Abstract
The reliable operation of solar-powered agricultural Internet of Things (IoT) devices heavily depends on the integrity of solar panels. However, monitoring these distributed assets for subtle anomalies such as bird droppings, cracks, and dust accumulation remains challenging under edge computational constraints. This paper presents YOLOv11-HPC, an optimized lightweight detector that incorporates a Hybrid Pooling Spatial Pyramid Pooling Fast module and a Dual-path Multi-scale Checkerboard Attention module. These components collectively improve multi-scale feature representation and introduce sparse attention-guided refinement, enabling accurate identification of small and complex anomalies with low computational overhead. Evaluated on a dedicated solar panel anomaly dataset, YOLOv11-HPC achieves an mAP (50) of 84.1% and a precision of 94.13%, surpassing existing YOLO models and classical detectors. When deployed on an NVIDIA Jetson Orin NX, the model sustains real-time inference at over 55 FPS in FP16 format, confirming its practical suitability for edge-based agricultural IoT device monitoring and sustainable agricultural applications.