk, arrows, etc.). This paper proposes a strategy to extract the lane marking information taking into consideration its features such as color, edge, and width, as well as the vehicle speed. Firstly, defining the region of interest is a critical task to achieve real-time performance. In this sense, the region of interest is dependent on vehicle speed. Secondly, the lane markings are detected by using a hybrid color-edge feature method along with a probabilistic method, based on distance-color dependence and a hierarchical fitting model. Thirdly, the following lane marking information is extracted: the number of lane markings to both sides of the vehicle, the respective fitting model, and the centroid information of the lane. Using these parameters, the region is computed by using a road geometric model. To evaluate the proposed method, a set of consecutive frames was used in order to validate the performance.
Highlights
The automotive industry is currently experiencing strong growth
A vision based real-time lane marking, lane understanding application was presented for use in intelligent vehicles
To introduce an automated method for extracting the region of interest based on the relationship between the vehicle speed and the typical stopping distance within the image
Summary
The automotive industry is currently experiencing strong growth. Factors behind this are increasing congestion, environmental issues, wireless network expansion, efficiencies in automotive logistics, and demand for driver, passenger, and pedestrian safety. In that sense, advanced driver assistance systems (ADAS) have shown a very significant development since the early 1970s. ADAS focuses on vision-based applications, with examples including lane departure warnings, lane keep assist, pedestrian detection, and collision avoidance. Recent technological advancements show significant development results, there are still problems to solve. Actively-researched problems include gauging uncertainty in a static/dynamic environment, improving processing time response, and managing road complexity
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