In this paper we propose a non-linear block shrinkage method in the wavelet domain for estimating an unknown function in the presence of Gaussian noise. This shrinkage utilizes an empirical Bayesian blocking approach that accounts for the sparseness of the representation of the unknown function. The modeling is accomplished by using a mixture of two normal-inverse gamma distributions as a joint prior on wavelet coefficients and noise variance in each block at a particular resolution level. This method results in an explicit and readily implementable weighted sum of shrinkage rules. An automatic, level-dependent choice for the model hyperparameters, that leads to amplitude-scale invariant solutions, is also suggested.
Wavelet Bayesian Block Shrinkage via mixture of Normal-Inverse-Gamma
De Canditiis D;
2004
Abstract
In this paper we propose a non-linear block shrinkage method in the wavelet domain for estimating an unknown function in the presence of Gaussian noise. This shrinkage utilizes an empirical Bayesian blocking approach that accounts for the sparseness of the representation of the unknown function. The modeling is accomplished by using a mixture of two normal-inverse gamma distributions as a joint prior on wavelet coefficients and noise variance in each block at a particular resolution level. This method results in an explicit and readily implementable weighted sum of shrinkage rules. An automatic, level-dependent choice for the model hyperparameters, that leads to amplitude-scale invariant solutions, is also suggested.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
