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一种权重的高阶扩散图像盲复原方法 被引量:1

A Weighted High-order Diffusion Method for Image Blind Restoration
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摘要 为了实现对模糊噪声图像的清晰化盲复原,提出了一种权重的高阶扩散图像盲复原方法。首先,在模糊核的估计阶段,运用一种各向异性扩散的图像结构提取策略和shock滤波器将图像中的强边缘准确地提取出来,并利用提取的图像强边缘实现对模糊核的准确估计;然后,在图像的复原阶段,利用高阶扩散模型和权重平衡参数,针对复原图像,提出了一种权重的高阶正则化约束来实现图像的清晰化复原;最后,运用了一种分裂的布雷格曼(splitBregman,SB)最优化迭代策略对提出的方法进行最优化求解。实验结果表明,较近几年的一些具有代表性的图像盲复原方法相比,不仅主观的视觉效果得到了较为明显的改进,而且客观的峰值信噪比也增加了1.0~2.7dB。 In order to recover the blurred-noisy image blindly, a weighted high-order diffusion method for image blind restoration is proposed. First, "for the blur kernel estimation, strong edges were extracted from the estimated image by using the anisotropic diffusion and shock filter. Then, the extracted strong edges are used for blur kernel estimation. Second, for the image restoration, combining the high-order diffusion model and the weighted parame- ter, a weighted high-order regularization constraint is proposed for image restoration. Finally, a split Bregman (SB) optimization strategy is employed to restore the image and simultaneously exactly estimate the blur kernel. Experimental results indicate that the proposed method outperforms some representative image blind restoration methods, not only the subjective vision has the betterment obviously, but also the peak signal to noise ratio im- proves between 1.0 dB and 2. 7 dB.
作者 陈曦
机构地区 长江师范学院数学与计算机学院
出处 《科学技术与工程》 北大核心 2014年第17期78-82,共5页 Science Technology and Engineering
关键词 图像盲复原 高阶扩散 各向异性扩散 shock滤波器 分裂的布雷格曼 imag blind restoration high-order diffusion anisotropic diffusion shock filtersplit Bregman
分类号 TN911.73 [电子电信—通信与信息系统]
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参考文献12

  • 1Gonzalez R C, Woods R E. Digital Image Processing. 2nd ed. Bei- jing: Publishing House of Electronics Industry, 2003.
  • 2Fergus R, Singh B, Hertzmann A, et al. Removing camera shake from a single photograph . ACM Transactions on Graphics, 2006 ;25 ( 3 ) :787-794.
  • 3Shan Q, Jia J, Agarwala A. High-quality motion dehlurring from a single image. ACM Transactions on Graphics, 2008 ; 27 ( 3 ) :73 : 10.
  • 4Money J H, Kang S H. Total variation minimizing blind deconvolution with shock filter reference. ELSEVIER Image and Vision Computing, 2008 ; 26:302-314.
  • 5Cho S, Lee S. Fast motion dehlurring. ACM Transactions on Graph- ics, 2009; 28(5) :8.
  • 6Xu L, Jia J. Two-phase kernel estimation for robust motion deblur- ring. llth European Conference on Computer Vision 6133 (ECCV) ,2010:157-170.
  • 7Almeida M S C, Almeida L B. Blind and semi-blind deblurring of natural images. IEEE Transactions on Image Processing, 2010; 19 ( 1 ) :36-52.
  • 8Cai J F, Ji H, Liu C Q, et el. Framelet-based blind motion deblur- ring from a single image. IEEE Transactions on Image Processing, 2012 ;21 (2) :562-572.
  • 9Pang ZF, Yang Y F. A projected gradient algorithm based on the augmented Lagrangian strategy for image restoration and texture ex- traction. Elsevier Image and Vision Computing, 2011 ; 29 ( 2-3 ) : 117-126.
  • 10Prasath V B S, Singh A. A hybrid convex variational model for im- age restoration. Elsevier Applied Mathematics and Computation, 2010 ; 215 (10) :3655-3664.

同被引文献19

  • 1Rudin L,Osher S, Fatemi E. Nonlinear total variation based noi re- moval algorithms [ J ]. PhysJca D, 1992,60 ( 1 ) :259- 268.
  • 2Chan T F,Wong C K. Total variation blind deconvolution[ J]. IEEE Trans on Image Processing, 1998,7 ( 3 ) :370-375.
  • 3Money J H, Kang S H. Total variation minimizing blind deconvolution with shock filter reference [ J ]. Imago and Vision Computing, 2008,26(2) :302-314.
  • 4Almeidam S C, Almeidam B. Blind and semi-blind deblurring of natu- ral images[J]. IEEE Yrans on Image Processing,2010,19 ( I ) : 36-52.
  • 5You Y L, Kaveh M. Fourth-order partial differential equations for noise removal [ J ]. IEEE Trans on Image Processing, 2000,19 (10) : 1723-1730.
  • 6Lysaker M, Lundervold A, Tai X C. Noise removal using fourth-order partial differential equation with application to medical magnetic reso- nance images in space and time[J]. IEEE Trans on Image Pro- eessing,2003,12( 12 ) : 1579-1590.
  • 7Pang Zhifeng,Yang Yufei. A projected gradient algorithm based on the augmented Lagrangian strategy for image restoration and texture extrac- tion[J]. Image and Vision Computing,2011,29(2-3 ) : 117-126.
  • 8Goldstein T, Osher S. The split Bregman algorithm for L1 regularized problem [ J ]. SIAM Journal on Imaging Sciences, 2009,2 ( 2 ) : 323-343.
  • 9Li Weihong,Li Quanli,Gong Weiguo,et al. Total variation blind decan- volution employ split Bregnum iteration[ J ]. Joumal of Visual Com- munication and Image Representation,2012,23(3 ) :409-417.
  • 10Osher S, Rudin L. Feature-oriented image enhancement using shock tlters[ J]. SIAM doumal on Numerical Analysis, 1990,27 ( 4 ) : 919-940.

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科学技术与工程
2014年 第17期

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