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Solving Constrained TV2L1-L2 MRI Signal Reconstruction via an Efficient Alternating Direction Method of Multipliers

Published online by Cambridge University Press:  12 September 2017

Tingting Wu*
Affiliation:
School of Mathematical Sciences, Jiangsu Key Laboratory for NSLSCS, Nanjing Normal University, Nanjing, 210023, China College of Science, Nanjing University of Posts and Telecommunications, Nanjing, 210023, China
David Z. W. Wang
Affiliation:
School of Civil and Environmental Engineering, Nanyang Technological University, Singapore, 639798, Singapore
Zhengmeng Jin
Affiliation:
College of Science, Nanjing University of Posts and Telecommunications, Nanjing, 210023, China
Jun Zhang
Affiliation:
College of Science, Nanchang Institute of Technology, Nanchang, 330099, Jiangxi, China
*
*Corresponding author. Email address:[email protected] (T. T. Wu)
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Abstract

High order total variation (TV2) and 1 based (TV2L1) model has its advantage over the TVL1 for its ability in avoiding the staircase; and a constrained model has the advantage over its unconstrained counterpart for simplicity in estimating the parameters. In this paper, we consider solving the TV2L1 based magnetic resonance imaging (MRI) signal reconstruction problem by an efficient alternating direction method of multipliers. By sufficiently utilizing the problem's special structure, we manage to make all subproblems either possess closed-form solutions or can be solved via Fast Fourier Transforms, which makes the cost per iteration very low. Experimental results for MRI reconstruction are presented to illustrate the effectiveness of the new model and algorithm. Comparisons with its recent unconstrained counterpart are also reported.

Type
Research Article
Copyright
Copyright © Global-Science Press 2017 

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References

[1] Afonso, M. V., Bioucasdias, J. M. and Figueiredo, M. A., Fast image recovery using variable splitting and constrained optimization, IEEE T. Image Process. A, 19(9) (2010), pp. 23452356.CrossRefGoogle ScholarPubMed
[2] Afonso, M. V., Bioucasdias, J. M. and Figueiredo, M. A., An augmented Lagrangian approach to the constrained optimization formulation of imaging inverse problems, IEEE T. Image Process., 20(3) (2011), pp. 681695.Google Scholar
[3] Cai, X., Han, D. and Yuan, X., On the convergence of the direct extension of ADMM for three-block separable convex minimization models with one strongly convex function, Comput. Optim. Appl., 66(1) (2017), pp. 3973.CrossRefGoogle Scholar
[4] Candès, E. J., Romberg, J. and Tao, T., Robust uncertainty principles: Exact signal reconstruction from highly incomplete frequency information, IEEE T. Inform. Theory, 52(2) (2006), pp. 489509.Google Scholar
[5] Chen, C., He, B., Ye, Y. and Yuan, X., The direct extension of ADMM for multi-block convex minimization problems is not necessarily convergent, Math. Program., 155(1-2) (2016), pp. 5779.Google Scholar
[6] Chen, C., Li, M., Liu, X. and Ye, Y., On the Convergence of Multi-Block Alternating Direction Method of Multipliers and Block Coordinate Descent Method, Mathemtics, 2016.Google Scholar
[7] Chen, C., Ng, M. K. and Zhao, X., Alternating direction method of multipliers for nonlinear image restoration problems, IEEE T. Image Process., 24(1) (2015), pp. 3343.Google Scholar
[8] Chen, H., Song, J. and Tai, X., A dual algorithm for minimization of the LLT model, Adv. Comput. Math., 31(1-3) (2009), pp. 115130.CrossRefGoogle Scholar
[9] Chen, Y., Hager, W., Huang, F., Phan, D., Ye, X. and Yin, W., Fast algorithms for image reconstruction with application to partially parallel MR imaging, SIAM Journal on Imaging Sciences, 5(1) (2012), pp. 90118.Google Scholar
[10] Chen, Y., Ye, X. and Huang, F., A novel method and fast algorithm for MR image reconstruction with significantly under-sampled data, Inverse Probl. Imag., 4(2) (2010), pp. 223240.CrossRefGoogle Scholar
[11] Compton, R., Osher, S. and Bouchard, L., Hybrid regularization for MRI reconstruction with static field inhomogeneity correction, IEEE International Symposium on Biomedical Imaging (ISBI), (2012), pp. 650655.Google Scholar
[12] Dai, Y., Han, D., Yuan, X. and Zhang, W., A sequential updating scheme of the Lagrange multiplier for separable convex programming, Math. Comput., 86(303) (2017), pp. 315343.Google Scholar
[13] Esser, E., Zhang, X. and Chan, T. F., A general framework for a class of first order primal-dual algorithms for convex optimization in imaging science, SIAM Journal on Imaging Sciences, 3(4) (2010), pp. 10151046.CrossRefGoogle Scholar
[14] Gabay, D. and Mercier, B., A dual algorithm for the solution of nonlinear variational problems via finite element approximation, Comput. Math. Appl., 2(1) (1976), pp. 1740.Google Scholar
[15] Glowinski, R., Numerical Methods for Nonlinear Variational Problems, Springer, 1984.CrossRefGoogle Scholar
[16] Glowinski, R. and Marroco, A., Sur l'approximation, par éléments finis d’ordre un, et la résolution, par pénalisation-dualité d’une classe de problèmes de Dirichlet non linéaires, Revue française d’automatique, informatique, recherche opérationnelle. Analyse numérique, 9(2) (1975), pp. 4176.Google Scholar
[17] Han, D., He, H., Yang, H. and Yuan, X., A customized Douglas–Rachford splitting algorithm for separable convex minimization with linear constraints, Numer Math, 127(1) (2014), pp. 167200.Google Scholar
[18] Han, D. and Yuan, X., Local linear convergence of the alternating direction method of multipliers for quadratic programs, SIAM J. Numer. Anal, 51(6) (2013), pp. 34463457.CrossRefGoogle Scholar
[19] Han, D., Yuan, X. and Zhang, W., An augmented Lagrangian based parallel splitting method for separable convex minimization with applications to image processing, Math. Comput., 83(289) (2014), pp. 22632291.CrossRefGoogle Scholar
[20] He, B., Liao, L., Han, D. and Yang, H., A new inexact alternating directions method for monotone variational inequalities, Math. Program., 92(1) (2002), pp. 103118.CrossRefGoogle Scholar
[21] He, B., Tao, M. and Yuan, X., Alternating direction method with Gaussian back substitution for separable convex programming, SIAM J. Optimiz, 22(2) (2012), pp. 313340.Google Scholar
[22] He, C., Hu, C., Li, X., Yang, X. and Zhang, W., A parallel alternating direction method with application to compound l1-regularized imaging inverse problems, Inform. Sciences, 348 (2016), pp. 179197.Google Scholar
[23] Lustig, M., Donoho, D. and Pauly, J. M., Sparse MRI: The application of compressed sensing for rapid MR imaging, Magn. Reson. Med., 58(6) (2007), pp. 11821195.Google Scholar
[24] Lysaker, M., Lundervold, A. and Tai, X., Noise removal using fourth-order partial differential equation with applications to medical magnetic resonance images in space and time, IEEE T. Image Process., 12(12) (2003), pp. 15791590.CrossRefGoogle ScholarPubMed
[25] Ng, M. K., Weiss, P. and Yuan, X., Solving constrained total-variation image restoration and reconstruction problems via alternating directionmethods, SIAM J. Sci. Comput., 32(5) (2010), pp. 27102736.Google Scholar
[26] Rudin, L. I., Osher, S. and Fatemi, E., Nonlinear total variation based noise removal algorithms, Physica D: Nonlinear Phenomena, 60(1) (1992), pp. 259268.Google Scholar
[27] Wu, C. and Tai, X., Augmented Lagrangian method, dual methods, and split Bregman iteration for ROF, vectorial TV, and high order models, SIAM Journal on Imaging Sciences, 3(3) (2010), pp. 300339.CrossRefGoogle Scholar
[28] Wu, T., Variable splitting based method for image restoration with impulse plus Gaussian noise, Math. Probl. Eng., (2016), 3151303.Google Scholar
[29] Xie, W., Yang, Y. and Zhou, B., An ADMM algorithm for second-order TV-based MR image reconstruction, Numer. Algorithms, 67(4) (2014), pp. 827843.Google Scholar
[30] Yang, J., Zhang, Y. and Yin, W., A fast alternating direction method for TVL1-L2 signal reconstruction from partial Fourier data, IEEE J. Sel. Top. Signa., 4(2) (2010), pp. 288297.Google Scholar
[31] Yang, W. and Han, D., Linear convergence of the alternating direction method of multipliers for a class of convex optimization problems, SIAM J. Numer. Anal., 54(2) (2016), pp. 625640.Google Scholar
[32] Ye, X., Chen, Y. and Huang, F., Computational acceleration for MR image reconstruction in partially parallel imaging, IEEE T. Med. Imaging, 30(5) (2011), pp. 10551063.Google Scholar
[33] Zhang, J., Chen, R., Deng, C. and Wang, S., Fast Linearized Augmented Lagrangian Method for Euler's Elastica Model, Numer. Math. Theor. Meth. Appl., 10(1) (2017), pp. 98115.Google Scholar
[34] Zhang, J., Wei, Z. and Xiao, L., Bi-component decomposition based hybrid regularization method for partly-textured CS-MR image reconstruction, Signal Process., 128 (2016), pp. 274290.CrossRefGoogle Scholar
[35] Zhi, Z., Sun, Y. and Pang, Z., Two-Stage Image Segmentation Scheme Based on Inexact Alternating Direction Method, Numer. Math. Theor. Meth. Appl., 9(3) (2016), pp. 451469.Google Scholar
[36] Zhu, Z., Cai, G. and Wen, Y., Adaptive Box-Constrained Total Variation Image Restoration Using Iterative Regularization Parameter Adjustment Method, Int. J. Pattern Recogn., 29(7) (2015), 1554003.Google Scholar