利用 CNN 与变压器相结合的网络提高地震图像分辨率

Tie Zhong;Kaiyuan Zheng;Shiqi Dong;Xunqian Tong;Xintong Dong
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引用次数: 0

摘要

地震图像的质量往往受到采集条件的限制和噪声干扰的影响,导致地震图像分辨率低,对后续地质解释产生误导。虽然基于卷积神经网络(CNN)的地震图像超分辨率方法表现良好,但由于 CNN 受感受野的限制,对相距较远的像素之间关系的感知能力较弱,弱事件尤其是深事件的质量仍有待提高。在这封信中,我们通过设计一种 CNN 和变换器的组合网络(CNCT)来解决这个问题。CNCT 由三部分组成:边缘特征融合块(EFB)、深度特征挖掘块(DMB)和特征增强块(FEB)。EFB 的目的是融合输入的低分辨率(LR)图像和通过 Sobel 算法获得的相应边缘,并执行初步的浅层特征提取。DMB 通过堆叠残差块来挖掘更深层次的特征,每个残差块通过结合变换器和 CNN,充分利用其对全局和局部信息的出色感知能力。最后,FEB 利用子像素卷积进行上采样,以扩大特征图的大小。在合成数据和实地数据上的实验结果表明,CNCT 不仅在感知效果和纹理细节上优于其他深度学习(DL)方法,而且还能抑制噪声并提高主频。
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Enhancing the Resolution of Seismic Images With a Network Combining CNN and Transformer
The quality of seismic images is often affected by the limitation of acquisition conditions and the interference of noises, which causes the low resolution of seismic images and misleads the following geological interpretation. Although the super-resolution method for seismic images based on convolutional neural network (CNN) has behaved well, the quality of weak events especially deep events is still need to be improved, due to CNN is limited by the receptive fields, which results in weaker ability to perceive relationships among pixels far apart. In this letter, we solve this problem by designing a combination network of CNN and transformer (CNCT). CNCT consists of three parts, edge feature fusion block (EFB), deep feature mining block (DMB), and feature enhancement block (FEB). The EFB aims to fuse the input low-resolution (LR) image and the corresponding edges obtained by the Sobel algorithm and performs preliminary shallow feature extraction. DMB mines deeper features by stacking residual blocks, and each residual block makes full use of its excellent perception of global and local information by combining transformer and CNN. Finally, the FEB uses subpixel convolution for upsampling to expand the size of feature maps. The experimental results on synthetic data and field data show that CNCT not only behaves better on perception effect and texture details than that of other deep learning (DL) methods but also can suppress noise and improve the dominant frequency.
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