• DocumentCode
    1266916
  • Title

    Edge-preserving tomographic reconstruction with nonlocal regularization

  • Author

    Yu, Daniel F. ; Fessler, Jeffrey A.

  • Volume
    21
  • Issue
    2
  • fYear
    2002
  • Firstpage
    159
  • Lastpage
    173
  • Abstract
    Tomographic image reconstruction using statistical methods can provide more accurate system modeling, statistical models, and physical constraints than the conventional filtered backprojection (FBP) method. Because of the ill posedness of the reconstruction problem, a roughness penalty is often imposed on the solution to control noise. To avoid smoothing of edges, which are important image attributes, various edge-preserving regularization methods have been proposed. Most of these schemes rely on information from local neighborhoods to determine the presence of edges. In this paper, we propose a cost function that incorporates nonlocal boundary information into the regularization method. We use an alternating minimization algorithm with deterministic annealing to minimize the proposed cost function, jointly estimating region boundaries and object pixel values. We apply variational techniques implemented using level-sets methods to update the boundary estimates; then, using the most recent boundary estimate, we minimize a space-variant quadratic cost function to update the image estimate. For the positron emission tomography transmission reconstruction application, we compare the bias-variance tradeoff of this method with that of a "conventional" penalized-likelihood algorithm with local Huber roughness penalty.
  • Keywords
    image reconstruction; medical image processing; minimisation; modelling; positron emission tomography; statistics; PET; alternating minimization algorithm; bias-variance tradeoff; deterministic annealing; edge-preserving regularization methods; edges presence detection; level sets; local Huber roughness penalty; local neighborhoods; medical diagnostic imaging; nuclear medicine; region-based transmission tomography; space-variant quadratic cost function minimization; Annealing; Cost function; Helium; Image reconstruction; Level set; Minimization methods; Modeling; Positron emission tomography; Smoothing methods; Statistical analysis; Algorithms; Computer Simulation; Humans; Image Enhancement; Models, Theoretical; Phantoms, Imaging; ROC Curve; Reproducibility of Results; Sensitivity and Specificity; Thorax; Tomography; Tomography, Emission-Computed;
  • fLanguage
    English
  • Journal_Title
    Medical Imaging, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0278-0062
  • Type

    jour

  • DOI
    10.1109/42.993134
  • Filename
    993134