Fusion of infrared and visible images combined with NSDTCT and sparse representation

被引：3

作者：

Yin M. ^{[1
]}

Duan P.-H. ^{[1
]}

Chu B. ^{[1
]}

Liang X.-Y. ^{[1
]}

机构：

[1] School of Mathematics, Hefei University of Technology, Hefei

来源：

Duan, Pu-Hong (duanpuhong@126.com) | 1763年 / Chinese Academy of Sciences卷 / 24期

关键词：

Adaptive Dual Channel Pulse Coupled Neural Network(APCNN); Image fusion; Infrared image; Morphology transform; Non-subsampled Dual-tree Complex Contourlet Transform(NSDTCT); Sparse representation; Visible image;

D O I：

10.3788/OPE.20162407.1763

中图分类号：

学科分类号：

摘要：

A novel fusion method of infrared and visible images was proposed based on Non-subsampled Dual-tree Complex Contourlet Transform(NSDTCT) and sparse representation to overcome the shortcomings of traditional image fusion method based on wavelet transform. With the proposed method, morphological transform was used to deal with source images, and then the source images were decomposed by the NSDTCT to obtain the low frequency sub-band coefficients and high frequency sub-band coefficients. According to the different characteristics of the low and high frequency coefficients, an Improved Sparse Representation (ISR) fusion rule was proposed for the low frequency sub-bands; Then, the improved spatial frequency was used as the external input of a pulse coupled neural network, and a fusion method based on the improved adaptive dual channel pulse coupled neural network (2APCNN) was presented for the high frequency sub-bands. Finally, the fused image was obtained by performing the inverse NSDTCT. Experimental results indicate that the proposed method outperforms the conventional image fusion methods in terms of both objective evaluation criteria and visual quality. As compared with conventional NSCT-SR method, the fusion quality indexes, Mutual Information(MI), Mount of edge Information(QAB/F), Average Gradient(AG) and Standard Deviation(SD) have increased by 9.89%, 6.39%, 104.64%, 55.09%, and 9.53%, 17.77%, 95.66%, 52.89%, respectively. © 2016, Science Press. All right reserved.

引用

页码：1763 / 1771

页数：8

共 23 条

[1] Yang G., Tong T., Lu S.Y., Et al., Fusion of infrared and visible images based on multi-features, Opt. Precision Eng., 22, 2, pp. 489-496, (2014)
[2] Zeng X.T., Zhang Y.Z., Sun J.S., Et al., One color contrast enhanced infrared and visible image fusion method, Infrared and Laser Engineering, 44, 4, pp. 1198-1202, (2015)
[3] Chen Z., Xing X.X., Image fusion algorithm based on non-subsampled Shearlet transform and compressed sensing, Chinese Journal of Liquid Crystals and Displays, 30, 6, pp. 1024-1031, (2015)
[4] Do M.N., Vetterli M., The contourlet transform: an efficient directional multiresolution image representation, IEEE Transactions on Image Processing, 14, 12, pp. 2091-2106, (2005)
[5] da Cunha A.L., Zhou J.P., Do M.N., The nonsub-sampled contourlet transform: theory, design, and applications, IEEE Transactions on Image Processing, 15, 10, pp. 3089-3101, (2006)
[6] Yang Y.T., Zhu M., He B.G., Et al., Fusion algorithm based on improved projected gradient NMF and NSCT, Opt. Precision Eng., 19, 5, pp. 1143-1150, (2011)
[7] Ying M., Liu W., Image denoising using mixed statistical model in nonsubsampled Contourlet transform domain, Acta Photonica Sinica, 41, 6, pp. 751-756, (2012)
[8] Ying M., Liu W., Zhao X., Et al., Image denoising using trivariate prior model in nonsubsampled dual-tree complex contourlet transform domain and non-local means filter in spatial domain, Optik, 124, 24, pp. 6896-6904, (2013)
[9] Kingsbury N., The dual-tree complex wavelet transform: a new efficient tool for image restoration and enhancement, Proceedings of Europen Signal Processing Conforence, pp. 319-322, (1998)
[10] Kingsbury N., A dual-tree complex wavelet transform with improved orthogonality and symmetry properties, International Conference on Image Processing, 2, pp. 375-378, (2000)

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