Abstract
To solve the problems such as obvious speckle noise and serious spectral distortion when existing fusion methods are applied to the fusion of optical and SAR images, this paper proposes a fusion method for optical and SAR images based on Dense-UGAN and Gram–Schmidt transformation. Firstly, dense connection with U-shaped network (Dense-UGAN) are used in GAN generator to deepen the network structure and obtain deeper source image information. Secondly, according to the particularity of SAR imaging mechanism, SGLCM loss for preserving SAR texture features and PSNR loss for reducing SAR speckle noise are introduced into the generator loss function. Meanwhile in order to keep more SAR image structure, SSIM loss is introduced to discriminator loss function to make the generated image retain more spatial features. In this way, the generated high-resolution image has both optical contour characteristics and SAR texture characteristics. Finally, the GS transformation of optical and generated image retains the necessary spectral properties. Experimental results show that the proposed method can well preserve the spectral information of optical images and texture information of SAR images, and also reduce the generation of speckle noise at the same time. The metrics are superior to other algorithms that currently perform well.
Highlights
This paper presents the theory of generative adversarial network and Gram–Schmidt transform, introduces the Dense‐U network into the GAN generator to ob‐
The Peak signal-to-noise ratio (PSNR) and SGLCM loss are introduced into the generator loss function, and the structural similarity (SSIM) loss is introduced into the discriminator to optimize the network parame‐
PSNR and SGLCM loss are introduced into the generator loss function, and the SSIM loss is introduced into the discriminator to optimize the network parameters and obtain the best network model
Summary
The model is widely used in image generation, style transfer, data enhancement and other fields In this network, the input of the generator is random noise z, after being processed by the generator, the output data G (z) is input into the discriminator D for judgment, and D will output a true or false judgment result, and discriminator D. In this network, the input of the generator is of 17 random noise z, after being processed by the generator, the output data G z is input3in‐
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