Super-Resolution of Optical Coherence Tomography Images by Scale Mixture Models

(2020) Super-Resolution of Optical Coherence Tomography Images by Scale Mixture Models. Ieee Transactions on Image Processing. pp. 5662-5676. ISSN 1057-7149

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Abstract

In this paper, a new statistical model is proposed for the single image super-resolution of retinal Optical Coherence Tomography (OCT) images. OCT imaging relies on interfero-metry, which explains why OCT images suffer from a high level of noise. Moreover, data subsampling is carried out during the acquisition of OCT A-scans and B-scans. So, it is necessary to utilize effective super-resolution algorithms to reconstruct high-resolution clean OCT images. In this paper, a nonlocal sparse model-based Bayesian framework is proposed for OCT restoration. For this reason, by characterizing nonlocal patches with similar structures, known as a group, the sparse coefficients of each group of OCT images are modeled by the scale mixture models. In this base, the coefficient vector is decomposed into the point-wise product of a random vector and a positive scaling variable. Estimation of the sparse coefficients depends on the proposed distribution for the random vector and scaling variable where the Laplacian random vector and Generalized Extreme-Value (GEV) scale parameter (Laplacian+GEV model) show the best goodness of fit for each group of OCT images. Finally, a new OCT super-resolution method based on this new scale mixture model is introduced, where the maximum a posterior estimation of both sparse coefficients and scaling variables are calculated efficiently by applying an alternating minimization method. Our experimental results prove that the proposed OCT super-resolution method based on the Laplacian+GEV model outperforms other competing methods in terms of both subjective and objective visual qualities.

Item Type: Article
Keywords: Image reconstruction GSM Spatial resolution Signal resolution Mixture models Estimation Optical coherent tomography (OCT) super-resolution sparse representation Bayesian framework maximum a posterior Gaussian Laplacia scale mixture SPECKLE NOISE-REDUCTION SPARSE REPRESENTATION TRANSFORM RECONSTRUCTION OCT ACQUISITION RECOVERY FILTER
Subjects: WW Ophthalmology
Divisions: Medical Image and Signal Processing Research Center
School of Advanced Technologies in Medicine > Department of Bioelectrics and Biomedical Engineering
Page Range: pp. 5662-5676
Journal or Publication Title: Ieee Transactions on Image Processing
Journal Index: ISI
Volume: 29
Identification Number: https://doi.org/10.1109/TIP.2020.2984896
ISSN: 1057-7149
Depositing User: Zahra Otroj
URI: http://eprints.mui.ac.ir/id/eprint/12362

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