一种多传感器自适应量测迭代更新GM-PHD跟踪算法

申屠晗; 李凯斌; 荣英佼; 李彦欣; 郭云飞

doi:10.11999/JEIT211138

一种多传感器自适应量测迭代更新GM-PHD跟踪算法

doi: 10.11999/JEIT211138

1.
杭州电子科技大学自动化学院杭州 310018
2.
近地面探测技术重点实验室无锡 214035

基金项目: 基础加强计划技术领域基金(2021-JCJQ-JJ-0301)，近地面探测技术重点实验室基金(6142414200203)，浙江省属高校基本科研业务费专项资金(GK219909299001-405)，浙江省自然科学基金重点项目(LZ20F010002)，国家大学生创新创业训练计划(202110336022)

详细信息

作者简介:
申屠晗：男，1984年生，副教授，研究方向为信息融合、目标检测与跟踪、机器学习与智能信息处理等

李凯斌：男，1997年生，硕士生，研究方向为多传感器多目标跟踪、SLAM

荣英佼：女，1978年生，工程师，研究方向为雷达信号处理、信息融合

郭云飞：男，1978年生，教授，研究方向为目标跟踪、信息融合

通讯作者:
荣英佼　yingjiao_rong@hotmail.com

中图分类号: TP212
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出版历程
- 收稿日期: 2021-10-18
- 修回日期: 2022-05-18
- 录用日期: 2022-05-24
- 网络出版日期: 2022-05-30
- 刊出日期: 2022-12-16

A Multi-sensor Adaptive Observation Iteratively Updating GM-PHD Tracking Algorithm

1.
Institution of Information and Control, Hangzhou Dianzi University, Hangzhou 310018, China
2.
Science and Technology on Near-Surface Detection Laboratory, Wuxi 214035, China

Funds: The Technology Foundation for Basic Enhancement Plan (2021-JCJQ-JJ-0301), The Foundation of Key Laboratory of Near Ground Detection Technology (6142414200203), The Fundamental Research Funds for the Provincial Universities of Zhejiang (GK219909299001-405), Zhejiang Provincial Natural Science Foundation of China (LZ20F010002), The National College Students Innovation and Entrepreneurship Training Program of China (202110336022)

摘要

摘要: 针对多传感器观测数据质量不同且未知时，多传感器量测迭代更新高斯混合概率假设密度(GM-PHD)滤波器跟踪算法的结果对更新顺序敏感的问题，该文提出一种多传感器自适应量测迭代更新GM-PHD跟踪算法AIU-GM-PHD。首先基于多传感器融合一致性度量，提出一种用于在线评估各传感器跟踪结果质量的方法；然后对多传感器迭代融合顺序进行优化，最后构建相应的多传感器GM-PHD融合跟踪算法。为了解决多传感器自适应顺序迭代融合无法体现传感器质量差距的问题，提出了一种自适应带权伪量测迭代更新GM-PHD跟踪算法PAIU-GM-PHD。仿真结果表明，与常规多传感器迭代更新GM-PHD跟踪算法相比，所提算法能够获得鲁棒性更好、精度更高的跟踪结果。
- 多传感器多目标跟踪 /
- 随机有限集 /
- 自适应融合 /
- 高斯混合概率假设密度滤波器 /
- 量测迭代更新
Abstract: For the problem that the results of multi-sensor measurement iteratively updating Gaussian Mixture Probability Hypothesis Density (GM-PHD) tracking algorithm is sensitive to the updating order if the qualities of multi-sensor observation data are different and unknown, a multi-sensor Adaptive observation Iteratively Updating GM-PHD tracking algorithm (AIU-GM-PHD) is proposed. Firstly, based on the multi-sensor fusion consistency measure, a method is proposed to evaluate the online quality of each sensor's tracking results. Then, the sequence of multi-sensor iterative fusion is optimized. Finally, the corresponding multi-sensor GM-PHD fusion tracking algorithm is constructed. To solve the problem that the multi-sensor adaptive order iterative fusion can not reflect the sensor quality gap, an Adaptive Iteratively Updating GM-PHD tracking algorithm PAIU-GM-PHD with weighted pseudo measurements is proposed. The simulation results show that, compared with the conventional multi-sensor iterative update GM-PHD tracking algorithm, the proposed algorithms can obtain more robust and accurate tracking results.
- Multi-sensor multi-target tracking /
- Random finite set /
- Adaptive fusion /
- Gaussian Mixture Probability Hypothesis Density (GM-PHD) filter /
- Measurement iteratively updating

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图 1 GM-PHD量测迭代更新流程图

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图 2 AIU-GM-PHD算法框架图

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图 3 场景1两种融合顺序的OSPA对比图和目标数目估计对比图

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图 4 场景2两种融合顺序的OSPA对比图和目标数目估计对比图

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图 5 场景1各算法的OSPA对比图和目标数目估计对比图

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图 6 场景2各算法的OSPA对比图和目标数目估计对比图

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图 7 场景3各算法的OSPA对比图和目标数目估计对比图

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表 1 实验1场景设置

	检测概率	杂波数量
场景1	$p_d^1 = 0.95,{\text{ } }p_d^2 = 0.85,{\text{ } }p_d^3 = 0.75,{\text{ } }p_d^4 = 0.65$	${\lambda _1} = 2,0{\text{ } }{\lambda _2} = 20,{\text{ } }{\lambda _3} = 20,{\text{ } }{\lambda _4} = 20$
场景2	$p_d^1 = 0.90,{\text{ } }p_d^2 = 0.90,{\text{ } }p_d^3 = 0.90,{\text{ } }p_d^4 = 0.90$	${\lambda _1} = 20,{\text{ } }{\lambda _2} = 30,{\text{ } }{\lambda _3} = 40,{\text{ } }{\lambda _4} = 50$

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表 2 实验2场景设置

	检测概率	杂波数量
场景1	$p_{{d} }^1 = 0.95,{\text{ } }p_{{d} }^2 = 0.85,{\text{ } }p_{{d} }^3 = 0.75,{\text{ } }p_{{d} }^4 = 0.65$	$ {\lambda _1} = 20,{\text{ }}{\lambda _2} = 20,{\text{ }}{\lambda _3} = 20,{\text{ }}{\lambda _4} = 20 $
场景2	${p}_{ {d} }^{1}=0.90，\text{}\text{}\text{}\text{}\text{}\text{}\text{}\text{}\text{ }{p}_{ {d} }^{2}=0.90,\text{ }{p}_{ {d} }^{3}=0.90,\text{ }{p}_{ {d} }^{4}=0.90\text{}\text{}$	${\lambda _1} = 20,{\text{ }}{\lambda _2} = 30,{\text{ }}{\lambda _3} = 40,{\text{ }}{\lambda _4} = 50$
场景3	$p_{{d} }^1 = 0.95,{\text{ } }p_{{d} }^2 = 0.85,{\text{ } }p_{{d} }^3 = 0.75,{\text{ } }p_{{d} }^4 = 0.65$	${\lambda _1} = 20,{\text{ }}{\lambda _2} = 30,{\text{ }}{\lambda _3} = 40,{\text{ }}{\lambda _4} = 50$

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表 3 场景1仿真结果

算法	OSPA精度	目标数目估计(真实3)
单传感器GM-PHD	22.8412	2.5361
RIU-GM-PHD	15.6506	2.7581
AIU-GM-PHD	10.5369	2.9808
PAIU-GM-PHD	10.3282	3.0557
MD-IC-PHD	12.9869	2.4657

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表 4 场景2仿真结果

算法	OSPA精度	目标数目估计(真实3)
单传感器GM-PHD	22.8412	2.5361
RIU-GM-PHD	20.4843	2.4578
AIU-GM-PHD	13.4627	2.8301
PAIU-GM-PHD	12.2804	2.9288
MD-IC-PHD	8.1814	2.9336

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表 5 场景3仿真数据

算法	OSPA精度	目标数估计(真实3)
单传感器GM-PHD	24.3033	2.4351
RIU-GM-PHD	20.5465	2.4874
AIU-GM-PHD	13.6899	2.8429
PAIU-GM-PHD	12.7136	2.9526
MD-IC-PHD	19.0824	2.4410

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表 6 3 种算法时间复杂度对比

算法	时间复杂度	空间复杂度	单帧时间消耗(s)
RIU-GM-PHD	$(2L - 1) \cdot O(n)$	$O(d)$	15.37
AIU-GM-PHD	$(2L - 1) \cdot O(n) + L \cdot O(s)$	$O(d) + O(L)$	19.02
PAIU-GM-PHD	$(2L - 1) \cdot O(n) + L \cdot (O(s) + O(j))$	$O(d) + 2 \cdot O(L)$	20.01

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