Abstract
Recently, the number of vehicles equipped with the Lane Keeping Assistance System (LKAS) is increasing. Therefore, safety evaluation to validate the LKAS has become more important. However, the actual vehicle test for safety evaluation has disadvantages such as the need for professional manpower, the use of expensive equipment, and environmental constraints. Therefore, we attempted to solve this problem using the dual cameras system with only inexpensive and accessible cameras. The optimal position of the dual cameras, image and focal length correction, and lane detection methods proposed in previous studies were used, and a theoretical equation for calculating the distance from the front wheel of the vehicle to the driving lane was proposed. For the actual vehicle testing, LKAS safety evaluation scenarios proposed in previous studies were used. According to the test results, the maximum error was 0.17 m, which indicated the reliability of the method because all errors in the tested scenarios exhibited similar trends and values. Therefore, through the use of the proposed theoretical equations in conjunction with inexpensive cameras, it is possible to reduce time, cost, and environmental problems in the development, vehicle application, and safety evaluation of LKAS components.
Highlights
The Lane Keeping Assistance System (LKAS) is a type of autonomous driving technology used in Advanced Driver Assistance Systems (ADASs)
This study proposed a theoretical equation for the LKAS safety evaluation, and the scenario was used because the actual test for verification was conducted on domestic general roads
A theoretical equation for the safety evaluation of the LKAS using dual cameras was proposed, and an actual vehicle test was conducted for verification
Summary
The Lane Keeping Assistance System (LKAS) is a type of autonomous driving technology used in Advanced Driver Assistance Systems (ADASs). Theoretical formulas were proposed and actual vehicle tests were conducted according to the test and evaluation procedure Methods such as correction and lane detection methods and camera mounting location determination were cited from the previous study in [28], and test evaluation scenarios were cited from the related study in [29]. The equation is based on an existing lane detection algorithm and image and focal length correction method, and on the optimal dual-camera position as determined in previous research It enables theoretical verification of the proposed theoretical equation in an environment where ADAS-related parts development or actual vehicle safety evaluation is impossible. This study proposed a theoretical equation for the LKAS safety evaluation, and the scenario was used because the actual test for verification was conducted on domestic general roads. The heading angle was obtained in approximately 1 s, and the vehicle returned to its driving lane in approximately 7 s
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