Fractional B-Spline Wavelets and U-Net Architecture for Robust and Reliable Vehicle Detection in Snowy Conditions
Author:
Mokayed Hamam1ORCID, Ulehla Christián1, Shurdhaj Elda1, Nayebiastaneh Amirhossein1, Alkhaled Lama1ORCID, Hagner Olle2, Hum Yan Chai3
Affiliation:
1. Electrical and Space Engineering, Luleå University of Technology, 97187 Luleå, Sweden 2. Smartplanes, Jävre, 94494 Piteå Municipality, Sweden 3. Mechatronics and Biomedical Engineering, Universiti Tunku Abdul Rahman, Jalan Sungai Long, Bandar Sungai Long, Kajang 43000, Selangor, Malaysia
Abstract
This paper addresses the critical need for advanced real-time vehicle detection methodologies in Vehicle Intelligence Systems (VIS), especially in the context of using Unmanned Aerial Vehicles (UAVs) for data acquisition in severe weather conditions, such as heavy snowfall typical of the Nordic region. Traditional vehicle detection techniques, which often rely on custom-engineered features and deterministic algorithms, fall short in adapting to diverse environmental challenges, leading to a demand for more precise and sophisticated methods. The limitations of current architectures, particularly when deployed in real-time on edge devices with restricted computational capabilities, are highlighted as significant hurdles in the development of efficient vehicle detection systems. To bridge this gap, our research focuses on the formulation of an innovative approach that combines the fractional B-spline wavelet transform with a tailored U-Net architecture, operational on a Raspberry Pi 4. This method aims to enhance vehicle detection and localization by leveraging the unique attributes of the NVD dataset, which comprises drone-captured imagery under the harsh winter conditions of northern Sweden. The dataset, featuring 8450 annotated frames with 26,313 vehicles, serves as the foundation for evaluating the proposed technique. The comparative analysis of the proposed method against state-of-the-art detectors, such as YOLO and Faster RCNN, in both accuracy and efficiency on constrained devices, emphasizes the capability of our method to balance the trade-off between speed and accuracy, thereby broadening its utility across various domains.
Reference17 articles.
1. Artificial intelligence: A powerful paradigm for scientific research;Xu;Innovation,2021 2. Tahir, N.U.A., Zhang, Z., Asim, M., Chen, J., and ELAffendi, M. (2024). Object Detection in Autonomous Vehicles under Adverse Weather: A Review of Traditional and Deep Learning Approaches. Algorithms, 17. 3. Edge intelligence empowered vehicle detection and image segmentation for autonomous vehicles;Chen;IEEE Trans. Intell. Transp. Syst.,2023 4. Mokayed, H., Nayebiastaneh, A., De, K., Sozos, S., Hagner, O., and Backe, B. (2023, January 17–24). Nordic Vehicle Dataset (NVD): Performance of vehicle detectors using newly captured NVD from UAV in different snowy weather conditions. Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition, Vancouver, BC, Canada. 5. Lee, S.H., and Lee, S.H. (2024). U-Net-Based Learning Using Enhanced Lane Detection with Directional Lane Attention Maps for Various Driving Environments. Mathematics, 12.
|
|