Performance evaluation of the particle swarm optimization algorithm to unambiguously estimate plasma parameters from incoherent scatter radar signals
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Martínez Ledesma, Miguel
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Performance evaluation of the particle swarm optimization algorithm to unambiguously estimate plasma parameters from incoherent scatter radar signals
Abstract
Simultaneously estimating plasma parameters of the ionosphere presents a problem for the incoherent scatter radar
(ISR) technique at altitudes between ~ 130 and ~ 300 km. Different mixtures of ion concentrations and temperatures
generate almost identical backscattered signals, hindering the discrimination between plasma parameters. This temperature–
ion composition ambiguity problem is commonly solved either by using models of ionospheric parameters
or by the addition of parameters determined from the plasma line of the radar. Some studies demonstrated that it is
also possible to unambiguously estimate ISR signals with very low signal fluctuation using the most frequently used
non-linear least squares (NLLS) fitting algorithm. In a previous study, the unambiguous estimation performance of
the particle swarm optimization (PSO) algorithm was evaluated, outperforming the standard NLLS algorithm fitting
signals with very small fluctuations. Nevertheless, this study considered a confined search range of plasma parameters
assuming a priori knowledge of the behavior of the ion composition and signals with very large SNR obtained at
the Arecibo Observatory, which are not commonly feasible at other ISR facilities worldwide. In the present study, we
conduct Monte Carlo simulations of PSO fittings to evaluate the performance of this algorithm at different signal fluctuation
levels. We also determine the effect of adding different combinations of parameters known from the plasma
line, different search ranges, and internal configurations of PSO parameters. Results suggest that similar performances
are obtained by PSO and NLLS algorithms, but PSO has much larger computational requirements. The PSO algorithm
obtains much lower convergences when no a priori information is provided. The a priori knowledge of Ne and Te/Ti
parameters shows better convergences and “correct” estimations. Also, results demonstrate that the addition of Ne and
Te parameters provides the most information to solve the ambiguity problem using both optimization algorithms.
Patrocinador
United States Department of Defense
Air Force Office of Scientific Research (AFOSR)
FA955019-1-0384
Comite Mixto ESO-Chile
ORP061/19
NLHPC
ECM-02
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Artículo de publicación ISI Artículo de publicación SCOPUS
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Earth, Planets and Space (2020) 72:172
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