Multi-Layer Deep Sparse Representation for Biological Slice Image Inpainting

• Published in: Computers, materials & continua Vol. 76; no. 3; pp. 3813 - 3832
• Main Authors: Hu, Haitao, Ma, Hongmei, Mei, Shuli
• Format: Journal Article
• Language: English
• Published: Henderson Tech Science Press 2023
• Subjects: Algorithms; Artificial neural networks; Complexity; Computed tomography; Dictionaries; Image reconstruction; Magnetic resonance imaging; Multilayers; Partial differential equations; Representations; Singular value decomposition
• ISSN: 1546-2226; 1546-2218; 1546-2226
• DOI: 10.32604/cmc.2023.041416

Biological slices are an effective tool for studying the physiological structure and evolution mechanism of biological systems. However, due to the complexity of preparation technology and the presence of many uncontrollable factors during the preparation processing, leads to problems such as difficulty in preparing slice images and breakage of slice images. Therefore, we proposed a biological slice image small-scale corruption inpainting algorithm with interpretability based on multi-layer deep sparse representation, achieving the high-fidelity reconstruction of slice images. We further discussed the relationship between deep convolutional neural networks and sparse representation, ensuring the high-fidelity characteristic of the algorithm first. A novel deep wavelet dictionary is proposed that can better obtain image prior and possess learnable feature. And multi-layer deep sparse representation is used to implement dictionary learning, acquiring better signal expression. Compared with methods such as NLABH, Shearlet, Partial Differential Equation (PDE), K-Singular Value Decomposition (K-SVD), Convolutional Sparse Coding, and Deep Image Prior, the proposed algorithm has better subjective reconstruction and objective evaluation with small-scale image data, which realized high-fidelity inpainting, under the condition of small-scale image data. And the -level time complexity makes the proposed algorithm practical. The proposed algorithm can be effectively extended to other cross-sectional image inpainting problems, such as magnetic resonance images, and computed tomography images.