Abstract
The Gaussian mixture model (GMM) plays an important role in image segmentation, but the difficulty of GMM for modeling asymmetric, heavy-tailed, or multimodal distributions of pixel intensities significantly limits its application. One effective way to improve the segmentation accuracy is to accurately model the statistical distributions of pixel intensities. In this study, an innovative high-resolution remote sensing image segmentation algorithm is proposed based on a flexible hierarchical GMM (HGMM). The components are first defined by the weighted sums of elements, in order to accurately model the complicated distributions of pixel intensities in object regions. The elements of components are defined by Gaussian distributions to model the distributions of pixel intensities in local regions of the object region. Following the Bayesian theorem, the segmentation model is then built by combining the HGMM and the prior distributions of parameters. Finally, a novel birth or death Markov chain Monte Carlo (BDMCMC) is designed to simulate the segmentation model, which can automatically determine the number of elements and flexibly model complex distributions of pixel intensities. Experiments were implemented on simulated and real high-resolution remote sensing images. The results show that the proposed algorithm is able to flexibly model the complicated distributions and accurately segment images.
Highlights
With the developments in remote sensing technology, the spatial resolution of remote sensing imagery has improved from meter level to centimeter level [1,2,3]
Since the components of hierarchical GMM (HGMM) are defined by the weighted sums of elements, the algorithm can flexibly model complicated distributions of pixel intensities in the object regions
The value ÿ was set by the histogram of the image, and it is greater than 2, which is enough to model the complicated distributions of pixel intensities in high-resolution remote sensing images
Summary
With the developments in remote sensing technology, the spatial resolution of remote sensing imagery has improved from meter level to centimeter level [1,2,3]. Its primary concerns consist of accurately building the statistical model of the image and estimating the optimal model parameters The former is the precondition while the latter is an essential requirement to obtain good results. In high-resolution remote sensing imagery, the statistical distribution of pixel intensities appears as randomly asymmetric, heavy tailed, or multimodal in an object region [12,13]. One effective way of obtaining highly accurate segmentation results is accurately modeling the distribution of pixel intensities. This process is not simple nor straightforward, and modeling complicated distributions has resulted in significant challenges in designing statistical model-based image segmentation algorithms
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