This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License.
R. Chouhan, C. P. Kumar, R. Kumar, and R. K. Jha, (2012), Contrast enhancement of dark images using stochastic resonance in wavelet domain. International Journal of Machine Learning and Computing, 2(5):711-715. 10.7763/IJMLC.2012.V2.220ChouhanRKumarC. P.KumarR.JhaR. K.2012Contrast enhancement of dark images using stochastic resonance in wavelet domainInternational Journal of Machine Learning and Computing257111510.7763/IJMLC.2012.V2.220Open DOISearch in Google Scholar
K. Dabov, A. Foi, V. Katkovnik, and K. Egiazarian, (2007), Image denoising by sparse 3D transform-domain collaborative filtering. IEEE Transactions on Image Processing, 16(8):2080–2095. 10.1109/TIP.2007.901238DabovKFoiAKatkovnikVEgiazarianK2007Image denoising by sparse 3D transform-domain collaborative filteringIEEE Transactions on Image Processing1682080209510.1109/TIP.2007.90123817688213Open DOISearch in Google Scholar
K. Dabov, A. Foi, V. Katkovnik, and K. Egiazarian, (2007), Joint image sharpening and denoising by 3D transform-domain collaborative filtering. In Proceedings of the International Workshop on Spectral Methods for Multirate Signal Process, SMMSP 2007, volume 2007.DabovKFoiAKatkovnikVEgiazarianK2007Joint image sharpening and denoising by 3D transform-domain collaborative filteringProceedings of the International Workshop on Spectral Methods for Multirate Signal Process, SMMSP 20072007Search in Google Scholar
F. H. Di Jia, J. Yang, Y. Zhang, D. Zhao, and G. Yu, (2010), A synchronization algorithm of MRI denoising and contrast enhancement based on PM-CLAHE model. JDCTA, 4(6):144–149.Di JiaF. H.YangJZhangY.ZhaoD.YuG.2010A synchronization algorithm of MRI denoising and contrast enhancement based on PM-CLAHE modelJDCTA4614414910.4156/jdcta.vol4.issue6.17Search in Google Scholar
M. Elad, (2002), On the origin of the bilateral filter and ways to improve it. IEEE Transactions on Image Processing, 11(10):1141–1151. 10.1109/TIP.2007.901238EladM2002On the origin of the bilateral filter and ways to improve itIEEE Transactions on Image Processing11101141115110.1109/TIP.2007.901238Open DOISearch in Google Scholar
L. Gammaitoni, P. Hänggi, P. Jung, and F. Marchesoni, (1998), Stochastic resonance. Reviews of Modern Physics, 70:223–287. 10.1103/RevModPhys.70.223GammaitoniL.HänggiP.JungP.MarchesoniF.1998Stochastic resonanceReviews of Modern Physics7022328710.1103/RevModPhys.70.223Open DOISearch in Google Scholar
G. Gilboa, N. Sochen, and Y. Y. Zeevi, (2002), Forward-and-backward diffusion processes for adaptive image enhancement and denoising. IEEE Transactions on Image Processing, 11(7):689–703. 10.1109/TIP.2002.800883GilboaG.SochenN.ZeeviY. Y.2002Forward-and-backward diffusion processes for adaptive image enhancement and denoisingIEEE Transactions on Image Processing11768970310.1109/TIP.2002.80088318244666Open DOISearch in Google Scholar
Z. Guo, J. Sun, D. Zhang, and B. Wu, (2012), Adaptive Perona–Malik model based on the variable exponent for image denoising. IEEE Transactions on Image Processing, 21(3):958–967. 10.1109/TIP.2011.2169272GuoZ.SunJ.ZhangD.WuB.2012Adaptive Perona–Malik model based on the variable exponent for image denoisingIEEE Transactions on Image Processing21395896710.1109/TIP.2011.216927221947525Open DOISearch in Google Scholar
B.-b. Hao, M. Li, and X.-c. Feng, (2008), Wavelet iterative regularization for image restoration with varying scale parameter. Signal Processing: Image Communication, 23(6):433–441. 10.1016/j.image.2008.04.006HaoB.-b.LiM.FengX.c.2008Wavelet iterative regularization for image restoration with varying scale parameterSignal Processing: Image Communication23643344110.1016/j.image.2008.04.006Open DOISearch in Google Scholar
T. Horiuchi, K. Watanabe, and S. Tominaga, (2007), Adaptive filtering for color image sharpening and denoising. In 14th International Conference on Image Analysis and Processing Workshops, ICIAPW 2007, 196–201.HoriuchiT.WatanabeK.TominagaS.2007Adaptive filtering for color image sharpening and denoising14th International Conference on Image Analysis and Processing Workshops, ICIAPW 200719620110.1109/ICIAPW.2007.11Search in Google Scholar
H. Ibrahim and N. S. P. Kong, (2007), Brightness preserving dynamic histogram equalization for image contrast enhancement. IEEE Transactions on Consumer Electronics, 53(4):403-410. 10.1109/TCE.2007.4429280IbrahimH.KongN. S. P.2007Brightness preserving dynamic histogram equalization for image contrast enhancementIEEE Transactions on Consumer Electronics53440341010.1109/TCE.2007.4429280Open DOISearch in Google Scholar
A. K. Jain, M. N. Murty, and P. J. Flynn, (1999), Data clustering: a review. ACM computing surveys (CSUR), 31(3):264–323. 10.1145/331499.331504JainA. K.MurtyM. N.FlynnP. J.1999Data clustering: a reviewACM computing surveys (CSUR)31326432310.1145/331499.331504Open DOISearch in Google Scholar
R. K. Jha, R. Chouhan, and K. Aizawa, (2014), Dynamic stochastic resonance-based improved logo extraction in discrete cosine transform domain. Computers & Electrical Engineering, 40(6):1917–1929. j.compeleceng.2013.07.024JhaR. K.ChouhanR.AizawaK.2014Dynamic stochastic resonance-based improved logo extraction in discrete cosine transform domainComputers & Electrical Engineering40619171929j.compeleceng.2013.07.024Open DOISearch in Google Scholar
R. K. Jha, R. Chouhan, P. K. Biswas, and K. Aizawa, (2012), Internal noise-induced contrast enhancement of dark images. In 19th IEEE International Conference on Image Processing (ICIP), 2012, pages 973–976.JhaR. K.ChouhanR.BiswasP. K.AizawaK.2012Internal noise-induced contrast enhancement of dark images19th IEEE International Conference on Image Processing (ICIP), 201297397610.1109/ICIP.2012.6467024Search in Google Scholar
C. Jordán, S. Morillas, and E. Sanabria-Codesal, (2012), Colour image smoothing through a soft-switching mechanism using a graph model. IET Image Processing, 6(9):1293–1298. 10.1049/IET-IPR.2011.0164JordánC.MorillasS.Sanabria-CodesalE.2012Colour image smoothing through a soft-switching mechanism using a graph modelIET Image Processing691293129810.1049/IET-IPR.2011.0164Open DOISearch in Google Scholar
W.-C. Kao and Y.-J. Chen, (2005), Multistage bilateral noise filtering and edge detection for color image enhancement. IEEE Transactions on Consumer Electronics, 51(4):1346–1351. 10.1109/TCE.2005.1561866KaoW.-C.ChenY.-J.2005Multistage bilateral noise filtering and edge detection for color image enhancementIEEE Transactions on Consumer Electronics5141346135110.1109/TCE.2005.1561866Open DOISearch in Google Scholar
C. Kenney, Y. Deng, B. Manjunath, and G. Hewer, (2001), Peer group image enhancement. IEEE Transactions on Image Processing, 10(2):326–334. 10.1109/83.902298KenneyC.DengY.ManjunathB.HewerG.2001Peer group image enhancementIEEE Transactions on Image Processing10232633410.1109/83.90229818249624Open DOISearch in Google Scholar
S. H. Kim and J. P. Allebach, (2005), Optimal unsharp mask for image sharpening and noise removal. Journal of Electronic Imaging, 14(2):023005. 10.1117/1.1924510KimS. H.AllebachJ. P.2005Optimal unsharp mask for image sharpening and noise removalJournal of Electronic Imaging14202300510.1117/1.1924510Open DOISearch in Google Scholar
Y.-T. Kim, (1997), Contrast enhancement using brightness preserving bi-histogram equalization. IEEE transactions on Consumer Electronics, 43(1):1–8. 10.1109/30.580378KimY.-T.1997Contrast enhancement using brightness preserving bi-histogram equalizationIEEE transactions on Consumer Electronics4311810.1109/30.580378Open DOISearch in Google Scholar
Y. H. Lee and S. Y. Park, (1990), A study of convex/concave edges and edge-enhancing operators based on the Laplacian. IEEE Transactions on Circuits and Systems, 37(7):940–946. 10.1109/31.55069LeeY. H.ParkS. Y.1990A study of convex/concave edges and edge-enhancing operators based on the LaplacianIEEE Transactions on Circuits and Systems37794094610.1109/31.55069Open DOISearch in Google Scholar
X. Li, (2007), On modeling interchannel dependency for color image denoising. International Journal of Imaging Systems and Technology, 17(3):163–173. 10.1002/ima.20112LiX.2007On modeling interchannel dependency for color image denoisingInternational Journal of Imaging Systems and Technology17316317310.1002/ima.20112Open DOISearch in Google Scholar
H. Li-na, G. Guo-hua, X. Jie, and X. Zheng-Long, (2009), Real-color image denoised and enhanced synchronously based on wavelet transform. In Second International Conference onIntelligent Computation Technology and Automation ICICTA’09, 1:658–661. 10.1109/AICI.2009.251Li-naH.Guo-huaG.JieX.Zheng-LongX.2009Real-color image denoised and enhanced synchronously based on wavelet transformSecond International Conference onIntelligent Computation Technology and Automation ICICTA’09165866110.1109/AICI.2009.251Open DOISearch in Google Scholar
X. Liu, G. Cheung, and X. Wu, (2015), Joint denoising and contrast enhancement of images using graph Laplacian operator. In IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP) 2015, 2274–2278. 10.1109/ICASSP.2015.7178376LiuX.CheungG.WuX.2015Joint denoising and contrast enhancement of images using graph Laplacian operatorIEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP) 20152274227810.1109/ICASSP.2015.7178376Open DOISearch in Google Scholar
A. Łoza, M. Al-Mualla, P. Verkade, P. Hill, D. Bull, and A. Achim, (2014) Joint denoising and contrast enhancement for light microscopy image sequences. In IEEE 11th International Symposium on Biomedical Imaging (ISBI), 2014, 1083–1086. 10.1109/ISBI.2014.6868062ŁozaA.Al-MuallaM.VerkadeP.HillP.BullD.AchimA.2014Joint denoising and contrast enhancement for light microscopy image sequencesIEEE 11th International Symposium on Biomedical Imaging (ISBI), 20141083108610.1109/ISBI.2014.6868062Open DOISearch in Google Scholar
A. Łoza, D. R. Bull, P. R. Hill, and A. M. Achim, (2013), Automatic contrast enhancement of low-light images based on local statistics of wavelet coefficients. Digital Signal Processing, 23(6):1856–1866. 10.1109/ICIP.2010.5651173ŁozaA.BullD. R.HillP. R.AchimA. M.2013Automatic contrast enhancement of low-light images based on local statistics of wavelet coefficientsDigital Signal Processing2361856186610.1109/ICIP.2010.5651173Open DOISearch in Google Scholar
J. Lu and D. Healy, (1994), Contrast enhancement via multiscale gradient transformation. In IEEE International Conference Image Processing, ICIP-94, 2:482–486. 10.1109/ICIP.1994.413617LuJ.HealyD.1994Contrast enhancement via multiscale gradient transformationIEEE International Conference Image Processing, ICIP-94248248610.1109/ICIP.1994.413617Open DOISearch in Google Scholar
L. Lucchese and S. K. Mitra, (2004), A new class of chromatic filters for color image processing. theory and applications. IEEE Transactions on Image Processing, 13(4):534–548. 10.1109/TIP.2003.822609LuccheseL.MitraS. K.2004A new class of chromatic filters for color image processing. theory and applicationsIEEE Transactions on Image Processing13453454810.1109/TIP.2003.822609Open DOISearch in Google Scholar
Z. Ma, H. R. Wu, and D. Feng, (2007), Fuzzy vector partition filtering technique for color image restoration. Computer Vision and Image Understanding, 107(1):26–37. 10.1016/j.cviu.2006.11.017MaZ.WuH. R.FengD.2007Fuzzy vector partition filtering technique for color image restorationComputer Vision and Image Understanding1071263710.1016/j.cviu.2006.11.017Open DOISearch in Google Scholar
S. Mallat, (1999), A wavelet tour of signal processing. Academic press, 1999. doi 10.1162/comj.2007.31.3.83MallatS.1999A wavelet tour of signal processingAcademic press, 199910.1162/comj.2007.31.3.83Open DOISearch in Google Scholar
S. G. Mallat, (1989), A theory for multiresolution signal decomposition: the wavelet representation. IEEE Transactions on Pattern Analysis and Machine Intelligence, 11(7):674–693. 10.1109/34.192463MallatS. G.1989A theory for multiresolution signal decomposition: the wavelet representationIEEE Transactions on Pattern Analysis and Machine Intelligence11767469310.1109/34.192463Open DOISearch in Google Scholar
M. K. Mihcak, I. Kozintsev, K. Ramchandran, and P. Moulin, (1999), Low-complexity image denoising based on statistical modeling of wavelet coefficients. IEEE Signal Processing Letters, 6(12):300–303. 10.1109/97.803428MihcakM. K.KozintsevI.RamchandranK.MoulinP.1999Low-complexity image denoising based on statistical modeling of wavelet coefficientsIEEE Signal Processing Letters61230030310.1109/97.803428Open DOISearch in Google Scholar
S. K. Mitra, H. Li, I.-S. Lin, and T.-H. Yu, (1991), A new class of nonlinear filters for image enhancement. In 1991 International Conference on Acoustics, Speech, and Signal Processing, ICASSP-91, 2525–2528. 10.1109/ICASSP.1991.150915MitraS. K.LiH.LinI.-S.YuT.-H.1991A new class of nonlinear filters for image enhancement1991 International Conference on Acoustics, Speech, and Signal Processing, ICASSP-912525252810.1109/ICASSP.1991.150915Open DOISearch in Google Scholar
S. Morillas, V. Gregori, and A. Hervás, (2009), Fuzzy peer groups for reducing mixed gaussian-impulse noise from color images. IEEE Transactions on Image Processing, 18(7):1452–1466. 10.1109/TIP.2009.2019305MorillasS.GregoriV.HervásA.2009Fuzzy peer groups for reducing mixed gaussian-impulse noise from color imagesIEEE Transactions on Image Processing1871452146610.1109/TIP.2009.2019305Open DOISearch in Google Scholar
S. Morillas, V. Gregori, and A. Sapena, (2006), Fuzzy bilateral filtering for color images. In International Conference Image Analysis and Recognition, 138–145. 10.1007/11867586_13MorillasS.GregoriV.SapenaA.2006Fuzzy bilateral filtering for color imagesInternational Conference Image Analysis and Recognition13814510.1007/11867586_13Open DOISearch in Google Scholar
S. Morillas, S. Schulte, T. Mélange, E. E. Kerre, and V. Gregori, (2007), A soft-switching approach to improve visual quality of colour image smoothing filters. In International Conference on Advanced Concepts for Intelligent Vision Systems, 254–261. 10.1007/978-3-540-74607-2_23MorillasS.SchulteS.MélangeT.KerreE. E.GregoriV.2007A soft-switching approach to improve visual quality of colour image smoothing filtersInternational Conference on Advanced Concepts for Intelligent Vision Systems25426110.1007/978-3-540-74607-2_23Open DOISearch in Google Scholar
D. D. Muresan and T. W. Parks, (2003), Adaptive principal components and image denoising. In International Conference on Image Processing, 2003, 1, 1–101. 10.1109/ICIP.2003.1246908MuresanD. D.ParksT. W.2003Adaptive principal components and image denoisingInternational Conference on Image Processing, 20031110110.1109/ICIP.2003.1246908Open DOISearch in Google Scholar
E. Oja, (1992), Principal components, minor components, and linear neural networks. Neural Networks, 5(6):927–935. doi 10.1016/S0893-6080(05)80089-9OjaE.1992Principal components, minor components, and linear neural networksNeural Networks5692793510.1016/S0893-6080(05)80089-9Open DOISearch in Google Scholar
Q. Pan, L. Zhang, G. Dai, and H. Zhang, (1999), Two denoising methods by wavelet transform. IEEE Transactions on Signal Processing, 47(12):3401–3406. 10.1109/78.806084PanQ.ZhangL.DaiG.ZhangH.1999Two denoising methods by wavelet transformIEEE Transactions on Signal Processing47123401340610.1109/78.806084Open DOISearch in Google Scholar
P. Perona and J. Malik, (1990), Scale-space and edge detection using anisotropic diffusion. IEEE Transactions on Pattern Analysis and Machine Intelligence, 12(7):629-639. 10.1109/34.56205PeronaP.MalikJ.1990Scale-space and edge detection using anisotropic diffusionIEEE Transactions on Pattern Analysis and Machine Intelligence12762963910.1109/34.56205Open DOISearch in Google Scholar
C. Pérez-Benito, C. Jordán, S. Morillas, and J. Conejero, (2018), A model based on local graphs for colour images and its application for Gaussian noise smoothing. Journal of Computational and Applied Mathematics. 10.1016/j.cam.2017.05.013Pérez-BenitoC.JordánC.MorillasS.ConejeroJ.2018A model based on local graphs for colour images and its application for Gaussian noise smoothingJournal of Computational and Applied Mathematics10.1016/j.cam.2017.05.013Open DOISearch in Google Scholar
C. C. Pham, S. V. U. Ha, and J. W. Jeon, (2011), Adaptive guided image filtering for sharpness enhancement and noise reduction. In Pacific-Rim Symposium on Image and Video Technology, 323–334. 10.1109/78.806084PhamC. C.HaS. V. U.JeonJ. W.2011Adaptive guided image filtering for sharpness enhancement and noise reductionPacific-Rim Symposium on Image and Video Technology32333410.1109/78.806084Open DOISearch in Google Scholar
C. C. Pham and J. W. Jeon, (2014), Efficient image sharpening and denoising using adaptive guided image filtering. IET Image Processing, 9(1):71–79. 10.1049/iet-ipr.2013.0563PhamC. C.JeonJ. W.2014Efficient image sharpening and denoising using adaptive guided image filteringIET Image Processing91717910.1049/iet-ipr.2013.0563Open DOISearch in Google Scholar
A. Pizurica, W. Philips, I. Lemahieu, and M. Acheroy, (2002), A joint inter-and intrascale statistical model for bayesian wavelet based image denoising. IEEE Transactions on Image Processing, 11(5):545–557. 10.1109/TIP.2002.1006401PizuricaA.PhilipsW.LemahieuI.AcheroyM.2002A joint inter-and intrascale statistical model for bayesian wavelet based image denoisingIEEE Transactions on Image Processing11554555710.1109/TIP.2002.100640118244654Open DOISearch in Google Scholar
K. Plataniotis and A. N. Venetsanopoulos, (2013), Color image processing and applications. Springer Science & Business Media. 10.1088/0957-0233/12/2/703PlataniotisK.VenetsanopoulosA. N.2013Color image processing and applicationsSpringer Science & Business Media10.1088/0957-0233/12/2/703Open DOISearch in Google Scholar
K. N. Plataniotis, D. Androutsos, and A. N. Venetsanopoulos, (1999), Adaptive fuzzy systems for multichannel signal processing. Proceedings of the IEEE, 87(9):1601–1622. 10.1109/5.784243PlataniotisK. N.AndroutsosD.VenetsanopoulosA. N.1999Adaptive fuzzy systems for multichannel signal processingProceedings of the IEEE8791601162210.1109/5.784243Open DOISearch in Google Scholar
A. Polesel, G. Ramponi, and V. J. Mathews, (2000), Image enhancement via adaptive unsharp masking. IEEE Transactions on Image Processing, 9(3):505–510. 10.1109/83.826787PoleselA.RamponiG.MathewsV. J.2000Image enhancement via adaptive unsharp maskingIEEE Transactions on Image Processing9350551010.1109/83.82678718255421Open DOISearch in Google Scholar
W. K. Pratt, (2001), Digital image processing: PIKS Inside, John Wiley & sons. Inc. 10.1002/0471221325PrattW. K.2001Digital image processing: PIKS Inside, John Wiley & sonsInc10.1002/0471221325Open DOISearch in Google Scholar
G. Ramponi, N. Strobel, S. K. Mitra, and T.-H. Yu, (1996), Nonlinear unsharp masking methods for image contrast enhancement. Journal of Electronic Imaging, 5(3):353–366. 10.1117/12.242618RamponiG.StrobelN.MitraS. K.YuT.-H.1996Nonlinear unsharp masking methods for image contrast enhancementJournal of Electronic Imaging5335336610.1117/12.242618Open DOISearch in Google Scholar
V. Ratner and Y. Y. Zeevi, (2011), Denoising-enhancing images on elastic manifolds. IEEE Transactions on Image Processing, 20(8):2099–2109. doi 10.1117/12.242618RatnerV.ZeeviY. Y.2011Denoising-enhancing images on elastic manifoldsIEEE Transactions on Image Processing2082099210910.1117/12.242618Open DOISearch in Google Scholar
V. Ratner and Y. Y. Zeevi, (2013), Stable denoising-enhancement of images by telegraph-diffusion operators. In 20th IEEE International Conference on Image Processing (ICIP), 2013, 1252–1256. 10.1109/ICIP.2013.6738258RatnerV.ZeeviY. Y.2013Stable denoising-enhancement of images by telegraph-diffusion operators20th IEEE International Conference on Image Processing (ICIP), 20131252125610.1109/ICIP.2013.6738258Open DOISearch in Google Scholar
F. Russo, (2000), Noise removal from image data using recursive neurofuzzy filters. IEEE Transactions on Instrumentation and Measurement, 49(2):307–314. 10.1109/IMTC.1999.776134RussoF.2000Noise removal from image data using recursive neurofuzzy filtersIEEE Transactions on Instrumentation and Measurement49230731410.1109/IMTC.1999.776134Open DOISearch in Google Scholar
F. Russo, (2002), An image enhancement technique combining sharpening and noise reduction. IEEE Transactions on Instrumentation and Measurement, 51(4):824–828. 10.1109/TIM.2002.803394RussoF.2002An image enhancement technique combining sharpening and noise reductionIEEE Transactions on Instrumentation and Measurement51482482810.1109/TIM.2002.803394Open DOISearch in Google Scholar
S. Schulte, V. De Witte, and E. E. Kerre, (2007), A fuzzy noise reduction method for color images. IEEE Transactions on Image Processing, 16(5):1425–1436. 10.1109/TIP.2007.891807SchulteS.De WitteV.KerreE. E.2007A fuzzy noise reduction method for color imagesIEEE Transactions on Image Processing1651425143610.1109/TIP.2007.89180717491470Open DOISearch in Google Scholar
M. Shao and K. E. Barner, (2006), Optimization of partition-based weighted sum filters and their application to image denoising. IEEE Transactions on Image Processing, 15(7):1900–1915. 10.1109/TIP.2006.873436ShaoM.BarnerK. E.2006Optimization of partition-based weighted sum filters and their application to image denoisingIEEE Transactions on Image Processing1571900191510.1109/TIP.2006.873436Open DOISearch in Google Scholar
D. Sheet, H. Garud, A. Suveer, M. Mahadevappa, and J. Chatterjee, (2010), Brightness preserving dynamic fuzzy histogram equalization. IEEE Transactions on Consumer Electronics, 56(4), 2475–2480. 10.1109/TCE.2010.5681130SheetD.GarudH.SuveerA.MahadevappaM.ChatterjeeJ.2010Brightness preserving dynamic fuzzy histogram equalizationIEEE Transactions on Consumer Electronics5642475248010.1109/TCE.2010.5681130Open DOISearch in Google Scholar
S. M. Smith and J. M. Brady, (1997), SUSAN – A new approach to low level image processing. International Journal of Computer Vision, 23(1):45–78. 10.1023/A:1007963824710SmithS. M.BradyJ. M.1997SUSAN – A new approach to low level image processingInternational Journal of Computer Vision231457810.1023/A:1007963824710Open DOISearch in Google Scholar
A. R. Teixeira, A. M. Tomé, K. Stadlthanner, and E. W. Lang, (2008), KPCA denoising and the pre-image problem revisited. Digital Signal Processing, 18(4):568–580. 10.1016/j.dsp.2007.08.001TeixeiraA. R.ToméA. M.StadlthannerK.LangE. W.2008KPCA denoising and the pre-image problem revisitedDigital Signal Processing18456858010.1016/j.dsp.2007.08.001Open DOISearch in Google Scholar
K. K. V. Toh and N. A. M. Isa, (2011), Locally adaptive bilateral clustering for image deblurring and sharpness enhancement. IEEE Transactions on Consumer Electronics, 57(3). 10.1109/TCE.2011.6018878TohK. K. V.IsaN. A. M.2011Locally adaptive bilateral clustering for image deblurring and sharpness enhancementIEEE Transactions on Consumer Electronics57310.1109/TCE.2011.6018878Open DOISearch in Google Scholar
C. Tomasi and R. Manduchi, (1998), Bilateral filtering for gray and color images. In Sixth International Conference on Computer Vision, 1998, 839–846. 10.1109/ICCV.1998.710815TomasiC.ManduchiR.1998Bilateral filtering for gray and color imagesSixth International Conference on Computer Vision, 199883984610.1109/ICCV.1998.710815Open DOISearch in Google Scholar
P. Trahanias and A. Venetsanopoulos, (1992), Color image enhancement through 3D histogram equalization. In Pattern Recognition, 1992. Vol. III. 11th IAPR International Conference on Image, Speech and Signal Analysis, 545–548. 10.1109/ICPR.1992.202045TrahaniasP.VenetsanopoulosA.1992Color image enhancement through 3D histogram equalizationPattern Recognition, 1992. Vol. III. 11th IAPR International Conference on Image, Speech and Signal Analysis54554810.1109/ICPR.1992.202045Open DOISearch in Google Scholar
Y. Wang, Q. Chen, and B. Zhang, (1999), Image enhancement based on equal area dualistic sub-image histogram equalization method. IEEE Transactions on Consumer Electronics, 45(1):68–75. 10.1109/30.754419WangY.ChenQ.ZhangB.1999Image enhancement based on equal area dualistic sub-image histogram equalization methodIEEE Transactions on Consumer Electronics451687510.1109/30.754419Open DOISearch in Google Scholar
Y. Wang, J. Guo, W. Chen, and W. Zhang, (2013), Image denoising using modified Perona–Malik model based on directional Laplacian. Signal Processing, 93(9):2548–2558. 10.1016/j.sigpro.2013.02.020WangY.GuoJ.ChenW.ZhangW.2013Image denoising using modified Perona–Malik model based on directional LaplacianSignal Processing9392548255810.1016/j.sigpro.2013.02.020Open DOISearch in Google Scholar
Y. Wang, L. Zhang, and P. Li, (2007), Local variance-controlled forward-and-backward diffusion for image enhancement and noise reduction. IEEE Transactions on Image Processing, 16(7):1854–1864. 10.1109/TIP.2007.899002WangY.ZhangL.LiP.2007Local variance-controlled forward-and-backward diffusion for image enhancement and noise reductionIEEE Transactions on Image Processing1671854186410.1109/TIP.2007.89900217605383Open DOISearch in Google Scholar
X. Wu, (2011), A linear programming approach for optimal contrast-tone mapping. IEEE Transactions on Image Processing, 20(5):1262–1272. 10.1109/TIP.2010.2092438WuX.2011A linear programming approach for optimal contrast-tone mappingIEEE Transactions on Image Processing2051262127210.1109/TIP.2010.209243821078574Open DOISearch in Google Scholar
M. F. Zakaria, H. Ibrahim, and S. A. Suandi, (2010), A review: Image compensation techniques. In 2nd International Conference on Computer Engineering and Technology (ICCET), 2010, 7: V7-404–V7-408. 10.1109/ICCET.2010.5485499ZakariaM. F.IbrahimH.SuandiS. A.2010A review: Image compensation techniques2nd International Conference on Computer Engineering and Technology (ICCET), 20107V7-404V7-40810.1109/ICCET.2010.5485499Open DOISearch in Google Scholar
B. Zhang and J. P. Allebach, (2008), Adaptive bilateral filter for sharpness enhancement and noise removal. IEEE Transactions on Image Processing, 17(5):664–678. 10.1109/TIP.2008.919949ZhangB.AllebachJ. P.2008Adaptive bilateral filter for sharpness enhancement and noise removalIEEE Transactions on Image Processing17566467810.1109/TIP.2008.91994918390373Open DOISearch in Google Scholar
L. Zhang, W. Dong, D. Zhang, and G. Shi, (2010), Two-stage image denoising by principal component analysis with local pixel grouping. Pattern Recognition, 43(4):1531–1549. 10.1109/TIP.2008.2011384ZhangL.DongW.ZhangD.ShiG.2010Two-stage image denoising by principal component analysis with local pixel groupingPattern Recognition4341531154910.1109/TIP.2008.201138419273050Open DOISearch in Google Scholar
L. Zhang, R. Lukac, X. Wu, and D. Zhang, (2009), PCA-based spatially adaptive denoising of CFA images for single-sensor digital cameras. IEEE Transactions on Image Processing, 18(4):797–812. 10.1109/TIP.2008.2011384ZhangL.LukacR.WuX.ZhangD.2009PCA-based spatially adaptive denoising of CFA images for single-sensor digital camerasIEEE Transactions on Image Processing18479781210.1109/TIP.2008.2011384Open DOISearch in Google Scholar
H. Zhu, F. H. Chan, and F. K. Lam, (1999), Image contrast enhancement by constrained local histogram equalization. Computer Vision and Image Understanding, 73(2):281–290. 10.1006/cviu.1998.0723ZhuH.ChanF. H.LamF. K.1999Image contrast enhancement by constrained local histogram equalizationComputer Vision and Image Understanding73228129010.1006/cviu.1998.0723Open DOISearch in Google Scholar
