On the computational model of a kind of deconvolution problem

Author

Mou-Yan, Zou ; Unbehauen, Rolf

Author_Institution

Lehrstuhl fur Allgemeine und Theor. Elektrotech., Erlangen-Nurnberg Univ., Germany

Volume

4

Issue

10

fYear

1995

fDate

10/1/1995 12:00:00 AM

Firstpage

1464

Lastpage

1467

Abstract

It is known that discretization of a continuous deconvolution problem can alleviate the ill-posedness of the problem. The currently used circulant matrix model, however, does not play such a role. Moreover, the approximation of deconvolution problems by circulant matrix model is rational only if the size of the kernel function is very small. We propose an aperiodic model of deconvolution. For discrete and finite deconvolution problems the new model is an exact one. In the general case, the new model can lead to a nonsingular system of equations that has a lower condition number than the circulant one, and the related computations in the deconvolution can be done efficiently by means of the DFT technique, as in the ease for circulant matrices. The rationality of the new model holds without regard to the size of the kernel and the image. The use of the aperiodic model is illustrated by gradient-based algorithms

Keywords

deconvolution; discrete Fourier transforms; image restoration; matrix algebra; DFT; aperiodic model; approximation; circulant matrix model; computational model; condition number; continuous deconvolution problem; discrete deconvolution problems; exact model; finite deconvolution problems; gradient-based algorithms; image restoration; iterative algorithm; kernel function; nonsingular equations; Computational modeling; Convolution; Deconvolution; Equations; Frequency; Image restoration; Kernel; Legged locomotion; Physics computing; Signal restoration;

fLanguage

English

Journal_Title

Image Processing, IEEE Transactions on

Publisher

ieee

ISSN

1057-7149

Type

jour

DOI

10.1109/83.465114

Filename

465114