Using Low-Cost Radar Sensors and Action Cameras to Measure Inter-Vehicle Distances in Real-World Truck Platooning
-
Published:2023-05-06
Issue:3
Volume:6
Page:55
-
ISSN:2571-5577
-
Container-title:Applied System Innovation
-
language:en
-
Short-container-title:ASI
Author:
Log Markus Metallinos1ORCID, Thoresen Thomas2, Eitrheim Maren H. R.13, Levin Tomas4, Tørset Trude1ORCID
Affiliation:
1. Department of Civil and Environmental Engineering, Norwegian University of Science and Technology (NTNU), NO-7491 Trondheim, Norway 2. Research Division Strategic Analyses and Joint Systems, Norwegian Defence Research Establishment (FFI), NO-2027 Kjeller, Norway 3. Department of Humans and Automation, Institute for Energy Technology (IFE), NO-1751 Halden, Norway 4. Norwegian Public Roads Administration (NPRA), NO-7031 Trondheim, Norway
Abstract
Many modern vehicles collect inter-vehicle distance data from radar sensors as input to driver assistance systems. However, vehicle manufacturers often use proprietary algorithms to conceal the collected data, making them inaccessible to external individuals, such as researchers. Aftermarket sensors may circumvent this issue. This study investigated the use of low-cost radar sensors to determine inter-vehicle distances during real-world semi-automated truck platooning on two-way, two-lane rural roads. Radar data from the two follower trucks in a three-truck platoon were collected, synchronized and filtered. The sensors measured distance, relative velocity and signal-to-noise ratio. Dashboard camera footage was collected, coded and synchronized to the radar data, providing context about the driving situation, such as oncoming trucks, roundabouts and tunnels. The sensors had different configuration parameters, suggested by the supplier, to avoid signal interference. With parameters as chosen, sensor ranges, inferred from maximum distance measurements, were approximately 74 and 71 m. These values were almost on par with theoretical calculations. The sensors captured the preceding truck for 83–85% of the time where they had the preceding truck within range, and 95–96% of the time in tunnels. While roundabouts are problematic, the sensors are feasible for collecting inter-vehicle distance data during truck platooning.
Funder
Innovation and Implementation initiative Norwegian Public Roads Administration Norwegian University of Science and Technology
Subject
Artificial Intelligence,Applied Mathematics,Industrial and Manufacturing Engineering,Human-Computer Interaction,Information Systems,Control and Systems Engineering
Reference47 articles.
1. A Review of Truck Platooning Projects for Energy Savings;Tsugawa;IEEE Trans. Intell. Veh.,2016 2. Opportunities and Barriers for Truck Platooning on Norwegian Rural Freight Routes;Eitrheim;Transp. Res. Rec.,2022 3. Horenberg, D. (2017). Proceedings of the 9th IBA Bachelor Thesis Conference, University of Twente, The Faculty of Behavioural, Management and Social Sciences. 4. Bergenhem, C., Shladover, S., Coelingh, E., Englund, C., and Tsugawa, S. (2012, January 22–26). Overview of Platooning Systems. Proceedings of the 19th ITS World Congress, Vienna, Austria. 5. Konstantinopoulou, L., Coda, A., and Schmidt, F. (2019, January 20–23). Specifications for Multi-Brand Truck Platooning. Proceedings of the 8th International Conference on Weigh-In-Motion, Prague, Czech Republic.
Cited by
2 articles.
订阅此论文施引文献
订阅此论文施引文献,注册后可以免费订阅5篇论文的施引文献,订阅后可以查看论文全部施引文献
|
|