基于改进YOLOX的隧道火灾检测算法

doi:10.16265/j.cnki.issn1003-3033.2025.04.0960

摘要/Abstract

摘要：

针对隧道初期火灾检测中存在的复杂环境干扰和低识别率问题,提出一种基于改进YOLOX算法的检测方法YOLOX-T。该方法在YOLOX中引入归一化注意力模块(NAM)机制来抑制环境噪声和干扰,提高系统的鲁棒性及识别的精确性;引入加权双向特征金字塔网络(BiFPN)增强特征提取和融合能力,优化α-交并比(IoU)损失函数,以提高对轮廓特征不明显的隧道初期烟雾火焰的检测精度;在现有公开数据集不足的情况下,通过网络采集、模拟试验和扩充现有数据集,构建隧道火灾数据集,在包含真实场景和模拟场景的自建隧道火灾数据集上进行验证。结果表明:相比于原始YOLOX模型,改进后的算法均值平均精度(mAP@0.5)提高1.89%,mAP@0.5~0.95提高0.88%,精确率提高4.57%,召回率提高5.45%,改进后的算法能够实现更优的检测性能。

关键词: 隧道火灾, YOLOX, 火灾检测, 归一化注意力模块(NAM), 加权双向特征金字塔网络(BiFPN)

Abstract:

To address the issues of complex environmental interference and low recognition rates in early-stage tunnel fire detection, an improved YOLOX-based detection method, YOLOX-T, was proposed. The proposed method incorporated a NAM into the YOLOX network to suppress environmental noise and interference, thereby enhancing the model's robustness. A weighted BiFPN was integrated to improve multi-scale feature extraction and fusion. Furthermore, an α-IoU(Intersection over Union) loss function was employed to enhance the detection accuracy of early-stage tunnel smoke and flames, which often exhibit indistinct contours. Addressing the scarcity of publicly available datasets, a tunnel fire dataset encompassing both real-world and simulated scenarios was constructed through web data acquisition, simulated fire experiments, and the augmentation of existing datasets. Experimental results on the self-built dataset demonstrate that, compared to the original YOLOX model, the YOLOX-T method achieves improvements of 1.89% in mean Average Precision (mAP@0.5), 0.88% in mAP@0.5~0.95, 4.57% in precision, and 5.45% in recall. The improved algorithm can achieve better detection performance.

Key words: tunnel fire, YOLOX, normalization-based attention module (NAM), bidirectional feature pyramid network (BiFPN), fire detection

中图分类号:

X932爆炸安全与防火、防爆

马庆禄, 邱高建, 白锋. 基于改进YOLOX的隧道火灾检测算法[J]. 中国安全科学学报, 2025, 35(4): 28-34.

MA Qinglu, QIU Gaojian, BAI Feng. Tunnel initial fire detection method based on improved YOLOX algorithm[J]. China Safety Science Journal, 2025, 35(4): 28-34.

图/表 10

图1

图2

图3

图4

图5

图6

表1

图7

图8

表2

参考文献 18

[1]	交通运输部. 2023年交通运输行业发展统计公报[R/OL]. (2024-06-18). https://www.gov.cn/lianbo/bumen/202406/content_6957901.htm
[2]	何潇剑. 公路隧道消防灭火系统优化设计研究[J]. 隧道建设, 2017, 37(4):505-509.
	HE Xiaojian. Study of optimization design of firefighting system of highway tunnel[J]. Tunnel Construction, 2017, 37(4):505-509.
[3]	张思祥, 甘凯, 周围. 提高火灾烟雾传感器检测精度的方法[J]. 传感器与微系统, 2021, 40(1):151-153.
	ZHANG Sixiang, GAN Kai, ZHOU Wei. Method for detection precision improving of fire smog sensor[J]. Transducer and Microsystem Technologies, 2021, 40(1):151-153.
[4]	李先锋, 徐森, 花义明. 基于OpenCV计算机视觉的海事视频船舶火灾烟雾检测技术[J]. 舰船科学技术, 2021, 43(22):202-204.
	LI Xianfeng, XU Sen, HUA Yiming. Maritime video ship fire smoke detection technology based on OpenCV computer vision[J]. Ship Science and Technology, 2021, 43(22):202-204.
[5]	ÇELIK T, DEMIREL H. Fire detection in video sequences using a generic color model[J]. Fire Safety Journal, 2009, 44(2):147-158.
[6]	MONDAL M S, PRASAD V, KUMAR R, et al. Automating fire detection and suppression with computer vision: a multi-layered filtering approach to enhanced fire safety and rapid response[J]. Fire Technology, 2023, 59(4):1555-1583.
[7]	TORABIAN M, POURGHASSEM H, MAHDAVI-NASAB H. Fire detection based on fractal analysis and spatio-temporal features[J]. Fire Technology, 2021, 57(5):2583-2614.
[8]	马庆禄, 孙枭, 唐小垚, 等. 基于改进YOLOv5s算法的隧道初期火灾检测模型[J]. 中国安全科学报, 2023, 33(10):214-223.
	MA Qinglu, SUN Xiao, TANG Xiaoyao, et al. Optimization method for tunnel initial fire detection based on YOLOv5s algorithm[J]. China Safety Science Journal, 2023, 33(10):214-223. doi: 10.16265/j.cnki.issn1003-3033.2023.10.2424
[9]	胡勤, 陈琛, 刘敏. 一种基于动态纹理的烟雾和火焰检测方法[J]. 消防科学与技术, 2014, 33(6): 667-669.
	HU Qin, CHEN Chen, LIU Min. A smoke and fire detection method based on dynamic texture[J]. Fire Science and Technology, 2014, 33(6):667-669.
[10]	李宁, 刘青, 熊俊, 等. 基于无人机的火灾检测系统设计与实现[J]. 火灾科学, 2022, 31(1):46-51.
	LI Ning, LIU Qing, XIONG Jun, et al. Design and implementation of fire detection system based on UAV[J]. Fire Safety Science, 2022, 31(1):46-51.
[11]	李澎林, 章军伟, 李伟. 基于光流改进与YOLOv3的烟雾检测方法[J]. 浙江工业大学学报, 2021, 49(1):9-15.
	LI Penglin, ZHANG Junwei, LI Wei. Smoke detection method based on optical flow improvement and YOLOv3[J]. Journal of Zhejiang University of Technology, 2021, 49(1):9-15.
[12]	王冠博, 杨俊东, 李波, 等. 改进YOLOv4的火焰图像实时检测[J]. 计算机工程与设计, 2022, 43(5):1358-1365.
	WANG Guanbo, YANG Jundong, LI Bo, et al. Real-time flame image detection using improved YOLOv4[J]. Computer Engineering and Design, 2022, 43(5):1358-1365.
[13]	曹康壮, 焦双健. 融合注意力机制的轻量级火灾检测模型[J]. 消防科学与技术, 2024, 43(3):378-383.
	CAO Kangzhuang, JIAO Shuangjian. A lightweight fire detection model integrating attention mechanism[J]. Fire Science and Technology, 2024, 43(3):378-383.
[14]	尚明鹏, 周敏, 陈燕军, 等. 融合BiFPN与YOLOv5网络的工厂火灾检测[J]. 智能计算机与应用, 2023, 13(10):137-141,146.
	SHANG Mingpeng, ZHOU Min, CHEN Yanjun, et al. Factory fire detection with BiFPN and YOLOv5[J]. Intelligent Computer and Applications, 2023, 13(10):137-141,146.
[15]	张军, 尹柳, 巩欣飞, 徐赫桦. 基于改进YOLOv5的小目标烟雾检测算法[J]. 中国安全科学学报, 2023, 33(11):75-81. doi: 10.16265/j.cnki.issn1003-3033.2023.11.0854
	ZHANG Jun, YIN Liu, GONG Xinfei, XU Hehua. Small target smoke detection algorithm based on improved YOLOv5[J]. China Safety Science Journal, 2023, 33(11):75-81. doi: 10.16265/j.cnki.issn1003-3033.2023.11.0854
[16]	GE Zheng, LIU Songtao, WANG Feng, et al. YOLOX:exceeding YOLO series in 2021[EB/OL]. [2024-07-05]. https://arxiv.org/abs/2107.08430v2
[17]	TAN Mingxing, QUOC L. Efficientnet: rethinking model scaling for convolutional neural networks[C]. International Conference on Machine Learning. PMLR, 2019: 6105-6114.
[18]	HE Jiabo, ERFANI S, MA Xingjun, et al. α-IoU: a family of power intersection over union losses for bounding box regression[EB/OL]. [2024-07-05]. https://arxiv.org/abs/2110.13675

模型	改进策略
模型	NAM	BiFPN	α-IoU	mAP@0.5	mAP@0.5~0.95	P	R
YOLOX	—	—	—	82.89	70.23	93.37	82.34
A	√	—	—	83.39	70.46	94.41	83.58
B	√	√	—	82.98	70.61	96.52	83.77
YOLOX-T	√	√	√	84.78	71.11	97.94	87.79

检测算法	mAP@0.5	P/%
Faster R-CNN	75.51	85.66
RetinaNet	75.32	83.54
SSD	71.46	78.69
YOLOv3	72.44	80.17
YOLOv4	73.66	81.67
YOLOv5S	75.43	85.33
YOLOX	82.89	93.37
YOLOX-T	84.78	97.94