Abstract:Recent deep learning-based methods have reconstructed a high dynamic range (HDR) image from a single low dynamic range (LDR) image by focusing on the exposure transfer task to reconstruct the multi-exposure stack. However, these methods often fail to fuse the multi-exposure stack into a perceptually pleasant HDR image as the local inversion artifacts are formed in the HDR imaging (HDRI) process. The artifacts arise from the impossibility of learning the whole HDRI process due to its non-differentiable structure of the camera response recovery. Therefore, we tackle the major challenge in stack reconstruction-based methods by proposing a novel framework with the fully differentiable HDRI process. Our framework enables a neural network to train the HDR image generation based on the end-to-end structure. Hence, a deep neural network can train the precise correlations between multi-exposure images in the HDRI process using our differentiable HDR synthesis layer. In addition, our network uses the image decomposition and the recursive process to facilitate the exposure transfer task and to adaptively respond to recursion frequency. The experimental results show that the proposed network outperforms the state-of-the-art quatitative and qualitative results in terms of both the exposure transfer tasks and the whole HDRI process.