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深度学习目标检测方法在森林火灾烟雾识别中的研究与应用

Research and application of deep learning object detection methods for forest fire smoke recognition.

作者信息

He Luhao, Zhou Yongzhang, Liu Lei, Zhang Yuqing, Ma Jianhua

机构信息

Center for Earth Environment and Earth Resources, Sun Yat-sen University, Zhuhai, 519000, Guangdong, China.

School of Earth Sciences and Engineering, Sun Yat-sen University, Zhuhai, 519000, Guangdong, China.

出版信息

Sci Rep. 2025 May 10;15(1):16328. doi: 10.1038/s41598-025-98086-w.

DOI:10.1038/s41598-025-98086-w
PMID:40348915
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12065873/
Abstract

Forest fires are severe ecological disasters worldwide that cause extensive ecological destruction and economic losses while threatening biodiversity and human safety. With the escalation of climate change, the frequency and intensity of forest fires are increasing annually, underscoring the urgent need for effective monitoring and early warning systems. This study investigates the application effectiveness of deep learning-based object detection technology in forest fire smoke recognition by using the YOLOv11x algorithm to develop an efficient fire detection model. The objective is to enhance early fire detection capabilities and mitigate potential damage. To improve the model's applicability and generalizability, two publicly available fire image datasets, WD (Wildfire Dataset) and FFS (Forest Fire Smoke), encompassing various complex scenarios and external conditions, were employed. After 501 training epochs, the model's detection performance was comprehensively evaluated via multiple metrics, including precision, recall, and mean average precision (mAP50 and mAP50-95). The results demonstrate that YOLOv11x excels in bounding box loss (box loss), classification loss (cls loss), and distribution focal loss (dfl loss), indicating effective optimization of object detection performance across multiple dimensions. Specifically, the model achieved a precision of 0.949, a recall of 0.850, an mAP50 of 0.901, and an mAP50-95 of 0.786, highlighting its high detection accuracy and stability. Analysis of the precision‒recall (PR) curve revealed an average mAP@0.5 of 0.901, further confirming the effectiveness of YOLOv11x in fire smoke detection. Notably, the mAP@0.5 for the smoke category reached 0.962, whereas for the flame category, it was 0.841, indicating superior performance in smoke detection compared with flame detection. This disparity primarily arises from the distinct visual characteristics of flames and smoke; flames possess more vivid colors and defined shapes, facilitating easier recognition by the model, whereas smoke exhibits more ambiguous and variable textures and shapes, increasing detection difficulty. In the test set, 86.89% of the samples had confidence scores exceeding 0.85, further validating the model's reliability. In summary, the YOLOv11x algorithm demonstrates excellent performance and broad application potential in forest fire smoke recognition, providing robust technical support for early fire warning systems and offering valuable insights for the design of intelligent monitoring systems in related fields.

摘要

森林火灾是全球范围内严重的生态灾难,会造成广泛的生态破坏和经济损失,同时威胁生物多样性和人类安全。随着气候变化的加剧,森林火灾的频率和强度逐年增加,凸显了有效监测和预警系统的迫切需求。本研究通过使用YOLOv11x算法开发高效的火灾检测模型,研究基于深度学习的目标检测技术在森林火灾烟雾识别中的应用效果。目的是提高早期火灾检测能力并减轻潜在损害。为了提高模型的适用性和通用性,使用了两个公开可用的火灾图像数据集,即WD(野火数据集)和FFS(森林火灾烟雾),它们涵盖了各种复杂场景和外部条件。经过501个训练轮次后,通过多个指标全面评估了模型的检测性能,包括精度、召回率和平均精度均值(mAP50和mAP50-95)。结果表明,YOLOv11x在边界框损失(box loss)、分类损失(cls loss)和分布焦点损失(dfl loss)方面表现出色,表明在多个维度上有效优化了目标检测性能。具体而言,该模型的精度为0.949,召回率为0.850,mAP50为0.901,mAP50-95为0.786,突出了其高检测精度和稳定性。对精确率-召回率(PR)曲线的分析显示平均mAP@0.5为0.901,进一步证实了YOLOv11x在火灾烟雾检测中的有效性。值得注意的是,烟雾类别的mAP@0.5达到0.962,而火焰类别的mAP@0.5为0.841,表明在烟雾检测方面比火焰检测具有更好的性能。这种差异主要源于火焰和烟雾不同的视觉特征;火焰具有更鲜艳的颜色和明确的形状,便于模型更容易识别,而烟雾表现出更模糊和多变的纹理及形状,增加了检测难度。在测试集中,86.89% 的样本置信度得分超过0.85,进一步验证了模型的可靠性。总之,YOLOv11x算法在森林火灾烟雾识别中表现出优异的性能和广泛的应用潜力,为早期火灾预警系统提供了强大的技术支持,并为相关领域智能监测系统的设计提供了有价值的见解。

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