Multi-Focus Image Fusion Based on Discrete Walsh-Hadamard Transform and Guided Filtering

Liang Hu; Xuejuan Hu; Zhenhong Huang; Lu Xu; Lijin Lian

doi:10.3788/LOP202158.2210003

[1] Li J, Yang Y C, Dang J W et al. NSST and guided filtering for multi-focus image fusion algorithm[J]. Journal of Harbin Institute of Technology, 50, 145-152(2018).

[2] Zhang Y F, Geng Z X, Wang J M. Extended phase stretch transform based multi-focus image fusion algorithm[J]. Laser & Optoelectronics Progress, 57, 221007(2020).

[3] Li H, Zhang L M, Jiang M R et al. Multi-focus image fusion algorithm based on supervised learning for fully convolutional neural networks[J]. Laser & Optoelectronics Progress, 57, 081015(2020).

[4] Li S T, Kang X D, Fang L Y et al. Pixel-level image fusion: a survey of the state of the art[J]. Information Fusion, 33, 100-112(2017).

[5] Qiu X H, Li M, Zhang L Q et al. Guided filter-based multi-focus image fusion through focus region detection[J]. Signal Processing: Image Communication, 72, 35-46(2019).

[6] Bai X Z, Zhang Y, Zhou F G et al. Quadtree-based multi-focus image fusion using a weighted focus-measure[J]. Information Fusion, 22, 105-118(2015).

[7] Saboori A, Birjandtalab J. PET-MRI image fusion using adaptive filter based on spectral and spatial discrepancy[J]. Signal, Image and Video Processing, 13, 135-143(2019).

[8] Chaudhary V, Kumar V. Block-based image fusion using multi-scale analysis to enhance depth of field and dynamic range[J]. Signal, Image and Video Processing, 12, 271-279(2018).

[9] Aslantas V, Kurban R. Fusion of multi-focus images using differential evolution algorithm[J]. Expert Systems With Applications, 37, 8861-8870(2010).

[10] Tian S, Ren Y F, Shao X Y et al. Multifocus fusion image enhancement based on image subtraction angiography and NSML[J]. Laser & Optoelectronics Progress, 57, 201016(2020).

[11] Li S T, Kwok J T, Wang Y N. Multifocus image fusion using artificial neural networks[J]. Pattern Recognition Letters, 23, 985-997(2002).

[12] Burt P J, Adelson E H. The Laplacian pyramid as a compact image code[J]. Readings in Computer Vision, 31, 671-679(1987).

[13] Toet A. Image fusion by a ratio of low-pass pyramid[J]. Pattern Recognition Letters, 9, 245-253(1989).

[14] Pajares G, de la Manuel C J. A wavelet-based image fusion tutorial[J]. Pattern Recognition, 37, 1855-1872(2004).

[15] Lewis J J, O’Callaghan R J, Nikolov S G et al. Pixel- and region-based image fusion with complex wavelets[J]. Information Fusion, 8, 119-130(2007).

[16] Do M N, Vetterli M. The contourlet transform: an efficient directional multiresolution image representation[J]. IEEE Transactions on Image Processing, 14, 2091-2106(2005).

[17] Miao Q G, Shi C, Xu P F et al. A novel algorithm of image fusion using shearlets[J]. Optics Communications, 284, 1540-1547(2011).

[18] da Cunha A L, Zhou J, Do M N. The nonsubsampled contourlet transform: theory, design, and applications[J]. IEEE Transactions on Image Processing, 15, 3089-3101(2006).

[19] Wang X W, Liang X, Zheng J J et al. Fast detection and segmentation of partial image blur based on discrete Walsh-Hadamard transform[J]. Signal Processing: Image Communication, 70, 47-56(2019).

[20] Chien S Y, Ma S Y, Chen L G. Efficient moving object segmentation algorithm using background registration technique[J]. IEEE Transactions on Circuits and Systems for Video Technology, 12, 577-586(2002).

[21] Bai X Z, Zhou F G. Analysis of new top-hat transformation and the application for infrared dim small target detection[J]. Pattern Recognition, 43, 2145-2156(2010).

[22] Li S, Kang X, Hu J. Image fusion with guided filtering[J]. IEEE Transactions on Image Processing, 22, 2864-2875(2013).

[23] Zhou Z Q, Li S, Wang B. Multi-scale weighted gradient-based fusion for multi-focus images[J]. Information Fusion, 20, 60-72(2014).

[24] Liu Y, Chen X, Peng H et al. Multi-focus image fusion with a deep convolutional neural network[J]. Information Fusion, 36, 191-207(2017).

[25] Haghighat M B A, Aghagolzadeh A, Seyedarabi H. Multi-focus image fusion for visual sensor networks in DCT domain[J]. Computers & Electrical Engineering, 37, 789-797(2011).

[26] Liu Z, Blasch E, Xue Z Y et al. Objective assessment of multiresolution image fusion algorithms for context enhancement in night vision: a comparative study[J]. IEEE Transactions on Pattern Analysis and Machine Intelligence, 34, 94-109(2012).

[27] Xydeas C S, Petrović V. Objective image fusion performance measure[J]. Electronics Letters, 36, 308-309(2000).

[28] Yang C, Zhang J Q, Wang X R et al. A novel similarity based quality metric for image fusion[J]. Information Fusion, 9, 156-160(2008).

[29] Pistonesi S, Martinez J, Ojeda S M et al. Structural similarity metrics for quality image fusion assessment: algorithms[J]. Image Processing on Line, 8, 345-368(2018).

[30] Chen Y, Blum R S. A new automated quality assessment algorithm for image fusion[J]. Image and Vision Computing, 27, 1421-1432(2009).

[31] Haghighat M, Razian M A. Fast-FMI: non-reference image fusion metric[C]. //2014 IEEE 8th International Conference on Application of Information and Communication Technologies (AICT), October 15-17, 2014, Astana, Kazakhstan, 14916890(2014).

[32] Mittal A, Soundararajan R, Bovik A C. Making a “completely blind” image quality analyzer[J]. IEEE Signal Processing Letters, 20, 209-212(2013).

[33] Xie X F, Zhou J, Wu Q Z. No-reference quality index for image blur[J]. Journal of Computer Applications, 30, 921-924(2010).

[34] Chen X Q, Zhang Q Y, Lin M H et al. No-reference color image quality assessment: from entropy to perceptual quality[J]. EURASIP Journal on Image and Video Processing, 2019, 1-14(2019).

[35] Ziaei Nafchi H, Cheriet M. Efficient no-reference quality assessment and classification model for contrast distorted images[J]. IEEE Transactions on Broadcasting, 64, 518-523(2018).