Photographs captured by smartphones and mid-range cameras have limited spatial resolution and dynamic range, with noisy response in underexposed regions and color artefacts in saturated areas. This paper introduces the first approach (to the best of our knowledge) to the reconstruction of high-resolution, high-dynamic range color images from raw photographic bursts captured by a handheld camera with exposure bracketing. This method uses a physically-accurate model of image formation to combine an iterative optimization algorithm for solving the corresponding inverse problem with a learned image representation for robust alignment and a learned natural image prior. The proposed algorithm is fast, with low memory requirements compared to state-of-the-art learning-based approaches to image restoration, and features that are learned end to end from synthetic yet realistic data. Extensive experiments demonstrate its excellent performance with super-resolution factors of up to $\times 4$ on real photographs taken in the wild with hand-held cameras, and high robustness to low-light conditions, noise, camera shake, and moderate object motion.
翻译:智能手机和中程照相机拍摄的照片的空间分辨率和动态范围有限,在未充分暴露的区域和饱和地区的彩色工艺品中反应吵闹,本文介绍了重建高分辨率高动态彩色图像的第一种办法(最符合我们的知识),即用带接触括号的手持照相机拍摄的原生摄影镜头拍摄的高分辨率、高动态彩色图像。这种方法使用物理精确的图像形成模型来结合迭代优化算法,以解决对应的反向问题,先用学习的图像表示方式进行稳健调整,再用学习的自然图像表示。提议的算法是快速的,与最先进的基于学习的图像恢复方法相比,记忆要求较低,并且从合成的、现实的数据中学习到结尾的特征。广泛的实验展示了在野外拍摄的超分辨率因子高达4美元的优异度表现,用手持照相机拍摄的真照片对低光度、噪音、相机摇晃动和中度物体运动的高度坚固度。