International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004
Figure (4) illustrates the results of some currently used speckle
reduction techniques on the same aerial image. As can be
observed, the proposed method has performed better in
reducing the speckle noise while preserving edge information.
Figure 4. (a) Original noisy image, (b-d) Results of the
proposed method, median filtering and Wiener filtering.
Figure (5) shows the results of applying three different speckle
noise reduction techniques including the proposed wavelet-
based method, Wiener filtering and median filtering on a noisy
SAR image.
Figure 5. (a) Original noisy SAR image, (b-d) Results of the
proposed wavelet-based method, Wiener filtering and median
filtering.
4. CONCLUDING REMARKS
A speckle noise reduction method in wavelet domain using a
trous algorithm was introduced. Major contributions of this
work were the optimal selection of the wavelet function and the
algorithm to be used for wavelet decomposition of the image.
The best model fitted to speckle pattern was found to be a
circularly symmetric Gaussian function. Therefore a two-
dimensional Gaussian function was proposed as the best
wavelet basis to be used. In order to achieve complete
30
reconstruction of the image using processed wavelet
coefficients, and to obtain shift invariancy property of the
wavelet transform, the a trous algorithm was selected as the
most appropriate for wavelet decomposition.
A Bayesian estimator was used for estimating the denoised
wavelet coefficients. This estimator uses a priori knowledge on
probability distribution of the signal and noise wavelet
coefficients. This estimator performs like a feature detector,
preserving the features that are clearly distinguishable in the
speckled data such as lines and edges.
The whole algorithm is computationally expensive. Particularly,
parameter estimation of the signal and noise distributions is the
most time consuming part of the algorithm. More efficient
parameter estimation algorithms may reduce the computational
cost of this part. Further improvements to this algorithm may be
achieved using knowledge-based information such as image
texture or PDF of radar cross section (RCS). Integrating these
different kinds of information may be performed using Neural
Networks.
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