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Volume 21, Issue 1
  • ISSN: 1573-4056
  • E-ISSN: 1875-6603
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Abstract

Introduction

The noise emergence in the digital image can occur throughout image acquisition, transmission, and processing steps. Consequently, eliminating the noise from the digital image is required before further processing. This study aims to denoise noisy images (including Magnetic Resonance Images ()) by employing our proposed image denoising approach.

Methods

This proposed approach is based on the Stationary Wavelet Transform () and the Dual-Tree Discrete Wavelet Transform (). The first step of this approach consists of applying the Dual-Tree to the noisy image to obtain noisy wavelet coefficients. The second step of this approach consists of denoising each of these coefficients by applying an 2- based denoising technique. The denoised image is finally obtained by applying the inverse of the 2-D Dual-Tree to the denoised coefficients obtained in the second step. The proposed image denoising approach is evaluated by comparing it to four denoising techniques existing in literature. The latters are the image denoising technique based on thresholding in the domain, the image denoising technique based on deep neural network, the image denoising technique based on soft thresholding in the domain of 2-D Dual-Tree DWT, and Non-local Means Filter.

Results

The proposed denoising approach, and the other four techniques previously mentioned, are applied to a number of noisy grey scale images and noisy Magnetic Resonance Images () and the obtained results are in terms of (Peak Signal to Noise Ratio), (Structural Similarity), (Normalized Mean Square Error) and Feature Similarity (). These results show that the proposed image denoising approach outperforms the other denoising techniques applied for our evaluation.

Discussion

In comparison with the four denoising techniques applied for our evaluation, the proposed approach permits to obtain highest values of , and and the lowest values of . Moreover, in cases where the noise level or , this approach permits the elimination of the noise from the noisy images and introduces slight distortions on the details of the original images. However, in case where or , this approach eliminates a great part of the noise and introduces some distortions on the original images.

Conclusion

The performance of this approach is proven by comparing it to four image denoising techniques existing in literature. These techniques are the denoising technique based on thresholding in the SWT-2D domain, the image denoising technique based on a deep neural network, the image denoising technique based on soft thresholding in the domain of Dual-Tree and the Non-local Means Filter. All these denoising techniques, including our approach, are applied to a number of noisy grey scale images and noisy , and the obtained results are in terms of (Peak Signal to Noise Ratio), (Structural Similarity), (Normalized Mean Square Error) and (Feature Similarity). These results show that this proposed approach outperforms the four denoising techniques applied for our evaluation.

© 2025 The Author(s). Published by Bentham Science Publishers.
This is an open access article published under CC BY 4.0 https://creativecommons.org/licenses/by/4.0/legalcode
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2025-07-07
2025-10-29

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/content/journals/cmir/10.2174/0115734056365765250630140748
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2-D Stationary Wavelet Transform and 2-D Dual-Tree DWT for MRI Denoising
Curr. Med. Imaging 21, E15734056365765 (2025); https://doi.org/10.2174/0115734056365765250630140748
/content/journals/cmir/10.2174/0115734056365765250630140748
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  • Article Type:     Research Article
Keyword(s): 2D Dual-Tree DWT; Denoising techniques; Feature Similarity; MR Image; SWT-2D; Thresholding

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