Solving rician data analysis problems: theory and numerical modeling using computer algebra metods in Wolfram Mathematica

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This paper considers theoretical foundations and mathematical methods of data analysis under the conditions of the Rice statistical distribution. The problem involves joint estimation of the signal and noise parameters. It is shown that this estimation requires the solution of a complex system of essentially nonlinear equations with two unknown variables, which implies significant computational costs. This study is aimed at mathematical optimization of computer algebra methods for numerical solution of the problem of Rician data analysis. As a result of the optimization, the solution of the system of two nonlinear equations is reduced to the solution of one equation with one unknown variable, which significantly simplifies algorithms for the numerical solution of the problem, reduces the amount of necessary computational resources, and enables the use of advanced methods for parameter estimation in information systems with priority of real-time operation. Results of numerical experiments carried out using Wolfram Mathematica confirm the effectiveness of the developed methods for two-parameter analysis of Rician data. The data analysis methods considered in this paper are useful for solving many scientific and applied problems that involve analysis of data described by the Rice statistical model.

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作者简介

T. Yakovleva

Federal Research Center “Computer Science and Control”, Russian Academy of Sciences

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Email: tan-ya@bk.ru
ORCID iD: 0000-0003-2401-9825
俄罗斯联邦, ul. Vavilova 44/2, Moscow, 119333

参考

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  5. Yakovleva T.V. A Theory of Signal Processing at the Rice Distribution, Dorodnicyn Computing Centre, RAS, Moscow, 2015, 268 p.
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  7. Port S.C. Theoretical Probability for Applications. New York: Wiley, 1944.
  8. Venttsel’ E.S., Teoriya veroyatnostei (Probability Theory), Moscow: Akademiya, 2005, 10th ed.
  9. Park J.H. Moments of the generalized Rayleigh distribution // Quarterly of Applied Mathematics. 1961. V. 19. № 1. P. 45–49.
  10. Abramowitz, M., Stegun, I.A. Handbook of Mathematical Functions, United States Department of Commerce, National Bureau of Standards (NBS), 1964.

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2. Fig. 1. An illustration of the behavior of the probability density function characterizing the distribution of the Rice value x, formed from the initial deterministic value A under the influence of Gaussian noise.

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3. Fig. 2. Illustration of the nonlinear properties of the Rice distribution: (a) – the nonlinear dependence of the mathematical expectation of the Rice value x on the Rice parameter r; (b) – the nonlinear dependence of the square of the standard deviation of the Rice signal on the dispersion of the Gaussian noise a2, forming the Rice random variable.

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4. Fig. 3. Three-dimensional graphs of the likelihood function of the statistical Rice distribution, constructed in the Wolfram Mathematica system for various ratios of the values of the Rice parameters.

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5. Fig. 4. The results of calculating the Rice parameters of the signal v (a) and noise a (b) in the Wolfram Mathematica system using the presented combined method.

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