Title :
Spatial resolution properties of penalized-likelihood image reconstruction: space-invariant tomographs
Author :
Fessler, Jeffrey A. ; Rogers, W. Leslie
Author_Institution :
Michigan Univ., Ann Arbor, MI, USA
fDate :
9/1/1996 12:00:00 AM
Abstract :
This paper examines the spatial resolution properties of penalized-likelihood image reconstruction methods by analyzing the local impulse response. The analysis shows that standard regularization penalties induce space-variant local impulse response functions, even for space-invariant tomographic systems. Paradoxically, for emission image reconstruction, the local resolution is generally poorest in high-count regions. We show that the linearized local impulse response induced by quadratic roughness penalties depends on the object only through its projections. This analysis leads naturally to a modified regularization penalty that yields reconstructed images with nearly uniform resolution. The modified penalty also provides a very practical method for choosing the regularization parameter to obtain a specified resolution in images reconstructed by penalized-likelihood methods
Keywords :
emission tomography; image reconstruction; image resolution; maximum likelihood estimation; medical image processing; transient analysis; transient response; emission image reconstruction; impulse response functions; linearized local impulse response; local impulse response; local resolution; modified regularization penalty; penalized likelihood image reconstruction; penalized likelihood methods; projections; quadratic roughness penalties; regularization parameter; space invariant tomographic systems; space invariant tomographs; spatial resolution; standard regularization penalties; uniform resolution; Convergence; Image analysis; Image converters; Image reconstruction; Image resolution; Iterative algorithms; Iterative methods; Noise reduction; Spatial resolution; Tomography;
Journal_Title :
Image Processing, IEEE Transactions on
