Abstract
We present an original application of fuzzy logic to restoration of phase images from interferometric synthetic aperture radar (InSAR), which are affected by zero-mean uncorrelated noise, whose variance depends on the underlying coherence, thereby yielding a nonstationary random noise process. Spatial filtering of the phase noise is recommended, either before phase unwrapping is accomplished, or simultaneously with it. In fact, phase unwrapping basically relies on a smoothness constraint of the phase field, which is severely hampered by the noise. Space-varying linear MMSE estimation is stated as a problem of matching pursuit, in which the estimator is obtained as an expansion in series of a finite number of prototype estimators, fitting the spatial features of the different statistical classes encountered, for example, fringes and steep slope areas. Such estimators are calculated in a fuzzy fashion through an automatic training procedure. The space-varying coefficients of the expansion are stated as degrees of fuzzy membership of a pixel to each of the estimators. Neither a priori knowledge on the noise variance is required nor particular signal and noise models are assumed. Filtering performances on simulated phase images show a steady SNR improvement over conventional box filtering. Applications of the proposed filter to interferometric phase images demonstrate a superior ability of restoring fringes yet preserving their discontinuities, together with an effective noise smoothing performance, irrespective of locally varying coherence characteristics.
Highlights
Synthetic aperture radar (SAR) enables imaging of the Earth by processing microwave backscattering data collected along the flight path of an airborne or spaceborne platform
We present an original application of fuzzy logic to restoration of phase images from interferometric synthetic aperture radar (InSAR), which are affected by zero-mean uncorrelated noise, whose variance depends on the underlying coherence, thereby yielding a nonstationary random noise process
Space-varying linear minimum MSE (MMSE) estimation is stated as a problem of matching pursuit, in which the estimator is obtained as an expansion in series of a finite number of prototype estimators, fitting the spatial features of the different statistical classes encountered, for example, fringes and steep slope areas
Summary
Synthetic aperture radar (SAR) enables imaging of the Earth by processing microwave backscattering data collected along the flight path of an airborne or spaceborne platform. What causes residues to occur on InSAR data is both noise, intended as local random errors in the phase estimation, which can be due, for example, to decorrelation or thermal sensor noise, as well as actual discontinuities in the underlying phase field [10]. These can be generated, for example, by strong topographic variations, or locally unfavorable geometric acquisition parameters (shadowing, layover, etc.). It has been demonstrated that modeling of the second-order statistics of the phase image by using complex-valued Markov random fields (CMRFs) may help the subsequent unwrapping step [14].
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