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Fast Algorithms for the Anisotropic LLT Model in Image Denoising

Published online by Cambridge University Press:  28 May 2015

Zhi-Feng Pang*
Affiliation:
College of Mathematics and Information Science, Henan University, Kaifeng, 475004, China Division of Mathematical Sciences, School of Physical and Mathematical Sciences, Nanyang Technological University, 637371, Singapore
Li-Lian Wang*
Affiliation:
Division of Mathematical Sciences, School of Physical and Mathematical Sciences, Nanyang Technological University, 637371, Singapore
Yu-Fei Yang*
Affiliation:
College of Mathematics and Econometrics, Hunan University, Changsha, 410082, China
*
Corresponding author. Email: [email protected]
Corresponding author. Email: [email protected]
Corresponding author. Email: [email protected]
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Abstract

In this paper, we propose a new projection method for solving a general minimization problems with two L1-regularization terms for image denoising. It is related to the split Bregman method, but it avoids solving PDEs in the iteration. We employ the fast iterative shrinkage-thresholding algorithm (FISTA) to speed up the proposed method to a convergence rate O(k−2). We also show the convergence of the algorithms. Finally, we apply the methods to the anisotropic Lysaker, Lundervold and Tai (LLT) model and demonstrate their efficiency.

Type
Research Article
Copyright
Copyright © Global-Science Press 2011

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References

[1]Ambrosio, L., Fusco, N., Pallara, D.. Functions of Bounded Variation and Free Discontinuity Problems. Oxford University Press, 2000.Google Scholar
[2]Aubert, G. and Kornprobst, P.. Mathematical Problems in Image Processing: Partial Diffrential Equations and the Calculus of Variations. Springer-Verlag, New York, 2002.CrossRefGoogle Scholar
[3]Aujol, J.. Some first-order algorithms for total variation based image restoration. Journal of Mathematical Imaging and Vision, 34(3)(2009), 307327.Google Scholar
[4]Beck, A. and Teboulle, M.. A fast iterative shrinkage-thresholding algorithm for linear inverse problems. SIAM Journal on Imaging Sciences, 2(1)(2009), 183202.Google Scholar
[5]Blomgern, P., Chan, T., Mulet, P., and Wong, C.. Total variation image restoration: Numerical methods and extensions. In: Proceedings, IEEE International Conference on Image Processing, III(1997), 384387.CrossRefGoogle Scholar
[6]Brune, C., Sawatzky, A., and Burger, M.. Primal and dual Bregman methods with application to optical nanoscopy. International Journal of Computer Vision, 92(2)(2011), 211229.Google Scholar
[7]Burger, M., Frick, K., Osher, S., and Scherzer, O.. Inverse total variation flow. Multiscale Modeling Simulation, 6(2)(2007), 366395.Google Scholar
[8]Cai, J. F., Osher, S., and Shen, Z.. Split Bregman methods and frame based image restoration. Multiscale Modeling Simulation, 8(2)(2009), 337369.CrossRefGoogle Scholar
[9]Chambolle, A.. Total variation minimization and a class of binary MRF models. In EMMCVPR 05, volume 3757 of Lecture Notes in Computer Sciences, (2005), 136152.Google Scholar
[10]Chambolle, A.. An algorithm for total variation minimization and applications. Journal of Mathematical Imaging and Vision, 20(1-2)(2004), 8997.Google Scholar
[11]Chambolle, A. and Lions, P. L.. Image recovery via total variation minimization and related problems. Numerische Maththematik, 76(1997), 167188.Google Scholar
[12]Chan, T., Golub, G., and Mulet, P.. A nonlinear primal-dual method for total variation-based image restoration. Journal on Scientific Computing, 20(1999), 19641977.Google Scholar
[13]Chan, T., Marquina, A., and Mulet, P.. High-order total variation-based image restoration. SIAM Journal on Scientific Computing, 22(2)(2000), 503516.Google Scholar
[14]Chan, T. and Shen, J.. Image Processing and Analysis-Variational, PDE, wavelet, and stochastic methods. SIAM Publisher, Philadelphia, 2005.Google Scholar
[15]Chen, H. Z., Song, J. P., and Tai, X. C.. A dual algorithm for minimization of the LLT model. Advances in Computational Mathematics, 31(13)(2009), 115130.Google Scholar
[16]Chen, K. and Tai, X. C.. A nonlinear multigrid method for total variation minimization from image restoration. Journal of Scientific Computing, 33(2)(2007), 115138.Google Scholar
[17]Combettes, P. L.. Solving monotone inclusions via compositions of nonexpansive averaged operators. Optimization, 53(5-6)(2204), 475504.Google Scholar
[18]Darbon, J. and Sigelle, M.. A fast and exact algorithm for total variation minimization. The second ICPRIA, 3522(2005), 351359.Google Scholar
[19]Douglas, J. and Rachford, H.. On the numerical solution of heat conduction problems in two and three space variables. Transactions of the American Mathematical Society, 82(2)(1956), 421439.Google Scholar
[20]Esser, E., Zhang, X., and Chan, T.. A general framework for a class of first order primal-dual algorithms for TV minimization. SIAM Journal on Imaging Sciences, 3(4)(2010), 10151046.CrossRefGoogle Scholar
[21]Goldstein, T., Bresson, X., and Osher, S.. Geometric applications of the split Bregman method: segmentation and surface reconstruction. Journal of Scientific Computing, 45(1-3)(2010), 272293.Google Scholar
[22]Goldstein, T. and Osher, S.. The split Bregman for L 1 regularized problems. SIAM Journal on Imaging Sciences, 2(2)(2009), 323343.Google Scholar
[23]He, L., Marquina, A., and Osher, S.. Blind deconvolution using TV regularization and Bregman iteration. International Journal of Imaging Systems and Technology, 15(1)(2005), 7483.Google Scholar
[24]Jia, R. Q. and Zhao, H.. A fast algorithm for the total variation model of image denoising. Advances in Computational Mathematics, 33(2)(2010), 231241.Google Scholar
[25]Jia, R. Q., Zhao, H., and Zhao, W.. Relaxation methods for image denoising based on difference schemes. Multiscale Modeling and Simulation, 9(1)(2011), 355372.CrossRefGoogle Scholar
[26]Li, Y. and Santosa, F.. A computational algorithm for minimizing total variation in image restoration. IEEE Transactions on Image Processing, 5(6)(1996), 987995.Google Scholar
[27]Lysaker, M., Lundervold, A., and Tai, X.-C.. Noise removal using fourth-order partial differential equation with applications to medical magnetic resonance images in space and time. IEEE Transactions on Image Processing, 12(12)(2003), 15791590.CrossRefGoogle ScholarPubMed
[28]Marquina, A.1 and Osher, S.. Image super-resolution by TV-regularization and Bregman iteration. Journal of Scientific Computing, 37(3)(2008), 367382.Google Scholar
[29]Micchelli, C., Shen, L.-X, and Xu, Y.-S. Proximity algorithms for image models: denoising. Inverse Problems, 27(4)(2011). (Doi: 10.1088/0266-5611.27/4/045009).CrossRefGoogle Scholar
[30]Ng, M. K., Qi, L., Yang, Y. F., and Huang, Y. M.. On semismooth Newton's methods for total variation minimization. Journal of Mathematical Imaging and Vision, 27(3)(2007), 265276.Google Scholar
[31]Osher, S., Burger, M., Goldfarb, D., Xu, J., and Yin, W.. An iterative regularization method for total variation-based image restoration. Multiscale Modeling and Simulation, 4(2)(2005), 460489.Google Scholar
[32]Pang, Z. F. and Yang, Y. F.. Semismooth Newton's methods for minimization of the LLT model. Inverse problems and Imaging, 3(4)(2009), 677691.Google Scholar
[33]Paragios, N., Chen, Y., and Faugeras, O.. Handbook of Mathematical Models in Computer Vision. Springer, Heidelberg, 2005.Google Scholar
[34]Plonka, G. and Ma, J.. Curvelet-wavelet regularized split Bregman iteration for compressed sensing. International Journal of Wavelets. Multiresolution and Information Processing, (2011), Preprint.Google Scholar
[35]Rudin, L., Osher, S., and Fatemi, E.. Nonlinear total variation based noise removal algorithms. Physica D, 60(1992), 259268.CrossRefGoogle Scholar
[36]Setzer, S.. Splitting methods in image processing. PhD Dissertation, (2009).Google Scholar
[37]Scherzer, O.. Denoising with higher order derivatives of bounded variation and an application to parameter estimation. Computing, 60(1998), 127.Google Scholar
[38]Steidl, G.. A note on the dual treatment of higher order regularization functionals. Computing, 76(1-2)(2006), 135148.Google Scholar
[39]Steidl, G. and Teuber, T.. Removing multiplicative noise by Douglas-Rachford splitting methods. Journal of Mathematical Imaging and Vision, 36(2)(2010), 168184.Google Scholar
[40]Tai, X. C. and Wu, C.. Augmented Lagrangian method, dual methods and split Bregman iteration for ROF model. The 2nd international conference, SSVM, LNCS 5567(2009), 502513.Google Scholar
[41]Vogel, C. R. and Oman, M.. Iterative methods for total variation denoising. SIAM Journal on Scientific Computing, 17(1)(1996), 227238.Google Scholar
[42]Wang, Y., Yang, J., Yin, W., and Zhang, Y.. A new alternating minimization algorithm for total variation image reconstruction. SIAM Journal on Imaging Sciences, 1(3)(2008), 248272.CrossRefGoogle Scholar
[43]Nocedal, J. and Wright, S.. Numerical Optimization. Springer, 1999.CrossRefGoogle Scholar
[44]Wu, C. and Tai, X.-C.. Augmented Lagrangian method, dual methods and split-Bregman iterations for ROF, vectorial TV and higher order models. SIAM Journal on Imaging Sciences, 3(3)(2010) 300339.CrossRefGoogle Scholar
[45]Yin, W., Osher, S., Goldfarb, D. and Darbon, J.. Bregman iterative algorithms for 1 minimization with applications to compressed sensing. SIAM Journal on Imaging Sciences, 1(1)(2008), 143168.CrossRefGoogle Scholar
[46]You, Y. L. and Kaveh, M.. Fourth-order partial differential equation for noise removal. IEEE Transactions on Image Processing, 9(10)(2000), 17231730.CrossRefGoogle ScholarPubMed