[3] CHEN Jun, LI Xuejiao, LUO Linbo, et al. Infrared and visible image fusion based on target-enhanced multiscale transform decomposition[J]. Information Sciences, 2020, 508: 64-78.

[4] LI G, LIN Y, QU X. An infrared and visible image fusion method based on multi-scale transformation and norm optimization[J]. Information Fusion, 2021, 71(2): 109-129.

[5] ZHANG S, LI X, ZHANG X, et al. Infrared and visible image fusion based on saliency detection and two-scale transform decomposition[J]. Infrared Physics & Technology, 2021, 114(3): 103626.

[9] Hussain K F, Mahmoud R. Efficient poisson image editing[J]. Electronic Letters on Computer Vision and Image Analysis, 2015, 14(2): 45-57.

[10] Chandani P, Nayak S. Generative adversarial networks: an overview[J]. Journal of Critical Reviews, 2020, 7(3): 753-758.

[11] MOON S. ReLU network with bounded width is a universal approximator in view of an approximate identity[J]. Applied Sciences, 2021, 11(1): 427-427.

[12] WU S, LI G, DENG L, et al. L1-norm batch normalization for efficient training of deep neural networks[J]. IEEE Transactions on Neural Networks and Learning Systems, 2019, 30(7): 2043-2051.

[13] Abdeimotaal H, Abdou A, Omar A, et al. Pix2pix conditional generative adversarial networks for scheimpflug camera color-coded corneal tomography image generation[J]. Translational Vision Science and Technology, 2021, 10(7): 21-21.

[17] CHEN J, LI X, LUO L, et al. Infrared and visible image fusion based on target-enhanced multiscale transform decomposition[J]. Information Sciences, 2020, 508: 64-78.

[19] KONG X, LIU L, QIAN Y, et al. Infrared and visible image fusion using structure-transferring fusion method[J]. Infrared Physics & Technology, 2019, 98: 161-173.