Low-light image enhancement is a classical computer vision problem aiming to recover normal-exposure images from low-light images. However, convolutional neural networks commonly used in this field are good at sampling low-frequency local structural features in the spatial domain, which leads to unclear texture details of the reconstructed images. To alleviate this problem, we propose a novel module using the Fourier coefficients, which can recover high-quality texture details under the constraint of semantics in the frequency phase and supplement the spatial domain. In addition, we design a simple and efficient module for the image spatial domain using dilated convolutions with different receptive fields to alleviate the loss of detail caused by frequent downsampling. We integrate the above parts into an end-to-end dual branch network and design a novel loss committee and an adaptive fusion module to guide the network to flexibly combine spatial and frequency domain features to generate more pleasing visual effects. Finally, we evaluate the proposed network on public benchmarks. Extensive experimental results show that our method outperforms many existing state-of-the-art ones, showing outstanding performance and potential.
翻译:低光图像增强是一个典型的计算机视觉问题,目的是从低光图像中恢复正常接触图像。然而,这个领域常用的进化神经网络在空间域中取样低频局部结构特征方面十分有用,这导致重建图像的纹理细节不明确。为了缓解这一问题,我们提议使用Fourier 系数建立一个新模块,在频率阶段的语义限制下恢复高质量的纹理细节并补充空间域。此外,我们设计了一个简单而高效的图像空间域模块,利用与不同接收域的变相组合来减轻频繁下标造成的细节损失。我们将以上部分纳入一个端到端双分支网络,并设计一个新的损失委员会和适应性融合模块,以指导网络灵活地将空间和频域特征结合起来,产生更令人愉快的视觉效果。最后,我们评估了公共基准的拟议网络。广泛的实验结果显示,我们的方法超越了许多现有的状态,显示了杰出的性能和潜力。