Accurate detection of small objects is critical in military surveillance and drone monitoring, yet standard detectors often fail due to feature loss during down-sampling. This study proposes a lightweight YOLOv5-based model optimized for small-object detection. The design introduces a high-resolution P2 detection head and removes the P5 head, while anchor boxes are re-optimized using a genetic algorithm aligned with dataset statistics. On a drone small-object dataset (24-32 px), the proposed model achieved +0.062 higher mAP@0.5 than YOLOv5s, +0.041 higher than YOLOv8s, and +0.020 higher than YOLOv11s, while maintaining fewer parameters (5.3M vs. 7.0-11.1 M). Additional experiments on medium-sized objects (64-96 px) confirmed strong generalization, with mAP@0.5 reaching 0.998, surpassing YOLOv5s (0.994) and YOLOv8s (0.988), and slightly exceeding YOLOv11s (0.989). Although mAP@0.5:0.95 was marginally lower compared to YOLOv8s and YOLOv11s, the proposed model achieves an effective trade-off between accuracy and efficiency, demonstrating suitability for edge deployment in defense and real-time monitoring applications.
Ko et al. (Thu,) studied this question.
Synapse has enriched 5 closely related papers on similar clinical questions. Consider them for comparative context: