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 patch-based exponentially weighted aggregation


PEWA: Patch-based Exponentially Weighted Aggregation for image denoising

Neural Information Processing Systems

Patch-based methods have been widely used for noise reduction in recent years. In this paper, we propose a general statistical aggregation method which combines image patches denoised with several commonly-used algorithms. We show that weakly denoised versions of the input image obtained with standard methods, can serve to compute an efficient patch-based aggregated estimd aggregation (EWA) estimator. The resulting approach (PEWA) is based on a MCMC sampling and has a nice statistical foundation while producing denoising results that are comparable to the current state-of-the-art. We demonstrate the performance of the denoising algorithm on real images and we compare the results to several competitive methods.


PEWA: Patch-based Exponentially Weighted Aggregation for image denoising

Neural Information Processing Systems

Patch-based methods have been widely used for noise reduction in recent years. In this paper, we propose a general statistical aggregation method which combines image patches denoised with several commonly-used algorithms. We show that weakly denoised versions of the input image obtained with standard methods, can serve to compute an efficient patch-based aggregated estimator. In our approach, we evaluate the Stein's Unbiased Risk Estimator (SURE) of each denoised candidate image patch and use this information to compute the exponential weighted aggregation (EWA) estimator. The aggregation method is flexible enough to combine any standard denoising algorithm and has an interpretation with Gibbs distribution. The denoising algorithm (PEWA) is based on a MCMC sampling and is able to produce results that are comparable to the current state-of-the-art.


PEWA: Patch-based Exponentially Weighted Aggregation for image denoising

Neural Information Processing Systems

Patch-based methods have been widely used for noise reduction in recent years. In this paper, we propose a general statistical aggregation method which combines image patches denoised with several commonly-used algorithms. We show that weakly denoised versions of the input image obtained with standard methods, can serve to compute an efficient patch-based aggregated estimator. In our approach, we evaluate the Stein's Unbiased Risk Estimator (SURE) of each denoised candidate image patch and use this information to compute the exponential weighted aggregation (EWA) estimator. The aggregation method is flexible enough to combine any standard denoising algorithm and has an interpretation with Gibbs distribution. The denoising algorithm (PEWA) is based on a MCMC sampling and is able to produce results that are comparable to the current state-of-the-art.


PEWA: Patch-based Exponentially Weighted Aggregation for image denoising

Neural Information Processing Systems

Patch-based methods have been widely used for noise reduction in recent years. In this paper, we propose a general statistical aggregation method which combines image patches denoised with several commonly-used algorithms. We show that weakly denoised versions of the input image obtained with standard methods, can serve to compute an efficient patch-based aggregated estimd aggregation (EWA) estimator. The resulting approach (PEWA) is based on a MCMC sampling and has a nice statistical foundation while producing denoising results that are comparable to the current state-of-the-art. We demonstrate the performance of the denoising algorithm on real images and we compare the results to several competitive methods.


PEWA: Patch-based Exponentially Weighted Aggregation for image denoising

Neural Information Processing Systems

Patch-based methods have been widely used for noise reduction in recent years. In this paper, we propose a general statistical aggregation method which combines image patches denoised with several commonly-used algorithms. We show that weakly denoised versions of the input image obtained with standard methods, can serve to compute an efficient patch-based aggregated estimator. In our approach, we evaluate the Stein's Unbiased Risk Estimator (SURE) of each denoised candidate imagepatch and use this information to compute the exponential weighted aggregation (EWA) estimator. The aggregation method is flexible enough to combine anystandard denoising algorithm and has an interpretation with Gibbs distribution. Thedenoising algorithm (PEWA) is based on a MCMC sampling and is able to produce results that are comparable to the current state-of-the-art.