论文信息 - A model for non Rayleigh sea clutter amplitudes using compound Inverse Gaussian distribution

A model for non Rayleigh sea clutter amplitudes using compound Inverse Gaussian distribution

Statistical model for high resolution sea clutter, which we called the compound Inverse Gaussian distribution (CIG), is proposed. The model is a mixture of the Rayleigh distribution and the Inverse Gaussian distribution to model the speckle and the texture components respectively. The proposed distribution is extended to cover the additive thermal noise to achieve a good match to real data. The overall amplitude distribution is given in an integral form as a function of three parameters which are estimated from the recorded data based on the curve fitting method of the cumulative distributed function (CDF). The Nelder-Mead (N-M) optimizer is used to provide the best estimates of these parameters. Based on the mean square error (MSE) of model estimates criterion, we compare the goodness of fit of the proposed compound IG distribution with that of the conventional models such as Weibull, Log-normal, compound K and Rician Inverse Gaussian (RiIG) distributions. It is shown that the proposed model turns out the best statistical model in all cases.

[1] Alessia Dorigoni,et al. Inverse Gaussian Distribution , 2015 .

[2] W. R. Schucany,et al. Generating Random Variates Using Transformations with Multiple Roots , 1976 .

[3] Simon Watts. The performance of cell-averaging CFAR systems in sea clutter , 2000, Record of the IEEE 2000 International Radar Conference [Cat. No. 00CH37037].

[4] Richard D. Deveaux,et al. Applied Smoothing Techniques for Data Analysis , 1999, Technometrics.

[5] H. Vincent Poor,et al. Compound-Gaussian Clutter Modeling With an Inverse Gaussian Texture Distribution , 2012, IEEE Signal Processing Letters.

[6] Torbjørn Eltoft,et al. The Rician inverse Gaussian distribution: a new model for non-Rayleigh signal amplitude statistics , 2005, IEEE Transactions on Image Processing.

[7] Djamel Chikouche,et al. Two novel methods for estimating the compound K-clutter parameters in presence of thermal noise , 2011 .

[8] S. Watts,et al. Radar Detection Prediction in K-Distributed Sea Clutter and Thermal Noise , 1987, IEEE Transactions on Aerospace and Electronic Systems.

[9] A. Zoubir,et al. Performance of the adaptive generalised matched subspace constant false alarm rate detector in non-Gaussian noise: an experimental analysis , 2009 .

[10] W. Schwarz. The ex-Wald distribution as a descriptive model of response times , 2001, Behavior research methods, instruments, & computers : a journal of the Psychonomic Society, Inc.