Abdul Ghafar

Work place: Yangzhou University/ College of Information Engineering (College of Artificial Intelligence), Jiangsu, China

E-mail: ayanghafar783@gmail.com

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Biography

Abdul Ghafar received a master degree in computer science and technology from Jiangsu University of Science and technology, China, in 2021. He is currently pursuing a PhD degree in Yangzhou University, china. His current research interests are machine learning and deep learning with a focus on crop disease classification using advanced computer vision techniques. His email is ayanghafar783@gmail.com

Author Articles
An Optimized YOLOv8-based Method for Airport Bird Detection: Incorporating ECA Attention, MBC3 Module, and SF-PAN for Improved Accuracy and Speed

By Zia Ur Rehman Abdul Ghafar Ahmad Syed Abu Tayab Md. Golam Rabbi

DOI: https://doi.org/10.5815/ijisa.2025.02.01, Pub. Date: 8 Apr. 2025

This research investigation utilizes deep learning object detection algorithms to achieve accurate recognition of birds near airports, thereby addressing the limitations of manual bird detection at airports, including low accuracy slow speed, and the high cost of radar detection. The ultimate goal is to ensure the safe operation of civil aviation. The following are the primary enhancements: First, an ECA (Efficient Channel Attention) attention mechanism was added to the Neck to enhance the network's emphasis on important characteristics. This resulted in a notable improvement in accuracy while only changing a few parameters. Second, by adding branches with various receptive fields, the MBC3 (Muti Branch C3) module was created to improve the expressiveness of the model. Thirdly, the model's right width and depth parameters will be chosen by investigating the effects of various network widths and depths on model performance. Fourth, to solve the problem of feature loss in recognizing tiny bird targets, the SF-PAN (Shallow Feature - Path Aggregation Network) structure was proposed. The model was evaluated using metrics such as mAP@50, FPS, precision, recall, and computational complexity on a test set derived from the dataset. Results show that the enhanced YOLOv8 achieves a mAP@50 of 83.1% and a speed of 31 FPS, a 2.5% improvement in accuracy and a 7 FPS increase over the baseline YOLOv8, while reducing parameters and weight size by approximately 48%. Comparative experiments further validate the model’s superiority over existing algorithms in terms of accuracy and resource efficiency. This upgraded YOLOv8 provides a novel, real-time solution for precise bird detection in challenging airport environments, ensuring safer civil aviation operations.

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