Home > Archive>Volume 17, Issue 1, 2021 >40-46. DOI:https://doi.org/10.1007/s11801-021-0081-y
PDF HTML XML Export Cite reminder
An improved image blind deblurring based on dark channel prior
CSTR:
[cstr]
Author:
Affiliation:

College of Electronic Engineering, Heilongjiang University, Harbin 150000, China

  • Article
    • | |
  • Metrics
    • |
  • Reference [25]
    • |
  • Related [20]
    • | | |
  • Comments
    Abstract:

    In order to solve the ringing effect caused by the incorrect estimation of the blur kernel, an improved blind image deblurring algorithm based on the dark channel prior is proposed. First, in the blur kernel estimation stage, high-pass filtering is introduced to enhance the image quality and enhance the edge information to make the blur kernel estimation more accurate. A combination of super Laplacian prior and dark channel prior is introduced to estimate the potential clear image. Then the accurate blur kernel is estimated through alternate iterations from coarse to fine. In the image restoration stage, a weighted least square filter is introduced to suppress the ringing effect of the original clear image to further improve the quality of image restoration. Finally, image deconvolution based on Laplace priors and L0 regularized priors is used to restore clear images. Experimental results show that our approach improves the peak signal-to-noise ratio (PSNR) by about 0.4 dB and structural similarity (SSIM) by about 0.01, respectively. Compared with the existing image deblurring algorithms, this method can estimate the blur information more accurately, so that the restored image can achieve the effect of keeping the edges and removing ringing.

    Reference
    [1]Krishnan D, Tay T and Fergus R, Blind Deconvolution Using a Normalized Sparsity Measure, IEEE Conference on Computer Vision and Pattern Recognition, 233 (2011).
    [2]Xu L, Zheng S and Jia J, Unnatural. L0 Sparse Representation for Natural Image Deblurring, IEEE Conference on Computer Vision and Pattern Recognition, 1107 (2013).
    [3]Yan J W, Xie T T, Peng H and Liu P H, Laser & Optoelectronics Progress 54, 156(2017). (in Chinese)
    [4]Feng X C, Liu X, Yang C Y and Wang W W, Journal of Beijing University of Posts and Telecommunications 41, 8 (2018). (in Chinese)
    [5]Yu Y B, Peng N and Gan J Y,Acta Electronica Sinica 44, 1168 (2016). (in Chinese)
    [6]Michaeli T and Irani M, Blind Deblurring Using Internal Patch Recurrence, European Conference on Computer Vision, 783 (2014).
    [7]Pan J, Hu Z, Su Z and Yang M H, IEEE Transactions on Pattern Analysis and Machine Intelligence 39, 342 (2017).
    [8]Zuo W, Ren D, Zhang D, Gu S and Zhang L, IEEE Transactions on Image Processing 25, 1751(2016).
    [9]Pan J, Sun D, Pfister H and Yang M H, IEEE Transactions on Pattern Analysis and Machine Intelligence 40, 2315 (2018).
    [10]Zhang H, Wu Y, Zhang L, Zhang Z and Li Y, Neurocomputing 398, 265 (2020).
    [11]J. Sun, W. Cao, Z. Xu and J. Ponce, Learning a Convolutional Neural Network for Non-Uniform Motion Blur Removal, IEEE Conference on Computer Vision and Pattern Recognition, 769 (2015).
    [12]S. Nah, T. H. Kim and K. M. Lee, Deep Multi-scale Convolutional Neural Network for Dynamic Scene Deblurring, IEEE Conference on Computer Vision and Pattern Recognition, 257 (2017).
    [13]T. M. Nimisha, A. K. Singh and A. N. Rajagopalan, Blur-Invariant Deep Learning for Blind-Deblurring, IEEE International Conference on Computer Vision, 4762 (2017).
    [14]Kupyn O, Budzan V and Mykhailych M, DeblurGAN:Blind Motion Deblurring Using Conditional Adversarial Networks, IEEE Conference on Computer Vision and Pattern Recognition, 8183 (2018).
    [15]G. Gong and K. Zhang, Local Blurred Natural Image Restoration Based on Self-Reference Deblurring Generative Adversarial Networks, IEEE International Con-ference on Signal and Image Processing Applications, 231 (2019).
    [16]Zuo W and Lin Z, IEEE Transactions on Image Processing 20, 2748 (2011).
    [17]He K, Sun J and Tang X, Single Image Haze Removal Using Dark Channel Prior, IEEE Computer Vision and Pattern Recognition, 1956 (2009).
    [18]Zhang Z, Li Q, Xu Z and Feng H, Opt. Precision Eng. 27, 181 (2019). (in Chinese)
    [19]Qiu X and Dai M, Opt. Precision Eng. 25, 2490 (2017). (in Chinese)
    [20]Tang J, Shu X, Qi G J, Li Z, Wang M, Yan S and Jain R, IEEE Transactions on Pattern Analysis and Machine Intelligence 39, 1662 (2017).
    [21]Wang Y, Yang J, Yin W and Zhang Y, SIAM Journal on Imaging Sciences 1, 248 (2008).
    [22]Tai Y W, Tan P and Brown M S,IEEE Transactions on Pattern Analysis and Machine Intelligence 33, 1603 (2010).
    [23]Krishnan D and Fergus R, Fast Image Deconvolution Using Hyper-Laplacian Priors, International Conference on Neural Information Processing Systems, 1033 (2009).
    [24]Wang Z, Bovik A C, Sheikh H R and Simoncelli E P, IEEE Transactions on Image Processing 13, 600 (2004).
    [25]Shearer P, Gilbert A C and Iii A O H, Correcting Camera Shake by Incremental Sparse Approximation, IEEE International Conference on Image Processing, 572 (2013).
    Cited by
    Comments
    Comments
    分享到微博
    Submit
Get Citation

WANG Man-wei, ZHU Fu-zhen, BAI Yu-yang. An improved image blind deblurring based on dark channel prior[J]. Optoelectronics Letters,2021,17(1):40-46

Copy
Share
Article Metrics
  • Abstract:1041
  • PDF: 21
  • HTML: 0
  • Cited by: 0
History
  • Received:May 15,2020
  • Revised:August 24,2020
  • Online: January 04,2021
Article QR Code
Phone:86-22-60214471
URL:http://www.oelett.com E-mail:oel@263.net
Supported by:Beijing E-Tiller Technology Development Co., Ltd.
® 2025 All Rights Reserved