Abstract
When tracking very long-range targets, wide-band radars capable of measuring targets with high precision at ranges have severe measurement nonlinearities. The existing nonlinear filtering technology, such as the extended Kalman filter and untracked Kalman filter, will have significant consistency problems and loss in tracking accuracy. A novel mid-state Kalman filter is proposed to avoid loss and preserve the filtering consistency. The observed state and its first-order state derivative are selected as the mid-state vector. The update process is transformed into the measurement space to ensure the Gaussian measurement distribution and the linearization of the measurement equation. In order to verify the filter performance in comparison, an iterative formulation of Cramér-Rao Low Bound for the nonlinear system is further derived and given in this paper. Simulation results show that the proposed method has excellent performance of high filtering accuracy and fast convergence by comparing the filter state estimation accuracy and consistency.
Highlights
Target tracking is a process that uses sensors to estimate the characteristics of a moving object of interest
Due to the complexity and uncertainty of very long-range target tracking, the Gaussian noise distribution in the measurement space will become a severe non-Gaussian distribution when it is converted into the state space in the update process
The unscented Kalman filter (UKF) is different from the extended Kalman filter (EKF) in that it directly calculates the mean and covariance of the target distribution, avoiding the approximation of nonlinear functions
Summary
Target tracking is a process that uses sensors to estimate the characteristics of a moving object of interest. The GHF is a polynomial integral approximation filtering algorithm for nonlinear system models [8] which uses Gauss-Hermite polynomials to approximate the probability density in Gaussian filtering. Due to the complexity and uncertainty of very long-range target tracking, the Gaussian noise distribution in the measurement space will become a severe non-Gaussian distribution when it is converted into the state space in the update process. This phenomenon is often encountered in wide-band radar systems with high-range accuracy [15]. The MSKF was applied to very long-range tracking problems and the simulation results prove the superiority and applicability of the algorithm
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