Decomposed Dissimilarity Measure for Evaluation of Digital Image Denoising

Maliński, Łukasz

doi:10.3390/s23125657

Sensors

2023

DOI: 10.3390/s23125657

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Decomposed Dissimilarity Measure for Evaluation of Digital Image Denoising

Łukasz Maliński

Abstract: A new approach to the evaluation of digital image denoising algorithms is presented. In the proposed method, the mean absolute error (MAE) is decomposed into three components that reflect the different cases of denoising imperfections. Moreover, aim plots are described, which are designed to be a very clear and intuitive form of presentation of the new decomposed measure. Finally, examples of the application of the decomposed MAE and the aim plots in the evaluation of impulsive noise removal algorithms are pre… Show more

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2024

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An efficient lightweight network for image denoising using progressive residual and convolutional attention feature fusion

Tiantian,

Hu,

Guan

2024

Sci Rep

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While deep learning has become the go-to method for image denoising due to its impressive noise removal capabilities, excessive network depth often plagues existing approaches, leading to significant computational burdens. To address this critical bottleneck, we propose a novel lightweight progressive residual and attention mechanism fusion network that effectively alleviates these limitations. This architecture tackles both Gaussian and real-world image noise with exceptional efficacy. Initiated through dense blocks (DB) tasked with discerning the noise distribution, this approach substantially reduces network parameters while comprehensively extracting local image features. The network then adopts a progressive strategy, whereby shallow convolutional features are incrementally integrated with deeper features, establishing a residual fusion framework adept at extracting encompassing global features relevant to noise characteristics. The process concludes by integrating the output feature maps from each DB and the robust edge features from the convolutional attention feature fusion module (CAFFM). These combined elements are then directed to the reconstruction layer, ultimately producing the final denoised image. Empirical analyses conducted in environments characterized by Gaussian white noise and natural noise, spanning noise levels 15–50, indicate a marked enhancement in performance. This assertion is quantitatively corroborated by increased average values in metrics such as Peak Signal-to-Noise Ratio (PSNR), Structural Similarity Index (SSIM), and Feature Similarity Index for Color images (FSIMc), outperforming the outcomes of more than 20 existing methods across six varied datasets. Collectively, the network delineated in this research exhibits exceptional adeptness in image denoising. Simultaneously, it adeptly preserves essential image features such as edges and textures, thereby signifying a notable progression in the domain of image processing. The proposed model finds applicability in a range of image-centric domains, encompassing image processing, computer vision, video analysis, and pattern recognition.

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An efficient lightweight network for image denoising using progressive residual and convolutional attention feature fusion

Tiantian,

Hu,

Guan

2024

Sci Rep

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Decomposed Dissimilarity Measure for Evaluation of Digital Image Denoising

Cited by 1 publication

References 44 publications

An efficient lightweight network for image denoising using progressive residual and convolutional attention feature fusion

An efficient lightweight network for image denoising using progressive residual and convolutional attention feature fusion

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