Priority-based Mojette reconstruction from sparse noisy projections.

Sparse-view Computed Tomography (CT) plays an important role in industrial inspection and medical diagnosis. However, the established reconstruction equations based on traditional Radon transform are ill-posed and obtain an approximate solution in the case of finite sampling angles. By contrast, Mojette transform is considered as the discrete geometry of the projection and reconstruction lattice. It determines the geometrical conditions for ensuring a unique solution instead of solving an ill-posed problem from the start. Therefore, Mojette transform results in theoretical exact image reconstruction in the discrete domain, and approximately gets the minimum number of projections, as well as their directions. However, the reconstruction method utilizing Mojette transform is very sensitive to noise. To address the problem, the paper proposes a sparse-view Mojette inversion algorithm based on the minimum noise accumulation by selecting the prioritized projections for an image reconstruction. Experimental results show that the proposed method can effectively suppress the noise accumulation without increasing the number of projections and produce better reconstruction results than traditional corner-based Mojette inversion (CBI).

[1]  G. Herman,et al.  Algebraic reconstruction techniques (ART) for three-dimensional electron microscopy and x-ray photography. , 1970, Journal of theoretical biology.

[2]  Imants D. Svalbe,et al.  Generalised finite radon transform for N×N images , 2007, Image Vis. Comput..

[3]  Imants D. Svalbe,et al.  Back-Projection Filtration Inversion of Discrete Projections , 2014, DGCI.

[4]  Dominique Barba,et al.  Psychovisual image coding via an exact discrete Radon transform , 1995, Other Conferences.

[5]  Shekhar Chandra,et al.  Exact image representation via a number-theoretic Radon transform , 2014, IET Comput. Vis..

[6]  Y. Bizais,et al.  Applying Mojette discrete radon transforms to classical tomographic data , 2008, SPIE Medical Imaging.

[7]  Richard Gordon,et al.  Questions of uniqueness and resolution in reconstruction from projection , 1978 .

[8]  Pascal Desbarats,et al.  Radon and Mojette Projections' Equivalence for Tomographic Reconstruction using Linear Systems , 2008 .

[9]  Jérôme Idier,et al.  Conjugate gradient Mojette reconstruction , 2005, SPIE Medical Imaging.

[10]  Vijay K. Madisetti,et al.  The fast discrete Radon transform. I. Theory , 1993, IEEE Trans. Image Process..

[11]  Eero P. Simoncelli,et al.  Image quality assessment: from error visibility to structural similarity , 2004, IEEE Transactions on Image Processing.

[12]  Nicolas Normand,et al.  A Geometry Driven Reconstruction Algorithm for the Mojette Transform , 2006, DGCI.

[13]  Dong Liang,et al.  Image reconstruction from few-view CT data by gradient-domain dictionary learning. , 2016, Journal of X-ray science and technology.

[14]  Pascal Desbarats,et al.  Mojette reconstruction from noisy projections , 2010, 2010 2nd International Conference on Image Processing Theory, Tools and Applications.

[15]  Dominique Barba,et al.  Controlled redundancy for image coding and high-speed transmission , 1996, Other Conferences.

[16]  Shekhar Chandra,et al.  Robust Digital Image Reconstruction via the Discrete Fourier Slice Theorem , 2014, IEEE Signal Processing Letters.

[17]  Tai-Chiu Hsung,et al.  Orthogonal discrete periodic Radon transform. Part II: applications , 2003, Signal Process..

[18]  Jean-Pierre Guédon The Mojette Transform: Theory and Applications , 2009 .

[19]  Imants D. Svalbe,et al.  Fourier Inversion of the Mojette Transform , 2014, DGCI.

[20]  Xiaochuan Pan,et al.  EMPIRICAL AVERAGE-CASE RELATION BETWEEN UNDERSAMPLING AND SPARSITY IN X-RAY CT. , 2012, Inverse problems and imaging.

[21]  Bin Yan,et al.  System matrix analysis for sparse-view iterative image reconstruction in X-ray CT. , 2015, Journal of X-ray science and technology.

[22]  Tai-Chiu Hsung,et al.  Orthogonal discrete periodic Radon transform. Part I: theory and realization , 2003, Signal Process..

[23]  L. Rudin,et al.  Nonlinear total variation based noise removal algorithms , 1992 .