Abstract
Digital image noise may be introduced during acquisition, transmission, or processing and affects readability and image processing effectiveness. The accuracy of established image processing techniques, such as segmentation, recognition, and edge detection, is adversely impacted by noise. There exists an extensive body of work which focuses on circumventing such issues through digital image enhancement and noise reduction, but this work is limited by a number of constraints including the application of non-adaptive parameters, potential loss of edge detail information, and (with supervised approaches) a requirement for clean, labeled, training data. This paper, developed on the principle of Noise2Void, presents a new unsupervised learning approach incorporating a pseudo-siamese network. Our method enables image denoising without the need for clean images or paired noise images, instead requiring only noise images. Two independent branches of the network utilize different filling strategies, namely zero filling and adjacent pixel filling. Then, the network employs a loss function to improve the similarity of the results in the two branches. We also modify the Efficient Channel Attention module to extract more diverse features and improve performance on the basis of global average pooling. Experimental results show that compared with traditional methods, the pseudo-siamese network has a greater improvement on the ADNI dataset in terms of quantitative and qualitative evaluation. Our method therefore has practical utility in cases where clean images are difficult to obtain.
Highlights
Vision is an indispensable way for humans to obtain information and gain basic cognition and understanding of the world
In the field of image denoising, the commonly used quantitative evaluation is the peak signal-to-noise ratio (PSNR), which calculates the degree of distortion between a denoised image p and a clean image q
PSNR is the ratio between the maximum possible power of a signal and the power of corrupted noise that affects the fidelity of its representation [53, 54]
Summary
Vision is an indispensable way for humans to obtain information and gain basic cognition and understanding of the world. The manual processing of large-scale image datasets is both time-consuming and laborious. Efficiencies can be achieved through utilization of machine vision methods (for example, via automated monitoring, object/scene identification, and segmentation), but image quality is a key factor in machine vision performance. In clinical medicine, medical imaging has become an important auxiliary tool for physicians. Highquality medical images can provide clear organ tissue and function information and improve the efficiency and accuracy of diagnosis and treatment. The image is inevitably injected with different concentrations and distribution of noise during the process of generation, storage, transmission, and application. The edges and characteristic information of the image are covered or blurred, resulting in the deterioration of the image quality, which does not meet the actual application requirements in production and scientific research
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