AI Article Synopsis
- Geometric high-order regularization methods like mean curvature and Gaussian curvature help maintain important image features, but struggle with balancing quality and speed.
- The authors introduce a fast multi-grid algorithm that efficiently minimizes curvature energy functionals without compromising accuracy or requiring extra parameters, enhancing robustness.
- Their method uses domain decomposition for parallel computing and demonstrates significant improvements in image denoising and reconstruction tasks, completing large-scale processing tasks much faster compared to existing methods.
Article Abstract
The geometric high-order regularization methods such as mean curvature and Gaussian curvature, have been intensively studied during the last decades due to their abilities in preserving geometric properties including image edges, corners, and contrast. However, the dilemma between restoration quality and computational efficiency is an essential roadblock for high-order methods. In this paper, we propose fast multi-grid algorithms for minimizing both mean curvature and Gaussian curvature energy functionals without sacrificing accuracy for efficiency. Unlike the existing approaches based on operator splitting and the Augmented Lagrangian method (ALM), no artificial parameters are introduced in our formulation, which guarantees the robustness of the proposed algorithm. Meanwhile, we adopt the domain decomposition method to promote parallel computing and use the fine-to-coarse structure to accelerate convergence. Numerical experiments are presented on image denoising, CT, and MRI reconstruction problems to demonstrate the superiority of our method in preserving geometric structures and fine details. The proposed method is also shown effective in dealing with large-scale image processing problems by recovering an image of size 1024×1024 within 40s, while the ALM method [1] requires around 200s.
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Article Synopsis
- Geometric high-order regularization methods like mean curvature and Gaussian curvature help maintain important image features, but struggle with balancing quality and speed.
- The authors introduce a fast multi-grid algorithm that efficiently minimizes curvature energy functionals without compromising accuracy or requiring extra parameters, enhancing robustness.
- Their method uses domain decomposition for parallel computing and demonstrates significant improvements in image denoising and reconstruction tasks, completing large-scale processing tasks much faster compared to existing methods.
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