Combined higher order non-convex total variation with overlapping group sparsity for impulse noise removal
A typical approach to eliminate impulse noise is to use the l(1)-norm for both the data fidelity term and the regularization terms. However, the l(1)-norm tends to over penalize signal entries which is one of its underpinnings. Hence, we propose a variational model that uses the non-convex l(p)-norm...
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my.um.eprints.263882022-02-25T02:44:24Z http://eprints.um.edu.my/26388/ Combined higher order non-convex total variation with overlapping group sparsity for impulse noise removal Adam, Tarmizi Paramesran, Raveendran Mingming, Yin Ratnavelu, Kuru QA75 Electronic computers. Computer science TA Engineering (General). Civil engineering (General) A typical approach to eliminate impulse noise is to use the l(1)-norm for both the data fidelity term and the regularization terms. However, the l(1)-norm tends to over penalize signal entries which is one of its underpinnings. Hence, we propose a variational model that uses the non-convex l(p)-norm, 0 < p < 1 for both the data fidelity and a second-order total variation regularization term combined with an overlapping group sparse regularizer. Specifically, to robustly eliminate impulse noise, the proposed method uses a non-convex data fidelity term. The hybrid combination of a second-order non-convex total variation and an overlapping group sparse regularization term is used to eliminate the remaining staircase artifacts while maintaining a sharp restored image. A mathematical formulation is derived and to implement it, the iterative re-weighted l(1) (IRL1) based alternating direction method of multipliers (ADMM) is used to solve the constraints and the subproblems. Experimental results for image denoising and deblurring on several widely used standard images demonstrate that the proposed method performed better when compared to the l(1)-norm total variation (TV), total generalized variation (TGV) model, and the non-convex l(p)-norm TV-based data fidelity model in terms of peak signal-to-noise ratio (PSNR) and structure similarity index measure (SSIM). Springer 2021-05 Article PeerReviewed Adam, Tarmizi and Paramesran, Raveendran and Mingming, Yin and Ratnavelu, Kuru (2021) Combined higher order non-convex total variation with overlapping group sparsity for impulse noise removal. Multimedia Tools and Applications, 80 (12). pp. 18503-18530. ISSN 1380-7501, DOI https://doi.org/10.1007/s11042-021-10583-y <https://doi.org/10.1007/s11042-021-10583-y>. 10.1007/s11042-021-10583-y |
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QA75 Electronic computers. Computer science TA Engineering (General). Civil engineering (General) Adam, Tarmizi Paramesran, Raveendran Mingming, Yin Ratnavelu, Kuru Combined higher order non-convex total variation with overlapping group sparsity for impulse noise removal |
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A typical approach to eliminate impulse noise is to use the l(1)-norm for both the data fidelity term and the regularization terms. However, the l(1)-norm tends to over penalize signal entries which is one of its underpinnings. Hence, we propose a variational model that uses the non-convex l(p)-norm, 0 < p < 1 for both the data fidelity and a second-order total variation regularization term combined with an overlapping group sparse regularizer. Specifically, to robustly eliminate impulse noise, the proposed method uses a non-convex data fidelity term. The hybrid combination of a second-order non-convex total variation and an overlapping group sparse regularization term is used to eliminate the remaining staircase artifacts while maintaining a sharp restored image. A mathematical formulation is derived and to implement it, the iterative re-weighted l(1) (IRL1) based alternating direction method of multipliers (ADMM) is used to solve the constraints and the subproblems. Experimental results for image denoising and deblurring on several widely used standard images demonstrate that the proposed method performed better when compared to the l(1)-norm total variation (TV), total generalized variation (TGV) model, and the non-convex l(p)-norm TV-based data fidelity model in terms of peak signal-to-noise ratio (PSNR) and structure similarity index measure (SSIM). |
| format |
Article |
| author |
Adam, Tarmizi Paramesran, Raveendran Mingming, Yin Ratnavelu, Kuru |
| author_facet |
Adam, Tarmizi Paramesran, Raveendran Mingming, Yin Ratnavelu, Kuru |
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Adam, Tarmizi |
| title |
Combined higher order non-convex total variation with overlapping group sparsity for impulse noise removal |
| title_short |
Combined higher order non-convex total variation with overlapping group sparsity for impulse noise removal |
| title_full |
Combined higher order non-convex total variation with overlapping group sparsity for impulse noise removal |
| title_fullStr |
Combined higher order non-convex total variation with overlapping group sparsity for impulse noise removal |
| title_full_unstemmed |
Combined higher order non-convex total variation with overlapping group sparsity for impulse noise removal |
| title_sort |
combined higher order non-convex total variation with overlapping group sparsity for impulse noise removal |
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Springer |
| publishDate |
2021 |
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http://eprints.um.edu.my/26388/ |
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