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Journal of Applied Remote Sensing

Parameter estimation of atmospheric refractivity from radar clutter using the particle swarm optimization via Lévy flight
Author(s): Zhi-Hua Zhang; Zheng Sheng; Han-Qing Shi
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Paper Abstract

Estimating refractivity profiles from radar sea clutter is a complex nonlinear optimization problem. To deal with the ill-posed difficulties, an inversion algorithm, particle swarm optimization with a Lévy flight (LPSO), was proposed to be applied in the refractivity from clutter (RFC) technique to retrieve atmospheric duct in this paper. PSO has many advantages in solving continuous optimization problems, while in its late period it has slow convergence speed and low precision. Therefore, we integrate the Lévy flights into the standard PSO algorithm to improve the precision and enhance the capability of jumping out of the local optima. To verify the feasibility and validation of the LPSO for estimating atmospheric duct parameters based on the RFC method, the synthetic and Wallops98 experimental data are implemented. Numerical experiments demonstrate that the optimal solutions obtained from the hybrid algorithm are more precise and efficient. Additionally, to test the algorithm inversion performance, the antinoise ability of LPSO is analyzed. The results indicate that the LPSO algorithm has a certain antinoise ability. Finally, according to the experiment results, it can be concluded that the LPSO algorithm can provide a more precise and efficient method for near-real-time inversion of atmospheric refractivity from radar clutter.

Paper Details

Date Published: 14 October 2015
PDF: 13 pages
J. Appl. Rem. Sens. 9(1) 095998 doi: 10.1117/1.JRS.9.095998
Published in: Journal of Applied Remote Sensing Volume 9, Issue 1
Show Author Affiliations
Zhi-Hua Zhang, The PLA Univ. of Science and Technology (China)
Zheng Sheng, The PLA Univ. of Science and Technology (China)
Han-Qing Shi, The PLA Univ. of Science and Technology (China)

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