@article{LI2026, 
author = {Cong LI and Wenfei TENG and Wenbo XU and Jiali WANG and Haitao CHENG and Jian DING},
title = {Image features and detection methods for early-stage wildfires in transmission line corridors from unmanned aerial vehicle perspectives},
year = {2026},
journal = {Journal of Tsinghua University (Science and Technology)},
volume = {66},
number = {7},
pages = {1376-1386},
keywords = {image detection, power transmission corridor, unmanned aerial vehicle Inspection, early-stage wildfires},
url = {https://www.sciopen.com/article/10.16511/j.cnki.qhdxxb.2026.26.036},
doi = {10.16511/j.cnki.qhdxxb.2026.26.036},
abstract = {ObjectiveUnmanned aerial vehicle (UAV) inspection technology has become an essential tool for monitoring wildfires in transmission line corridors due to its flexibility, cost-effectiveness, and adaptability to remote and complex terrains. However, current research lacks initial wildfire image datasets from the perspective of UAV inspections, and existing algorithms struggle to accurately identify early-stage wildfires. This study constructs an initial wildfire image dataset from a UAV perspective and proposes the YOLOv11n-MCC detection model for transmission line corridors.MethodsThrough the field inspections of national transmission line corridors for 174 h, covering 82 000 km with UAVs, 1 308 transmission line corridor inspection images were obtained, and a transmission line corridor inspection image dataset from the perspective of the UAV was constructed. This dataset was analyzed to identify the characteristics of the initial wildfire images. The early wildfire detection model, YOLOv11n-MCC, based on an enhanced version of YOLOv11n, was then proposed. First, part of the traditional convolutional network in YOLOv11n was replaced with multi-scale feature convolution(MFConv) to reduce computational load while improving feature extraction. Second, the C2PSA module in the backbone network was replaced with the spatialand channel synergy attention(SCSA) mechanism to improve target localization. Finally, C3k2_ABlock with convolutional additive token mixer(CATM) at its core was embedded to improve target representation and selection in complex backgrounds.ResultsMFConv, SCSA attention, and C3k2_ABlock with CATM sequentially improved the YOLOv11n-MCC model's ability to detect targets in complex scenes. Comparative experiments revealed that the YOLOv11n-MCC model significantly outperforms the YOLOv11n baseline model in terms of accuracy, mAP50, parameter count, and giga floating-point operations per second(GFLOPS) for early mountain fire small-target detection, making it portable but still computationally efficient. Specifically, precision increased by 9.0 percentage point, recall by 3.8 percentage point, and mAP50 by 5.7 percentage point. In addition, the number of parameters and GFLOPS decreased by 0.149×106 and 0.2, respectively. The YOLOv11n-MCC architecture achieves enhanced multiscale feature representation while maintaining reduced computational complexity, thereby improving operational efficiency without compromising detection performance.ConclusionsThe image dataset for transmission line corridor inspection constructed in this study can effectively support the training and testing of the improved fire detection algorithm. The proposed YOLOv11n-MCC model demonstrates stable performance in detecting small initial mountain fire targets and can be effectively applied to real-time wildfire detection in transmission line corridors using UAVs, thereby providing essential technical support for early wildfire detection. Future work will focus on examining the influence of varying smoke-to-fire ratios on model training to further enhance wildfire detection accuracy.}
}