Kalavathy Sundarrajan and Ramalingam M. Suresh
[1] G. Beylkin, On the representation of operators in bases ofcompactly supported wavelets, SIAM Journal on NumericalAnalysis, 29, 1992, 1716–1740. [2] M.K. Mihcak, I. Kozintsev, K. Ramchandran, and P. Moulin,Low complexity image denoising based on statistical modelingof wavelet coefficients, IEEE Transactions on Signal Processing,6 (12), 1999, 300–303. [3] S.G. Chang, B. Yu, and M. Vetterli, Spatially adaptive waveletthresholding context modeling for image denoising, Fifth IEEEInternational Conf. on Image Processing, Chicago, IL, IEEEComputer Society, 1998. [4] J. Portilla, V. Strela, M.J. Wainwright, and E.P. Simoncelli,Image denoising using scale mixtures of Gaussians in thewavelet domain, IEEE Trans. on Image Processing, 12 (11),2003, 1338–1351. [5] V. Strela, Denoising via block Wiener filtering in waveletdomain, Third European Congress of Mathematics (Barcelona:Birkh¨auser Verlag, 2000). [6] S.G. Mallat, A theory for multiresolution signal decomposition:The wavelet representation, IEEE Transactions on PatternAnalysis and Machine Intelligence, 11(7), 1989, 674–693. [7] R.N. Strickland and He Il Hahn, Wavelet transform methodsfor object detection and recovery, IEEE Transactions on ImageProcessing, 6 (5), 1997, 724–735. [8] A. Cohen, I. Daubechies, and J.C. Feauveau, Biorthogonalbases of compactly supported wavelets, Journal of Communa-tions on Pure and Applied Mathematics, Wiley Interscience,45(2), 2006, 485–560. [9] M. Vetterli and C. Herley, Wavelets and filter banks: Theoryand design, IEEE Transactions on Signal Processing, 40 (9),1992, 2207–2232. [10] M. Grgic, M. Ravnjak, and B. Zovko-Cihlar, Filter comparisonin wavelet transform of still images, Proc. IEEE InternationalSymposium on Industrial Electronics, ISIE ’99, 1, 1999,105–110. [11] X. Li and M.T. Orchard, Spatially adaptive image denoisingunder overcomplete expansion, IEEE International Conferenceon Image Processing, 3, 2000, 300–303. [12] V. Strela, J. Portilla, and E.P. Simoncelli, Image denoisingusing a local Gaussian scale mixture model in the waveletdomain, Proc. SPIE, 4119, 2000, 363–371. [13] J. Portilla, V. Strela, M. Wainwright, and E. Simoncelli,Adaptive Wiener denoising using a Gaussian scale mixturemodel in the wavelet domain, Proc. 8th IEEE InternationalConf. on Image Processing, 2, 2001, 37–40. [14] P. Moulin and J. Liu, Analysis of multiresolution image de-noising schemes using generalized Gaussian and complexitypriors, IEEE Transactions Information Theory, 45 (3), 1999,909–919. [15] L. Sendur and I.W. Selesnick, Bivariate shrinkage functionsfor wavelet-based denoising exploiting interscale dependency,IEEE Transactions on Signal Processing, 50 (11), 2002,2744–2756. [16] S.G. Chang, B. Yu, and M. Vetterli, Spatially adaptive waveletthresholding with context modeling in favor of image denoising,Fifth IEEE International Conf. on Image Processing, 1, 1998,535–539. [17] T. Stathaki, Image fusion-algorithms and application (London:Elsevier, 2008). [18] X. Zhang and D. Li, `A Trous wavelet decomposition applied toimage edge detection, Geographic Information Sciences, 7 (2),2001, 1947–5683 (print), 1947–5691 (online). [19] A.K. Fletcher, Denoising via recursive wavelet thresholding, Athesis submitted in partial satisfaction of the requirements forthe degree of Master of Science in Electrical Engineering inthe graduate division of the University of California, Berkeley,2002. [20] Tai-Wai Chan, O.C. Au, Tak-Song Chong, and Wing-SanChau, A novel content-adaptive video denoising filter, Proc.(ICASSP 05) IEEE International Conf. on Acoustics Speechand Signal Processing, 2, 18–23 March 2005, 649–652.
Important Links:
Go Back
