digital image processing
ARTICLE IN PRESS
Pattern Recognition 43 (2010) 1531–1549
Contents lists available at ScienceDirect
Pattern Recognition journal homepage: www.elsevier.de/locate/pr
Two-stage image denoising by principal component analysis with local pixel grouping
Lei Zhang a,Ã, Weisheng Dong a,b, David Zhang a, Guangming Shi b a b
Department of Computing, The Hong Kong Polytechnic University, Hong Kong, China
Key Laboratory of Intelligent Perception and Image Understanding (Chinese Ministry of Education), School of Electronic Engineering, Xidian University, China
a r t i c l e in fo
abstract
Article history:
Received 5 November 2008
Received in revised form
18 September 2009
Accepted 22 September 2009
This paper presents an efficient image denoising scheme by using principal component analysis (PCA) with local pixel grouping (LPG). For a better preservation of image local structures, a pixel and its nearest neighbors are modeled as a vector variable, whose training samples are selected from the local window by using block matching based LPG. Such an LPG procedure guarantees that only the sample blocks with similar contents are used in the local statistics calculation for PCA transform estimation, so that the image local features can be well preserved after coefficient shrinkage in the PCA domain to remove the noise. The LPG-PCA denoising procedure is iterated one more time to further improve the denoising performance, and the noise level is adaptively adjusted in the second stage. Experimental results on benchmark test images demonstrate that the LPG-PCA method achieves very competitive denoising performance, especially in image fine structure preservation, compared with state-of-the-art denoising algorithms.
& 2009 Elsevier Ltd. All rights reserved.
Keywords:
Denoising
Principal component analysis (PCA)
Edge preservation
1. Introduction
Noise will be inevitably introduced in the image acquisition process and denoising is an
Pattern Recognition 43 (2010) 1531–1549
Contents lists available at ScienceDirect
Pattern Recognition journal homepage: www.elsevier.de/locate/pr
Two-stage image denoising by principal component analysis with local pixel grouping
Lei Zhang a,Ã, Weisheng Dong a,b, David Zhang a, Guangming Shi b a b
Department of Computing, The Hong Kong Polytechnic University, Hong Kong, China
Key Laboratory of Intelligent Perception and Image Understanding (Chinese Ministry of Education), School of Electronic Engineering, Xidian University, China
a r t i c l e in fo
abstract
Article history:
Received 5 November 2008
Received in revised form
18 September 2009
Accepted 22 September 2009
This paper presents an efficient image denoising scheme by using principal component analysis (PCA) with local pixel grouping (LPG). For a better preservation of image local structures, a pixel and its nearest neighbors are modeled as a vector variable, whose training samples are selected from the local window by using block matching based LPG. Such an LPG procedure guarantees that only the sample blocks with similar contents are used in the local statistics calculation for PCA transform estimation, so that the image local features can be well preserved after coefficient shrinkage in the PCA domain to remove the noise. The LPG-PCA denoising procedure is iterated one more time to further improve the denoising performance, and the noise level is adaptively adjusted in the second stage. Experimental results on benchmark test images demonstrate that the LPG-PCA method achieves very competitive denoising performance, especially in image fine structure preservation, compared with state-of-the-art denoising algorithms.
& 2009 Elsevier Ltd. All rights reserved.
Keywords:
Denoising
Principal component analysis (PCA)
Edge preservation
1. Introduction
Noise will be inevitably introduced in the image acquisition process and denoising is an
References: [1] D.L. Donoho, De-noising by soft thresholding, IEEE Transactions on Information Theory 41 (1995) 613–627. denoising based on statistical modeling of wavelet coefficients, IEEE Signal Processing Letters 6 (12) (1999) 300–303. 9 (9) (2000) 1522–1531. [5] A. Pizurica, W. Philips, I. Lamachieu, M. Acheroy, A joint inter- and intrascale statistical model for Bayesian wavelet based image denoising, IEEE Transaction on Image Processing 11 (5) (2002) 545–557. [6] L. Zhang, B. Paul, X. Wu, Hybrid inter- and intra wavelet scale image restoration, Pattern Recognition 36 (8) (2003) 1737–1746. [7] Z. Hou, Adaptive singular value decomposition in wavelet domain for image denoising, Pattern Recognition 36 (8) (2003) 1747–1763. Processing 12 (11) (2003) 1338–1351. Technology 15 (4) (2005) 469–481. Transaction on Image Processing 15 (3) (2006) 654–665. [11] J.L. Starck, E.J. Candes, D.L. Donoho, The curvelet transform for image denoising, IEEE Transaction on Image Processing 11 (6) (2002) 670–684. Recognition 40 (2) (2007) 578–585. [13] M. Elad, M. Aharon, Image denoising via sparse and redundant representations over learned dictionaries, IEEE Transaction on Image Processing 15 (12) (2006) 3736–3745. Signal Processing 54 (11) (2006) 4311–4322. [15] A. Foi, V. Katkovnik, K. Egiazarian, Pointwise shape-adaptive DCT for highquality denoising and deblocking of grayscale and color images, IEEE Transaction on Image Processing 16 (5) (2007). Bombay, India, 1998, pp. 839–846. Transaction on Pattern Analysis and Machine Intelligence 24 (6) (2002) 844–847. [18] A. Buades, B. Coll, J.M. Morel, A review of image denoising algorithms, with a new one, Multiscale Modeling Simulation 4 (2) (2005) 490–530. [19] C. Kervrann, J. Boulanger, Optimal spatial adaptation for patch based image denoising, IEEE Transaction on Image Processing 15 (10) (2006) [20] K. Dabov, A. Foi, V. Katkovnik, K. Egiazarian, Image denoising by sparse 3D transform-domain collaborative filtering, IEEE Transaction on Image Processing 16 (8) (2007) 2080–2095. Processing, 14–17 September, vol. 1, 2003, pp. I101–I104. Processing 13 (4) (2004). [23] L.P. Yaroslavsky, Digital Signal Processing—An Introduction, Springer, Berlin, 1985. [24] S. Mallat, A Wavelet Tour of Signal Processing, Academic Press, New York, 1998. [25] R.C. Gonzalez, R.E. Woods, Digital Image Processing, second ed., PrenticeHall, Englewood Cliffs, NJ, 2002. [26] K. Fukunaga, Introduction to Statistical Pattern Recognition, second ed, Academic Press, New York, 1991.