Automatic Estimation and Removal of Noise from a Single Image

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Automatic Estimation and Removal of Noise from a Single Image Accepted for publication by IEEE Transactions on Pattern Analysis and Machine Intelligence Automatic Estimation and Removal of Noise from a Single Image Ce Liu* Richard Szeliski† Sing Bing Kang† C. Lawrence Zitnick† William T. Freeman* *CSAIL, MIT †Microsoft Research

The criteria of image denoising Perceptually flat regions should be flat Image boundaries should be preserved (neither blurred or sharpened) Texture details should not be lost Global contrast should be preserved No artifacts should be generated

Denoising is hard… Different source and type of noise How strong is the noise? Locally, it is hard to distinguish Texture vs. noise Object boundary vs. structural noise Speed? Quality?

Related work Wavelets (coring, GSM) Anisotropic diffusion (PDEs) FRAME & FOE Bilateral filtering Nonlocal methods Conditional Random Fields

Segmentation-based piecewise smooth image models An image can be reconstructed by Over-segmentation (your favorite method) Affine reconstruction for each segment (RGB is an affine function of xy) Boundary blur estimation Piecewise smooth image reconstruction

Piecewise smooth reconstruction (a) Original image (b) Segmentation (c) Per-segment affine reconstruction (d) Affine reconstruction + boundary blur

Important properties of piecewise smooth image model Piecewise smooth image model is consistent with sparse image prior horizontal vertical Piecewise smooth reconstruction Filter responses

Important properties of piecewise smooth image model The color distribution per segment can be well approximated by a line segment Sorted eigenvalues in RGB space for each segment. The reddish picture indicates that the largest eigenvalue is significantly bigger than the second and third RGB values projected onto the eigenvector w.r.t. the largest eigenvalue. It is almost identical to the original image.

Important properties of piecewise smooth image model The standard deviation of residual per each segment is the upper bound of the noise level in that segment s I Brightness Residual std. dev. Assume brightness mean I is accurate estimate Standard deviation s is an over-estimate: (may contain signal) The lower envelope is the upper bound of noise level function (NLF)

Insert the CVPR slides on noise estimation

Segmentation-based noise reduction The noise level (std dev) for each segment, each RGB channel (from the inferred NLF) 0th-order model Assume the pixel is independent of the neighbors (of course this is not true) Bayesian MAP inference for each pixel (trivial)

The results of 0th order model

1st order Gaussian CRF Of course the neighboring pixels are dependent A Gaussian conditional random field (GCRF) is formed to incorporate Distance to noise Distance to signal Image-dependent regularization Inference by conjugate gradient method

Experimental results 17 images are randomly selected from Berkeley image segmentation database Compare to bilateral filtering, curvature preserving PDE and wavelet GSM.

We win the PSNR battle

Visual inspection 10% AWGN PDE Wavelet GSM Ours Original

Close-up view 10% AWGN PDE Wavelet GSM Ours Original

Visual inspection 10% AWGN PDE Wavelet GSM Ours Original

Close-up view 10% AWGN PDE Wavelet GSM Ours Original

Apply to real CCD noise Estimated NLF

Close-up view Since wavelet GSM only takes one constant noise level, it either over-smoothes (as s =15%) or under-smoothes (s =10%). We estimate signal-dependent noise level (NLF), and our approach handles both high and low noise level well. Estimated NLF

A very challenging example Real digital camera noise (low light, high ISO) Denoised by wavelet GSM Denoised by our model Estimated NLF

Conclusion Noise estimation and removal using one framework: piecewise smooth image model The chrominance component of the noise can be significantly reduced by simple projection Computer vision algorithms can be automated by estimating the peripheral parameters such as noise level, blur level, lighting, …