基于目标机动模式识别的VSMM算法

doi:10.3969/j.issn.1001-506X.2020.05.05

Abstract

Abstract:

In order to solve the problems of the high maneuvering target tracking algorithm with fixed structure multiple models, which are difficult to meet the real-time requirements of the system, such as large computation amount and long computation time, a variable structure multiple model (VSMM) algorithm based on the target maneuvering pattern recognition is proposed. This algorithm can select the model set that matches the target motion state, and has the advantages of time-varying and self-adaptive. By using a small number of motion models to form a model group, and then combining different motion models to form different model groups, the proposed algrithm replaces the multiple models in the original fixed structure model with the model group, and selects whether to replace the model group according to the detected target motion pattern, so as to obtain a more accurate suboptimal solution with a small number of operations. The simulation results show that the algorithm can not only reduce the computational burden effectively, but also make the model set and the motion state of the target better matched, so as to improve the tracking accuracy of the target.

Key words: maneuvering target tracking, variable structure multiple model(VSMM), pattern recognition, adaptive

CLC Number:

Xing CHEN, Zhanwu LI, An XU, Xiaodong HU. VSMM algorithm based on target maneuver pattern recognition[J]. Systems Engineering and Electronics, 2020, 42(5): 999-1006.

Figures/Tables 11

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References 27

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当前模型	模型状态	参数变化	有效转换模型
M1	切向加速度恒定,法向加速度较小	切向加速度机动频率达到转换条件	M2
		切向加速度消失	M3
		法向加速度增大到阈值	M4
M2	切向加速度不可忽略且变化频率高	切向加速度恒定或法向加速度增大到阈值	M1
M3	匀速直线运动	切向或法向加速度增大到阈值	M1
M4	法向加速度和切向加速度同时存在且恒定的曲线运动	切向加速度为0	M6
		法向加速度为0	M1
		切向或法向加速度机动频率达到转换条件	M5
M5	1.法向加速度不可忽略且变化频率高,对切向加速度无要求。 2.法向加速度不可忽略且切向加速度不可忽略且变化频率高	切向和法向加速度恒定或法向加速度很小	M4
M6	匀速圆周运动运动	切向加速度达到阈值或者法向加速度很小	M4

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VSMM algorithm based on target maneuver pattern recognition

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