A mixed model with multi-fidelity terms and nonlocal low rank regularization for natural image noise removal

Abstract

Reconstructing an original image from its corrupted observation is an important and fundamental problem in many image processing applications. Generally, the L1-norm or L2-norm combined with a regularization term (the total variation (TV), total generalized variation (TGV) or nuclear norm) is used to fit the impulse noise and Gaussian noise, respectively. However, these methods can only be used to remove a single type of noise from images, and traditional regularization terms often have difficulties in capturing some important prior knowledge of images, such as nonlocal self-similarity, low rank and sparsity. To overcome the above issues, we propose a mixed noise removal model with L1-L2 fidelity terms and a popular nonlocal low-rank regularization term, which has been shown to have more effective image denoising performance than traditional regularization methods. To solve this model, the split Bregman iteration method (SBIM) is adopted to decompose the difficult minimization optimization problem into four simple subproblems. Extensive experiments on natural images demonstrate that the effectiveness of the proposed method is better than that of other state-of-the-art methods.