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Karsaz, A., Molaei Kaboodan, S. (2019). High Maneuvering Target Tracking Based on Augmented State Method using Adaptive Unscented Kalman Filter. Electronic and Cyber Defense, 7(2), 93-108.
A. Karsaz; S. V. Molaei Kaboodan. "High Maneuvering Target Tracking Based on Augmented State Method using Adaptive Unscented Kalman Filter". Electronic and Cyber Defense, 7, 2, 2019, 93-108.
Karsaz, A., Molaei Kaboodan, S. (2019). 'High Maneuvering Target Tracking Based on Augmented State Method using Adaptive Unscented Kalman Filter', Electronic and Cyber Defense, 7(2), pp. 93-108.
Karsaz, A., Molaei Kaboodan, S. High Maneuvering Target Tracking Based on Augmented State Method using Adaptive Unscented Kalman Filter. Electronic and Cyber Defense, 2019; 7(2): 93-108.

High Maneuvering Target Tracking Based on Augmented State Method using Adaptive Unscented Kalman Filter

پدافند الکترونیکی و سایبری
Article 9, Volume 7, Issue 2 - Serial Number 26, July 2019, Pages 93-108    PDF (1.68 M)
Document Type: Original Article
Authors
A. Karsaz* ; S. V. Molaei Kaboodan
khorasan university
Receive Date: 30 July 2018Accept Date: 13 October 2018 
Abstract
Many high maneuvering target tracking approaches, such as augmented state method, are based on target motion and radar modeling in the Cartesian coordinates., The projected radar observation errors along the Cartesian coordinates are continuously increasing in the target tracking problem in noisy       operation environments especially in the high maneuvering situations that the target is moving away from radar location. Whereas, in various simulations that are performed in many papers, these observation    errors are considered to have constant covariance values along the Cartesian coordinates. The real radar observation vector including target range and bearing is generally stated in Polar coordinates, and the nonlinearity of the radar observations in the Polar coordinates makes it necessary to implement the       nonlinear estimation approaches such as unscented Kalman filter (UKF) or extended Kalman filter (EKF). In this paper, high maneuvering target tracking is performed using the augmented state idea in the Polar coordinates based on UKF. The new proposed method also overcomes the late convergence of estimation and prevents filter divergence using the adaptive covariance matrix approach. The simulation results     obtained by the proposed method for both medium and high maneuvering scenarios show more than 90  percent improvement compared with the UKF and EKF algorithms.
 
Keywords
Unknown Input Estimation; High Maneuvering Target Tracking; Adaptive UKF; Augmented State Approac
Supplementary Files
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