一种复杂监控场景下的人体检测算法

doi:10.19665/j.issn1001-2400.2021.05.009

Abstract

Abstract:

In the video surveillance scene,due to the influence of factors such as complex background,multi-posture and occlusion,existing human body detection algorithms have problems such as low accuracy and weak model generalization ability.In response to the above problems,we have designed a detection network feature fusion method and feature map generation strategy based on the feature image pyramid and multi-scale receptive field theory.By relying on the lightweight feature image pyramid technology and combining optimization methods such as data enhancement,anchor box matching strategy and occlusion loss function,we have further proposed a human body detection algorithm EFIPNet based on the deep neural network.Meantime,in order to fully verify the effectiveness of the EFIPNet algorithm,this paper establishes 4 diversified video surveillance scene data sets,which involves a total of 50 common human body postures.The validation of the algorithm shows that the human detection network we have designed can effectively improve the detection accuracy of the human body,and achieve accurate and real-time human body detection in complex monitoring scenarios.In addition,in order to verify the effectiveness of different modules in the EFIPNet algorithm,we have used the ablation research method to analyze the influence of the main modules in the network on the performance of the human body detection model.On the Person dataset,compared with the SSD detection algorithm,the EFIPNet algorithm improves the detection accuracy of human targets by 4.34% while maintaining the detection speed of 45 frames per second.

Key words: deep neural network, video surveillance, feature fusion, feature map generation strategy, human body detection

CLC Number:

TP18

ZHANG Shuwei,LI Junmin. Human body detection algorithm in complex monitoring scenes[J].Journal of Xidian University, 2021, 48(5): 68-77.

Figures/Tables 13

References 16

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算法	数据集	输入尺寸/像素	召回率	精确率	mAP
SSD	Stanford40	300×300	74.08	82.78	74.86
	VOC2012	300×300	81.98	82.78	81.80
	Indoor	300×300	87.34	93.59	87.26
	Person	300×300	88.40	98.69	89.41
EFIPNet	Stanford40	300×300	76.65	88.41	76.80
	VOC2012	300×300	85.74	87.92	84.77
	Indoor	300×300	89.54	97.41	89.21
	Person	300×300	93.42	99.68	93.75

算法	输入尺寸/像素	模型大小/MB	FPS/(帧·s^-1)	mAP/%
SSD	300×300	95	56	89.41
	512×512	95	43	92.52
EFIPNet	300×300	110	45	93.75

算法	输入尺寸/像素	模型大小/MB	FPS/(帧·s^-1)	mAP/%
SSD	300×300	95.0	56	89.41
RFBNet	300×300	135.2	37	90.86
RefineDet	300×300	142.3	32	91.59
EFIPNet	300×300	110.0	45	93.75

算法	RFB	RFBs	FFM	LCB + FAM	mAP/%
SSD					89.41
EFIPNet	P				90.32
	P	P			90.46
	P	P	P		91.35
	P	P	P	P	93.75

Human body detection algorithm in complex monitoring scenes

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