Article

Fast image deconvolution using hyper-Laplacian priors

Authors:

Dilip Krishnan,

Rob FergusAuthors Info & Claims

NIPS'09: Proceedings of the 22nd International Conference on Neural Information Processing Systems

Pages 1033 - 1041

Published: 07 December 2009 Publication History

Abstract

The heavy-tailed distribution of gradients in natural scenes have proven effective priors for a range of problems such as denoising, deblurring and super-resolution. These distributions are well modeled by a hyper-Laplacian (p(x) ∝ e^{-k|x|^α}), typically with 0.5 ≤ α ≤ 0.8. However, the use of sparse distributions makes the problem non-convex and impractically slow to solve for multi-megapixel images. In this paper we describe a deconvolution approach that is several orders of magnitude faster than existing techniques that use hyper-Laplacian priors. We adopt an alternating minimization scheme where one of the two phases is a non-convex problem that is separable over pixels. This per-pixel sub-problem may be solved with a lookup table (LUT). Alternatively, for two specific values of α, 1/2 and 2/3 an analytic solution can be found, by finding the roots of a cubic and quartic polynomial, respectively. Our approach (using either LUTs or analytic formulae) is able to deconvolve a 1 megapixel image in less than ~3 seconds, achieving comparable quality to existing methods such as iteratively reweighted least squares (IRLS) that take ~20 minutes. Furthermore, our method is quite general and can easily be extended to related image processing problems, beyond the deconvolution application demonstrated.

References

[1]

R. Chartrand. Fast algorithms for nonconvex compressive sensing: Mri reconstruction from very few data. In IEEE International Symposium on Biomedical Imaging (ISBI), 2009.

[2]

R. Chartrand and V. Staneva. Restricted isometry properties and nonconvex compressive sensing. Inverse Problems, 24:1-14, 2008.

[3]

R. Fergus, B. Singh, A. Hertzmann, S. T. Roweis, and W. Freeman. Removing camera shake from a single photograph. ACM TOG (Proc. SIGGRAPH), 25:787-794, 2006.

[4]

D. Field. What is the goal of sensory coding? Neural Computation, 6:559-601, 1994.

[5]

D. Geman and G. Reynolds. Constrained restoration and recovery of discontinuities. PAMI, 14(3):367-383, 1992.

[6]

D. Geman and C. Yang. Nonlinear image recovery with half-quadratic regularization. PAMI, 4:932-946, 1995.

[7]

N. Joshi, L. Zitnick, R. Szeliski, and D. Kriegman. Image deblurring and denoising using color priors. In CVPR, 2009.

[8]

D. Krishnan and R. Fergus. Fast image deconvolution using hyper-laplacian priors, supplementary material. NYU Tech. Rep. 2009, 2009.

[9]

A. Levin. Blind motion deblurring using image statistics. In NIPS, 2006.

[10]

A. Levin, R. Fergus, F. Durand, and W. Freeman. Image and depth from a conventional camera with a coded aperture. ACM TOG (Proc. SIGGRAPH), 26(3):70, 2007.

[11]

A. Levin and Y. Weiss. User assisted separation of reflections from a single image using a sparsity prior. PAMI, 29(9):1647-1654, Sept 2007.

[12]

A. Levin, Y. Weiss, F. Durand, and W. T. Freeman. Understanding and evaluating blind deconvolution algorithms. In CVPR, 2009.

[13]

S. Osindero, M. Welling, and G. Hinton. Topographic product models applied to natural scene statistics. Neural Computation, 1995.

[14]

J. Portilla, V. Strela, M. J. Wainwright, and E. P. Simoncelli. Image denoising using a scale mixture of Gaussians in the wavelet domain. IEEE TIP, 12(11):1338-1351, November 2003.

[15]

W. Richardson. Bayesian-based iterative method of image restoration. 62:55-59, 1972.

[16]

S. Roth and M. J. Black. Fields of Experts: A Framework for Learning Image Priors. In CVPR, volume 2, pages 860-867, 2005.

[17]

L. Rudin, S. Osher, and E. Fatemi. Nonlinear total variation based noise removal algorithms. Physica D, 60:259-268, 1992.

[18]

E. Simoncelli and E. H. Adelson. Noise removal via bayesian wavelet coring. In ICIP, pages 379-382, 1996.

[19]

C.V. Stewart. Robust parameter estimation in computer vision. SIAM Reviews, 41(3):513-537, Sept. 1999.

[20]

M. F. Tappen, B. C. Russell, and W. T. Freeman. Exploiting the sparse derivative prior for super-resolution and image demosaicing. In SCTV, 2003.

[21]

M. Wainwright and S. Simoncelli. Scale mixtures of gaussians and teh statistics of natural images. In NIPS, pages 855-861, 1999.

[22]

Y. Wang, J. Yang, W. Yin, and Y. Zhang. A new alternating minimization algorithm for total variation image reconstruction. SIAM J. Imaging Sciences, 1(3):248-272, 2008.

[23]

E. W. Weisstein. Cubic formula. http://mathworld.wolfram.com/CubicFormula.html.

[24]

E. W. Weisstein. Quartic equation. http://mathworld.wolfram.com/QuarticEquation.html.

[25]

M. Welling, G. Hinton, and S. Osindero. Learning sparse topographic representations with products of student-t distributions. In NIPS, 2002.

[26]

S. Wright, R. Nowak, and M. Figueredo. Sparse reconstruction by separable approximation. IEEE Trans. Signal Processing, page To appear, 2009.

Cited By

Weiss ANadler B(2022)“Self-Wiener” Filtering: Data-Driven Deconvolution of Deterministic SignalsIEEE Transactions on Signal Processing10.1109/TSP.2021.313371070(468-481)Online publication date: 1-Jan-2022
https://dl.acm.org/doi/10.1109/TSP.2021.3133710
Wu YHong CTang CZeng Z(2020)Stack-Based Scale-Recurrent Network for Image DeblurringProceedings of the 2020 9th International Conference on Computing and Pattern Recognition10.1145/3436369.3437419(328-336)Online publication date: 30-Oct-2020
https://dl.acm.org/doi/10.1145/3436369.3437419
Guo BHan YWen JWallach HLarochelle HBeygelzimer Ad'Alché-Buc FFox E(2019)AGEMProceedings of the 33rd International Conference on Neural Information Processing Systems10.5555/3454287.3454337(547-558)Online publication date: 8-Dec-2019
https://dl.acm.org/doi/10.5555/3454287.3454337
Show More Cited By

Recommendations

Fast image deconvolution using closed-form thresholding formulas of Lq(q=12,23) regularization

In this paper, we focus on the research of fast deconvolution algorithm based on the non-convex L"q(q=12,23) sparse regularization. Recently, we have deduced the closed-form thresholding formula for L"1"2 regularization model (Xu (2010) [1]). In this ...
Total variation image restoration using hyper-Laplacian prior with overlapping group sparsity

Image restoration is a highly ill-posed problem and requires to be regularized. Many common image priors aim to make full use of natural image prior information. Total variation (TV) regularize prior has good performance of preserving edges but also has ...
High Quality Image Deblurring Scheme Using the Pyramid Hyper-Laplacian L2 Norm Priors Algorithm
Advances in Multimedia Information Processing – PCM 2013
Abstract
In this paper, a very effective image deblurring algorithm is proposed. It combines the techniques of the pyramid structure, the Hyper-Laplacian model, the hybrid norm priors for gradients, and the half-quadratic penalty method. In image ...

Comments

Please enable JavaScript to view thecomments powered by Disqus.

Information & Contributors

Information

Published In

cover image Guide Proceedings

NIPS'09: Proceedings of the 22nd International Conference on Neural Information Processing Systems

December 2009

2348 pages

ISBN:9781615679119

Publisher

Curran Associates Inc.

Red Hook, NY, United States

Publication History

Published: 07 December 2009

Qualifiers

Article

Contributors

Other Metrics

View Article Metrics

Bibliometrics & Citations

Bibliometrics

Article Metrics

45
Total Citations
View Citations
0
Total Downloads

Downloads (Last 12 months)0
Downloads (Last 6 weeks)0

Reflects downloads up to 03 Nov 2024

Other Metrics

View Author Metrics

Citations

Cited By

Weiss ANadler B(2022)“Self-Wiener” Filtering: Data-Driven Deconvolution of Deterministic SignalsIEEE Transactions on Signal Processing10.1109/TSP.2021.313371070(468-481)Online publication date: 1-Jan-2022
https://dl.acm.org/doi/10.1109/TSP.2021.3133710
Wu YHong CTang CZeng Z(2020)Stack-Based Scale-Recurrent Network for Image DeblurringProceedings of the 2020 9th International Conference on Computing and Pattern Recognition10.1145/3436369.3437419(328-336)Online publication date: 30-Oct-2020
https://dl.acm.org/doi/10.1145/3436369.3437419
Guo BHan YWen JWallach HLarochelle HBeygelzimer Ad'Alché-Buc FFox E(2019)AGEMProceedings of the 33rd International Conference on Neural Information Processing Systems10.5555/3454287.3454337(547-558)Online publication date: 8-Dec-2019
https://dl.acm.org/doi/10.5555/3454287.3454337
Leonidas LJie YAbdelbasit G(2019)Image De-Blurring Technique Combining Wiener Filtering and CSF De-Noising TechniqueProceedings of the 2019 International Conference on Artificial Intelligence and Computer Science10.1145/3349341.3349390(132-135)Online publication date: 12-Jul-2019
https://dl.acm.org/doi/10.1145/3349341.3349390
Li J(2019)A Blur-SURE-Based Approach to Kernel Estimation for Motion DeblurringPattern Recognition and Image Analysis10.1134/S105466181901016429:2(240-251)Online publication date: 1-Apr-2019
https://dl.acm.org/doi/10.1134/S1054661819010164
Li LPan JLai WGao CSang NYang M(2019)Blind Image Deblurring via Deep Discriminative PriorsInternational Journal of Computer Vision10.1007/s11263-018-01146-0127:8(1025-1043)Online publication date: 1-Aug-2019
https://dl.acm.org/doi/10.1007/s11263-018-01146-0
Shao WWang FHuang L(2019)Adapting total generalized variation for blind image restorationMultidimensional Systems and Signal Processing10.1007/s11045-018-0586-030:2(857-883)Online publication date: 1-Apr-2019
https://dl.acm.org/doi/10.1007/s11045-018-0586-0
Mei JWu ZChen XQiao YDing HJiang X(2019)DeepDeblurMultimedia Tools and Applications10.1007/s11042-019-7251-y78:13(18869-18885)Online publication date: 1-Jul-2019
https://dl.acm.org/doi/10.1007/s11042-019-7251-y
Pu HFan MYang JLian J(2019)Quick response barcode deblurring via doubly convolutional neural networkMultimedia Tools and Applications10.1007/s11042-018-5802-278:1(897-912)Online publication date: 1-Jan-2019
https://dl.acm.org/doi/10.1007/s11042-018-5802-2
Shao WGe QWang LLin YDeng HLi H(2019)Nonparametric Blind Super-Resolution Using Adaptive Heavy-Tailed PriorsJournal of Mathematical Imaging and Vision10.1007/s10851-019-00876-161:6(885-917)Online publication date: 1-Jul-2019
https://dl.acm.org/doi/10.1007/s10851-019-00876-1
Show More Cited By

View Options

View options

Media

Figures

Other

Tables

View Table of Contents