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浙江大学学报(工学版)
浙江大学学报(工学版)  2022, Vol. 56 Issue (6): 1135-1143, 1167    DOI: 10.3785/j.issn.1008-973X.2022.06.010
智能机器人     
融合运动信息和跟踪评价的高效卷积算子
张迅1(),李建胜1,*(),欧阳文1,陈润泽1,汲振1,郑凯2
1. 战略支援部队信息工程大学 地理空间信息学院,河南 郑州 450001
2. 73159部队,福建 泉州 362110
Efficient convolution operators integrating motion information and tracking evaluation
Xun ZHANG1(),Jian-sheng LI1,*(),Wen OUYANG1,Run-ze CHEN1,Zhen JI1,Kai ZHENG2
1. Institute of Geographical Spatial Information, Information Engineering University, zhengzhou 450001, China
2. 73159 Troops, Quanzhou 362100, China
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摘要:

针对基于方向梯度直方图与颜色命名的高效卷积算子(ECO-HC)算法缺少跟踪质量评价和滤波模板更新监督机制的问题,提出融合运动信息和跟踪评价的高效卷积算子. 将卡尔曼滤波器加入ECO-HC跟踪定位框架对目标执行联合跟踪,设计高置信度判别指标评价ECO-HC对每帧图像的跟踪效果,使用原始跟踪结果和卡尔曼滤波预测值的加权融合值,修正不满足判别指标的跟踪结果. 在滤波模板隔帧更新策略的基础上,加入当前帧跟踪结果质量评价信息,当2个条件同时满足时执行模板更新. 依托公开数据集OTB-2015评估算法性能,结果显示改进算法整体跟踪精确度、成功率和跟踪速率均优于原算法,在运动模糊、低分辨率、离开视野场景中的精确度分别提高3.0%、3.5%和2.8%,成功率分别提高3.8%、2.1%和4.0%. 改进算法在保证实时性的同时,有效提升了复杂场景下的跟踪效果.
关键词: 视觉目标跟踪高效卷积算子(ECO)跟踪评价高置信度指标卡尔曼滤波器    
Abstract:

An efficient convolution operator integrating motion information and tracking evaluation was proposed, to solve the problems that an efficient convolution operators algorithm named by histogram of oriented gridients and color (ECO-HC) lacks the quality evaluation of tracking result and the supervision mechanism of filter model updating. Firstly, the Kalman filter was added to the ECO-HC positioning framework to carry out joint tracking of objects. A high-confidence discriminant indicator was designed to evaluate the tracking result of ECO-HC for each frame of video. If the current frame tracking results did not meet the confidence requirement, the weighted fusion value of the algorithm tracking results and the predicted value of Kalman filter would be used as the final target tracking results. Then, based on the filter template update strategy of the original algorithm, the quality evaluation information of the current frame tracking results was added.The filter template update was performed when the two conditions were true. Finally, the performance of the improved algorithm was evaluated on a open data set OTB-2015. The results showed that the overall tracking precision, success rate and tracking rate of the algorithm with proposed operator were superior to the original algorithm. The precision in the scene with motion blur, low resolution and out of view was increased by 3.0%, 3.5% and 2.8% respectively, and the success rate was increased by 3.8%, 2.1% and 4.0% respectively. The proposed algorithm not only ensured the real-time performance, but also improved the tracking performance in complex scenes.
Key words: visual object tracking    efficient convolution operator(ECO)    tracking evaluation    high-confidence discrimination indicator    Kalman filter
收稿日期: 2021-07-14 出版日期: 2022-06-30
CLC:  TP 391  
通讯作者: 李建胜     E-mail: 1219233886@qq.com;ljs2021@vip.henu.edu.cn
作者简介: 张迅(1997—),男,硕士生,从事图像处理与模式识别研究. orcid.org/0000-0002-5436-5879. E-mail: 1219233886@qq.com
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引用本文:

张迅,李建胜,欧阳文,陈润泽,汲振,郑凯. 融合运动信息和跟踪评价的高效卷积算子[J]. 浙江大学学报(工学版), 2022, 56(6): 1135-1143, 1167.

Xun ZHANG,Jian-sheng LI,Wen OUYANG,Run-ze CHEN,Zhen JI,Kai ZHENG. Efficient convolution operators integrating motion information and tracking evaluation. Journal of ZheJiang University (Engineering Science), 2022, 56(6): 1135-1143, 1167.

链接本文:

https://www.zjujournals.com/eng/CN/10.3785/j.issn.1008-973X.2022.06.010        https://www.zjujournals.com/eng/CN/Y2022/V56/I6/1135

图 1  改进ECO-HC算法跟踪框架
图 2  Girl2序列的ECO-HC算法跟踪结果
图 3  Girl2序列的ECO-HC算法融合特征响应图
$ {\beta }_{1},{\beta }_{2} $ P S $ {\beta }_{1},{\beta }_{2} $ P S
(0,0.45) 83.3 77.1 (0.6,0.45) 83.9 77.5
(0.55,0.45) 83.3 77.0 (0.6,0.50) 83.4 76.6
(0.6,0) 83.8 76.8 (0.65,0.45) 84.0 77.0
(0.6,0.40) 83.5 76.5 ? ? ?
表 1  各对照组总体跟踪效果对比结果
跟踪算法 P/% S/% R/(帧·s ?1
本研究 83.9 77.5 37.1
ECO-HC 83.3 76.1 36.5
DSST 67.9 60.0 60.5
SRDCF 79.0 72.8 3.4
SRDCFdecon 82.5 76.6 1.8
表 2  跟踪5种算法的总体跟踪效果和跟踪速率对比结果
图 4  OTB2015数据集上不同算法一次通过评估的总体精确度和成功率图
跟踪算法 P
IV OPR SV OCC DEF MB FM IPR OV BC LR
本研究 80.0 81.6 81.0 80.1 81.0 80.6 81.4 77.0 80.2 81.5 83.7
ECO-HC 78.7 80.3 79.6 78.2 79.8 77.6 80.2 76.4 77.4 81.7 80.2
DSST 71.5 64.4 63.3 58.9 53.3 56.7 55.2 69.1 48.1 70.4 56.7
SRDCF 78.6 74.2 74.1 73.0 72.8 76.7 76.9 74.5 59.7 77.5 65.5
SRDCFdecon 83.3 79.7 80.3 76.5 75.0 81.4 77.5 77.6 64.1 85.0 64.4
表 3  不同挑战场景序列下5种跟踪算法的跟踪精确度对比结果
跟踪算法 S
IV OPR SV OCC DEF MB FM IPR OV BC LR
本研究 76.5 73.5 73.0 75.0 73.6 78.6 77.0 68.1 73.3 77.5 72.1
ECO-HC 75.5 71.7 70.6 73.0 70.9 74.8 75.2 65.8 69.3 76.8 70.0
DSST 64.9 55.1 52.5 53.1 47.9 55.1 51.7 58.9 44.2 61.3 44.2
SRDCF 74.0 66.4 66.2 67.8 65.9 72.9 71.7 66.2 55.8 70.1 62.6
SRDCFdecon 78.9 72.0 73.3 72.5 67.3 79.9 73.2 69.8 64.1 78.6 61.9
表 4  不同挑战场景序列下5种跟踪算法的跟踪成功率对比结果
图 5  典型复杂场景序列下不同跟踪算法的跟踪对比
指标 EAO R f Acc
本研究 0.2805 21.1684 0.3967
ECO-HC 0.2693 23.8174 0.3828
表 5  基于VOT2016数据集的算法总体跟踪效果
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