Directional multiscale statistical modeling of images

The contourlet transform is a new extension to the wavelet transform in two dimensions using nonseparable and directional filter banks. The contourlet expansion is composed of basis images oriented at varying directions in multiple scales, with flexible aspect ratios. With this rich set of basis images, the contourlet transform can eectively capture the smooth contours, which are the dominant features in natural images, with only a small number of coecients. We begin with a detail study of the statistics of the contourlet coecients of natural images, using histogram estimates of the marginal and joint distributions, and mutual information measurements to characterize the dependencies between coecients. The study reveals the non-Gaussian marginal statistics and strong intra-subband, cross-scale, and cross-orientation dependencies of contourlet coecients. It is also found that conditioned on the magnitudes of their generalized neighborhood coecients, contourlet coecients can approximately be modeled as Gaussian variables with variances directly related to the generalized neighborhood magnitudes. Based on these statistics, we model contourlet coecients using a hidden Markov tree (HMT) model that can capture all of their inter-scale, inter-orientation, and intra-subband dependencies. We experiment this model in the image denoising and texture retrieval applications where the results are very promising. In denoising, contourlet HMT outperforms wavelet HMT and other classical methods in terms of both peak signal-to-noise ratio (PSNR) and visual quality. In texture retrieval, it shows improvements in performance over wavelet methods for various oriented textures.