Title :
Finite-memory denoising in impulsive noise using Gaussian mixture models
Author :
Eldar, Yonina C. ; Yeredor, Arie
Author_Institution :
Dept. of Electr. Engineering-Systems, Tel Aviv Univ., Israel
fDate :
11/1/2001 12:00:00 AM
Abstract :
We propose an efficiently structured nonlinear finite-memory filter for denoising (filtering) a Gaussian signal contaminated by additive impulsive colored noise. The noise is modeled as a zero-mean Gaussian mixture (ZMGM) process. We first derive the optimal estimator for the static case, in which a Gaussian random variable (RV) is contaminated by an impulsive ZMGM RV. We provide an analytical derivation of the resulting mean-squared error (MSE), and compare the performance to that of the optimal linear estimator, identifying cases of significant improvement. Building upon these results, we develop a suboptimal finite-memory filter for the dynamic case, which is nearly optimal in the minimum MSE sense. The resulting filter is a nonlinearly weighted combination of a fixed number of linear filters, for which a computationally efficient architecture is proposed. Substantial improvement in performance over the optimal linear filter is demonstrated using simulation results
Keywords :
error analysis; estimation theory; filtering theory; impulse noise; mean square error methods; nonlinear filters; random noise; Gaussian mixture models; Gaussian random variable; Gaussian signal; additive impulsive colored noise; computationally efficient architecture; dynamic case; finite-memory denoising; mean-squared error; minimum MSE sense; nonlinear finite memory filter; nonlinearly weighted combination; optimal estimator; suboptimal filter; zero-mean Gaussian mixture process; Additive noise; Buildings; Colored noise; Computer architecture; Filtering; Gaussian noise; Noise reduction; Nonlinear filters; Performance analysis; Random variables;
Journal_Title :
Circuits and Systems II: Analog and Digital Signal Processing, IEEE Transactions on
