Abstract
“Collision warning systems” are actively researched in the area of computer vision and the automotive industry. Using monocular vision only, this chapter discusses the part of our study that aims at detecting and tracking the vehicles ahead, to identify safety distances, and to provide timely information to assist a distracted driver under various weather and lighting conditions. As part of the work presented in this chapter, we also adopt the previously discussed dynamic global Haar (DGHaar) features for vehicle detection. We introduce “taillight segmentation” and a “virtual symmetry detection” technique for pairing the rear-light contours of the vehicles on the road. Applying a heuristic geometric solution, we also develop a method for inter-vehicle “distance estimation” using only a monocular vision sensor. Inspired by Dempster–Shafer theory, we finally fuse all the available clues and information to reach a higher degree of certainty. The proposed algorithm is able to detect vehicles ahead both at day and night, and also for a wide range of distances. Experimental results under various conditions, including sunny, rainy, foggy, or snowy weather, show that the proposed algorithm outperforms other currently published algorithms that are selected for comparison.
Notes
- 1.
We refer to challenging lighting conditions when the subject (e.g. a vehicle) is located under any non-ideal condition such as very low light, night, very bright reflections, rainy, foggy, or snowy weather, where object detection becomes very difficult, from a technical point of view.
- 2.
Experimentally identified as the optimum value.
- 3.
Instead of 10, it could be any other number. The more the sets the better the interpolation results. The number 10 proved to be sufficient for obtaining an acceptable interpolation.
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Rezaei, M., Klette, R. (2017). Vehicle Detection and Distance Estimation. In: Computer Vision for Driver Assistance. Computational Imaging and Vision, vol 45. Springer, Cham. https://doi.org/10.1007/978-3-319-50551-0_7
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