An adaptive waveform-detection threshold joint optimization method for target tracking 被引量：5

An adaptive waveform-detection threshold joint optimization method for target tracking

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摘要 The joint optimization of detection threshold and waveform parameters for target tracking which comes from the idea of cognitive radar is investigated for the modified probabilistic data association(MPDA)filter.The transmitted waveforms and detection threshold are adaptively selected to enhance the tracking performance.The modified Riccati equation is adopted to predict the error covariance which is used as the criterion function,while the optimization problem is solved through the genetic algorithm(GA).The detection probability,false alarm probability and measurement noise covariance are all considered together,which significantly improves the tracking performance of the joint detection and tracking system.Simulation results show that the proposed adaptive waveform-detection threshold joint optimization method outperforms the adaptive threshold method and the fixed parameters method,which will reduce the tracking error.The average reduction of range error between the adaptive joint method and the fixed parameters method is about 0.6 m,while that between the adaptive joint method and the adaptive threshold only method is about 0.3 m.Similar error reduction occurs for the velocity error and acceleration error. The joint optimization of detection threshold and waveform parameters for target tracking which comes from the idea of cognitive radar is investigated for the modified probabilistic data association （MPDA） filter. The transmitted waveforms and detection threshold are adaptively selected to enhance the tracking performance. The modified Riccati equation is adopted to predict the error covariance which is used as the criterion function, while the optimization problem is solved through the genetic algorithm （GA）. The detection probability, false alarm probability and measurement noise covariance are all considered together, which significantly improves the tracking performance of the joint detection and tracking system. Simulation results show that the proposed adaptive waveform-detection threshold joint optimization method outperforms the adaptive threshold method and the fixed parameters method, which will reduce the tracking error. The average reduction of range error between the adaptive joint method and the fixed parameters method is about 0.6 m, while that between the adaptive joint method and the adaptive threshold only method is about 0.3 m. Similar error reduction occurs for the velocity error and acceleration error.

作者王宏强夏洪恩程永强王璐璐

机构地区 School of Electronic Science and Engineering [

出处《Journal of Central South University》 SCIE EI CAS 2013年第11期3057-3064,共8页 中南大学学报（英文版）

基金 Project(61171133) supported by the National Natural Science Foundation of China Project(11JJ1010) supported by the Natural Science Fund for Distinguished Young Scholars of Hunan Province,China

关键词 cognitive radar adaptive waveform selection target tracking joint optimization detection-tracking system 自适应阈值检测阈值波形参数联合优化目标跟踪 Riccati方程误差协方差加速度误差

分类号 TN953 [电子电信—信号与信息处理] TP391.41 [自动化与计算机技术—计算机应用技术]

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