Title :
Robust estimation approach for blind denoising
Author_Institution :
Intelligent Transp. Syst. Centre, Univ. of Toronto, Ont., Canada
Abstract :
This work develops a new robust statistical framework for blind image denoising. Robust statistics addresses the problem of estimation when the idealized assumptions about a system are occasionally violated. The contaminating noise in an image is considered as a violation of the assumption of spatial coherence of the image intensities and is treated as an outlier random variable. A denoised image is estimated by fitting a spatially coherent stationary image model to the available noisy data using a robust estimator-based regression method within an optimal-size adaptive window. The robust formulation aims at eliminating the noise outliers while preserving the edge structures in the restored image. Several examples demonstrating the effectiveness of this robust denoising technique are reported and a comparison with other standard denoising filters is presented.
Keywords :
Gaussian noise; filtering theory; image denoising; image restoration; interference suppression; regression analysis; Gaussian noise filtering; blind image denoising; image restoration; noise elimination; random variable; regression method; standard denoising filter; Degradation; Gaussian noise; Image denoising; Image restoration; Noise reduction; Noise robustness; Optical noise; Spatial coherence; Statistics; Wiener filter; Blind denoising; Gaussian noise filtering; image restoration; outliers; redescending estimators; robust denoising; robust statistics; Algorithms; Artifacts; Artificial Intelligence; Computer Simulation; Image Enhancement; Image Interpretation, Computer-Assisted; Information Storage and Retrieval; Models, Statistical; Stochastic Processes;
Journal_Title :
Image Processing, IEEE Transactions on
DOI :
10.1109/TIP.2005.857276
