融合运动信息与表观信息的多目标跟踪算法

doi:10.16180/j.cnki.issn1007-7820.2020.09.004

电子科技 ›› 2020, Vol. 33 ›› Issue (9): 21-25.doi: 10.16180/j.cnki.issn1007-7820.2020.09.004

融合运动信息与表观信息的多目标跟踪算法

黎阳,沈烨,刘敏,戴仁月,姜晓燕

上海工程技术大学电子电气工程学院,上海 201620

收稿日期:2019-06-14 出版日期:2020-09-15 发布日期:2020-09-12
作者简介:黎阳(1994-),男,硕士研究生。研究方向:数字图像处理、计算机视觉和机器学习。|姜晓燕(1985-),女,博士,讲师。研究方向:无人驾驶、多目标跟踪、多源信息融合、无人机视觉SLAM、多摄像机网络。
基金资助:
国家自然科学基金(61702322);国家自然科学基金(6177051715);国家自然科学基金(61802251);上海市科委重点项目(18511101600)

Multi-target Tracking Algorithm by Combining Motion Information and Apparent Information

LI Yang,SHEN Ye,LIU Min,DAI Renyue,JIANG Xiaoyan

School of Electronic and Electrical Engineering,Shanghai University of Engineering Science,Shanghai 201620,China

Received:2019-06-14 Online:2020-09-15 Published:2020-09-12
Supported by:
National Natural Science Foundation of China(61702322);National Natural Science Foundation of China(6177051715);National Natural Science Foundation of China(61802251);Essential Project of Shanghai Science and Technology Committee(18511101600)

摘要/Abstract

摘要：

多目标跟踪是计算机视觉领域的重要研究方向,其在智能视频监控、人机交互、机器人导航、公共安全等领域有着重要的作用。目前目标跟踪算法仍面临诸多的挑战,例如遮挡、背景复杂、运动模糊等因素所造成的影响难以完全规避。文中基于一种简单的在线跟踪方法,提出一种融合多类信息的算法,有效地提升了跟踪器的性能。模型关注于帧与帧之间的目标检测与数据关联问题,依赖于不同帧之间目标运动与表观的相似性,当目标丢失及存在遮挡时,融合多源信息减少相关的不确定性。同时,该算法在真实环境中可实现实时跟踪的性能。实验评估结果表明,提出的跟踪器在公开数据集上具有良好的性能,可以显著减少目标丢失率以及身份交换率。

关键词: 计算机视觉, 多目标跟踪, 目标检测, 目标遮挡, 实时跟踪, 数据关联

Abstract:

Multi-target tracking is an important research direction in the field of computer vision. Multi-target tracking plays an important role in the fields of intelligent video surveillance, human-computer interaction, robot navigation, and public safety. At present, the target tracking algorithm still faces many challenges, such as the effects of occlusion, complex background, motion blur, etc., which are difficult to completely avoid. This paper proposes an algorithm that combines multiple types of information, which effectively improves the performance of the tracker. The model focuses on the problem of object detection and data association between frames, which depends on the similarity of the target motion and the apparent between different frames. When the target is lost and there is occlusion, the fusion of multi-source information reduces the related uncertainty. At the same time, the algorithm achieves real-time tracking performance in real-world environments. Experimental evaluation shows that the proposed tracker has good performance on the public data set, greatly reducing the target loss rate and ID switch.

Key words: computer vision, multi-target tracking, object detection, target occlusion, real-time tracking, data association

中图分类号:

TP391.4

黎阳,沈烨,刘敏,戴仁月,姜晓燕. 融合运动信息与表观信息的多目标跟踪算法[J]. 电子科技, 2020, 33(9): 21-25.

LI Yang,SHEN Ye,LIU Min,DAI Renyue,JIANG Xiaoyan. Multi-target Tracking Algorithm by Combining Motion Information and Apparent Information[J]. Electronic Science and Technology, 2020, 33(9): 21-25.

图/表 5

图1

表1

图2

表2

表3

参考文献 18

[1]	Pirsiavash H, Ramanan D, Fowlkes C C. Globally-optimal greedy algorithms for tracking avariable number of objects[C]. Springs:IEEE Conference on Computer Vision and Pattern Recognition, 2011.
[2]	Jérôme B, François F, Engin T, et al. Multiple object tracking using K-shortest paths optimization[J]. IEEE Transactions on Pattern Analysis & Machine Intelligence, 2011,33(9):1806-1819. pmid: 21282851
[3]	Nevatia R, Yang B. An online learned CRF model for multi-target tracking[C]. Providence:IEEE Conference on Computer Vision and Pattern Recognition, 2012.
[4]	Yang B, Nevatia R. Multi-target tracking by online learning of non-linear motion patterns and robust appearance models[C]. Providence:IEEE Conference on Computer Vision and Pattern Recognition, 2012.
[5]	Roth S, Andriyenko A, Schindler K. Discrete-continuous optimization for multi-target tracking[C]. Providence: IEEE Conference on Computer Vision and Pattern Recognition, 2012.
[6]	Milan A, Schindler K, Roth S. Detection and trajectory level exclusion in multiple object tracking[C]. Portland:Computer Vision & Pattern Recognition, 2013.
[7]	Kim C, Li F, Ciptadi A, et al. Multiple hypoconfproc tracking revisited[C]. Santiago:IEEE International Conference on Computer Vision, 2015.
[8]	Rezatofighi S H, Milan A, Zhang Z, et al. Joint probabilistic data association revisited[C]. Santiago:IEEE International Conference on Computer Vision, 2015.
[9]	Bewley A, Ge Z, Ott L, et al. Simple online and realtime tracking[C]. Phoenix:IEEE International Conference on Image Processing, 2016.
[10]	Ren S, He K, Girshick R, et al. Faster R-CNN: towards real-time object detection with region proposal networks[C]. Quebec City:IEEE International Conference on Image Processing, 2015.
[11]	王伟栋, 李菲菲, 谢林, 等. 基于深度神经网络和哈希算法的图像检索研究[J]. 电子科技, 2018,31(10):52-56.
	Wang Weidong, Li Feifei, Xie Lin, et al. Research on image retrieval based on deep neural network and Hash algorithm[J]. Electronic Science and Technology, 2018,31(10):52-56.
[12]	Redmon J, Divvala S, Girshick R, et al. You only look once: Unified, Real-Time object detection[C]. Boston: Computer Vision and Pattern Recognition, 2015.
[13]	Redmon J, Farhadi A. YOLO9000:better, faster, stronger[C]. Honolulu:IEEE Conference on Computer Vision and Pattern Recognition, 2017.
[14]	李远状, 韩彦芳, 于书盼. 一种核相关滤波器的多尺度目标跟踪方法[J]. 电子科技, 2018,31(10):5-9.
	Li Yuanzhuang, Han Yanfang, Yu Shupan. Multi-scale target tracking method for nuclear correlation filter[J]. Electronic Science and Technology, 2018,31(10):5-9.
[15]	Leal Taixé L, Milan A, Reid L, et al. MOTChallenge 2015: towards a benchmark for multi-target tracking[C]. Boston:Computer Vision and Pattern Recognition, 2015.
[16]	Milan A, Leal-Taixe L, Reid I, et al. MOT16:A benchmark for multi-object tracking[C]. Las Vegas:Computer Vision and Pattern Recognition, 2016.
[17]	Ristani E, Solera F, Zou R S, et al. Performance measures and a data set for multi-target,multi-camera tracking[C]. Amsterdam:European Conference on Computer Vision, 2016.
[18]	李盈盈, 李菲菲, 陈虬. 基于改进HOG共生概率特征的行人检测算法[J]. 电子科技, 2018,31(9):4-8.
	Li Yingying, Li Feifei, Chen Qiu. Pedestrian detection algorithm based on improved HOG symbiotic probability feature[J]. Electronic Science and Technology, 2018,31(9):4-8.

类型	滤波器	尺寸/步长	输出
卷积	32	3×3	224×224
最大池化	-	2×2/2	112×112
卷积	64	3×3	112×112
最大池化	-	2×2/2	56×56
卷积	128	3×3	56×56
卷积	64	1×1	56×56
卷积	128	3×3	56×56
最大池化	-	2×2/2	28×28
卷积	256	3×3	28×28
卷积	128	1×1	28×28
卷积	256	3×3	28×28
最大池化	-	2×2/2	14×14
卷积	512	3×3	14×14
卷积	256	1×1	14×14
卷积	512	3×3	14×14
卷积	256	1×1	14×14
卷积	512	3×3	14×14
最大池化	-	2×2/2	7×7
卷积	1 024	3×3	7×7
卷积	512	1×1	7×7
卷积	1 024	3×3	7×7
卷积	512	1×1	7×7
卷积	1 024	3×3	7×7
卷积	1 000	1×1	7×7
平均池化	-	全局	1 000
Softmax	-	-	-

测量指标	效果	最好效果	描述
Avg Rank	lower	1	这是每个跟踪器在所有当前评估测量中的平均等级
MOTA	higher	100%	多目标跟踪精度(该措施结合了3个错误来源:误报,丢失目标和身份交换)
MOTP	higher	100%	多目标跟踪精度(注释和预测的边界框之间的不对齐)
IDF1	higher	100%	IDF1得分^[17](正确识别的检测与平均真实数和计算检测数之比)
FAF	lower	0	每帧的平均误报警数
MT	higher	100%	主要是跟踪目标(轨道假设所覆盖的Ground-truth轨迹的比率至少为其各自存在周期的80%)
ML	lower	0%	主要是丢失目标(轨道假设所覆盖的Ground-truth轨迹的比率最多为其各自存在周期的20%)
FP	lower	0	假正样本总数
FN	lower	0	假负样本总数(丢失目标)
ID Sw.	lower	0	身份交换的总数(遵循描述中更严格的身份交换定义)
Frag	lower	0	轨迹被分段(即在跟踪期间中断)的总次数
Hz	higher	Inf.	基准测试的处理速度(以每秒帧数为单位,不包括探测器)

指标	MOT15	MOT16
IDF1	41.2	33.4
IDP	53.2	62.4
IDR	33.6	22.8
Rcll	45.3	32.7
PT	161	184
ML	258	297
FP	7 129	5 382
FN	21 842	75 426
Prcn	71.7	86.7
FAR	1.3	1.9
GT	500	517
MT	81	36
ID Sw.	220	41
FM	338	457
MOTA	26.9	26.4
MOTP	72.4	75.9

融合运动信息与表观信息的多目标跟踪算法

Multi-target Tracking Algorithm by Combining Motion Information and Apparent Information

RichHTML

PDF (PC)

赞

可视化

摘要/Abstract

引用本文

使用本文

图/表 5

参考文献 18

相关文章 15

Metrics

本文评价

推荐阅读 10

[1]	赵崇,迟蒙蒙,储聪,张鹏. 导盲犬行走机构运动仿真及其视觉识别算法研究[J]. 电子科技, 2021, 34(9): 66-72.
[2]	陈文佑,章伟,史晓帆,宋芳. 一种改进ORB特征匹配的半稠密三维重建ORB-SLAM算法[J]. 电子科技, 2021, 34(12): 62-67.
[3]	叶飞, 刘子龙. 基于改进YOLOv3算法的行人检测研究[J]. 电子科技, 2021, 34(1): 5-9.
[4]	王春江,李鹏. 基于ZYNQ的运动目标检测系统设计[J]. 电子科技, 2020, 33(5): 82-86.
[5]	官洪运,苏振涛,汪晨. 基于特征融合的背景差分改进算法[J]. 电子科技, 2020, 33(12): 22-27.
[6]	邵玉娥,王暕来,周生华,刘宏伟,张月红. 基于LASSO的雷达脉压压缩方法[J]. 电子科技, 2020, 33(11): 7-10.
[7]	杨标,刘翔,汤显,陈俊廷. 智能工厂下的AGV多目标跟踪[J]. 电子科技, 2019, 32(11): 23-27.
[8]	肖儿良,韩超. 应用于人脸自动实时跟踪的改进Struck算法[J]. , 2016, 29(3): 42-.
[9]	刘金利,傅志中,周阳,黄波. 基于帧间差分法和VIBE算法的运动目标检测[J]. , 2015, 28(8): 91-.
[10]	李露,詹强. 铁路视频监控中运动目标检测算法研究[J]. , 2015, 28(5): 27-.
[11]	刘云波,黄华. 施工现场安全帽佩戴情况监控技术研究[J]. , 2015, 28(4): 69-.
[12]	赵日成. 基于车底阴影的车前障碍物检测[J]. , 2015, 28(3): 15-.
[13]	刘甜甜. 基于稀疏和低秩表示的显著性目标检测[J]. , 2015, 28(2): 112-.
[14]	蔡肖芋,眭海刚. 一种显著图分割的遥感油库检测方法[J]. , 2015, 28(11): 154-.
[15]	张传伟,王京梅,林晓明,赵文俊. 基于背景差分的一种运动目标检测方法[J]. , 2015, 28(10): 69-.