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CLC number: TP391
On-line Access: 2024-08-27
Received: 2023-10-17
Revision Accepted: 2024-05-08
Crosschecked: 2020-08-28
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Citations: Bibtex RefMan EndNote GB/T7714
An improved method for image denoising based on fractional-order integration
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Li Xu, Guo Huang, Qing-li Chen, Hong-yin Qin, Tao Men, Yi-fei Pu. An improved method for image denoising based on fractional-order integration[J]. Frontiers of Information Technology & Electronic Engineering, 2020, 21(10): 1485-1493.
@article{title="An improved method for image denoising based on fractional-order integration",
author="Li Xu, Guo Huang, Qing-li Chen, Hong-yin Qin, Tao Men, Yi-fei Pu",
journal="Frontiers of Information Technology & Electronic Engineering",
volume="21",
number="10",
pages="1485-1493",
year="2020",
publisher="Zhejiang University Press & Springer",
doi="10.1631/FITEE.1900727"
}
%0 Journal Article
%T An improved method for image denoising based on fractional-order integration
%A Li Xu
%A Guo Huang
%A Qing-li Chen
%A Hong-yin Qin
%A Tao Men
%A Yi-fei Pu
%J Frontiers of Information Technology & Electronic Engineering
%V 21
%N 10
%P 1485-1493
%@ 2095-9184
%D 2020
%I Zhejiang University Press & Springer
%DOI 10.1631/FITEE.1900727
TY - JOUR
T1 - An improved method for image denoising based on fractional-order integration
A1 - Li Xu
A1 - Guo Huang
A1 - Qing-li Chen
A1 - Hong-yin Qin
A1 - Tao Men
A1 - Yi-fei Pu
J0 - Frontiers of Information Technology & Electronic Engineering
VL - 21
IS - 10
SP - 1485
EP - 1493
%@ 2095-9184
Y1 - 2020
PB - Zhejiang University Press & Springer
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DOI - 10.1631/FITEE.1900727
Abstract: Given that the existing image denoising methods damage the texture details of an image, a new method based on fractional integration is proposed. First, the fractional-order integral formula is deduced by generalizing the cauchy integral, and then the approximate value of the fractional-order integral operator is estimated by a numerical method. Finally, a fractional-order integral mask operator of any order is constructed in eight pixel directions of the image. Simulation results show that the proposed image denoising method can protect the edge texture information of the image while removing the noise. Moreover, this method can obtain higher image feature values and better image vision after denoising than the existing denoising methods, because a texture protection mechanism is adopted during the iterative processing.
[1]Amoako-Yirenkyi P, Appati JK, Dontwi IK, 2016. A new construction of a fractional derivative mask for image edge analysis based on Riemann-Liouville fractional derivative. Adv Differ Equat, 2016:238.
[2]Bai YR, Baleanu D, Wu GC, 2018. A novel shuffling technique based on fractional chaotic maps. Optik, 168:553-562.
[3]Bhrawy AH, Zaky MA, 2017. An improved collocation method for multi-dimensional space-time variable-order fractional Schrödinger equations. Appl Numer Math, 111:197-218.
[4]Chen DL, Sun SS, Zhang CR, 2013. Fractional-order TV-L2 model for image denoising. Cent Eur J Phys, 11(10):1414-1422.
[5]Chen E, Min LQ, Chen GR, 2017. Discrete chaotic systems with one-line equilibria and their application to image encryption. Int J Bifurc Chaos, 27(3):1750046.
[6]Ding HF, Li CP, Yi Q, 2017. A new second-order midpoint approximation formula for Riemann-Liouville derivative: algorithm and its application. IMA J Appl Math, 82(5):909-944.
[7]He N, Wang JB, Zhang LL, et al., 2014. An improved fractional-order differentiation model for image denoising. Signal Process, 112:180-188.
[8]Huang G, Pu YF, Chen QL, et al., 2011. Research on image denoising based on fractional order integral. Syst Eng Electron, 33(4):925-932 (in Chinese).
[9]Jain S, Bajaj V, Kumar A, 2018. Riemann Liouvelle fractional integral based empirical mode decomposition for ECG denoising. IEEE J Biomed Health Inform, 22(4):1133-1139.
[10]Jalab HA, Ibrahim RW, 2015. Fractional Alexander polynomials for image denoising. Signal Process, 107:340-354.
[11]Jalab HA, Ibrahim RW, Ahmed A, 2017. Image denoising algorithm based on the convolution of fractional Tsallis entropy with the Riesz fractional derivative. Neur Comput Appl, 28(S1):217-223.
[12]Jiang W, Wang ZX, 2012. Image denoising new method based on fractional partial differential equation. Adv Mater Res, 532-533:797-802.
[13]Li B, Xie W, 2016. Image enhancement and denoising algorithms based on adaptive fractional differential and integral. Syst Eng Electron, 38(1):185-192 (in Chinese).
[14]Liu ST, Yu L, Zhu BH, 2001. Optical image encryption by cascaded fractional Fourier transforms with random phase filtering. Opt Commun, 187(1-3):57-63.
[15]Liu Y, Pu YF, Zhou JL, 2011. A digital image denoising method based on fractional calculus. J Sichuan Univ (Eng Sci Ed), 43(3):90-95, 144 (in Chinese).
[16]Liu ZJ, Liu ST, 2007. Double image encryption based on iterative fractional Fourier transform. Opt Commun, 275(2):324-329.
[17]Nandal A, Gamboa-Rosales H, Dhaka A, et al., 2018. Image edge detection using fractional calculus with feature and contrast enhancement. Circ Syst Signal Process, 37(9):3946-3972.
[18]Podlubny I, 1999. Fractional Differential Equations. Academic Press, New York, NY, USA, p.16-45.
[19]Pu YF, Wang WX, Zhou JL, et al., 2008. Fractional differential approach to detecting textural features of digital image and its fractional differential filter implementation. Sci China Ser F, 51(9):1319-1339.
[20]Pu YF, Siarry P, Zhou JL, et al., 2014. A fractional partial differential equation based multiscale denoising model for texture image. Math Meth Appl Sci, 37(12):1784-1806.
[21]Pu YF, Zhang N, Zhang Y, et al., 2016. A texture image denoising approach based on fractional developmental mathematics. Patt Anal Appl, 19(2):427-445.
[22]Pu YF, Siarry P, Chatterjee A, et al., 2018. A fractional-order variational framework for retinex: fractional-order partial differential equation-based formulation for multi-scale nonlocal contrast enhancement with texture preserving. IEEE Trans Image Process, 27(3):1214-1229.
[23]Shao L, Yan RM, Li XL, et al., 2014. From heuristic optimization to dictionary learning: a review and comprehensive comparison of image denoising algorithms. IEEE Trans Cybern, 44(7):1001-1013.
[24]Tian D, Xue DY, Wang DH, 2015. A fractional-order adaptive regularization primal–dual algorithm for image denoising. Inform Sci, 296:147-159.
[25]Wu GC, Zeng DQ, Baleanu D, 2019a. Fractional impulsive differential equations: exact solutions, integral equations and short memory case. Frac Calc Appl Anal, 22(1):180-192.
[26]Wu GC, Deng ZG, Baleanu D, 2019b. New variable-order fractional chaotic systems for fast image encryption. Chaos, 29(8):083103.
[27]Wu XJ, Li Y, Kurths J, 2015. A new color image encryption scheme using CML and a fractional-order chaotic system. PLoS ONE, 10(3):e0119660.
[28]Yu JM, Tan LJ, Zhou SB, et al., 2017. Image denoising algorithm based on entropy and adaptive fractional order calculus operator. IEEE Access, 5:12275-12285.
[29]Zhang GM, Sun XX, Liu JX, 2016. Fractional total variation denoising model based on adaptive projection algorithm. Patt Recogn Artif Intell, 29(11):1009-1018 (in Chinese).
[30]Zhang J, Wei ZH, Xiao L, 2012. Adaptive fractional-order multi-scale method for image denoising. J Math Imag Vis, 43(1):39-49.
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