平滑交互式压缩网络的红外小目标检测算法

doi:10.19665/j.issn1001-2400.20231203

摘要/Abstract

摘要：

红外小目标检测是对地观测、抢险救灾等诸多领域的重要课题,一直受到学界的广泛关注。由于红外小目标通常只占据几十个像素且分布在整个背景中,因此大范围内探索图像特征之间的语义信息以挖掘目标与背景之间的差异对检测性能的提升至关重要。然而,传统卷积神经网络的编码局域性与计算资源的巨大需求削弱了网络捕获小目标形状和位置的能力,极易产生漏检与虚警。基于此,提出了一种平滑交互式压缩网络模型,主要包含平滑交互模块与交叉关注模块。平滑交互模块在拓展特征图感受野的同时增添其依赖性,提升了网络在复杂背景条件下检测性能的鲁棒性。交叉关注模块综合考量信道的贡献度与剪枝的可解释性,从而动态融合不同分辨率的特征图。最后,在公开的SIRST数据集和IRSTD-1K数据集上的大量试验结果表明,提出的网络可以有效地解决目标丢失、虚警率高、视觉效果不佳等问题。以SIRST数据集为例,与性能第2的模型相比,IoU、nIoU和P_d分别提高了约3.05%、3.41%和1.02%;F_a和FLOPs分别降低了约33.33%和82.30%。

关键词: 红外小目标检测, 深度学习, 网络编码, 模型压缩

Abstract:

Infrared Small Target Detection is a critical focus of various fields,including earth observation and disaster relief efforts,receiving considerable attention within the academic community.Since infrared small targets often occupy just a few dozen pixels and are scattered within complex backgrounds,it becomes paramount to extract semantic information from a broad range of image features to distinguish targets from their surroundings and enhance detection performance.Traditional convolutional neural networks,due to their limited receptive fields and substantial computational demands,face challenges in effectively capturing the shape and precise positioning of small targets,leading to missed detections and false alarms.In response to these challenges,this paper proposes a novel Smooth Interactive Compression Network comprising two main components:the Smooth Interaction Module and the Cross Compression Module.The Smooth Interaction Module extends the feature map's receptive field and enhances inter-feature dependencies,thus bolstering the network’s detection robustness in complex background scenarios.The Cross Compression Module takes into account channel contributions and the interpretability of pruning,dynamically fusing feature maps of varying resolutions.Extensive experiments conducted on the publicly available SIRST dataset and IRSTD-1K dataset demonstrate that the proposed network effectively addresses issues such as target loss,a high false alarm rate,and subpar visual results.Taking the SIRST dataset as an example,compared to the second-best performing model,the proposed model achieved a remarkable improvement in metrics:IoU,nIoU,and P_d are increased by 3.05%,3.41%,and 1.02%,respectively.Meanwhile,F_a and FLOPs are decreased by 33.33% and 82.30%,respectively.

Key words: Infrared Small Target Detection, deep learning, network coding, model compression

中图分类号:

TN219

张铭津, 周楠, 李云松. 平滑交互式压缩网络的红外小目标检测算法[J]. 西安电子科技大学学报, 2024, 51(4): 1-14.

ZHANG Mingjin, ZHOU Nan, LI Yunsong. Smooth interactive compression network for infrared small target detection[J]. Journal of Xidian University, 2024, 51(4): 1-14.

图/表 16

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骨干网的详细信息"

网络层	输出	骨架
阶段-1	480×480	$3 × 3 c o n v, 16 3 × 3 c o n v, 16$
阶段-2	240×240	$3 × 3 c o n v, 32 3 × 3 c o n v, 32$
阶段-3	120×120	$3 × 3 c o n v, 64 3 × 3 c o n v, 64$

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参考文献 29

[1]	DESHPANDE S Y, ER M H, VENK R. Max-Mean and Max-Median Filters for Detection of Small Targets[J]. Signal and Data Processing of Small Targets, 1999,3809:74-83.
[2]	HAN J, LIU S, QIN G, et al. A Local Contrast Method Combined with Adaptive Background Estimation for Infrared Small Target Detection[J]. IEEE Transactions on Geoscience and Remote Sensing, 2019, 16(9):1442-1446.
[3]	ZHANG M J, WANG N, LI Y, et al. Neural Probabilistic Graphical Model for Face Sketch Synthesis[J]. IEEE Transactions on Neural Networks and Learning Systems, 2020, 31(7):2623-2637. doi: 10.1109/TNNLS.2019.2933590 pmid: 31494561
[4]	ZHANG M J, WU Q, ZHANG J, et al. Fluid Micelle Network for Image Super-Resolution Reconstruction[J]. IEEE Transactions on Cybernetics, 2023, 53(1):578-591.
[5]	WANG H, ZHOU L P, WANG L. Miss Detection vs.False Alarm:Adversarial Learning for Small Object Segmentation in Infrared Images[C]//Proceedings of the IEEE/CVF International Conference on Computer Vision. Piscataway:IEEE, 2019:8509-8518.
[6]	DAI Y M, WU Y Q, ZHOU F, et al. Asymmetric Contextual Modulation for Infrared Small Target Detection[C]//Proceedings of the IEEE/CVF Winter Conference on Applications of Computer Vision. Piscataway:IEEE, 2021:950-959.
[7]	ZHANG M J, BAI H, ZHANG J, et al. RKformer:Runge-Kutta Transformer with Random-Connection Attention for Infrared Small Target Detection[C]//The 30th ACM International Conference on Multimedia. New York: ACM, 2022:1730-1738.
[8]	TOM V T, PEIL T, MAY L, et al. Morphologybased Algorithm for Point Target Detection in Infrared Backgrounds[J]. Signal and Data Processing of Small Targets International Society for Optics and Photonics, 1993, 1954:2-11.
[9]	ZHANG M J, ZHANG R, YANG Y X, et al. ISNet:Shape Matters for Infrared Small Target Detection.[C]//Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition. Piscataway:IEEE, 2022:877-886.
[10]	汪西莉, 梁敏, 刘涛. 特征增强的单阶段遥感图像目标检测模型[J]. 西安电子科技大学学报, 2022, 49(3):160-170.
	WANG Xili, LIANG Min, LIU Tao. Feature Enhanced Single-Stage Remote Sensing Image Object Detection Model[J]. Journal of Xidian University, 2022, 49(3):160-170.
[11]	杨子轩, 肖嵩, 董文倩, 等. 一种引入注意力机制的红外目标检测方法[J]. 西安电子科技大学学报, 2022, 49(3):28-35.
	YANG Zixuan, XIAO Song, DONG Wenqian, et al. Thermal Target Detection Method Introducing an Attention Mechanism[J]. Journal of Xidian University, 2022, 49(3):28-35.
[12]	董如婵, 焦李成, 赵进, 等. 一种深度融合机制的遥感图像目标检测技术[J]. 西安电子科技大学学报, 2021, 48(5):128-138.
	DONG Ruchan, JIAO Licheng, ZHAO Jin, et al. Application of the Deep Fusion Mechanism in Object Detection of Remote Sensing Images[J]. Journal of Xidian University, 2021, 48(5):128-138.
[13]	ZHANG M J, WU Q, GUO J, et al. Heat Transfer-Inspired Network for Image Super-Resolution Reconstruction[J]. IEEE Transactions on Neural Networks and Learning Systems, 2024, 35(2):1810-1820.
[14]	ZHANG M J, XIN J, ZHANG J, et al. Curvature Consistent Network for Microscope Chip Image Super-Resolution[J]. IEEE Transactions on Neural Networks and Learning Systems, 2023, 34(12):10538-10551.
[15]	ZHANG M J, WANG N, LI Y, et al. Deep Latent Low-Rank Representation for Face Sketch Synthesis[J]. IEEE Transactions on Neural Networks and Learning Systems, 2019, 30(10):3109-3123. doi: 10.1109/TNNLS.2018.2890017 pmid: 30676980
[16]	DENG H, SUN X, LIU M, et al. Small Infrared Target Detection Based on Weighted Local Difference Measure[J]. IEEE Transactions on Geoscience and Remote Sensing, 2016, 54(7):4204-4214.
[17]	ZHAO Y, PAN H, DU C, et al. Bilateral Two-Dimensional Least Mean Square Filter for Infrared Small Target Detection[J]. Infrared Physics & Technology, 2014,65:17-23.
[18]	ZHU H, LIU S, DENG L, et al. Infrared Small Target Detection via Low-Rank Tensor Completion with Top-Hat Regularization[J]. IEEE Transactions on Geoscience and Remote Sensing, 2020, 58(2):1004-1016.
[19]	BAI X, BI Y. Derivative Entropy-Based Contrast Measure for Infrared Small-Target Detection[J]. IEEE Transactions on Geoscience and Remote Sensing, 2018, 56(4):2452-2466.
[20]	HE K, ZHANG X, REN S, et al. Deep Residual Learning for Image Recognition[C]//Proceedings of IEEE Conference Computer Vision Pattern Recognition. Piscataway:IEEE, 2016:770-778.
[21]	SERGEY Z, NIKOS K. Paying More Attention to Attention:Improving the Performance of Convolutional Neural Networks via Attention Transfer[C]//International Conference on Learning Representations. La Jolla: ICLR, 2017:1-13.
[22]	TIAN Y L, KRISHNAN D, ISOLA P. Contrastive Representation Distillation[C]//International Conference on Learning Representations. La Jolla: ICLR, 2020:1-19.
[23]	PARK W, KIM D, LU Y. Relational Knowledge Distillation[C]//IEEE Conference on Computer Vision and Pattern Recognition. Piscataway:IEEE, 2019:3967-3976.
[24]	SHI J, XU J, TASAKA K, et al. SASL:Saliency-Adaptive Sparsity Learning for Neural Network Acceleration[J]. IEEE Transaction Circuits System Video Technology, 2021, 31(5):2008-2019.
[25]	HUANG Z, WANG N. Data-Driven Sparse Structure Selection for Deep Neural Networks[C]//Proceedings Europe Conference Computer Vision. Heidelberg:Springer, 2018:304-320.
[26]	LIU Z C, MU H Y, ZHANG X Y, et al. MetaPruning:Meta Learning for Automatic Neural Network Channel Pruning[C]//Proceedings IEEE/CVF International Conference on Computer Vision. Piscataway:IEEE, 2019:3296-3305.
[27]	刘侍刚, 张同, 杨建功, 等. 递进式空洞残差深度双目立体匹配网络[J]. 西安电子科技大学学报, 2022, 49(5):175-180.
	LIU Shigang, ZHANG Tong, YANG Jiangong, et al. Progressive Dialtion Residual Network for Deep Binocular Stereo Matching[J]. Journal of Xidian University, 2022, 49(5):175-180.
[28]	WANG Z, XU X, HUA Z, et al. Lightweight Recognition for the Oestrus Behavior of Dairy Cows Combining YOLO v5n and Channel Pruning[J]. Transactions of the Chinese Society of Agricultural Engineering, 2022, 38(23):130-140.
[29]	LIN T Y, PIOTR D, ROSS G, et al. Feature Pyramid Networks for Object Detection[C]//Proceedings of the IEEE conference on computer vision and pattern recognition. Piscataway:IEEE, 2017:2117-2125.

目标类型	IoU	nIoU	PD	FA
生物	0.654(+0.003)	0.647(+0.003)	0.927(-0.005)	0.162(-0.003)
飞机	0.647(-0.004)	0.644(+0.001)	0.932(+0.000)	0.168(+0.003)
船只	0.651(+0.000)	0.641(-0.002)	0.935(+0.003)	0.159(-0.006)
整个数据集平均值	0.651	0.643	0.932	0.165

方案	FLOPs	IoU	nIoU	PD	FA
SIC-Net	-17.6	+2.17	+1.28	+2.38	-1.29
MDvsFA	-10.6	-0.37	+0.72	+1.02	-0.32
SKNet	-7.2	+0.87	+1.07	+0.47	-0.11
ACMNet	-12.9	-0.16	+0.86	+1.26	-0.87
ALCNet	-8.7	+1.17	+0.97	+2.07	-0.41

融合方法	SIRST				IRSTD-1K
融合方法	IoU	nIoU	PD	FA	IoU	nIoU	PD	FA
未融合(P)	0.712	0.706	0.90	0.13	0.588	0.571	0.85	0.31
未融合(P')	0.722	0.701	0.89	0.12	0.592	0.569	0.88	0.34
SC-SUM	0.731	0.711	0.95	0.05	0.642	0.625	0.91	0.17
CC	0.729	0.721	0.97	0.08	0.649	0.631	0.92	0.19
C-c(文中提出)	0.743	0.728	0.99	0.06	0.651	0.643	0.93	0.16

方法	FLOPs/G	SIRST				IRSTD-1K
方法	FLOPs/G	IoU/%	nIoU/%	PD/%	FA/10^-6	IoU/%	nIoU/%	PD/%	FA/10^-6
Top-Hat		1.64	1.38	93.58	1 513	10.61	7.44	75.11	1 442
Max-Median		4.98	3.79	89.44	827.8	6.99	3.05	65.21	57.93
WSLCM		3.94	3.56	95.41	8 132	3.45	0.67	72.44	6 632
TLLCM		2.96	1.85	96.33	10 112	3.31	0.78	77.39	6 578
IPI		45.39	40.33	92.66	62.97	27.92	20.46	81.37	16.25
NRAM		17.28	15.34	72.48	8.89	15.25	9.98	70.68	16.79
RIPT		15.33	13.87	81.10	37.78	14.11	8.09	77.55	28.53
PSTNN		30.72	27.96	81.65	41.70	24.57	17.93	71.99	36.75
MSLSTIPT		13.11	12.85	85.73	1 571	14.11	5.93	79.10	1 524
MDvsFA	25.76	59.56	57.56	89.98	50.23	49.51	47.41	82.11	82.43
SKNet	21.45	66.13	65.08	97.25	56.78	57.27	55.06	86.20	19.34
ACMNet	22.37	70.41	68.99	96.98	6.91	60.97	58.02	90.58	21.80
ALCNet	19.60	72.19	70.38	98.22	9.61	62.05	59.58	92.19	31.61
SIC-Net(教师模型)	13.2	74.81	73.11	98.81	6.21	65.50	65.20	94.51	15.71
SIC-Net(学生模型)	3.47	74.33	72.82	99.21	6.42	65.11	64.31	93.20	16.50

方案	IoU	nIoU	PD	FA
添加噪声前	0.743	0.728	0.992	0.064
添加噪声后	0.741(-0.002)	0.719(-0.009)	0.997(+0.005)	0.068(+0.004)