EI / SCOPUS / CSCD 收录

中文核心期刊

基于自适应无迹卡尔曼滤波的中近程运动目标水平定位精度优化

Optimization of horizontal positioning accuracy of medium and short range moving target based on adaptive unscented Kalman filter

  • 摘要: 针对矢量传感器测量数据对目标定位结果存在误差随距离增大而递增的问题, 提出了使用自适应无迹卡尔曼滤波对非径向运动目标在水平方向进行定位精度优化的方法。首先基于接收信号的矢量特性, 利用复声强法在频域得到目标的方位角估计; 然后利用直达波和一次海面反射波时延信息, 匹配目标的水平距离; 在此基础上, 构建水平距离和方位角为测量矩阵, 建立自适应无迹卡尔曼滤波对非径向运动目标水平方向的追踪定位。仿真结果表明, 在一定声源级条件下, 矢量传感器在近距离处对目标方位和水平距离的测量结果较为精准, 基于良好初值条件的自适应无迹卡尔曼滤波方法可以优化测量信息的追踪定位结果; 实验数据论证了在水平距离约15 km范围内, 目标在各采样点处的定位误差均大幅减小, 同一位置的水平定位误差最大可由28.65%降低至3.86%, 定位精度明显提升, 验证了本文算法的有效性。

     

    Abstract: In order to solve the problem that the error of the target positioning result from the vector sensor measurement data increases with the distance, an adaptive unscented Kalman filter is proposed to optimize the positioning accuracy of non-radial moving target in the horizontal direction. Firstly, based on the vector characteristics of the received signal, the azimuth estimation of the target is obtained in frequency domain by using the complex acoustic intensity method. Then, the horizontal distance of the target is matched by using the time delay information of the direct wave and the primary sea surface reflection wave. On this basis, the horizontal distance and azimuth are constructed as the measurement matrix, and the adaptive unscented Kalman filter is established to track and locate the non-radial moving target in the horizontal direction. Simulation results indicate that, under a certain sound source level condition, the vector sensor can provide relatively accurate measurements of target bearing and horizontal range at close distances, and the adaptive unscented Kalman filter method, under favorable initial conditions, can further improve the tracking and localization performance based on the measurements. The experimental data demonstrate that the positioning error of the target at each sampling point is greatly reduced within the horizontal distance of about 15 km, and the horizontal positioning error at the same position can be reduced from 28.65% to 3.86%, and the positioning accuracy is obviously improved, which verifies the effectiveness of the algorithm in this paper.

     

/

返回文章
返回