Iterative image restoration using approximate inverse preconditioning

Author

Nagy, James G. ; Plemmons, Robert J. ; Torgersen, Todd C.

Author_Institution

Dept. of Math., Southern Methodist Univ., Dallas, TX, USA

Volume

5

Issue

7

fYear

1996

fDate

7/1/1996 12:00:00 AM

Firstpage

1151

Lastpage

1162

Abstract

Removing a linear shift-invariant blur from a signal or image can be accomplished by inverse or Wiener filtering, or by an iterative least-squares deblurring procedure. Because of the ill-posed characteristics of the deconvolution problem, in the presence of noise, filtering methods often yield poor results. On the other hand, iterative methods often suffer from slow convergence at high spatial frequencies. This paper concerns solving deconvolution problems for atmospherically blurred images by the preconditioned conjugate gradient algorithm, where a new approximate inverse preconditioner is used to increase the rate of convergence. Theoretical results are established to show that fast convergence can be expected, and test results are reported for a ground-based astronomical imaging problem

Keywords

astronomical techniques; astronomy computing; atmospheric optics; conjugate gradient methods; convergence of numerical methods; deconvolution; image restoration; inverse problems; noise; approximate inverse preconditioning; atmospherically blurred images; deconvolution problem; ground-based astronomical imaging problem; ill-posed characteristics; iterative image restoration; linear shift-invariant blur; noise; preconditioned conjugate gradient algorithm; rate of convergence; Adaptive optics; Convergence; Deconvolution; Educational institutions; Filtering; Frequency; Image restoration; Iterative algorithms; Iterative methods; Testing; Wiener filter;

fLanguage

English

Journal_Title

Image Processing, IEEE Transactions on

Publisher

ieee

ISSN

1057-7149

Type

jour

DOI

10.1109/83.502394

Filename

502394