模型参数自适应的低复杂度ATPM-VSIMM算法

doi:10.11959/j.issn.1000-436x.2023186

Abstract

Abstract:

Aiming at the problem that for maneuvering target tracking, the accuracy of tracking degraded in interacting multiple model algorithms due to the fixed model sets and the fixed transition probability matrix, a low-complexity ATPM-VSIMM algorithm was proposed, which could update the model parameters adaptively.The maneuvering situation of the target was judged according to the innovation changes of the system, and the state noise of the model sets was adjusted to realize the adaptive update of the model sets.Then, the more accurate transition probability matrix was computed through the change of the model posterior probability and the inter-model switching relationship.Therefore, the matching degree between the system motion model and the target motion trajectory was improved.Finally, the high filtering accuracy and the fast response speed of the tracking system were guaranteed.The effectiveness of the proposed algorithm was verified through three aspects that are the initial value of the model posterior probability, the initial value of the transition probability matrix, and the state noise.Simulation results demonstrate that the filtering accuracy of the ATPM-VSIMM algorithm is improved about 8% compared with the existing algorithms.

Key words: maneuvering target tracking, adaptive state noise covariance matrix, adaptive transition probability matrix, variable structure interacting multiple model

CLC Number:

TN953

Hao ZENG, Wangqiang MU, Yang JIANG, Shunping YANG. Low-complexity ATPM-VSIMM algorithm with adaptive model parameters[J]. Journal on Communications, 2023, 44(9): 25-35.

Figures/Tables 16

References 21

[1]	LI X R , JILKOV V P . Survey of maneuvering target tracking.Part V.multiple-model methods[J]. IEEE Transactions on Aerospace and Electronic Systems, 2005,41(4): 1255-1321.
[2]	BLOM H A P , SHALOM Y B . The interacting multiple model algorithm for systems with Markovian switching coefficients[J]. IEEE Transactions on Automatic Control, 1988,33(8): 780-783.
[3]	LI X R , SHALOM Y B . Multiple-model estimation with variable structure[J]. IEEE Transactions on Automatic Control, 1996,41(4): 478-493.
[4]	JIN X B , ROBERT R J , SU T L ,et al. The new trend of state estimation:from model-driven to hybrid-driven methods[J]. Sensors, 2021,21(6): 2085-2106.
[5]	SADEGHZADEH N N , POSHTAN J . Distributed interacting multiple filters for fault diagnosis of navigation sensors in a robotic system[J]. IEEE Transactions on Systems,Man,and Cybernetics:Systems, 2017,47(7): 1383-1393.
[6]	LI X R , ZHI X R , ZHANG Y M . Multiple-model estimation with variable structure-Part III:model-group switching algorithm[J]. IEEE Transactions on Aerospace and Electronic Systems, 1999,35(1): 225-241.
[7]	LI X R , ZHANG Y M . Multiple-model estimation with variable structure.V.Likely-model set algorithm[J]. IEEE Transactions on Aerospace and Electronic Systems, 2000,36(2): 448-466.
[8]	KRISHNAMURTHY V , GAO S J . Syntactic enhancement to VSIMM for roadmap based anomalous trajectory detection:a natural language processing approach[J]. IEEE Transactions on Signal Processing, 2018,66(20): 5212-5227.
[9]	潘媚媚, 曹运合, 王宇 ,等. 基于机动判别的变结构交互多模型跟踪算法[J]. 系统工程与电子技术, 2019,41(4): 730-736.
	PAN M M , CAO Y H , WANG Y ,et al. Variable structure interactive multi-model tracking algorithm based on maneuvering discriminant[J]. Systems Engineering and Electronics, 2019,41(4): 730-736.
[10]	陈维义, 何凡, 刘国强 ,等. 变结构交互式多模型滤波和平滑算法[J]. 系统工程与电子技术, 2023,4(1): 1-10.
	CHEN W Y , HE F , LIU G Q ,et al. A variable structure interactive multiple model filtering and smoothing algorithm[J]. Systems Engineering and Electronics, 2023,4(1): 1-10.
[11]	ZHANG B L , GAO Y X , DUAN Z S . Variable structure multiple model fixed-interval smoothing[J]. Chinese Journal of Aeronautics, 2023,36(2): 139-148.
[12]	SUN L F , ZHANG J J , YU H F ,et al. Tracking of maneuvering extended target using modified variable structure multiple-model based on adaptive grid best model augmentation[J]. Remote Sensing, 2022,14(7): 1613-1625.
[13]	ZHU Z L , GUO B , WANG J F . A real-time interactive multi-model target tracking method[C]// Proceedings of 2021 IEEE International Conference on Artificial Intelligence and Computer Applications. Piscataway:IEEE Press, 2021: 503-507.
[14]	许登荣, 程水英, 包守亮 . 自适应转移概率交互式多模型跟踪算法[J]. 电子学报, 2017,45(9): 2113-2120.
	XU D R , CHENG S Y , BAO S L . Interacting multiple model algorithm based on adaptive transition probability[J]. Acta Electronica Sinica, 2017,45(9): 2113-2120.
[15]	尹聚祺, 杨震, 罗亚中 ,等. 空间机动目标跟踪的改进自适应 IMM算法[J]. 系统工程与电子技术, 2021,43(12): 3658-3666.
	YIN J Q , YANG Z , LUO Y Z ,et al. Improved adaptive IMM algorithm for space maneuvering target tracking[J]. Systems Engineering and Electronics, 2021,43(12): 3658-3666.
[16]	HAN B , HUANG H Q , LEI L ,et al. An improved IMM algorithm based on STSRCKF for maneuvering target tracking[J]. IEEE Access, 2019,7: 57795-57804.
[17]	MA J , GUO X T . Combination of IMM algorithm and ASTRWCKF for maneuvering target tracking[J]. IEEE Access, 2020,8: 143095-143103.
[18]	XIE G , SUN L L , WEN T ,et al. Adaptive transition probability matrix-based parallel IMM algorithm[J]. IEEE Transactions on Systems,Man,and Cybernetics:Systems, 2021,51(5): 2980-2989.
[19]	曾浩, 母王强, 杨顺平 . 高机动目标跟踪ATPM-IMM算法[J]. 通信学报, 2022,43(7): 93-101.
	ZENG H , MU W Q , YANG S P . High maneuvering target tracking ATPM-IMM algorithm[J]. Journal on Communications, 2022,43(7): 93-101.
[20]	李昊润, 卜凡康, 周剑雄 . 修正的马尔科夫转移矩阵自适应 IMM算法[J]. 火力与指挥控制, 2021,46(9): 118-124,132.
	LI H R , BU F K , ZHOU J X . Improved adaptive Markov matrix IMM algorithm[J]. Fire Control ＆ Command Control, 2021,46(9): 118-124,132.
[21]	姜仁华, 谢洋, 刘闯 ,等. 基于改进“当前”统计模型的机动目标IMM跟踪算法[J]. 现代雷达, 2019,41(2): 39-42.
	JIANG R H , XIE Y , LIU C ,et al. Maneuvering target IMM algorithm based on improved current statistical model[J]. Modern Radar, 2019,41(2): 39-42.

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算法	模型集结构或参数	TPM
IMM	固定结构	固定TPM
文献[11]算法	LMS	固定TPM
文献[19]算法	固定结构	自适应TPM
VSIMM	自适应参数Q	固定TPM
ATPM-IMM	固定结构	自适应TPM（式(14)）
ATPM-VSIMM	自适应参数Q	自适应TPM（式(14)）

算法	乘法次数/次	加法次数/次
IMM	14 241	11 829
文献[11]算法	22 756	18 854
文献[19]算法	26 839	22 506
VSIMM	14 253	11 837
ATPM-IMM	14 313	11 868
ATPM-VSIMM	14 325	11 876

算法	X方向/m	Y方向/m	Z方向/m	空间位置/m
测量值	29.96	29.89	29.98	51.88
IMM	23.38	23.23	22.91	40.16
文献[11]算法	23.09	22.94	22.53	39.60
文献[19]算法	23.31	21.20	21.20	39.16
VSIMM	21.66	21.52	21.13	37.15
ATPM-IMM	23.01	22.84	22.05	39.23
ATPM-VSIMM	21.14	20.97	20.02	35.94

算法	X方向/m	Y方向/m	Z方向/m	空间位置/m
测量值	29.96	30.01	30.00	51.96
IMM	20.25	20.16	19.84	34.80
文献[11]算法	19.93	19.86	19.42	34.20
文献[19]算法	20.58	17.25	17.25	33.95
VSIMM	19.05	18.96	18.43	32.60
ATPM-IMM	19.38	19.31	18.22	32.90
ATPM-VSIMM	18.44	18.33	17.04	31.16

算法	X方向/m	Y方向/m	Z方向/m	空间位置/m
测量值	29.93	29.91	29.92	51.84
IMM	29.44	29.43	29.38	50.97
文献[11]算法	29.36	29.35	29.33	50.85
文献[19]算法	29.67	29.63	29.62	51.37
VSIMM	26.95	26.94	26.81	46.61
ATPM-IMM	29.43	29.42	29.34	50.94
ATPM-VSIMM	26.79	26.78	26.40	46.21

Low-complexity ATPM-VSIMM algorithm with adaptive model parameters

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References 21

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