Title :
Blind image deconvolution using a robust GCD approach
Author :
Pillai, S. Unnikrishna ; Liang, Ben
Author_Institution :
Dept. of Electr. Eng., Polytech. Univ., Brooklyn, NY, USA
fDate :
2/1/1999 12:00:00 AM
Abstract :
In this correspondence, a new viewpoint is proposed for estimating an image from its distorted versions in presence of noise without the a priori knowledge of the distortion functions. In z-domain, the desired image can be regarded as the greatest common polynomial divisor among the distorted versions. With the assumption that the distortion filters are finite impulse response (FIR) and relatively coprime, in the absence of noise, this becomes a problem of taking the greatest common divisor (GCD) of two or more two-dimensional (2-D) polynomials. Exact GCD is not desirable because even extremely small variations due to quantization error or additive noise can destroy the integrity of the polynomial system and lead to a trivial solution. Our approach to this blind deconvolution approximation problem introduces a new robust interpolative 2-D GCD method based on a one-dimensional (1-D) Sylvester-type GCD algorithm. Experimental results with both synthetically blurred images and real motion-blurred pictures show that it is computationally efficient and moderately noise robust
Keywords :
FIR filters; blind equalisers; deconvolution; image restoration; interpolation; noise; polynomials; 1D Sylvester-type GCD algorithm; 2D polynomials; FIR distortion filters; additive noise; blind image deconvolution; distorted versions; distortion functions; greatest common polynomial divisor; image estimation; interpolative 2D GCD method; noise; polynomial system; quantization error; real motion-blurred pictures; robust GCD approach; synthetically blurred images; trivial solution; z-domain; Decoding; Deconvolution; Distortion measurement; Image coding; Image processing; Noise robustness; PSNR; Polynomials; Predictive coding; Vector quantization;
Journal_Title :
Image Processing, IEEE Transactions on
