Systems Engineering and Electronics ›› 2023, Vol. 45 ›› Issue (11): 3411-3418.doi: 10.12305/j.issn.1001-506X.2023.11.06
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3D extended target PMBM tracking algorithm based on moving least square
Bowen HENG, Cuiyun LI, Xiang LI
- School of Electronic Engineering, Xidian University, Xi'an 710071, China
-
Received:2022-06-07Online:2023-10-25Published:2023-10-31 -
Contact:Bowen HENG
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Cite this article
Bowen HENG, Cuiyun LI, Xiang LI. 3D extended target PMBM tracking algorithm based on moving least square[J]. Systems Engineering and Electronics, 2023, 45(11): 3411-3418.
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Fig.1
Initialized shape and control points"
Fig.1
Fig.2
Measurements received by sensors while tracking multiple targets"
Fig.2
Fig.3
Trajectories of the three targets"
Fig.3
Table 1
Initialization parameters for the targets"
| 目标 | 目标初始运动状态 | 存活时间/s |
| 1 | x1=[-175, -175, -175, 7, 7, 7]T | t1∈[1, 50] |
| 2 | x2=[-175, 150, 120, 5, -5, -6]T | t2∈[1, 30] |
| 3 | x3=[-175, -150, 140, -5, 7, -5]T | t3∈[20, 50] |
Table 1
Fig.4
Shape rendering of MLS-PMBM when estimating the ellipsoidal target"
Fig.4
Fig.5
Local magnification of MLS-PMBM when tracking the cube target"
Fig.5
Fig.6
Local magnification of MLS-PMBM when tracking the cross target"
Fig.6
Fig.7
Shape rendering of GGIW-PMBM when estimating the ellipsoidal target"
Fig.7
Fig.8
Trajectory diagram of GGIW-PMBM when tracking the cube target"
Fig.8
Fig.9
Trajectory diagram of GGIW-PMBM when tracking the cross target"
Fig.9
Table 2
Comparison of average IoU estimated by MLS-PMBM and GGIW-PMBM algorithms"
| 目标类型 | 算法 | |
| MLS-PMBM | GGIW-PMBM | |
| 椭球 | 0.912 3 | 0.909 2 |
| 立方体 | 0.841 9 | 0.217 4 |
| 十字架 | 0.823 3 | 0.243 8 |
Table 2
Table 3
Comparison of the time taken by single step arithmetic s"
| 算法 | 估计椭球目标形状时算法的单步耗时 | 估计立方体目标形状时算法的单步耗时 | 估计十字架目标形状时算法的单步耗时 |
| MLS-PMBM | 0.631 0 | 0.652 1 | 0.621 2 |
| GGIW-PMBM | 0.263 6 | 0.249 3 | 0.245 2 |
Table 3
Fig.10
Target number estimation in Experiment 1"
Fig.10
Fig.11
OSPA comparison of the two algorithms"
Fig.11
Fig.12
Result of the original point cloud visualization"
Fig.12
Table 4
Motion state of each stage of the target"
| 目标 | 目标运动状态 | 时间/s |
| 1 | x1=[0, 0, 126, 7, 0, 0]T | t1∈[1, 30] |
| 2 | x2=[38, 2, 126, 10, 0, 0]T | t2∈[9, 15] |
| x2=[98, 2, 126, 7, 0, 0]T | t2∈[15, 18] | |
| x2=[119, 2, 126, 20, 0, 0]T | t2∈[18, 30] |
Table 4
Fig.13
Local magnification of MLS-PMBM when tracking the vehicle target"
Fig.13
Fig.14
Local magnification of the tracking result when tracking the targets crossed"
Fig.14
Fig.15
Target number estimation in Experiment 2"
Fig.15
Fig.16
OSPA of this algorithm when tracking the car model"
Fig.16
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