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

[2] J Y Ma, Y Ma, C Li. Infrared and visible image fusion methods and applications: A survey. Information Fusion, 45, 153-178(2019).

[3] N J Short, A J Yuffa, G Videen, et al. Effects of surface materials on polarimetric-thermal measurements: Applications to face recognition. Applied Optics, 55, 5226-5233(2016).

[4] Heo J, Kong S G, Abidi B R. Fusion of visual thermal signatures with eyeglass removal f robust face recognition[C]Computer Vision Pattern Recognition Wkshop, 2004,19: 122127.

[5] Kumar K S, Kavitha G, Subramanian R, et al. MATLABA Ubiquitous Tool f the Practical Engineer[M]. Croatia: In Tech, 2011: 307326.

[6] J C Castillo, A Fernandez-Caballero, J Serrano-Cuerda, et al. Smart environment architecture for robust people detection by infrared and visible video fusion. Journal of Ambient Intelligence and Humanized Computing, 8, 223-237(2017).

[7] E Fendri, R R Boukhriss, M Hammami. Fusion of thermal infrared and visible spectra for robust moving object detection. Pattern Analysis and Applications, 20, 907-926(2017).

[8] A Apatean, A Rogozan, A Bensrhair. Visible-infrared fusion schemes for road obstacle classification. Transportation Research Part C-Emerging Technologies, 35, 180-192(2013).

[9] D M Bulanon, T F Burks, V Alchanatis. Image fusion of visible and thermal images for fruit detection. Biosystems Engineering, 103, 12-22(2009).

[10] S E A Raza, V Sanchez, G Prince, et al. Registration of thermal and visible light images of diseased plants using silhouette extraction in the wavelet domain. Pattern Recognition, 48, 2119-2128(2015).

[11] P Burt, E Adelson. The laplacian pyramid as a compact image code. IEEE Transations on Communications, 31, 532-540(1983).

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

[13] A Toet, L J Vanruyven, J M Valeton. Merging thermal and visual images by a contrast pyramid. Optical Engineering, 28, 789-792(1989).

[14] A Toet. A morphological pyramidal image decomposition. Pattern Recognition Letters, 9, 255-261(1989).

[15] W T Freeman, E H Adelson, M Intell. The design and use of steerable filters. IEEE Transpattern Anal, 13, 891-906(1991).

[16] X L Yu, J L Ren, Q Chen, et al. A false color image fusion method based on multi-resolution color transfer in normalization YCBCR space. Optik, 125, 6010-6016(2014).

[17] H Y Jin, L C Jiao, F Liu, et al. Fusion of infrared and visual images based on contrast pyramid directional filter banks using clonal selection optimizing. Optical Engineering, 47, 27002-27008(2008).

[18] He D X, Meng Y, Wang C Y. Contrast pyra based image fusion scheme f infrared image visible image[C]2011 IEEE International Geoscience Remote Sensing Symposium, 2011: 597600.

[19] A Grossmann, J Morlet. Decomposition of hardy functions into square integrable wavelets of constant shape. Siam Journal on Mathematical Analysis, 15, 723-736(1984).

[20] S G Mallat. A theory for multiresolution signal decomposition-the wavelet representation. IEEE Transactions on Pattern Analysis and Machine Intelligence, 11, 674-693(1989).

[21] Y Niu, S Xu, L Wu, et al. Airborne infrared and visible image fusion for target perception based on target region segmentation and discrete wavelet transform. Mathematical Problems in Engineering, 2012, 732-748(2012).

[22] K Madheswari, N Venkateswaran. Swarm intelligence based optimisation in thermal image fusion using dual tree discrete wavelet transform. Quantitative Infrared Thermography Journal, 14, 24-43(2017).

[23] Y Zou, X Liang, T Wang. Visible and infrared image fusion using the lifting wavelet. Telkomnika Indonesian Journal of Electrical Engineering, 11, 6290-6295(2013).

[24] P F Chai, X Q Luo, Z C Zhang. Image fusion using quaternion wavelet transform and multiple features. IEEE Access, 5, 6724-6734(2017).

[25] X Yan, H L Qin, J Li, et al. Infrared and visible image fusion with spectral graph wavelet transform. Journal of the Optical Society of America a-Optics Image Science and Vision, 32, 1643-1652(2015).

[26] G Q Tao, D P Li, G H Lu. On image fusion based on different fusion rules of wavelet transform. Acta Photonica Sinica, 33, 221-224(2004).

[27] I W Selesnick, R G Baraniuk, N G Kingsbury. The dual-tree complex wavelet transform. IEEE Signal Processing Magazine, 22, 123-151(2005).

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

[29] Yin S, Cao L, Tan Q, et al. Infrared visible image fusion based on NSCT fuzzy logic[C]Proceedings of the 2010 IEEE International Conference on Mechatronics Automation, 2010,5: 671675.

[30] H X Liu, T H Zhu, J J Zhao. Infrared and visible image fusion based on region of interest detection and nonsubsampled contourlet transform. Journal of Shanghai Jiaotong University (Science), 18, 526-534(2013).

[31] K Guo, D Labate. Optimally sparse multidimensional representation using shearlets. Siam Journal on Mathematical Analysis, 39, 298-318(2007).

[32] G Easley, D Labate, W Q Lim. Sparse directional image representations using the discrete shearlet transform. Applied and Computational Harmonic Analysis, 25, 25-46(2008).

[33] W W Kong, B H Wang, Y Lei. Technique for infrared and visible image fusion based on non-subsampled shearlet transform and spiking cortical model. Infrared Physics & Technology, 71, 87-98(2015).

[34] W Kong, Y Lei, H Zhao. Adaptive fusion method of visible light and infrared images based on non-subsampled shearlet transform and fast non-negative matrix factorization. Infrared Physics & Technology, 67, 161-172(2014).

[35] H M Hu, J W Wu, B Li, et al. An adaptive fusion algorithm for visible and infrared videos based on entropy and the cumulative distribution of gray levels. IEEE Transactions on Multimedia, 19, 2706-2719(2017).

[36] X Y Zhang, Y Ma, F Fan, et al. Infrared and visible image fusion via saliency analysis and local edge-preserving multi-scale decomposition. Journal of the Optical Society of America a-Optics Image Science and Vision, 34, 1400-1410(2017).

[37] B Yang, S T Li. Multifocus image fusion and restoration with sparse representation. IEEE Transactions on Instrumentation and Measurement, 59, 884-892(2010).

[38] Y Liu, S P Liu, Z F Wang. A general framework for image fusion based on multi-scale transform and sparse representation. Information Fusion, 24, 147-164(2015).

[39] H T Yin. Sparse representation with learned multiscale dictionary for image fusion. Neurocomputing, 148, 600-610(2015).

[40] B Yang, S T Li. Pixel-level image fusion with simultaneous orthogonal matching pursuit. Information Fusion, 13, 10-19(2012).

[41] Y Liu, Z F Wang. Simultaneous image fusion and denoising with adaptive sparse representation. Iet Image Processing, 9, 347-357(2015).

[42] H T Yin, S T Li. Multimodal image fusion with joint sparsity model. Optical Engineering, 50, 067007-067009(2011).

[43] M Nejati, S Samavi, S Shirani. Multi-focus image fusion using dictionary-based sparse representation. Information Fusion, 25, 72-84(2015).

[44] J Wang, J Y Peng, X Y Feng, et al. Fusion method for infrared and visible images by using non-negative sparse representation. Infrared Physics & Technology, 67, 477-489(2014).

[45] Q Zhang, M D Levine. Robust multi-focus image fusion using multi-task sparse representation and spatial context. IEEE Transactions on Image Processing, 25, 2045-2058(2016).

[46] Q H Zhang, Y L Fu, H F Li, et al. Dictionary learning method for joint sparse representation-based image fusion. Optical Engineering, 52, 1-11(2013).

[47] N N Yu, T S Qiu, F Bi, et al. Image features extraction and fusion based on joint sparse representation. IEEE Journal of Selected Topics in Signal Processing, 5, 1074-1082(2011).

[48] Engan K, Aase S O, Husoy J H. Method of optimal directions f frame design[C]1999 IEEE International Conference on Acoustics, Speech, Signal Processing,1999: 24432446.

[49] M Aharon, M Elad, A Bruckstein. K-SVD: An algorithm for designing overcomplete dictionaries for sparse representation. IEEE Transactions on Signal Processing, 54, 4311-4322(2006).

[50] R Rubinstein, M Zibulevsky, M Elad. Double sparsity: Learning sparse dictionaries for sparse signal approximation. IEEE Transactions on Signal Processing, 58, 1553-1564(2010).

[51] M Kim, D K Han, H Ko. Joint patch clustering-based dictionary learning for multimodal image fusion. Information Fusion, 27, 198-214(2016).

[52] Dong W S, Li X, Zhang L, et al. Sparsitybased image denoising via dictionary learning structural clustering[C]2011 IEEE Conference on Computer Vision Pattern Recognition (CVPR), 2011: 457464.

[53] P Chatterjee, P Milanfar. Clustering-based denoising with locally learned dictionaries. IEEE Transactions on Image Processing, 18, 1438-1451(2009).

[54] Y Yao, P Guo, X Xin, et al. Image fusion by hierarchical joint sparse representation. Cognitive Computation, 6, 281-292(2014).

[55] B Ophir, M Lustig, M Elad. Multi-scale dictionary learning using wavelets. IEEE Journal of Selected Topics in Signal Processing, 5, 1014-1024(2011).

[56] X Q Lu, B H Zhang, Y Zhao, et al. Theinfrared and visible image fusion algorithm based on target separation and sparse representation. Infrared Physics & Technology, 67, 397-407(2014).

[57] Z Q Zhu, H P Yin, Y Chai, et al. A novel multi-modality image fusion method based on image decomposition and sparse representation. Information Sciences, 432, 516-529(2018).

[58] K P Wang, G Q Qi, Z Q Zhu, et al. A novel geometric dictionary construction approach for sparse representation based image fusion. Entropy, 19, 306(2017).

[59] Q Zhang, Y Liu, R S Blum, et al. Sparse representation based multi-sensor image fusion for multi-focus and multi-modality images: A review. Information Fusion, 40, 57-75(2018).

[60] W W Kong, L J Zhang, Y Lei. Novel fusion method for visible light and infrared images based on NSST-SF-PCNN. Infrared Physics & Technology, 65, 103-112(2014).

[61] T Z Xiang, L Yan, R R Gao. A fusion algorithm for infrared and visible images based on adaptive dual-channel unit-linking PCNN in NSCT domain. Infrared Physics & Technology, 69, 53-61(2015).

[62] Ma L J, Zhao C H. An effective image fusion method based on nonsubsampled contourlet transfm pulse coupled neural wk[C]Proceedings of the 2nd International Conference on Computer Infmation Applications (ICCIA 2012), 2012: 812.

[63] Li Y, Song GH, Yang SC. Multisens image fusion by NSCTPCNN transfm[C]2011 IEEE International Conference on Computer Science Automation Engineering, 2011: 638642.

[64] W W Kong, Y J Lei, Y Lei, et al. Image fusion technique based on non-subsampled contourlet transform and adaptive unit-fast-linking pulse-coupled neural network. Iet Image Processing, 5, 113-121(2011).

[65] X B Qu, J W Yan, H Z Xiao, et al. Image fusion algorithm based on spatia frequency-motivated pulse coupled neural networks in nonsubsampled contourlet transform Domain. Acta Automatica Sinica, 12, 1508-1514(2009).

[66] G S El-taweel, A K Helmy. Image fusion scheme based on modified dual pulse coupled neural network. Iet Image Processing, 7, 407-414(2013).

[67] Z Yu, L Yan, N Han, et al. Image fusion algorithm based on contourlet transform and PCNN for detecting obstacles in forests. Cybernetics and Information Technologies, 15, 116-125(2015).

[68] S Liu, Y Piao, M Tahir. Research on fusion technology based on low-light visible image and infrared image. Optical Engineering, 55, 123104(2016).

[69] Li H, Wu X J, Kittler J. Infrared visible image fusion using a deep learning framewk[C]2018 24th International Conference on Pattern Recognition, 2018: 27052710.

[70] Ren X, Meng F, Hu T, et al. Infraredvisible image fusion based on convolutional neural wks (CNN)[C]International Conference on Intelligent Science Big Data Engineering, 2018: 301307.

[71] J Y Ma, W Yu, P W Liang, et al. FusionGAN: A generative adversarial network for infrared and visible image fusion. Information Fusion, 48, 11-26(2019).

[72] H Li, L Liu, W Huang, et al. An improved fusion algorithm for infrared and visible images based on multi-scale transform. Infrared Physics & Technology, 74, 28-37(2016).

[73] Z Z Fu, X Wang, J Xu, et al. Infrared and visible images fusion based on RPCA and NSCT. Infrared Physics & Technology, 77, 114-123(2016).

[74] N Cvejic, D Bull, N Canagarajah. Region-based multimodal image fusion using ICA bases. IEEE Sensors Journal, 7, 743-751(2007).

[75] Mou J, Gao W, Song Z. Image fusion based on nonnegative matrix factization infrared feature extraction[C] 2013 6th International Congress on Image Signal Processing (CISP), 2013: 10461050.

[76] Z W Liu, Y Feng, H Chen, et al. A fusion algorithm for infrared and visible based on guided filtering and phase congruency in NSST domain. Optics and Lasers in Engineering, 97, 71-77(2017).

[77] D P Bavirisetti, R Dhuli. Two-scale image fusion of visible and infrared images using saliency detection. Infrared Physics & Technology, 76, 52-64(2016).

[78] W Gan, X H Wu, W Wu, et al. Infrared and visible image fusion with the use of multi-scale edge-preserving decomposition and guided image filter. Infrared Physics & Technology, 72, 37-51(2015).

[79] G M Cui, H J Feng, Z H Xu, et al. Detail preserved fusion of visible and infrared images using regional saliency extraction and multi-scale image decomposition. Optics Communications, 341, 199-209(2015).

[80] J F Zhao, Q Zhou, Y T Chen, et al. Fusion of visible and infrared images using saliency analysis and detail preserving based image decomposition. Infrared Physics & Technology, 56, 93-99(2013).

[81] B H Zhang, X Q Lu, H Q Pei, et al. A fusion algorithm for infrared and visible images based on saliency analysis and non-subsampled shearlet transform. Infrared Physics & Technology, 73, 286-297(2015).

[82] F Meng, M Song, B Guo, et al. Image fusion based on object region detection and non-subsampled contourlet transform. Computers & Electrical Engineering, 62, 375-383(2017).

[83] J J Cai, Q M Cheng, M J Peng, et al. Fusion of infrared and visible images based on nonsubsampled contourlet transform and sparse K-SVD dictionary learning. Infrared Physics & Technology, 82, 85-95(2017).

[84] M Yin, P H Duan, W Liu, et al. A novel infrared and visible image fusion algorithm based on shift-invariant dual-tree complex shearlet transform and sparse representation. Neurocomputing, 226, 182-191(2017).

[85] Y Chai, H F Li, J F Qu. Image fusion scheme using a novel dual-channel PCNN in lifting stationary wavelet domain. Optics Communications, 283, 3591-3602(2010).

[86] B Yang, S T Li. Visual attention guided image fusion with sparse representation. Optik, 125, 4881-4888(2014).

[87] C H Liu, Y Qi, W R Ding. Infrared and visible image fusion method based on saliency detection in sparse domain. Infrared Physics & Technology, 83, 94-102(2017).

[88] W W Kong. Technique for gray-scale visual light and infrared image fusion based on non-subsampled shearlet transform. Infrared Physics & Technology, 63, 110-118(2014).

[89] J H Adu, J H Gan, Y Wang, et al. Image fusion based on nonsubsampled contourlet transform for infrared and visible light image. Infrared Physics & Technology, 61, 94-100(2013).

[90] Z Liu, K Tsukada, K Hanasaki, et al. Image fusion by using steerable pyramid. Pattern Recognition Letters, 22, 929-939(2001).

[91] Liu G, L Jing Z, Y Sun S, et al. Image fusion based on expectation maximization algorithm and steerable pyramid. Chinese Optics Letters, 2, 18-21(2004).

[92] Deng H, Ma Y. Image Fusion based on steerable pyra PCNN[C]2009 Second International Conference on the Applications of Digital Infmation Web Technologies, 2009: 569573.

[93] L Zhan, Y Zhuang, L Huang. Infrared and visible images fusion method based on discrete wavelet transform. Journal of Computers, 28, 057-071(2017).

[94] J Saeedi, K Faez. Infrared and visible image fusion using fuzzy logic and population-based optimization. Applied Soft Computing, 12, 1041-1054(2012).

[95] L H Chang, X C Feng, R Zhang, et al. Image decomposition fusion method based on sparse representation and neural network. Applied Optics, 56, 7969-7977(2017).

[96] Omri F, Foufou S, Abidi M. NIR visible image fusion f improving face recognition at long distance[C]International Conference on Image Signal Processing, 2014: 549557.

[97] Singh S, Gyaourova A, Bebis G, et al. Infrared visible image fusion f face recognition[C]Biometric Technology f Human Identification, International Society f Optics Photonics, 2004: 585596.

[98] Heo J, Kong S G, Abidi B R, et al. Fusion of visual thermal signatures with eyeglass removal f robust face recognition[C]2004 Conference on Computer Vision Pattern Recognition Wkshop, 2004: 122122.

[99] A Abaza, T Bourlai. On ear-based human identification in the mid-wave infrared spectrum. Image Vision Computing, 31, 640-648(2013).

[100] M Uzair, A Mahmood, A Mian, et al. Periocular region-based person identification in the visible, infrared and hyperspectral Imagery. Neurocomputing, 149, 854-867(2015).

[101] J G Han, E J Pauwels, Zeeuw P de. Fast saliency-aware multi-modality image fusion. Neurocomputing, 111, 70-80(2013).

[102] Schnelle S R, Chan A L. Enhanced target tracking through infraredvisible image fusion[C]14th International Conference on Infmation Fusion, 2011: 18.

[103] X Jin, Q Jiang, S W Yao, et al. A survey of infrared and visual image fusion methods. Infrared Physics & Technology, 85, 478-501(2017).

[104] A Toet. Natural colour mapping for multiband nightvision imagery. Information Fusion, 4, 155-166(2003).

[105] A Toet, M A Hogervorst. Progress in color night vision. Optical Engineering, 51, 010901(2012).

[106] J W Davis, V Sharma. Background-subtraction using contour-based fusion of thermal and visible imagery. Computer Vision and Image Understanding, 107, 162-182(2007).

[107] Y F Niu, S T Xu, L Z Wu, et al. Airborne infrared and visible image fusion for target perception based on target region segmentation and discrete wavelet transform. Mathematical Problems in Engineering, 10, 732-748(2012).

[108] G Bhatnagar, Z Liu. A novel image fusion framework for night-vision navigation and surveillance. Signal Image and Video Processing, 9, 165-175(2015).

[109] N Paramanandham, K Rajendiran. Multi sensor image fusion for surveillance applications using hybrid image fusion algorithm. Multimedia Tools and Applications, 77, 12405-12436(2018).

[110] V Tsagaris, V Anastassopoulos. Fusion of visible and infrared imagery for night color vision. Displays, 26, 191-196(2005).

[111] M A Hogervorst, A Toet. Fast natural color mapping for night-time imagery. Information Fusion, 11, 69-77(2010).

[112] F Mendoza, R F Lu, H Y Cen. Comparison and fusion of four nondestructive sensors for predicting apple fruit firmness and soluble solids content. Postharvest Biology and Technology, 73, 89-98(2012).

[113] B V Hanna, A M Gorbach, F A Gage, et al. Intraoperative assessment of critical biliary structures with visible range/infrared image fusion. Journal of the American College of Surgeons, 206, 1227-1231(2008).

[114] M Eslami, A Mohammadzadeh. Developing a spectral-based strategy for urban object detection from airborne hyperspectral TIR and visible data. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 9, 1808-1816(2016).

[115] L Han, B Wulie, Y L Yang, et al. Direct fusion of geostationary meteorological satellite visible and infrared images based on thermal physical properties. Sensors, 15, 703-714(2015).

[116] H G Li, W R Ding, X B Cao, et al. Image registration and fusion of visible and infrared integrated camera for medium-altitude unmanned aerial vehicle remote sensing. Remote Sensing, 9, 441-469(2017).

[117] X Chang, L C Jiao, F Liu, et al. Multicontourlet-based adaptive fusion of infrared and visible remote sensing images. IEEE Geoscience and Remote Sensing Letters, 7, 549-553(2010).

[118] X C Lu, J P Zhang, T Li, et al. Synergetic classification of long-wave infrared hyperspectral and visible images. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 8, 3546-3557(2015).

[119] M Gargano, D Bertani, M Greco, et al. A perceptual approach to the fusion of visible and NIR images in the examination of ancient documents. Journal of Cultural Heritage, 16, 518-525(2015).

[120] S J Kim, F Deng, M S Brown. Visual enhancement of old documents with hyperspectral imaging. Pattern Recognition, 44, 1461-1469(2011).

[121] Z J Feng, X L Zhang, L Y Yuan, et al. Infrared target detection and location for visual surveillance using fusion scheme of visible and infrared images. Mathematical Problems in Engineering, 2013, 831-842(2013).

[122] C Zhao, Y Guo, Y Wang. A fast fusion scheme for infrared and visible light images in NSCT domain. Infrared Physics & Technology, 72, 266-275(2015).

[123] X L Zhang, X F Li, J Li. Validation and correlation analysis of metrics for evaluation performance of image fusion. Acta Automatica Sinica, 40, 306-315(2014).

[124] V Aardt, an J. Assessment of image fusion procedures using entropy, image quality, and multispectral classification. Journal of Applied Remote Sensing, 2, 1-28(2008).

[125] J Yun, ao R. In-fibre Bragg grating sensors. Measurement Science Technology, 8, 355(1997).

[126] X X Zhu, R Bamler. A sparse image fusion algorithm with application to pan-sharpening. IEEE Transactions on Geoscience Remote Sensing, 51, 2827-2836(2012).

[127] C S Xydeas, P V V.. Objective image fusion performance measure. Military Technical Courier, 56, 181-193(2000).

[128] M Deshmukh, U Bhosale. Image fusion and image quality assessment of fused images. International Journal of Image Processing, 4, 484-508(2010).

[129] Z Wang, A C Bovik, H R Sheikh, et al. Image quality assessment: From error visibility to structural similarity. IEEE Trans Image Process, 13, 600-612(2004).

[130] S Li, B Yang, J Hu. Performance comparison of different multi-resolution transforms for image fusion. Information Fusion, 12, 74-84(2011).

[131] X B Qu, J W Yan, H Z Xiao, et al. Image fusion algorithm based on spatial frequency-motivated pulse coupled neural networks in nonsubsampled contourlet transform domain. Acta Automatica Sinica, 34, 1508-1514(2008).