Abstract

Multi-channel systems appear in several fields of application in science. In the Synthetic Aperture Radar (SAR) context, multi-channel systems may refer to different domains, as multi-polarization, multi-interferometric or multi-temporal data, or even a combination of them. Due to the inherent speckle phenomenon present in SAR images, the statistical description of the data is almost mandatory for its utilization. The complex images acquired over natural media present in general zero-mean circular Gaussian characteristics. In this case, second order statistics as the multi-channel covariance matrix fully describe the data. For practical situations however, the covariance matrix has to be estimated using a limited number of samples, and this sample covariance matrix follow the complex Wishart distribution. In this context, the eigendecomposition of the multi-channel covariance matrix has been shown in different areas of high relevance regarding the physical properties of the imaged scene. Specifically, the maximum eigenvalue of the covariance matrix has been frequently used in different applications as target or change detection, estimation of the dominant scattering mechanism in polarimetric data, moving target indication, etc. In this paper, the statistical behavior of the maximum eigenvalue derived from the eigendecomposition of the sample multi-channel covariance matrix in terms of multi-channel SAR images is simplified for SAR community. Validation is performed against simulated data and examples of estimation and detection problems using the analytical expressions are as well given.

Highlights

  • Multi-channel systems with random nature appear in a wide range of fields in the literature

  • The results are based on a exact closed-form expressions of Probability Density Function (PDF), Cumulative Density Function (CDF) and Moment Generating Function (MGF)

  • In this study, existing density functions of the sample maximum eigenvalue were extended and/or implemented into multi-channel Synthetic Aperture Radar (SAR) system in order to obtain a simple expression of the sample eigenvalues giving a way to fruitful applications

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Summary

Introduction

Multi-channel systems with random nature appear in a wide range of fields in the literature. In the case of multi-channel SAR systems, the assumption of zero-mean multivariate complex Gaussian distribution is frequently valid for geophysical media, being fully described by the complex Hermitian covariance matrix This is the statistical case treated in this work. In this paper the results of [18] is supported by addressing analytical solutions It is derived an exact closed form expressions for the Moment Generating Function (MGF) of the sample covariance matrix maximum eigenvalue. The section reminds the basics of the statistical description of multi-channel SAR systems and of the covariance matrix eigendecomposition. It includes the derived theorems presenting the statistical founds.

Preliminaries
Sample Maximum Eigenvalue Statistical Description
Dependence of the Covariance Matrix Eigenvalues
Validation and Analysis of the Theoretical Expressions
Estimation Bias
Analysis of Detection Problems
Detection of a Dominant Maximum Eigenvalue
Target Detection Using Polarimetric Matched Filter
Conclusions and Discussion

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