FireYOLO-Lite: Lightweight Forest Fire Detection Network with Wide-Field Multi-Scale Attention Mechanism

Forests Pub Date : 2024-07-17 DOI:10.3390/f15071244

Sha Sheng, Zhengyin Liang, Wenxing Xu, Yong Wang, Jiangdan Su

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Abstract

A lightweight forest fire detection model based on YOLOv8 is proposed in this paper in response to the problems existing in traditional sensors for forest fire detection. The performance of traditional sensors is easily constrained by hardware computing power, and their adaptability in different environments needs improvement. To balance the accuracy and speed of fire detection, the GhostNetV2 lightweight network is adopted to replace the backbone network for feature extraction of YOLOv8. The Ghost module is utilized to replace traditional convolution operations, conducting feature extraction independently in different dimensional channels, significantly reducing the complexity of the model while maintaining excellent performance. Additionally, an improved CPDCA channel priority attention mechanism is proposed, which extracts spatial features through dilated convolution, thereby reducing computational overhead and enabling the model to focus more on fire targets, achieving more accurate detection. In response to the problem of small targets in fire detection, the Inner IoU loss function is introduced. By adjusting the size of the auxiliary bounding boxes, this function effectively enhances the convergence effect of small target detection, further reducing missed detections, and improving overall detection accuracy. Experimental results indicate that, compared with traditional methods, the algorithm proposed in this paper significantly improves the average precision and FPS of fire detection while maintaining a smaller model size. Through experimental analysis, compared with YOLOv3-tiny, the average precision increased by 5.9% and the frame rate reached 285.3 FPS when the model size was only 4.9 M; compared with Shufflenet, the average precision increased by 2.9%, and the inference speed tripled. Additionally, the algorithm effectively addresses false positives, such as cloud and reflective light, further enhancing the detection of small targets and reducing missed detections.

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FireYOLO-Lite：采用宽域多尺度关注机制的轻量级林火探测网络

针对传统林火探测传感器存在的问题，本文提出了一种基于 YOLOv8 的轻量级林火探测模型。传统传感器的性能容易受到硬件计算能力的制约，在不同环境下的适应性有待提高。为了兼顾火情检测的精度和速度，本文采用 GhostNetV2 轻量级网络来替代 YOLOv8 的主干网络进行特征提取。利用 Ghost 模块取代传统的卷积运算，在不同维度的信道中独立进行特征提取，在保持优异性能的同时大大降低了模型的复杂度。此外，还提出了一种改进的 CPDCA 信道优先关注机制，通过扩张卷积提取空间特征，从而降低了计算开销，使模型能更多地关注火力目标，实现更精确的检测。针对火灾探测中的小目标问题，引入了 Inner IoU 损失函数。该函数通过调整辅助边界框的大小，有效增强了小目标检测的收敛效果，进一步减少了漏检，提高了整体检测精度。实验结果表明，与传统方法相比，本文提出的算法在保持较小模型规模的同时，显著提高了火力探测的平均精度和 FPS。通过实验分析，与 YOLOv3-tiny 相比，当模型大小仅为 4.9 M 时，平均精度提高了 5.9%，帧速率达到 285.3 FPS；与 Shufflenet 相比，平均精度提高了 2.9%，推理速度提高了三倍。此外，该算法还有效地解决了云和反射光等误报问题，进一步提高了对小目标的检测能力，减少了漏检。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Forests

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