Authors: Yasuhiro Matsui—National Traffic Safety and Environment Laboratory, Japan; Shoko Oikawa—Tokyo Metropolitan University
Abstract
Vehicles that start moving from a stationary position can cause fatal traffic accidents involving pedestrians. Ultrasonic sensors installed in the vehicle front are an active technology designed to alert drivers to the presence of stationary objects such as rigid walls in front of their vehicles. However, the ability of such sensors to detect humans has not yet been established. Therefore, this study aims to ascertain whether these sensor systems can successfully detect humans. First, we conducted experiments using four vehicles equipped with ultrasonic sensor systems for vehicle-forward moving-off maneuvers and investigated the detection distances between the vehicles and a pipe (1 m long and having a diameter of 75 mm), child, adult female, or adult male. The detections of human volunteers were evaluated under two different conditions: front-facing and side-facing toward the front of each vehicle. Front-facing is defined as the condition where the human faces the vehicle front, while side-facing is that where the side of the human faces it. For both the front-facing and side-facing conditions, the results indicated that the sensor-detection distances for a child were shorter than those for the pipe, whereas those for adults were less than or approximately equivalent to those for the pipe. These results revealed that ultrasonic sensor systems for vehicle-forward moving-off maneuvers can detect not only stationary objects but also humans, indicating that ultrasonic sensors installed in the vehicle front could possibly reduce the risk of vehicle-forward moving-off accidents involving pedestrians.
Type: Full Paper
Keywords: Vehicle-forward moving-off accidents, ultrasonic sensors, pedestrian detection systems, vehicle front
© Stapp Association, 2021
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